JPH08314572A - Electronic device provided with active noise control system - Google Patents

Abstract

PURPOSE: To efficiently control noise by providing plural discharge ducts indepen dent from each other and arranging the discharge ducts in the relation of not overlapping the vertical and horizontal projects of their discharge port, so as to prevent noise from creeping from another system. CONSTITUTION: The plural discharge ducts independent from each other 1 and 1' are provided. A noise detection sensor 10 is fixed to the inlet side of the discharge duct 1 and an error detection sensor 11 is fixt to the outlet side of the discharge duct 1. In addition, to the discharge duct 1', a noise detection sensor 10' and an error detection sensor 11' are fixed like the discharge duct 1. Then the respective discharge ducts 1 and 1' are arranged so as not to overlap the vertical and horizontal projects of the discharge ports by the noise detection sensors 10 and 10' and the error detection sensors 11 and 11'. Thereby, noise is efficiently controlled lest the noise of discharged air mutually influence the other discharge duct.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic device having an active noise control system. Large electronic devices, which generate a large amount of heat, are equipped with air-cooling fans and exhaust ducts for forced cooling, but the noise generated by the cooling air is radiated to the outside from the exhaust ducts. Therefore, it is necessary to configure electronic devices so that noise is reduced.

[0002]

2. Description of the Related Art FIG. 11 shows a conventional electronic device. Figure 11
11A is a front view, and FIG. 11B is a side view.

In FIG. 11, reference numeral 300 is an electronic device. 301, 302, 303, 304, 305, 306
Is a fan that forcibly creates an air flow for cooling.

Reference numeral 307 is an exhaust duct for exhausting air that has cooled the electronic equipment. Reference numeral 310 is an electronic device storage section.

Reference numeral 311 is an intake duct for taking in air to the electronic equipment housing. Reference numeral 312 denotes the air filter 1, which filters the air entering the electronic device housing 310.

Reference numeral 313 is an oriami, which is the intake duct 3
This is to prevent dust from being sucked into the inside 11.
Reference numeral 314 is an air filter 2 for filtering the cooling air entering the power supply device 315.

Reference numeral 316 is a looper. 320 is a support base. In the configuration of FIG. 11, fans 301 to 304 forcibly generate an air flow, and cooling air flows in from the lower part of the intake duct 311 to cool the electronic device housed in the electronic device housing portion 310. The air heated by cooling the electronic device is forcedly exhausted from the exhaust duct 307 by the fans 301 to 306.

The electronic device 300 shown in FIG. 11 has a fan 3
The noise based on the air flow generated by 01 to 306 was radiated to the outside from the exhaust duct 307. Therefore, sound absorbing materials were installed inside the exhaust duct and intake duct to reduce noise. However, the frequency of noise that can be reduced by the sound absorbing material is as high as about 1 KHz and lower frequencies can be reduced. There wasn't. Therefore, for noise of about 1 KHz or less, an active noise control system is provided, and a speaker is provided at the outlet of the exhaust duct so that a noise having a phase opposite to that of the noise is passed to reduce the noise.

FIG. 12 shows a conventional active noise control system. In FIG. 12, 330 is an exhaust duct.

Reference numeral 331 is a fan. Reference numeral 332 is a noise detection sensor, which is a microphone (hereinafter referred to as a microphone) that detects noise on the inlet side of the exhaust duct 330.

An error detection sensor 333 is a microphone for detecting noise on the outlet side of the exhaust duct. Reference numeral 334 denotes a secondary sound source, which is a speaker, which produces a noise canceling noise at the outlet of the exhaust duct 330.

Reference numeral 335 denotes a feedback suppression filter, which eliminates the noise generated from the secondary sound source 334 and detects the noise.
It cancels the components returned to. A noise control filter 336 is a noise control filter for eliminating noise.

Reference numeral 338 is an error scattering filter that simulates the characteristics between the erased sound generated by the secondary sound source 334 and the error detection sensor 333. Reference numeral 339 is a weight control unit.

Reference numeral 340 is an M-sequence signal source. In the above configuration, the weight update of the noise control filter 336 is performed by, for example, H _{n + 1} (m) = H _n (m) + K {Σ _n [E _j Y _j (m)]} for the m-th tap. / Σ _n [Σ Y _j ² × (i)] ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ (1) where Σ _n is j = n ( N + 13) +1 to n (N + 1
3) Shows cumulative addition up to + N. The other two filter coefficients are learned in advance by the M-sequence signal provided in ANCS.

By adjusting the step gain K in the configuration of FIG. 12, the noise output from the exhaust duct 330 can be reduced.

[0016]

In an active noise control system having a plurality of ducts, consideration is given to the influence of the sounds generated by the fans of other ducts and the secondary sound source (speaker) wrapping around in its own duct. There is a need. There is also a method of designing a filter in consideration of the influence, but it is not possible to complete it, so it is better to eliminate the sneak from the fan and speaker of other ducts as much as possible.

FIG. 13 is an explanatory diagram of a problem to be solved by the invention. FIG. 13A shows how the sound generated by each fan and each speaker is transmitted to each sensor when there are two fans and two ducts.

FIG. 13B shows, among the sound transmission paths shown in FIG. 13A, the sound paths that need to shield the mutual influences on the other ducts to eliminate mutual interference. FIG. 13 (A),
In FIG. 13 (B), reference numeral 350 denotes a fan 1, which sends air to the duct 1 (353).

Reference numeral 351 is a fan 2, which includes a duct 2 (3
54) to send air. Reference numeral 353 is the duct 1. Reference numeral 354 is the duct 2.

Reference numeral 355 is a speaker 1, which is a duct 1
It is the secondary sound source of (353). A speaker 2 is a secondary sound source of the duct 2 (354). Reference numeral 357 denotes the microphone 1, which is a noise detection sensor for the duct 1 (353). Reference numeral 358 denotes a microphone 2 and duct 1 (35
It is the error detection sensor of 3). The microphone 359 is a noise detection sensor for the duct 2 (354). Three
Reference numeral 60 denotes a microphone 4, which is an error detection sensor for the duct 2 (354).

The duct 1 (35 of the system of FIG. 13A)
Focusing on the system of 3), the power of the own system is represented by P, the power due to the wraparound from the sound source of the other system is represented by ΣP _E , and P _{S / N} = P _E / ΣP _E , Applied to active noise control systems.

In the coherence function h (f), h (f) = g _er1 / g _SNS1 g _er1 is the gain of the microphone 2 (358) (error sensor) at the frequency f.

G _SNS1 is the microphone 1 (35
7) Gain of (noise detection sensor). Where h
(F) A section expression (distance between the microphone 1 (357) and the microphone 2 (358)) is performed with a numerical value of ≧ 1.

H (f) = 1 is a state in which noise is ideally eliminated. Therefore, letting Δer1 and Δsns1 be wraparound components from other systems of the respective gains, h (f) = [g _er1 + Δer1] / [g _SNS1 + Δsns1]
1] In general, Δer1 ≠ Δsns1, and h
(F) deteriorates to a value smaller than 1.

The deterioration of the coherence function cannot be correctly identified between a given transfer system and two points of the microphone 1 (357) and the microphone 2 (358). Therefore, the speaker 1 (355) (erasing speaker) In (), it is not possible to generate G _j having the same sound pressure level and the opposite phase to the original target noise, and the noise reduction is significantly deteriorated.

Therefore, it is necessary for active noise control to prevent such wraparound. Therefore, FIG. 13 (A)
Refer to to analyze the noise transmission path in the exhaust duct.

In FIG. 13 (A), (a) shows the speaker 1.
This is the path of the sound of (355) that is detected by the microphone 3 (359) by flowing into the duct 2 (354).

(B) is a path of the sound of the speaker 1 (355) detected by the microphone 1 (357). (c) is a path of the sound from the speaker 1 (355) that is detected by the microphone 4 (360) by flowing into the duct 2 (354).

(D) is the path of the sound from the speaker 1 (355) detected by the microphone 2 (358). (e) is a path of the sound of the speaker 2 (356) that is detected by the microphone 4 (360) by flowing into the duct 1 (353).

(F) is a path of the sound of the speaker 2 (356) detected by the microphone 3 (359). (g) is a path of the sound of the speaker 2 (356) detected by the microphone 4 (360).

(H) shows a route in which the sound of the speaker 2 (356) is circulated to the duct 1 (353) and detected by the microphone 2 (358). (j) is a path through which the sound of the fan 1 (350) is transmitted to the microphone 2 (358).

In (k), the sound of the fan 2 (351) is the microphone 4
This is the route transmitted to (360). (l) is fan 1
It is a path through which the sound of (350) is transmitted to the microphone 1 (357).

In (m), the sound of the fan 2 (351) is the microphone 3
This is the route transmitted to (359). (n) is fan 1
It is a path through which the sound of (350) travels outside the duct 1 (353) and is transmitted to the microphone 2 (358).

In (o), the sound of the fan 2 (351) is the duct 2
It is a path that travels outside (354) and is transmitted to the microphone 4 (360). 13 (A), (j), (l),
Since (k) and (m) are original noise countermeasures, they are not wraparound sounds. Since (d) and (g) are secondary sound sources, they are not wraparound sounds.

Then, when the routes in which the wraparound is a problem are sorted out, it becomes as shown in FIG. 13 (B), and (a), (f), (c),
Only (h), (n) and (o) need be considered. It is an object of the present invention to provide an electronic device having an active noise control system capable of preventing noise from sneaking in from another system and performing noise control with high efficiency.

[0036]

Based on the above analysis, the present invention has a plurality of exhaust ducts which are independent of each other in order to prevent the sound from flowing around as shown in FIG.
The exhaust port is arranged so that the vertical and horizontal projections do not overlap (claim 1). Alternatively, a plurality of exhaust ducts and a plurality of fan accommodating parts are provided, and one exhaust duct and one fan accommodating part are set as one set to have one exhaust path, so that the plurality of exhaust paths are independent from each other. (Claim 2).

FIG. 1 shows a basic configuration (1) of the present invention, and shows a positional relationship between an exhaust duct and an intake duct. FIG. 1 shows the case of two exhaust ducts as an example. Figure 1 (A) is a front view, (B) is a side view, (C) is a top view, and (D) is a perspective view.

In FIGS. 1A, 1B, 1C and 1D, 1
Is the exhaust duct 1. 2 is an exhaust duct 2.

A suction port 3 is a fan (not shown)
The air sent from is taken into the exhaust duct. Reference numeral 10 denotes a sensor 1, which is a noise detection sensor placed on the inlet side of the exhaust duct 1 (1).

Reference numeral 11 is a sensor 2, which is an exhaust duct 1
It is an error detection sensor placed on the exit side of (1). 1
A speaker 1 is a secondary sound source of the exhaust duct 1 (1).

Reference numeral 10 'is a sensor 1', which is a noise detecting sensor placed on the inlet side of the exhaust duct 2 (1 ').
Reference numeral 11 'denotes a sensor 2', which is an error detection sensor placed on the outlet side of the exhaust duct 2 (1 ').

Reference numeral 12 'is a speaker 2', which is a secondary sound source of the exhaust duct 2 (1 '). By arranging multiple exhaust ducts so that the vertical and horizontal projections of their exhaust ports do not overlap as shown in the figure, it is possible to prevent the noise of the exhausted air from affecting each other's exhaust ducts. . The arrangement shown in FIG. 1 can also be applied to the intake duct. By doing so, active noise control can be effectively performed.

FIG. 2 shows the basic configuration (2) of the present invention,
The case of one fan housing and two exhaust ducts will be described as an example. In FIG. 2, 1 is an exhaust duct 1.

Reference numeral 1'denotes an exhaust duct 2. 2 is an exhaust port. 3'is an intake port.

Reference numeral 10 is a sensor 1. Reference numeral 11 is the sensor 2. Reference numeral 12 is the speaker 1.

10 'is the sensor 1'. 11 'is a sensor 2'. Reference numeral 12 'is the speaker 2.

Reference numeral 20 denotes a divided member, which is the exhaust duct 1
The system (1) and the fan storage unit 1 (21) are separated from the system of the exhaust duct 2 (1 ') and the fan storage unit 2 (21') so as not to interfere with noise.

Reference numeral 21 denotes a fan housing portion 2, which is a fan housing portion on the exhaust duct 1 (1) side. Reference numeral 21 'denotes a fan housing portion 2, which is a fan housing portion on the exhaust duct 2 (1') side.

The basic configuration (2) of the present invention is the exhaust duct 1
The system 1 of (1) and the fan storage unit 1 (21) and the system 2 of the exhaust duct 2 (1 ') and the fan storage unit 2 (21') are divided by the dividing member 20 so that the fan sound is transmitted to other systems. I tried not to interfere. Therefore, fan 1 of system 1
The noise of (21) does not enter the system 2 and
The noise of the fan 2 (21 ′) of 1 does not enter the system 1 and the active noise control system can be operated correctly.

FIG. 3 shows the basic configuration (3) of the present invention, in which noise is prevented from sneaking in from the electronic equipment housing portion. 3A is a conceptual diagram, FIG. 3B is a top view, and FIG.
(C) is a partially enlarged view.

In FIG. 3 (A), FIG. 3 (B), and FIG. 3 (C), reference numeral 21 is a fan housing section 1. Reference numeral 21 'is the fan storage unit 2.

22 is a fan 1. 22 'is fan 2
Is. Reference numeral 20 denotes a split member, which is an electronic device storage unit 1
(30) and the electronic device storage 2 (30 ') are separated.

Reference numeral 30 designates an electronic equipment housing 1 for housing electronic equipment such as a printed circuit board. Reference numeral 30 ′ is the electronic device storage section 2.

Reference numeral 31 is the intake duct 1. 31 'is the intake duct 2. Reference numeral 32 denotes a sealing member, which surrounds the electronic device storage 1 (30) and the electronic device storage 2 (3
0 ') is covered and hermetically sealed, and the electronic device storage 1 (3
It is intended to prevent noise generated from 0) from sneaking into other systems, and noise of other systems from sneaking into itself.

Reference numeral 33 denotes a protrusion of the sealing member, which is fitted into the groove 35 of the fixing member 34 of the sealing member to fix the sealing member. Reference numeral 34 denotes a fixing member for the sealing member, which fixes the sealing member 32 by being fixed to the pillar of the electronic device housing 1 (30) and the electronic device housing 2 (30 ').

Reference numeral 35 denotes a groove of the fixing member 34 of the sealing member, which fits and fixes the projection 33 of the sealing member 32. The basic configuration (3) of the present invention is to seal the periphery of the electronic device housing 1 (30) and the electronic device housing 2 (30 ′) with a sealing member, and to divide the electronic device housing 1 (30) with the dividing member 20. 30) and the electronic device housing 2 (30 ') are separated and independent from each other so that the noise generated by each electronic device and the noise generated by the fan of each system do not affect each other. It is a thing.

FIG. 4 shows the basic configuration (4) of the present invention. The sound generated by the fan is also transmitted to the intake duct side, reflected on the floor surface, and enters the other system. Therefore, it is necessary to prevent noise from affecting each other on the inlet side of the intake duct. The basic configuration (4) of the present invention prevents noises from affecting each other by the intake port of the intake duct.

FIG. 4A is a top view of the intake duct,
FIG. 4B is a front view and FIG. 4C is a side view. FIG. 4D is an enlarged sectional view of the intake port dividing member.
In FIGS. 4 (A), (B), (C), and (D), 210
Is a sensor 1 and is a microphone for error detection.

Reference numeral 211 denotes the sensor 2, which is a microphone for noise detection. The speaker 12 is a secondary sound source of the intake duct 1 (31). Reference numeral 211 'is a sensor 1', which is a microphone for error detection.

Reference numeral 213 'is a sensor 2', which is a noise detecting microphone. Reference numeral 212 'denotes a speaker 2, which is a secondary sound source of the intake duct 2 (31'). Reference numeral 31 is the intake duct 1.

31 'is the intake duct 2. Reference numeral 40 denotes a support, which supports the intake duct 1 and the intake duct 2. Reference numeral 41 denotes an intake port dividing member that divides the space between the intake duct 1 (31), the intake duct 2 (31 ') and the floor.

The intake port dividing member 41 is composed of sound absorbing intake port dividing member support members 42 and 42 ', a support member 43 of the intake port dividing member, and a sound absorbing member 44 covering the surface of the support column 43. is there.

According to the basic configuration (4) of the present invention, the noise generated by the fan is reflected on the floor surface by the intake port dividing member 41 and enters the intake duct 1 (31) and the intake duct 2 (31 '). It is possible to prevent them from affecting each other.

The surface is covered with a sound absorbing member 44, and the sound absorbing support member (42, 42 ') is brought into contact with the floor and the contact portion with the intake duct to further improve the sound blocking effect. Can be higher.

It is possible to effectively reduce noise by constructing an electronic device by combining a plurality or all of the above basic configurations.

[0066]

According to the present invention, in an electronic equipment system having a plurality of ducts, the sound generated by the fan of another system (another exhaust path) and the secondary sound source (speaker) wraps around to its own system and enters the control system. It can be prevented from affecting. Therefore, an electronic device having an active noise control system that can perform noise control with high efficiency can be provided.

[0067]

EXAMPLE 1 FIG. 5 shows Example 1 of the present invention in which an exhaust duct or an intake duct is arranged. The respective embodiments of FIG. 5 show the case of an exhaust duct as an example.

FIG. 5A is a front view when three exhaust ducts are provided, and FIG. 5B is a perspective view of FIG. 5A.
FIG. 5C shows an embodiment in which there are four exhaust ducts, and shows only a front view.

FIG. 5D shows an embodiment in which there are five exhaust ducts, and shows only a front view. FIG. 5 (A),
In (B), (C), and (D), 51 is the exhaust duct 1
Is.

Reference numeral 52 is the exhaust duct 2. 53 is the exhaust duct 3. Reference numeral 54 is the exhaust duct 4.

Reference numeral 55 is the exhaust duct 5. FIG. 6 is a second embodiment of the present invention. FIG. 6 shows a case in which there are three exhaust duct systems, and the exhaust duct, fan storage section, electronic device storage section, and intake duct of each system are separated by a dividing member for each system.

In FIG. 6, reference numeral 51 is the exhaust duct 1. 52 is the exhaust duct 2.

Reference numeral 53 is the exhaust duct 3. Reference numeral 64 denotes a fan storage portion, which is a fan storage portion of the system of the exhaust duct 1 (51).

Reference numeral 65 denotes an electronic equipment housing portion, which is an electronic equipment housing portion of the system of the exhaust duct 1 (51) (electronic equipment (printed circuit board etc. arranged inside) is not shown. ).

Reference numeral 66 is a sealing member that seals the electronic equipment housing portion 65. 67 is an intake duct, which is an exhaust duct of the exhaust duct 1 (51) system. 6
Reference numeral 8 is a dividing member for separating the system of the exhaust duct 1 (51) and the system of the exhaust duct 2 (52).

Reference numeral 69 is a dividing member, which is the exhaust duct 2
The system of (52) and the system of the exhaust duct 3 (53) are separated. The exhaust duct 2 (52) system fan, fan storage section, electronic device storage section, and intake duct are also the exhaust duct 1
It is the same as the system 1 of (51). In addition, the exhaust duct 3 (5
The fan, fan housing, electronic device housing, and intake duct of the system 3) are also the same as those of the system 1 of the exhaust duct 1 (51).
The system 1 and the system 2 are separated by the dividing member 68, and the system 2 and the system 3 are separated by the dividing member 69.

Although not shown, in the configuration of FIG. 6, the space between the intake duct of the system 1 and the intake duct of the system 2 and the floor is partitioned by a partition member to separate the intake duct of the system 2 and the system 3 from each other. If the space between the intake duct and the floor surface is also partitioned by dividing members, it is possible to more completely prevent the sound from flowing between the systems.

FIG. 7 shows a third embodiment of the present invention, showing the construction of an exhaust duct and a fan housing. FIG. 7 shows a case in which there are four exhaust duct systems, and each exhaust duct and fan housing are separated by a dividing member.

In FIG. 7, 51 is the exhaust duct 1. 52 is the exhaust duct 2.

Reference numeral 53 is the exhaust duct 3. Reference numeral 54 is the exhaust duct 4. Reference numeral 71 denotes the fan storage unit 1, which is a fan storage unit of the system of the exhaust duct 1 (51).

Reference numeral 72 denotes a fan storage portion 2 which is a fan storage portion of the system of the exhaust duct 2 (52). Reference numeral 73 denotes a fan storage portion 3 which is a fan storage portion of the system of the exhaust duct 3 (53).

Reference numeral 74 is a fan housing portion 4, which is a fan housing portion of the system of the exhaust duct 4 (54). Reference numeral 81 denotes the exhaust port 1, which is the exhaust port of the exhaust duct 1 (51).

Reference numeral 82 denotes the exhaust port 2 and the exhaust duct 2
It is the exhaust port of (52). Reference numeral 83 denotes the exhaust port 3, which is the exhaust port of the exhaust duct 3 (53). Reference numeral 84 denotes the exhaust port 4, which is the exhaust port of the exhaust duct 4 (54).

Reference numeral 91 is an intake port 1, which is a fan storage unit 1.
It is the intake port of (71). 100 is a dividing member,
The system of the exhaust duct 1, the system of the exhaust duct 2 and the system of the exhaust duct 3 and the system of the exhaust duct 4 are separated. Figure 7
In (A), the separation member is not shown. The exhaust duct 1 (51) and the exhaust duct 2 (52) are also separated. Exhaust duct 3 (53) and exhaust duct 4 (5
It is also separated during 4). Similarly, the fan storage unit 1
The (71) and the fan housing 2 (72) are also separated. Fan storage part 3 (73) and fan storage part 4 (74)
Is also separated.

Therefore, the systems of the exhaust ducts and the fan housings are all separated from each other. In FIG. 7, each exhaust duct is provided with a noise detection sensor (microphone), an error detection sensor (microphone), and a secondary sound source (speaker), but they are not shown.

FIG. 8 shows a fourth embodiment of the present invention. FIG. 8 shows a fan housing portion, an electronic equipment housing portion, an air intake duct, and an air inlet dividing member, and is a portion on which the third embodiment of the present invention shown in FIG. 7 is mounted (the fan housing portion is common to FIGS. 7 and 8). ).

In FIG. 8, reference numeral 71 is a fan housing section 1. Reference numeral 72 denotes the fan storage unit 2.

Reference numeral 73 is a fan housing section 3. 74 is a fan storage unit 4. Each fan storage part is divided into 1 (1
00) and the dividing member 2 (101).

Reference numeral 110 denotes an electronic equipment storage section. The electronic device housing 110 is divided into four independent sections by the electronic device mounting plates 115 and 116 and the dividing member 1 (100). The part connected to the fan storage part 1 (71) is system 1, the part connected to the fan storage part 2 (72) is system 2, the part connected to the fan storage part 3 (73) is system 3, fan storage part 4 (74). The connected part is system 4. A filter for active noise control is provided in the electronic equipment storage section.

Reference numeral 121 is the intake duct 1. 122 is the intake duct 2. Reference numeral 123 is the intake duct 3.

Reference numeral 124 is the intake duct 4. Each intake duct is separated by a dividing member 1 (100) and a dividing member 2 (101).

Reference numeral 130 denotes an intake port dividing member which separates the intake ports of the intake ducts (121, 122, 123, 124). 131 is a support stand.

In the configuration of FIG. 8, the intake duct 1 (12
The air taken in 1) cools the electronic equipment of the system 1, passes through the electronic equipment housing portion, and enters from the fan housing portion 1 (71). Then, the air discharged from the fan housing portion 1 enters the exhaust duct 1 and exits from the exhaust port (see FIG. 7 for the exhaust duct).

Similarly, the air taken into the intake duct 2 (122) is used for storing the electronic equipment and the fan 2 in the system 2.
Pass (72). And the exhaust duct 2 (122)
Enter and exit through the exhaust port (see Fig. 7 for exhaust duct). Similarly, the air that has entered from the intake duct 3 (123) is also used for storing the electronic device and fan of the system 3 (7).
3) and goes out from the exhaust duct 3 (see FIG. 7 for the exhaust duct). Also, the intake duct 4 (124)
Similarly, the air that has entered from the device also passes through the electronic device housing portion and the fan housing portion 4 (74) of the system 4 and exits from the exhaust duct 4 (see FIG. 7 for the exhaust duct).

FIG. 9 shows the fifth embodiment of the present invention and is a detail of the electronic equipment housing portion of FIG. In FIG. 9, reference numeral 100 is the dividing member 1.

Reference numeral 115 is an electronic device mounting plate. 14
Reference numeral 0 is a printed circuit board. 140 'is a connector to which a printed circuit board is attached.

Reference numeral 141 is a frame. Reference numeral 150 is a sealing member. Reference numeral 155 is a mounting member for the sealing member. The attachment member of the sealing member is fixed to the split member 1 (100) and each frame 141.

The electronic device housing is divided into four parts by the dividing member 1 (100) and the electronic device mounting plate 115, and the outside is covered with the sealing member 150, which is hermetically sealed so that sound does not leak outside. FIG. 10 is Embodiment 5 of the present invention and is a detail of the intake port dividing member of the intake duct of the embodiment of the present invention of FIG.

FIG. 10A is a plan view.
(B) is a front view. FIG. 10C is a perspective view of the intake port dividing member. In FIG. 10A, FIG. 10B, and FIG. 10C, 121 is the intake duct 1.

Reference numeral 122 is the intake duct 2. Reference numeral 123 is the intake duct 3. Reference numeral 124 is the intake duct 4.

Reference numeral 131 is a support base. Reference numeral 160 is an intake port. Reference numeral 171 is the intake port dividing member 1.

Reference numeral 172 is the intake port dividing member 2. 180
Is a pillar of the intake port dividing member. 181 is a sound absorbing member.

Reference numeral 182 denotes a support member for the intake port dividing member, which is composed of a sound absorbing member. Reference numeral 182 'denotes a support member for the intake port dividing member, which is composed of a sound absorbing member.

The intake port dividing member 1 (171) and the intake port dividing member 2 (172) are connected to the intake ducts (121, 12).
2, 123, 124) to divide the space between the intake port and the floor so that noises do not affect each other through the intake ducts.

[0105]

According to the present invention, in an electronic equipment system having a plurality of ducts, it is possible that the sound generated by the fan of another system and the secondary sound source (speaker) sneak into its own system and affect the control system. It can be prevented. Therefore, the noise reduction effect is not weakened by noise from other systems, and it becomes possible to perform noise control with high efficiency.

[Brief description of drawings]

FIG. 1 is a diagram showing a basic configuration (1) of the present invention.

FIG. 2 is a diagram showing a basic configuration (2) of the present invention.

FIG. 3 is a diagram showing a basic configuration (3) of the present invention.

FIG. 4 is a diagram showing a basic configuration (4) of the present invention.

FIG. 5 is a diagram showing a first embodiment (exhaust duct or intake duct) of the present invention.

FIG. 6 is a diagram showing a second embodiment of the present invention.

FIG. 7 is a diagram showing a third embodiment (exhaust duct) of the present invention.

FIG. 8 is a diagram showing a fourth embodiment (fan storage portion, electronic device storage portion, intake duct) of the present invention.

FIG. 9 is a diagram showing a fifth embodiment (electronic device storage section) of the present invention.

FIG. 10 is a diagram showing Embodiment 5 (intake duct, intake port dividing member) of the present invention.

FIG. 11 is a diagram showing a conventional electronic device.

FIG. 12 is a diagram showing a conventional active noise control system.

FIG. 13 is an explanatory diagram of a problem to be solved by the invention.

[Explanation of symbols]

 1: Exhaust duct 1 1 ': Exhaust duct 2 2: Exhaust port 3: Inlet port 10: Sensor 1 10': Sensor 1'11: Sensor 2 11 ': Sensor 2'12: Speaker 1 12': Speaker 2

Claims (8)

[Claims] 1. An electronic device having an active noise control system, comprising a plurality of exhaust ducts independent of each other, and having an arrangement relationship such that the vertical and horizontal projections of the exhaust ports do not overlap. An electronic device equipped with an active noise control system characterized by being present. 2. An air intake duct is provided, and the air intake duct is arranged so that projections of the air intake ports in the vertical direction and the horizontal direction do not overlap with each other.
An electronic device comprising the active noise control system according to. 3. An electronic device having an active noise control system, comprising a plurality of exhaust ducts and a plurality of fan storage parts, and one exhaust duct and one fan storage part as one set having one exhaust path. An electronic device equipped with an active noise control system, characterized in that a plurality of exhaust paths are independent of each other. 4. The electronic device having the active noise control system according to claim 3, wherein the vertical and horizontal projections of the exhaust ports of the plurality of exhaust ducts are arranged so as not to overlap each other. . 5. The electronic device storage section is divided into a plurality of compartments,
5. An electronic device having an active noise control system according to claim 3, wherein one exhaust duct, one fan storage section and one section of the electronic device storage section constitute one exhaust path. . 6. The active noise control system according to claim 5, wherein the partitioned electronic equipment storage section is provided with an independent exhaust path by covering the periphery of the electronic equipment storage section with a sealing member. Equipped electronic equipment. 7. A plurality of intake ducts independent of each other, one exhaust duct, one fan storage section, one electronic equipment storage section, and one intake duct.
4. An exhaust path is configured as one exhaust path.
An electronic device including the active noise control system according to 4, 5, or 6. 8. The air intake port of the air intake duct faces the floor surface, and a dividing member is provided in a space between the air intake duct and the floor surface so that the air entering the air intake duct does not affect each other. An electronic device comprising the active noise control system according to claim 7.