JP2018155940A - Silencer, cooling system and oa device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To realize a new interference type silencer.SOLUTION: The silencer is a silencer for muffling the noise due to a noise source 3 provided inside a pipe conduit 1 having at least one of a portion 8 where the pipe conduit cross-sectional area changes smoothly and a pipe conduit bent portion, along a flow passage through which the air flows, and the open side is a side branch type opened on the side of the pipe conduit 1, and is disposed at least one of the portion 8 where the pipe conduit cross-sectional area changes smoothly and the pipe conduit bent portion between the noise source 3 of the pipe conduit 1 and an open end 5 of the pipe conduit 1.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a silencer, a cooling device, and OA equipment.

A facsimile machine, a printer, a copier, an image forming apparatus which is a composite device thereof, and an electronic device such as a computer are collectively referred to as “OA device” or simply “device” in this specification.
In general, an OA device has a portion that generates heat (hereinafter referred to as a “heat generating portion”) such as a motor or a light emitter. In order to suppress an increase in temperature inside the apparatus due to heat generated by the heat generating portion, a cooling apparatus that performs cooling with cooling air is generally provided.
The cooling air is circulated through the pipe for circulating the cooling air to “a portion where the heat is generated in the device or the vicinity thereof” for cooling. A cooling air circulation pipe (hereinafter also referred to as “duct”) is provided with a fan, and the cooling air is circulated in the pipe by the fan.
Both ends of the pipeline are open ends, the open end on the side where the cooling air is introduced is the “intake side open end”, and the open end on the side where the cooling air used for cooling is discharged is the “exhaust side open end” Call it.
In order to take in low-temperature air from the outside of the OA device, the intake-side open end is often opened outward from the device exterior (casing or cover member) of the OA device.
When the fan is driven to distribute the cooling air, the driving sound propagates through the cooling air flow passage and is diffused into the room from the open end on the intake side, which affects the indoor environment as noise. “Fan” becomes “noise source”.
Various silencers are known as means for reducing the external influence of noise generated in a duct by a noise source. Among them, side branch type silencers mute using sound wave interference. So no energy is required for mute. Conventionally, as the side branch type silencer, those disclosed in Patent Documents 1 and 2 are known.

  An object of the present invention is to realize a novel side-branch silencer.

  The silencer of the present invention is based on a noise source provided inside the pipe having at least one of a part where the pipe cross-sectional area changes smoothly and a pipe bending part along a flow path through which air flows. A silencer that silences noise, and is a side branch type with an open side opened to the pipeline side, and the pipeline cross-sectional area is smooth between the noise source of the pipeline and the open end of the pipeline It is arrange | positioned in at least one of the part which changes to the said, and the said pipe line bending part.

  According to the present invention, a novel side branch type silencer can be realized.

It is a figure which shows one example of a cooling mechanism explanatory. It is an external appearance perspective view of the cooling mechanism shown in FIG. It is a clear figure explaining the principle of silence by a side branch type silencer. In the example of the cooling mechanism described with reference to FIGS. 1 and 2, the fans 3 and 4 are rotationally driven, and the noise measured at the position of the intake port 5 is FFT-analyzed in a frequency range up to 2 k (Hz). It is a figure which shows the result of having performed. It is a figure which shows distribution of the sound pressure level in each distance which measured the inlet 5 of the duct 1 shown in FIG. 1, FIG. 2 from the reference | standard to the fan 3 side. It is a figure for demonstrating one Embodiment of a cooling device. It is a figure for demonstrating another embodiment of a cooling device. FIG. 8 is a diagram showing the result of FFT analysis up to a frequency of noise: 2 kHz when the fans 3 and 4 are rotated in the embodiment of FIG. 7. 4 is a graph showing a silencing effect of the side branch 18; It is a figure for demonstrating other embodiment of a cooling device. It is a perspective view which shows embodiment of FIG. FIG. 11 is a diagram illustrating a result of FFT analysis up to a noise frequency of 2 kHz when the fans 3 and 4 are rotated in the embodiment illustrated in FIG. 10. 3 is a graph showing a silencing effect of the side branch 19; It is a figure for demonstrating embodiment using the side branch. FIG. 4 is a block diagram showing an example of “adjustment means” for variably adjusting the length L3 of the side branch 21 in the tube axis direction. 1 is a diagram for describing one embodiment of an image forming apparatus as an example of an OA device. FIG. FIG. 17 is a diagram for conceptually explaining cooling of a heat pipe roller 201 mounted on the image forming apparatus of FIG. 16. An example is shown in which a fan is inserted in a pipe line and a side branch type silencer 19 or 21 is installed in order to cool a heat pipe roller portion in the image forming apparatus.

Hereinafter, embodiments will be described.
FIG. 1 illustrates an example of a cooling mechanism.
The cooling mechanism is a mechanism for cooling a portion 2 to be cooled of the heat generating portion (hereinafter simply referred to as “heat generating portion 2”) with cooling air.

  The cooling mechanism has a pipe line (duct) 1. The duct 1 has an intake side opening end 5 (hereinafter referred to as an intake port 5) at one end and an exhaust side opening end 6 (hereinafter referred to as an exhaust port 6) at the other end. The cooling air flow path leading to is formed. In the flow path, the heat generating part 2 is installed at the installation part indicated by reference numeral 7, the fan 3 is arranged on the side of the intake port 5 from the heat generating part 2, and the fan 4 is arranged on the side of the exhaust port 6 from the heat generating part 2. Is arranged. The fans 3 and 4 are driven to suck outside air from the intake port 5 as shown by the arrow, circulate the flow path in the duct to cool the heat generating part 2, and exhaust the absorbed heat as exhaust from the exhaust port 6. .

  Only one of the fans 3 and 4 may be provided depending on the amount of heat generated in the heat generating unit 2, the flow rate of the cooling air, and the required cooling temperature.

  In addition, the exhaust port 6 is opened toward the front side orthogonal to the drawing.

FIG. 2 shows an external perspective view of the cooling mechanism shown in FIG.
The heating unit 2 described with reference to FIG. 1 is an element necessary for the function of a device (for example, “OA device”) provided with a cooling mechanism. Therefore, “according to the original function of the OA device”. The layout is determined according to the “layout”. On the other hand, since the cooling mechanism is an auxiliary means for effectively functioning the functions of the OA equipment, the form and the arrangement state are adjusted so as not to disturb the original layout of the OA equipment.

For this reason, as for the form of the duct 1, a pipe line is bent or the cross-sectional area of a pipe line is not uniform like the example shown in FIG. 1, FIG. For example, in FIG. 1, the intake port 5 is positioned higher than the heat generating portion 2 so that the original layout of the AO device is not hindered, and the size of the intake port 5 is smaller than the size of the fan 3. For this reason, in the part shown with the code | symbol 8, the duct of the duct 1 is bent and the cross-sectional area is also reducing smoothly toward the inlet side.
The heat generating portion 2 is cylindrical, and the pipe shape of the portion of the installation portion 7 where the heat generating portion 2 is installed is also cylindrical.

  When the fans 3 and 4 are driven, the drive sound propagates through the flow path of the duct 1 and is dissipated as noise from the intake port 5 and the exhaust port 6. In the following, the silencing of noise diffused from the intake port 5 will be mainly described.

The silencer of the present invention is a “side branch type”.
FIG. 3 is an explanatory diagram for explaining the principle of silencing by a side branch type silencer.
The sound from the sound source 12 (including the sound to be muted) propagates through the duct 9 to the right. The pipe line 9 is referred to as “main pipe 9”. Both ends of the main pipe 9 are opened to form an opening, and the sound source 12 is disposed in one opening. In the other opening 11, “noise is dissipated”.

A side-branch silencer 10 is provided between the sound source 12 and the opening 11 of the main pipe 9. The muffler 10 has a “cylindrical shape in which one end is open and the other end is closed”, and the open portion is provided so as to match a hole formed in the tube wall of the main pipe 9.
That is, the silencer 10 is a branch pipe (side branch) in which the main pipe 9 is “branched”. Therefore, in the following description, the side branch type silencer is also simply referred to as “side branch”.
The side branch 10 shown in FIG. 3 has a uniform cross-sectional area and is a so-called “straight tube type”.
Of the sound waves propagating through the main pipe 9 to the right in the figure, the wavelength of the sound to be silenced is “λ”. That is, it is a sound having a frequency of ν (= V / λ) where the sound speed is “V”.
When the sound wave propagating through the main tube 9 enters the side branch 10, it is reflected by the closed surface of the side branch 10 and returned to the main tube 9, and overlaps the sound (sound wave) that travels through the main tube 9 toward the opening 11.
When the length of the side branch 10 is set to λ / 4 with respect to the “sound of wavelength: λ” to be silenced, the sound that enters the side branch 10 and returns to the main tube 9 passes through the main tube 9 through the opening 11. Wavelength propagating to the side: delayed by “λ / 2” with respect to the sound of λ. The phase is 180 degrees.
That is, if the sound of wavelength: λ propagating from the sound source 12 through the main tube 9 is the sound 13 shown in FIG. 3, the sound returning from the side branch 10 to the main tube 9 becomes the sound 14 shown in FIG. The sound toward the opening 11 is a sound 15 in which the sound 13 and the sound 14 are superimposed.

If the amplitude of the sound 14 returning from the side branch 10 to the main pipe 9 is the same as the amplitude of the sound 13, the amplitude of the sound 15 becomes 0 due to the superposition of the sound 13 and the sound 14, and the sound 13 of the wavelength: λ is “completely muted. "
Actually, the sound 14 reflected from the side branch 10 is weaker than the sound 13, and the amplitude of the sound 15 obtained by synthesizing the sound 13 and the sound 14 is rarely completely zero.

  FIG. 4 shows the example of the cooling mechanism described above with reference to FIGS. 1 and 2, the fans 3 and 4 are rotationally driven, and the noise measured at the position of the intake port 5 is a frequency region up to 2 k (Hz). The result of having performed FFT analysis with respect to is shown.

In this example, the frequencies: 635 Hz, 823 Hz, and 845 Hz are conspicuous. These frequencies are “frequency obtained by multiplying the number of fan rotations of the fan and the number of fan blades”, and are referred to as fan wind noise.
The frequency of the fundamental wave of the wind noise of the fan 3 is 634 Hz (= 126.8 × 5) because the rotational speed of the motor is 126.8 rps and the number of blades is 5.
Fan 4 “installs two fans in parallel” and supplies the same voltage, but because the shape of pipe 1 is complex, “air flow resistance” differs between the two fans, and there is a difference in fan motor speed. Has occurred. The rotation speeds of the two fan motors at this time are 164.6 rps and 169.0 rps, respectively, and the number of blades of the two fans 4 is 5, so that wind noises of frequencies: 823 Hz and 845 Hz are generated, respectively. .

  FIG. 5 is a diagram showing the distribution of the sound pressure level at each distance measured along the flow path from the inlet 5 of the duct 1 shown in FIGS. 1 and 2 to the fan 3 side. With respect to the distance on the horizontal axis, the position of the intake port 5 is set as a reference (0 mm), the distance to the fan side is set as the “− side”, and a microphone is installed at each position.

Although the position of the fan 3 is “−160 mm” from the intake port 5, since it cannot be measured by contacting the fan 3 rotating the microphone, it is 5 mm away from the fan 3 toward the intake port 5. Measurement was performed with a microphone installed at the position (= -155 mm).
AP of the sound pressure level of the measurement data (all pass: the value obtained by leveling and calculating the average total power (effective value) directly without frequency analysis of the output signal) and 635 Hz of the result of frequency analysis of the measurement data The sound pressure level at 823 Hz was measured and plotted every 20 mm.
Note that the distribution of the sound pressure level in the pipe line can also be expressed by using a result of acoustic simulation with good accuracy instead of such measurement.

A side branch type silencer can generally achieve a “higher silencing effect” by installing it at a “position where the sound pressure level of the sound of the frequency to be reduced (silenced) is high”.
From this point of view, as shown in FIG. 5, the sound pressure level is high for both “AP, 634 Hz, and 823 Hz” at a position of 80 mm along the flow path from the air inlet 5 to the fan 3 side. Therefore, the “higher effect” can be expected by installing the side branch at this position (−80 mm position). At the position of −80 mm, the frequency: 823 Hz has a higher sound pressure level than the sound of the frequency: 634 Hz. Therefore, when the sound pressure of the frequency: 823 Hz is lowered, the sound pressure value of the AP can be expected to decrease.

In addition, the sound pressure of the sound of frequency: 823 Hz has almost the same level height in the range of −60 mm to −100 mm as shown in FIG. 5. Therefore, the side branch type silencer is
Even if it is arranged at an appropriate position in this region, an effective silencing effect can be expected.

Below, the case where a side branch type silencer is provided in the position of -80 mm along a flow path from the inlet port 5 to the fan side is demonstrated.
The frequency of the sound to be muted is 823 Hz.
Temperature: Sound velocity propagating through the air at T: V (m / Sec) is well known:
V = 331.5 + 0.6T
It is. Speed of sound: V depends on frequency: ν and wavelength: λ
V = λ ・ ν
Is given by
λ ・ ν = 336 + 0.6T
It becomes.
Assuming normal temperature (room temperature: 25 ° C.) as the air temperature from the fan 3 to the inlet 5 in the duct 1,
λ · ν = 331.5 + 0.6 × 25 = 331.5 + 15 = 346.5 m
It becomes.
ν = 823 Hz
Therefore, the wavelength: λ is
λ = 0.421m
It becomes.

Therefore, the length of the side branch type silencer (side branch) for silencing the sound of frequency: 823 Hz is:
λ / 4 = 0.421 / 4 = 0.1053 m = 105.3 mm
It becomes. It should be noted that the length of the side branch actually requires opening end correction.

FIG. 6 is an explanatory view showing one embodiment of the cooling device of the present invention.
This embodiment is a cooling device 1 in which a side branch type silencer 16 (hereinafter also referred to as a side branch 16) is provided in the duct 1 of the cooling mechanism described above with reference to FIGS. It is an example.

As an effective position to mute noise of 823 Hz, the “position 80 mm away from the inlet 5 toward the fan 3 side” obtained as described above is “the duct 1 is bent, The cross-sectional area is also a portion that smoothly decreases toward the intake port 5 side ”. The arrows in the figure indicate sound waves propagating in the duct 1 from the fan 3 toward the intake port 5 side.
Therefore, the side branch 16 is provided in “a portion indicated by reference numeral 8 (hereinafter, referred to as an arrangement portion 8 or an attachment portion 8)”. The length L shown in the figure is 105.3 mm calculated above.

  In this embodiment, the closed side of the side branch 16 is located so as to protrude from the surface of the intake port 5 by a distance A on the right side in the drawing. If the exterior surface of the AO device provided with the cooling device is the same surface as the intake port 5, the side branch 16 cannot be used.

FIG. 7 is a diagram showing another embodiment of the cooling device.
In this embodiment, there is a “spatial margin” below the duct 1, and the side branch 18 is disposed in this portion. In this embodiment, since the tube axis direction of the side branch 18 is parallel to the vertical direction in the figure, the closed end of the side branch 18 protrudes to the right from the surface of the intake port 5. However, the present invention can also be used in the case where the exterior surface of the AO device provided with the cooling device is the same surface as the intake port 5.
The length of the side branch 18 is the average value of distances L1 and L2 from the portion indicated by reference numeral 8 of the duct 1 (the portion where the opening of the side branch 18 is located) to the end on the closed side.
FIG. 8 shows the result of FFT analysis up to 2 kHz of noise frequency when the fans 3 and 4 are rotated in the embodiment of FIG.

  8 is compared with that in FIG. 4, the graph of “823 Hz, 845 Hz and surrounding sound pressure levels” in the case of the embodiment of FIG. 7 is the state of FIG. 4 (when the sound is not silenced by the side branch). It is lower than that. Since the silencing effect of the side branch 18 has a certain range of frequencies, the silencing effect can be exhibited even if the silencing frequency is slightly shifted.

  FIG. 9 is a graph showing the silencing effect of the side branch 18, and is the result of subtracting the graph of FIG. 8 from the graph of FIG.

As is clear from FIG. 9, “a silencing effect of up to about 14 dB with a peak at 829 Hz” is recognized.
FIG. 10 is a diagram for explaining another embodiment of the cooling device.
In this embodiment, the side branch 19 is disposed at a portion indicated by reference numeral 8 of the duct 1.
In the side branch 19, a closed side surface (hereinafter referred to as a closed portion) 20 of a closed tubular silencer is parallel to the mounting portion 8 in the duct (pipe) 1, and the “branch direction” of the side branch 19 is “(Axial direction of the closed tubular portion)” is inclined with respect to the pipe line in the attachment portion 8.

  The surface of the closing part 20 is parallel to the attachment part 8 in the duct 1. The length L1 of the side branch 19 in the tube axis direction is 1/4 (= 105.3 mm) of the wavelength of the sound to be silenced (wavelength: 823 Hz sound).

FIG. 11 is a perspective view showing a state in which the side branch 19 is installed in the pipeline 1.
FIG. 12 is a diagram showing “FFT analysis results” for a frequency range up to 2 kHz of noise frequency when the fans 3 and 4 are rotated in the embodiment described with reference to FIG. Compared with the graph of FIG. 8, “823 Hz, 845 Hz and surrounding sound pressure levels” are further lowered.

  FIG. 13 is a graph showing the silencing effect of the side branch 19, which is the result of subtracting the graph of FIG. 12 from the graph of FIG. It turns out that there is a silencing effect of about 18 dB at maximum with a frequency: 836 Hz as a peak.

  FIG. 14 is a view for explaining an embodiment using a side branch 21 as a side branch type silencer of the invention.

  The side branch 21 is configured by “two members of a base portion 22 and a closing portion 23”. The base portion 22 is fixedly disposed on the mounting portion 8 of the duct 1, and the closing portion 23 is fitted to the base portion 22 with high accuracy and is “slidable in the tube axis direction”. By this sliding, the “length in the tube axis direction: L3” of the side branch 21 which is a closed tubular silencer can be changed.

Thus, the frequency of the sound to be muted can be changed by changing the length L3 of the side branch 21 in the tube axis direction.
The number of rotations of the fan 3 and the fan 4 arranged in the pipe line 1 of the cooling device may change due to the deterioration of the fan drive mechanism over time, and even if the fan speed remains unchanged, the cooling in the pipe line The temperature of the air may change due to changes in the environmental temperature.
In such a case, the frequency of the noise to be silenced also varies, and if the length of the side branch in the tube axis direction is unchanged, the silencing effect varies.

  As in the side branch 21 of the embodiment of FIG. 14, if the length in the tube axis direction: L3 is variable, the length: L3 is adjusted even when the frequency of the noise to be silenced varies. Therefore, the best silencing effect can always be achieved. In FIG. 14, reference numeral 25 indicates “side branch length changing means” which will be described later.

  FIG. 15 is a block diagram showing an example of “adjustment means” for variably adjusting the length L3 in the tube axis direction of the side branch 21 that is a silencer.

The adjustment means includes noise frequency detection means 302 or fan motor rotation speed detection means 301, side branch length control means 24, and side branch length change means 25.
The noise detection means 302 is composed of, for example, a “small microphone and frequency analysis means”. A small microphone such as “a surface microphone made by B & K” “a thin type that is attached to the inner surface of the pipe 1” may not increase the air resistance in the pipe.

  As the fan motor rotation speed detection means 301, for example, a structure in which the actual rotation speed of the fan is “detected by a disk with a slit attached to the fan motor and a photo interrupter” can be used. If the number of rotations can be detected, the noise frequency (= number of fan blades × number of rotations (rps)) can be arithmetically determined as described above.

The noise frequency data detected by the noise frequency detection means 302 or the rotation speed data detected by the fan motor rotation speed detection means 301 is input to the side branch length control means 24 as an electrical signal. .
The side branch length control means 24 is configured as a CPU or a microcomputer, and determines the optimum value of the length L3 of the side branch 21 in the tube axis direction according to the input frequency or rotational speed data. Note that the relationship between the rotational speed of the fan motor, the wind noise frequency of the fan, and the optimum length L3 of the side branch 21 is experimentally determined in advance in consideration of opening correction, and the side branch length control unit 24 is obtained. Determines the length L3 of the side branch according to the input data.
Length determined by the side branch length control means 24: In accordance with the data of L3, the side branch length changing means 25 slides the closing portion 23 with respect to the base portion 22 in the tube axis direction and determines the determined length. : Realize L3.
The side branch length changing means 25 can be constituted by, for example, “a combination of a motor and a rack and pinion mechanism”, and controls the operation of the motor by a signal from the side branch length control means 24.
As another method, if the scale of the frequency is written or engraved on the side of the two members of the cylindrical portion connected to the base portion 22 and the closing portion 23, the length: It is also possible to adjust L3 according to the scale of the frequency to be silenced by “manual”. In the case of manual operation, when the length is finally determined, it may be fixed with a screw or the like.

  Hereinafter, an “image forming apparatus to which a side branch type silencer is applied” will be described as an embodiment of the OA device of the present invention.

FIG. 16 is a schematic configuration diagram of the image forming apparatus.
Reference numeral 100 denotes an image forming apparatus capable of forming (printing) a full-color image on paper P which is also a recording medium. The image forming apparatus 100 is hereinafter referred to as “printer 100”.
For the sake of simplicity, the paper reversing device (paper discharge reversing path) used for duplex printing is not shown.
The printer 100 mainly includes an apparatus main body 101, an operation / display control panel 102 provided above the apparatus main body 101, and the like.
In the upper part of the apparatus main body 101, laser scanning devices 110Y, 110M, 110C, respectively corresponding to four development colors of yellow (Y), magenta (M), cyan (C), and black (K) from the left side. 110K is disposed, and charging devices 111Y, 111M, 111C, and 111K, photosensitive drums 112Y, 112M, 112C, and 112K, developing devices 113Y, 113M, 113C, and 113K are disposed according to these.
Below the photosensitive drums 112Y, 112M, 112C, and 112K, an intermediate transfer belt 107 stretched around a plurality of stretching rollers is provided so as to contact each drum, and the photosensitive drum is interposed via the intermediate transfer belt 107. Primary transfer rollers 114Y, 114M, 114C, and 114K are provided at positions facing 112Y and the like, respectively.
Below the intermediate transfer belt 107, as a secondary transfer means (recording means) for transferring (recording) a color toner image onto the paper P, the intermediate transfer belt 107 stretched around the backup roller 103 and the “transfer nip portion” ”Is provided.

  In the lower part of the apparatus main body 101, a first paper feed cassette 105 for storing paper P and a second paper feed cassette 106 are arranged up and down, and paper according to information input from the control panel 102 or an external device. P is fed toward the upper “transfer nip portion”.

In the conveyance path 115 for guiding the sheet P fed from the sheet cassette to the sheet discharge tray 117 provided on the left side plate of the apparatus main body 101, the secondary transfer roller 104, A fixing device 108, a conveying device 200, and the like are provided in order.
When a print job is received (input) from the control panel 102 or an external device as a print execution instruction for a printed material having a plurality of pages and a plurality of copies, the printer 100 starts a printing operation (image forming operation).

  The printer 100 includes a main body control unit (not shown) that controls each device in the apparatus main body 101, the control panel 102, and the like, performs image processing, and exchanges (communications) information with external devices. The main body control unit includes a central processing unit (CPU), a volatile or nonvolatile memory, a driver that drives each device, an interface (I / F) that communicates with an external device, and the like. Yes.

Hereinafter, the process of the image forming operation will be described by taking as an example the case of forming a yellow (Y) image.
First, the photosensitive drum 112Y that is rotated by the charging device 111Y is uniformly charged, and then laser light corresponding to the image data is irradiated by the laser scanning device 110Y, and an electrostatic latent image of a Y-color image is formed on the photosensitive drum 112Y. Form an image.
Next, the developing device 113Y performs development by attaching yellow toner to the electrostatic latent image on the photosensitive drum 112Y to form a yellow toner image.
The toner image on the photosensitive drum 112Y is primarily transferred to the intermediate transfer belt 107 running in the direction of arrow B by the action of a high voltage applied to the primary transfer roller 114Y.
For the other colors (M, C, K), the same process is used to form toner images of the respective colors on the photosensitive drums 112M, 112C, 112K, and on the intermediate transfer belt 107 so that the toner images overlap. By transferring the toner image, a color toner image is formed.
The toner image formed on the intermediate transfer belt 107 is secondarily transferred onto the paper P conveyed in the direction of arrow A through the conveyance path 115 by the action of a high voltage applied to the secondary transfer roller 104.
The paper P on which the toner image has been transferred is fixed with the toner image by applying heat and pressure by the fixing device 108, and is then absorbed by the “heat pipe roller 201 that is a cooling means” of the conveying device 200, thereby conveying the belt. The sheet is conveyed to the discharge tray 117 via 210 and discharged.

  FIG. 17 is a diagram for conceptually explaining cooling of the heat pipe roller 201 mounted on the image forming apparatus of FIG.

  The heat pipe roller 201 includes a heat pipe 202 that is a heat absorbing portion that absorbs heat applied to the paper P by the fixing device 108, and a heat radiating fin 203 that is a heat radiating portion that radiates the heat of the heat pipe 202. The heat pipe roller 201 is also a cooling member that cools the paper P.

The paper P is transported downstream by the heat pipe roller 201 and the transport belt 210.
The heat pipe roller 201 is the “part corresponding to the heat generating portion 2” described above with reference to FIG. 6 and the like, and is installed in the installation portion 7 as shown in FIG. The fans 3 and 4 generate a cooling airflow that increases the heat dissipation efficiency from the heat dissipation fins 203 and lowers the temperature of the heat pipe roller 201.
Fans 3 and 4 are powerful fans and have high sound pressure levels. The noise generated by these fans is silenced by attaching the above-described side branch type silencer 16, 18, 19 or 21 (not shown in FIG. 17) to the duct.

  When the side branch 21 is used, the fan motor rotational speed detecting means 301 or the noise frequency detecting means 302 of the fan 3 and the fan 4 is provided, and as described above, the “length in the tube axis direction suitable for the noise frequency” is provided. "S: L3" is adjusted and set.

  FIG. 18 shows an example in which a side branch type silencer 19 or 21 is installed by inserting a fan in the pipe line in order to cool the heat pipe roller 201 in the image forming apparatus 100.

  The position of the intake port 5 of the duct 1 and the position of the heat pipe roller 201 are determined in relation to the arrangement of other components. Further, the size of the fan is determined in order to perform necessary cooling, and the shape of the pipe line 1 is determined in order to cool the heat pipe roller 201.

  Due to the positional relationship between the components, the cooling device provided with the side branch type silencers 16, 18, 19 and 21 which are space-saving and have a high noise reduction effect reduces the fan noise of the image forming apparatus and reduces noise during operation. Can be reduced.

  As described above, according to the present invention, the following silencer, cooling device, and OA device can be realized.

[1]
A noise source (1) provided inside the pipe (1) having at least one of a part where the pipe cross-sectional area changes smoothly along the flow path through which the air flows and the pipe bending part (8) ( 3. A silencer that silences noise caused by 3, 4), which is a side branch type with an open side opened to the pipeline side, and the noise source of the pipeline (1) and the open end (5, 6) of the pipeline. Muffler (16, 18, 19, 21) disposed in at least one of the portion where the pipe cross-sectional area changes smoothly and the pipe bending portion.

[2]
[1] The silencer according to [1], wherein a surface on the closed side opposite to the open side is parallel to the arrangement portion in the pipe line (16, 19, 21).

[3]
[2] The silencer according to [2], wherein the pipe axis direction is inclined with respect to the pipe line at the attachment position (8) to the pipe line.

[4]
The silencer according to [2] or [3], wherein the length in the tube axis direction is variable.

[5]
A pipe (1) that forms a flow path for circulating cooling air; fans (3, 4) that are provided in the pipe and that flow cooling air; and a silencer; 1) has an intake-side opening end (5) that sucks outside air into the cooling air and an exhaust-side opening end (6) that exhausts cooling air that contributes to cooling, and has a smooth cross-sectional area of the pipe line It has at least one of the part to change and the said pipe bending part (8), The said silencer is a thing of any one of [1] thru | or [4], Comprising: The said pipe (1) The cooling device provided in at least one of the fan, the portion where the cross-sectional area of the pipe line smoothly changes, and the bent portion of the pipe line between at least one of the intake side open end and the exhaust side open end (FIGS. 6, 7, 10, 11, and 14).

[6]
[5] The cooling device according to [5], wherein the silencer (21) according to [4] is used as the silencer, and includes an adjusting unit that variably adjusts the length L3 of the silencer in the tube axis direction. Cooling device (FIGS. 14 and 15).

[7]
It is OA equipment which has a part which generates heat inside, and is the OA equipment which uses the thing of Claim 5 or 6 as a cooling device which cools the part which generates heat (Drawing 16-Drawing 18).

The preferred embodiments of the present invention have been described above. However, the present invention is not limited to the specific embodiments described above, and the invention described in the claims unless otherwise specified in the above description. Various modifications and changes are possible within the scope of the above.
It goes without saying that the side branch type silencer is not limited to the “straight tube type” illustrated above, but can use a so-called “expansion branch” in which the diameter on the closed side is expanded.
The side branch 16 shown in FIG. 6, the side branch 18 shown in FIG. 7, the side branch 20 shown in FIG. 10, and the base 22 of the side branch 21 shown in FIG. However, it may be “formed integrally with the duct 1” as a part of the shape of the duct 1.

  The effects described in the embodiments of the present invention are merely a list of suitable effects resulting from the invention, and the effects of the present invention are not limited to those described in the embodiments.

1 pipeline (duct)
2 Heating part
3, 4 fans
5 Inlet side open end (inlet)
6 Exhaust side open end (exhaust port)
16, 18, 19, 21 Side branch type silencer (side branch)
100 Image forming equipment (AO equipment)

JP-A-8-156367 JP 2012-128230 A

Claims (7)

A silencer that silences noise caused by a noise source provided in the pipe having at least one of a part in which the pipe cross-sectional area changes smoothly and a pipe bending part along a flow path through which air flows. There,
A side branch type in which an open side is open to the pipe line side, and a part where the pipe cross-sectional area changes smoothly between the noise source of the pipe line and an open end of the pipe line, and the pipe bending part A silencer placed on at least one side. The muffler according to claim 1,
A silencer in which a surface on the closed side opposite to the open side is parallel to the arrangement portion in the pipe. The muffler according to claim 2,
A silencer in which a pipe axis direction is inclined with respect to the pipe line at a mounting position on the pipe line. The muffler according to claim 2 or 3,
A silencer having a variable length in the tube axis direction. A duct that forms a flow path through which the cooling air flows, a fan that is provided in the duct and distributes the cooling air, and a silencer,
The pipe has an intake-side opening end that sucks outside air and serves as the cooling air, and an exhaust-side opening end that discharges cooling air that contributes to cooling, and the pipe cross-sectional area changes smoothly, Having at least one of the conduit bend portion,
The silencer according to any one of claims 1 to 4, wherein at least one of the fan and the pipe line between the intake side open end and the exhaust side open end of the pipe line is provided. The cooling device provided in at least one of the part in which a cross-sectional area changes smoothly, and the said pipe line bending part. The cooling device according to claim 5,
A cooling device using the silencer according to claim 4 as the silencer, and comprising adjusting means for variably adjusting the length of the silencer in the tube axis direction. An OA device having a portion that generates heat inside,
The OA apparatus in which the thing of Claim 5 or 6 is used as a cooling device which cools the said heat-emitting part.

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