JP6165043B2 - Noise evaluation apparatus and noise evaluation method - Google Patents

Description

  The present invention relates to a noise evaluation apparatus and a noise evaluation method.

  In plant equipment such as a compressor and a steam turbine, the sound of a machine emitted from the plant equipment may become noise relative to the surroundings. Therefore, it is necessary to appropriately measure and grasp the noise level emitted from the plant equipment around the plant equipment.

  However, since the noise level measured around the plant equipment is affected by noise from the surrounding environment and noise generated from mechanical parts other than the plant equipment, this may cause measurement errors. Therefore, a measurement method and a measurement apparatus that accurately measure noise generated by the plant equipment itself are required. Examples of such a noise measurement method include an acoustic intensity method and an acoustic camera method that measure sound from a specific direction.

  As a noise measurement device, for example, Patent Document 1 discloses a measurement device using an evaluation point microphone to which a parabolic antenna is attached as a sound collector and a plurality of reference signal microphones. In this measuring apparatus, noise can be efficiently captured from a specific direction of interest by an evaluation point microphone to which a parabolic antenna is attached. In addition, this measuring apparatus measures the noise at a place where a reference microphone is installed in the background noise source when the background noise source where noise other than the noise from the target sound source is known to some extent. Thus, the noise from the background noise source other than the specific direction can be removed, and the noise from the target specific direction can be measured.

JP 2000-346757 A

  However, in the measuring apparatus as described above, of the noise emitted from other than the plant equipment that is the noise measurement object, the noise reflected by the plant equipment is also measured as the noise emitted by the plant equipment. Therefore, it cannot be said that the result measured by such a measuring device is sufficiently accurate as a result of measuring noise emitted from a single plant device. Moreover, in such a measuring apparatus, it is difficult to know what kind of noise countermeasure is effective in order to suppress the measured noise, and it is difficult to take an effective noise countermeasure. That is, there is a problem that it is difficult to acquire information on noise with high accuracy necessary for evaluation for taking effective noise countermeasures on the noise measurement object.

  The present invention has been made to solve the above-described problems, and a noise evaluation apparatus and a noise that can easily acquire information on highly accurate noise necessary for evaluating noise generated by a noise measurement object The purpose is to provide an evaluation method.

In order to solve the above problems, the present invention proposes the following means.
The noise evaluation apparatus according to the first aspect of the present invention is attached to a noise measurement object to be a noise measurement object, and covers a part of the outer surface of the noise measurement object to suppress the propagation of noise from the outside. A soundproof box that forms a measurement space; an internal noise measurement unit that is attached to the soundproof box and measures a noise level of noise in the measurement space as an internal noise level; and is attached to the soundproof box, A vibration measurement unit that measures vibration characteristics as a surface vibration value in the measurement space, an external noise measurement unit that measures a noise level of noise at a predetermined measurement position outside the soundproof box as an external noise level, and the internal A noise evaluation control unit that performs control processing related to noise evaluation based on a noise level, the surface vibration value, and the external noise level, and the noise evaluation control unit includes the external noise level. A first noise evaluation value calculation unit that calculates and outputs a ratio of the internal noise level to the noise as a first noise evaluation value; and a noise level of noise directly propagated from the outer surface based on the surface vibration value A theoretical noise level calculation unit that calculates the theoretical noise level; and a second noise evaluation value calculation unit that calculates and outputs a ratio of the internal noise level to the theoretical noise level as a second noise evaluation value.

According to the noise evaluation apparatus having such a configuration, noise from the surrounding environment outside the noise measurement object can be eliminated by the soundproof box. Therefore, the noise emitted from the noise measurement object can be measured with high accuracy by the internal noise measurement unit.
Further, by measuring the external noise level, it is possible to measure the noise generated from the noise measurement object including the noise from the surrounding environment. Then, the first noise evaluation value calculation unit can acquire highly accurate information indicating how much the noise measured at the measurement position is affected by the noise emitted from the noise measurement object.
Furthermore, by measuring the surface vibration value, it is possible to measure the vibration of the outer surface corresponding to the noise measured by the internal noise measuring unit. Then, the second noise evaluation value calculation unit calculates the ratio between the theoretical noise level and the internal noise level as the second noise evaluation value, and is actually measured as the noise level theoretically generated from the vibration of the outer surface. The noise level can be compared. Therefore, it is possible to acquire information on whether or not the noise level of the noise emitted from the noise measurement object and actually measured is close to the theoretical noise level. Therefore, it is possible to acquire highly accurate information indicating the ease of conversion of the vibration of the outer surface of the noise measurement object into noise.

  The noise evaluation apparatus according to another aspect of the present invention includes a sound absorbing member provided inside the soundproof box and having a predetermined sound absorption coefficient, and the noise evaluation control unit includes the shape of the soundproof box and the sound absorbing member. A diffused sound calculating unit that calculates a noise level of noise reflected at least once in the measurement space as a diffused sound noise level based on the sound absorption rate of the sound, and radiates a difference between the diffused sound noise level and the internal noise level A radiated sound calculation unit that calculates a sound noise level, and the first noise evaluation value calculation unit calculates the first noise evaluation value by using the radiated sound noise level as the internal noise level. Also good.

  According to the noise evaluation apparatus having such a configuration, the sound level of the diffused sound measured by the internal noise measurement unit is suppressed by the sound absorbing member from suppressing the radiated sound emitted from the noise measurement object from being reflected in the measurement space. Can be reduced. Then, by calculating the difference between the internal noise level and the diffuse noise level, it is possible to remove the noise level component due to the diffuse sound that could not be removed by the sound absorbing member from the internal noise level measured by the internal noise measurement unit. it can. Therefore, the noise level of the noise directly emitted from the noise measurement object can be acquired with high accuracy. Thereby, information necessary for evaluation of noise generated by the noise measurement object can be acquired as more accurate information.

  Furthermore, in the noise evaluation apparatus according to another aspect of the present invention, the soundproof box may be attached in contact with the outer surface via an elastic member.

  According to the noise evaluation apparatus having such a configuration, it can be attached in close contact without providing a gap between the soundproof box and the outer surface. Thereby, the measurement space formed by the soundproof box and the outer surface can be easily made a space isolated from the surrounding environment. Thereby, the influence of the noise from the surrounding environment can be sufficiently suppressed, and the noise in the measurement space can be measured with high accuracy.

  In the noise evaluation apparatus according to another aspect of the present invention, the vibration measurement unit may be attached to the soundproof box via a vibration isolation unit that suppresses propagation of vibration from the soundproof box.

  According to the noise evaluation apparatus having such a configuration, the vibration of the soundproof box can be prevented from propagating to the vibration measuring unit. When the vibration measurement unit measures the vibration of the outer surface of the noise measurement object, the vibration of the noise measurement object is propagated to the vibration measurement unit by being attached to the soundproof box. However, since the vibration measurement unit is supported by the vibration isolation unit, the vibration transmitted from the soundproof box can be absorbed and the vibration measurement unit itself can be prevented from vibrating. Thereby, it is possible to easily measure the vibration of the outer surface of the noise measurement object with high accuracy by the vibration measuring unit.

  Furthermore, the noise evaluation device according to another aspect of the present invention includes a first noise determination unit that determines whether or not the first noise evaluation value exceeds a predetermined first reference ratio. You may have.

  According to the noise evaluation apparatus having such a configuration, it is possible to determine whether or not the noise measured at the measurement position is greatly affected by the noise emitted from the noise measurement object. Therefore, it can be determined that the noise level at the measurement position is increased due to the noise emitted from the noise measurement object. That is, it can be easily determined that the measurement position has a noise level that exceeds the standard to be guaranteed by the noise emitted from the noise measurement object. As a result, it is possible to take effective noise countermeasures on the noise measurement object without performing wasteful noise countermeasures only by taking noise countermeasures so as to reduce the noise level at the measurement position.

  The noise evaluation apparatus according to another aspect of the present invention includes a second noise determination unit that determines whether or not the second noise evaluation value exceeds a predetermined second reference ratio. You may have.

  According to the noise evaluation apparatus having such a configuration, it can be determined whether or not the vibration of the outer surface of the noise measurement object is easily converted into noise. Therefore, it is possible to easily determine whether or not noise countermeasures are necessary for the noise measurement object.

  Furthermore, in the noise evaluation apparatus in another aspect of the present invention, the noise evaluation control unit is configured to calculate the first noise evaluation value calculation unit based on external noise levels measured at the plurality of measurement positions by the external noise measurement unit. Based on the plurality of first noise evaluation values stored in the storage unit, the storage unit that stores the plurality of first noise evaluation values calculated by the above and the positional information of the plurality of measurement positions in association with each other And a rank assigning unit that ranks the position information of the plurality of corresponding measurement positions.

  According to the noise evaluation apparatus having such a configuration, the noise measurement object is obtained by ranking the position information of the plurality of measurement positions in the rank giving unit based on the first noise evaluation value stored in the storage unit. The position information of the measurement positions can be ranked in the order in which they are affected by the noise emitted from. That is, it is possible to easily determine the measurement position where the contribution ratio of the noise emitted from the noise measurement object is greatly affected. Therefore, it is possible to prioritize the measurement positions in the order in which noise countermeasures are required, and noise countermeasures can be taken from a place where more noise countermeasures are required among a plurality of measurement positions.

  In the noise evaluation method according to the second aspect of the present invention, a soundproof box is attached to a noise measurement object to be measured for noise, and a part of the outer surface of the noise measurement object is covered to propagate noise from the outside. A measurement space forming step for forming a measurement space in which noise is suppressed, an internal noise measurement step for measuring a noise level of noise in the measurement space as an internal noise level, and a vibration characteristic of the outer surface as a surface vibration value. A vibration measurement step for measuring in a measurement space; an external noise measurement step for measuring a noise level of noise at a predetermined measurement position outside the measurement space as an external noise level; the internal noise level, the surface vibration value, and the A noise evaluation processing step for performing processing related to noise evaluation based on the external noise level, wherein the noise evaluation processing step includes the internal noise level relative to the external noise level. The first noise evaluation value calculation step for calculating and outputting the noise ratio as the first noise evaluation value, and the noise level of the noise directly propagated from the outer surface is calculated as the theoretical noise level based on the surface vibration value And a second noise evaluation value calculation step for calculating and outputting a ratio of the internal noise level to the theoretical noise level as a second noise evaluation value.

  Furthermore, the noise evaluation method according to another aspect of the present invention includes a sound absorbing member attaching step of providing a sound absorbing member having a predetermined sound absorption coefficient inside the soundproof box, and the noise evaluation processing step includes the shape of the soundproof box and Based on the sound absorption rate of the sound absorbing member, a diffuse sound calculation step for calculating a noise level of noise reflected at least once in the measurement space as a diffuse sound noise level; and the diffuse sound noise level and the internal noise level A radiated sound calculation step of calculating a difference as a radiated sound noise level, wherein the first noise evaluation value calculation step uses the radiated sound noise level as the internal noise level, and calculates the first noise evaluation value. It may be calculated.

  The noise evaluation method according to another aspect of the present invention includes a first noise determination step in which the noise evaluation processing step determines whether or not the first noise evaluation value exceeds a predetermined first reference ratio. You may have.

  Furthermore, in the noise evaluation method according to another aspect of the present invention, the noise evaluation processing step includes a second noise determination step of determining whether the second noise evaluation value exceeds a predetermined second reference ratio. You may have.

  Further, in the noise evaluation method according to another aspect of the present invention, the noise evaluation processing step includes the first noise evaluation value based on a plurality of external noise levels measured at the plurality of measurement positions by the external noise measurement step. A storage step of storing the plurality of first noise evaluation values calculated by the calculation step in association with position information of the plurality of measurement positions, and a plurality of the first noise evaluation values stored in the storage step And a rank assigning step for ranking the position information of the plurality of corresponding measurement positions.

  According to the noise evaluation apparatus of the present invention, by calculating the first noise evaluation value and the second noise evaluation value, it is possible to easily obtain information on high-accuracy noise necessary for evaluating noise generated by the noise measurement object. To do.

It is a schematic diagram which shows the noise evaluation apparatus in 1st embodiment of this invention. It is process drawing which shows an example of the operation | movement flow of the noise evaluation apparatus in 1st embodiment of this invention. It is process drawing which shows an example of the operation | movement flow of the noise evaluation apparatus in 1st embodiment of this invention. It is process drawing which shows an example of the operation | movement flow of the noise evaluation apparatus in 1st embodiment of this invention. It is a schematic diagram which shows the noise evaluation apparatus in 2nd embodiment of this invention. It is process drawing which shows an example of the operation | movement flow of the noise evaluation apparatus in 2nd embodiment of this invention.

<< first embodiment >>
Hereinafter, a first embodiment of the present invention will be described with reference to FIGS.
As shown in FIG. 1, the noise evaluation apparatus 100 according to the first embodiment measures noise emitted from a noise measurement object 500 that is a noise measurement target, and evaluates whether or not countermeasures are necessary. It is a device that enables noise evaluation by obtaining an evaluation value. The noise here refers to a sound that disturbs a living environment or the like exceeding a predetermined standard among sounds emitted from the noise measurement object 500. In this embodiment, the noise measurement object 500 of the noise evaluation apparatus 100 is, for example, a gas turbine or a centrifugal compressor.

  The noise evaluation apparatus 100 according to the first embodiment includes a soundproof box 1 attached to the outer surface 501 of the noise measurement object 500 and a sound absorbing member 2 provided inside the soundproof box 1. The noise evaluation apparatus 100 includes an internal noise measurement unit 3 that measures the noise level of the noise in the space inside the soundproof box 1, a vibration measurement unit 4 that measures the vibration of the outer surface 501 in the soundproof box 1, and the soundproof box 1. And an external noise measuring unit 5 that measures the noise level of noise at a predetermined measurement position X in the external space. The noise evaluation apparatus 100 includes a noise evaluation control unit 101 that performs control processing related to noise evaluation based on the measurement results of the internal noise measurement unit 3, the vibration measurement unit 4, and the external noise measurement unit 5.

  The soundproof box 1 is attached to the outer surface 501 of the noise measurement object 500 through an elastic member 1a. The soundproof box 1 covers a part of the outer surface 501 to form a measurement space Am in which the propagation of noise from the outside that is the surrounding environment is suppressed. The soundproof box 1 is made of a sound-insulating material that almost shields noise propagation from the outside. The soundproof box 1 of the present embodiment has a rectangular box shape with one surface opened as a shape predetermined by an operator who uses the noise evaluation apparatus 100. The soundproof box 1 has an opening formed so as to correspond to the shape of the outer surface 501 of the noise measurement object 500. That is, the soundproof box 1 is attached so as to be in close contact with the outer surface 501 via the elastic member 1a, so that the open surface side is closed to form the measurement space Am.

  The elastic member 1 a is disposed between the outer periphery of the opening portion of the soundproof box 1 and the outer surface 501. That is, the elastic member 1a of the present embodiment closely contacts the soundproof box 1 with the outer surface 501 of the noise measurement object 500 without any gap. For example, a rubber material or a resin material is used for the elastic member 1a. The elastic member 1a of the present embodiment has a sealing structure such as packing, and is deformed between the outer periphery of the opening portion of the soundproof box 1 and the outer surface 501, thereby the soundproof box 1 and the outer surface 501. And make sure that there is no gap.

  The sound absorbing member 2 is provided inside the soundproof box 1 and reduces noise reflection in the measurement space Am. The sound absorbing member 2 is a material having a predetermined sound absorption coefficient α known in advance by the operator. The sound absorbing member 2 of the present embodiment is a sheet-like material that absorbs or transmits noise in the measurement space Am and attenuates it. The sound absorbing member 2 is attached to the inner wall surface forming the measurement space Am of the soundproof box 1 with no gap therebetween. Examples of the sound absorbing member 2 include glass wool and flexible polyurethane foam.

  The internal noise measurement unit 3 is attached to the soundproof box 1 and measures the noise level that is the level of noise in the measurement space Am as the internal noise level Li. The internal noise measurement unit 3 outputs information on the measured internal noise level Li to the noise evaluation control unit 101. The noise level referred to here is a value representing a noise level, which is obtained by performing frequency correction close to the case where a person listens, among sound pressure levels that are the volume of sound. The internal noise measuring unit 3 of the present embodiment is a sound level meter having a sound collecting microphone. The internal noise measurement unit 3 is integrally attached to the soundproof box 1 so that the main body passes through a part of the wall surface facing the opening of the soundproof box 1 so that the microphone is arranged in the measurement space Am. ing.

  The vibration measurement unit 4 is attached to the soundproof box 1 and measures the vibration characteristics of the outer surface 501 as the surface vibration value v in the measurement space Am. The vibration measuring unit 4 measures acceleration, speed, and displacement of vibration as the vibration characteristics of the outer surface 501. The vibration measuring unit 4 outputs information on the measured surface vibration value v to the noise evaluation control unit 101. The vibration measuring unit 4 of the present embodiment is a non-contact type vibrometer that measures the vibration speed of the outer surface 501. The vibration measuring unit 4 penetrates a part of the wall surface on the side facing the opening of the soundproof box 1 so that the vibration of the outer surface 501 opened at the opening of the soundproof box 1 can be measured. It is attached integrally.

  The external noise measuring unit 5 measures a noise level that is a noise level at a predetermined measurement position X outside the soundproof box 1 as an external noise level Lo. Specifically, the external noise measurement unit 5 is installed at a measurement position X away from a place where the soundproof box 1, which is a predetermined position by an operator, in the surrounding environment outside the soundproof box 1. That is, the external noise level Lo measured by the external noise measuring unit 5 is a noise level including not only the noise emitted from the noise measurement object 500 but also the noise in the surrounding environment of the noise measurement object 500. The external noise measurement unit 5 outputs information on the measured external noise level Lo to the noise evaluation control unit 101.

  The external noise measurement unit 5 of the present embodiment is a sound level meter of the same type as the internal noise measurement unit 3. The predetermined measurement position X in the present embodiment is a noise guarantee point that is a position where it should be ensured that the noise level of the noise emitted from the noise measurement object 500 is within a predetermined standard.

  The noise evaluation control unit 101 performs control processing related to noise evaluation based on the input internal noise level Li, surface vibration value v, and external noise level Lo. Specifically, the noise evaluation control unit 101 of this embodiment calculates an evaluation value necessary for noise evaluation based on the internal noise level Li, the surface vibration value v, and the external noise level Lo, and calculates the calculated evaluation value. By determining, the noise from the noise measurement object 500 is evaluated. The noise evaluation control unit 101 according to the first embodiment includes a manual input unit 11 that is manually operated by an operator and inputs information, and an internal noise level input that receives internal noise level Li information from the internal noise measurement unit 3. Unit 12, surface vibration value input unit 13 to which information on surface vibration value v is input from vibration measurement unit 4, and external noise level input unit 14 to which information on external noise level Lo is input from external noise measurement unit 5 Have The noise evaluation control unit 101 calculates the noise level of the sound reflected at least once in the measurement space Am based on the information input by the manual input unit 11, and the diffusion sound calculation unit 15 calculates the noise level. And a radiated sound calculation unit 16 for calculating a difference between the noise level and the internal noise level Li. The noise evaluation control unit 101 includes a first noise evaluation value calculation unit 17 that calculates a ratio of the internal noise level Li to the external noise level Lo, and a calculation result of the first noise evaluation value calculation unit 17 exceeds a predetermined reference value. A first noise determination unit 18 for determining whether or not the The noise evaluation control unit 101 includes a theoretical noise level calculation unit 19 that calculates a noise level of noise propagated from the outer surface 501 based on information on the surface vibration value v input to the surface vibration value input unit 13. The noise evaluation control unit 101 includes a second noise evaluation value calculation unit 20 that calculates the ratio of the internal noise level Li to the noise level calculated by the theoretical noise level calculation unit 19, and calculation results of the second noise evaluation value calculation unit 20 It has the 2nd noise determination part 21 which determines whether it exceeds the predetermined reference value, and the output part 22 which outputs the determination result of the 1st noise determination part 18, and the determination result of the 2nd noise determination part 21 .

  The manual input unit 11 receives information such as the shape of the soundproof box 1 and the sound absorption coefficient α of the sound absorbing member 2 by an operator. Specifically, the information on the shape of the soundproof box 1 input to the manual input unit 11 of the present embodiment is the soundproof box 1 facing the measurement space Am calculated by the operator from the predetermined shape of the soundproof box 1. It is the information of the surface area S of the inner wall surface. Further, the information on the sound absorption rate α input to the manual input unit 11 of the present embodiment is information on an index indicating the degree of sound absorption determined in advance by the material of the sound absorbing member 2. The manual input unit 11 sends the input information to the diffuse sound calculation unit 15.

  Information on the internal noise level Li measured in the measurement space Am by the internal noise measurement unit 3 is input to the internal noise level input unit 12. The internal noise level input unit 12 sends information on the input internal noise level Li to the radiated sound calculation unit 16.

  Information on the external noise level Lo measured at the measurement position X by the external noise measurement unit 5 is input to the external noise level input unit 14. The external noise level input unit 14 sends information on the input external noise level Lo to the first noise evaluation value calculation unit 17.

The diffuse sound calculation unit 15 calculates the noise level of the diffuse sound, which is noise reflected at least once in the measurement space Am, based on the information input by the manual input unit 11 as the diffuse sound noise level Ld. The diffuse sound referred to in the present embodiment is a sound that is reflected at least once by the inner wall surface of the soundproof box 1 facing the measurement space Am, and the noise emitted from the noise measurement object 500 to the measurement space Am. The diffuse sound calculation unit 15 sends the calculated diffuse sound noise level Ld to the radiated sound calculation unit 16. In the diffused sound calculation unit 15 of the present embodiment, the diffused sound noise level is obtained from the information on the surface area S of the soundproof box 1 and the sound absorption coefficient α of the sound absorbing member 2 input by the manual input unit 11 based on the following equation (1). Ld is calculated theoretically. That is, the diffuse sound calculation unit 15 estimates based on the surface area S of the soundproof box 1 and the sound absorption coefficient α of the sound absorbing member 2 instead of the internal noise level Li in the measurement space Am actually measured by the internal noise measurement unit 3. The noise level of the virtual diffused sound is calculated.
Ld = 6-10 log αS (Formula 1)

The radiated sound calculation unit 16 uses the difference between the diffused sound noise level Ld calculated by the diffused sound calculation unit 15 and the internal noise level Li input to the internal noise level input unit 12 as the radiated sound noise that is the noise level of the radiated sound. Calculated as level Lr. The radiated sound referred to in the present embodiment is noise directly propagated from the outer surface 501 of the noise measurement object 500 to the internal noise measurement unit 3. That is, the radiated sound is noise obtained by removing diffused sound from noise in the measurement space Am measured by the internal noise measuring unit 3. The radiated sound calculation unit 16 sends the calculated radiated sound noise level Lr to the first noise evaluation value calculation unit 17. In the radiated sound calculation unit 16 of the present embodiment, the radiated sound noise level Lr is calculated as a difference between the internal noise level Li and the diffused sound noise level Ld based on the following equation (2).
Lr = Li−Ld (Formula 2)

  The first noise evaluation value calculation unit 17 calculates the ratio of the internal noise level Li to the external noise level Lo as the first noise evaluation value E1. That is, the first noise evaluation value calculation unit 17 calculates the contribution that the radiated sound noise level Lr gives to the external noise level Lo at the measurement position X. Therefore, the fact that the first noise evaluation value E1 is large means that the noise level at the measurement position X is increased by the noise from the noise measurement object 500 and the influence of the noise from the noise measurement object 500 is large. Show. On the contrary, the fact that the first noise evaluation value E1 is small indicates that the noise level at the measurement position X is increased by the noise from the surrounding environment, and the influence of the noise from the noise measurement object 500 is small. Yes. The first noise evaluation value calculation unit 17 sends information of the calculated first noise evaluation value E1 to the first noise determination unit 18.

The first noise evaluation value calculation unit 17 of the present embodiment uses a radiated sound noise level Lr that is the magnitude of the radiated sound excluding the diffused sound among the internal noise level Li that is the magnitude of the noise in the measurement space Am. . That is, the first noise evaluation value calculation unit 17 calculates the ratio of the radiated sound noise level Lr to the external noise level Lo as the first noise evaluation value E1. Specifically, the first noise evaluation value calculation unit 17 calculates the first noise evaluation value E1 based on the following equation (3).
E1 = Lr / Lo (Formula 3)

  The first noise determination unit 18 determines whether or not the first noise evaluation value E1 that is a calculation result of the first noise evaluation value calculation unit 17 exceeds a first reference ratio that is a predetermined reference value. The first noise determination unit 18 sends information on the determination result to the output unit 22.

  The first reference ratio is a value predetermined by the operator, and is an upper limit value as a contribution degree of the radiated sound noise level Lr at the measurement position X. That is, the first noise determination unit 18 of the present embodiment determines whether or not the influence of the noise from the noise measurement object 500 on the noise level at the measurement position X is greater than a predetermined value. Specifically, when the first noise evaluation value E1 exceeds the first reference ratio, the first noise determination unit 18 measures the noise emitted from the outer surface 501 of the measured noise measurement object 500. It is determined that the position X has a large influence. Conversely, when the first noise evaluation value E1 does not exceed the first reference ratio, the first noise determination unit 18 determines that the noise emitted from the outer surface 501 of the measured noise measurement object 500 is the measurement position X. It is determined that there is no significant impact on

  The theoretical noise level calculation unit 19 calculates the noise level of noise directly propagated from the outer surface 501 to the internal noise measurement unit 3 based on the information on the surface vibration value v input to the surface vibration value input unit 13. That is, the theoretical noise level calculation unit 19 calculates the theoretical noise level Lt that is the magnitude of the theoretical noise that is the theoretical noise when the vibration of the outer surface 501 is converted into noise most efficiently. The theoretical noise level calculation unit 19 sends information on the calculated theoretical noise level Lt to the second noise evaluation value calculation unit 20.

Specifically, the theoretical noise level calculation unit 19 of the present embodiment calculates the theoretical acoustic power Pt that is the strength of the theoretical noise from the surface vibration value v that is the vibration speed of the outer surface 501 based on the following equation (4). To calculate.
Pt = Nρcv ² (Formula 4)
Here, the unit of the above-mentioned theoretical sound power Pt is [W], and the theoretical noise level Lt can be obtained by converting this to the unit [dB] of the noise level.
Note that ρc used here is a characteristic impedance of air and is approximately 400 [Pa / s · m].

  N is an acoustic radiation efficiency which is an index indicating the ease of change from vibration to sound. For example, when the noise measurement object 500 is a flat plate, if the coincidence frequency or higher, the acoustic radiation efficiency approaches 1, and theoretically all vibrations are converted into sound. On the other hand, if it is below the coincidence frequency, the acoustic radiation efficiency is less than 1. The smaller the acoustic radiation efficiency, the less vibration is converted into sound. Therefore, for example, when the above-described theoretical acoustic power Pt is obtained, the acoustic radiation efficiency is 1 in this case because it is a noise level when almost all vibrations are theoretically converted into noise.

  Further, the coincidence frequency is a value determined by the size and material of the noise measurement object 500 when the noise measurement object 500 is a flat plate. The coincidence frequency of the present embodiment is determined by, for example, the plate thickness of a member constituting the outer surface 501 of the noise measurement object 500 and the Young's modulus and density of the material constituting the outer surface 501.

  The second noise evaluation value calculation unit 20 calculates the ratio of the acoustic radiation efficiency as the second noise evaluation value E2 based on the ratio of the radiated sound noise level Lr to the theoretical noise level Lt. The calculated second noise evaluation value E2 is sent to the second noise determination unit 21.

The second noise evaluation value calculation unit 20 of the present embodiment uses a radiated sound noise level Lr which is the magnitude of the radiated sound excluding the diffused sound among the internal noise level Li which is the magnitude of the noise in the measurement space Am. . That is, the second noise evaluation value calculation unit 20 calculates the ratio of the acoustic radiation efficiency obtained by calculating the ratio of the radiated sound noise level Lr to the theoretical noise level Lt as the second noise evaluation value E2. Since the acoustic radiation efficiency of the theoretical noise level Lt is 1 in the second noise evaluation value calculation unit 20, the acoustic radiation of the radiated noise level Lr is calculated by calculating the ratio of the radiated noise level Lr to the theoretical noise level Lt. Efficiency is calculated. Specifically, the second noise evaluation value calculation unit 20 calculates a second noise evaluation value E2 based on the following equation (5).
E2 = Lr / Lo (Formula 5)

  The second noise determination unit 21 determines whether or not the second noise evaluation value E2 that is a calculation result of the second noise evaluation value calculation unit 20 exceeds a second reference ratio that is a predetermined reference value. The second noise determination unit 21 sends the determination result to the output unit 22.

  The second reference ratio is a value determined in advance by the operator, and is an upper limit value as the acoustic radiation efficiency on the outer surface 501 of the noise measurement object 500 to which the soundproof box 1 is attached. That is, in the second noise determination unit 21 of the present embodiment, it is determined whether or not the acoustic radiation efficiency of the outer surface 501 where the vibration is measured exceeds the second reference ratio, thereby determining the outer surface 501 being measured. It is determined whether or not vibration is easily converted into noise. Specifically, when the second noise evaluation value E2 exceeds the second reference ratio, the second noise determination unit 21 measures the acoustic radiation efficiency because it is close to the second reference ratio with respect to 1. It is determined that the conversion rate at which the vibration of the outer surface 501 of the noise measurement object 500 is converted as noise is high. On the other hand, when the second noise evaluation value E2 does not exceed the second reference ratio, the second noise determination unit 21 measures the acoustic radiation efficiency because it is far from the second reference ratio with respect to 1. It is determined that the conversion rate at which the vibration of the outer surface 501 of the noise measurement object 500 is converted as noise is low.

  The output unit 22 outputs the determination results of the first noise determination unit 18 and the second noise determination unit 21 to the operator. The output unit 22 of the present embodiment has a display that displays the determination result of the first noise determination unit 18 and the determination result of the second noise determination unit 21 separately and outputs them.

Next, a noise evaluation method using the noise evaluation apparatus 100 described above will be described with reference to the process diagrams shown in FIGS.
2 to 4 exemplify an operation flow using the noise evaluation apparatus 100 in the noise evaluation method. Note that FIG. 1 is referred to in the description of this operation flow.

  As shown in FIG. 2, before attaching the soundproof box 1 to the noise measurement object 500, the operator manually inputs information on the shape of the soundproof box 1 to be attached and information on the sound absorbing member 2 provided in the soundproof box 1. It inputs into the part 11 (manual input process S101). Specifically, the operator calculates in advance the surface area S of the inner wall surface of the soundproof box 1 from the shape of the soundproof box 1 to be attached, and inputs it to the manual input unit 11 as information relating to the shape of the soundproof box 1. Further, the operator inputs the sound absorption coefficient α determined in advance by the material of the sound absorbing member 2 provided inside the soundproof box 1 to the manual input unit 11 as information on the sound absorbing member 2. The manual input unit 11 to which information on the surface area S of the soundproof box 1 and the sound absorption coefficient α of the sound absorbing member 2 has been input by the operator sends the information to the diffuse sound calculation unit 15.

  Upon receiving these pieces of information, the noise evaluation control unit 101 performs control processing related to noise evaluation based on the surface vibration value v (noise evaluation processing step S10). Specifically, the diffuse sound calculation unit 15 calculates the noise level of the diffuse sound, which is the noise reflected at least once in the measurement space Am, as the diffuse sound noise level Ld (diffuse sound calculation step S102). The diffuse sound calculation unit 15 of the present embodiment calculates the diffuse sound noise level Ld from the information on the surface area S of the soundproof box 1 and the sound absorption coefficient α of the sound absorbing member 2. The diffuse sound calculation unit 15 sends the calculated diffuse sound noise level Ld to the radiated sound calculation unit 16.

  When the input to the manual input unit 11 is completed by the operator, the operator attaches the soundproof box 1 so as to cover a part of the outer surface 501 of the noise measurement object 500 as shown in FIG. A measurement space Am that is surrounded by the wall surface and the outer surface 501 and that suppresses the propagation of noise from the outside is formed (measurement space formation step S201S201). Specifically, in this embodiment, the operator has a soundproof box in which the sound absorbing member 2 is attached to the inner wall surface, and a sound level meter that is the internal noise measuring unit 3 and a vibration speed meter that is the vibration measuring unit 4 are provided. 1 is fixed to the outer surface 501 of the noise measurement object 500 whose noise is to be measured. When fixing the soundproof box 1, the elastic member 1 a is sandwiched between the opening of the soundproof box 1 and the outer surface 501. The soundproof box 1 is fixed in a state where the elastic member 1a is in close contact with both the opening portion of the soundproof box 1 and the outer surface 501 while the elastic member 1a is deformed.

  After fixing the soundproof box 1 to the outer surface 501, the noise level of the noise in the measurement space Am is measured by the internal noise measuring unit 3 as the internal noise level Li (internal noise measuring step S202). The internal noise measurement unit 3 outputs the measured internal noise level Li as information to the internal noise level input unit 12 of the noise evaluation control unit 101.

When the information of the internal noise level Li is input, the noise evaluation control unit 101 performs control processing related to noise evaluation based on the internal noise level Li (noise evaluation processing step S10). Specifically, the internal noise level input unit 12 sends information on the internal noise level Li to the radiated sound calculation unit 16.
When information on the diffused sound noise level Ld and the internal noise level Li is input, as processing related to the noise evaluation, the radiated sound calculating unit 16 calculates the diffused sound noise level Ld calculated by the diffused sound calculating unit 15 and the internal noise level input unit. 12 is calculated as a radiated sound noise level Lr which is a noise level of the radiated sound (radiated sound calculation step S203). The radiated sound calculation unit 16 sends information on the calculated radiated sound noise level Lr to the first noise evaluation value calculation unit 17 and the second noise evaluation value calculation unit 20, respectively.

  After fixing the soundproof box 1 to the outer surface 501, the external noise measuring unit 5, which is a sound level meter, measures the noise level, which is the noise level at a predetermined measurement position X outside the soundproof box 1, as the external noise level Lo ( External noise measurement step S302). The external noise measurement unit 5 outputs the measured external noise level Lo as information to the external noise level input unit 14 of the noise evaluation control unit 101.

When the external noise level Lo is input, the noise evaluation control unit 101 performs control processing related to noise evaluation based on the external noise level Lo (noise evaluation processing step S10). Specifically, the external noise level input unit 14 sends information on the external noise level Lo to the first noise evaluation value calculation unit 17.
When the external noise level Lo and the radiated noise level Lr calculated from the internal noise level Li are received, as a process related to the noise evaluation, the first noise evaluation value calculator 17 calculates the radiated noise level Lr with respect to the external noise level Lo. The ratio is calculated as the first noise evaluation value E1 (first noise evaluation value calculation step S304). The first noise evaluation value calculation unit 17 of the present embodiment uses the radiated sound noise level Lr calculated from the internal noise level Li among the internal noise levels Li. That is, the first noise evaluation value calculation unit 17 calculates the ratio of the radiated sound noise level Lr to the external noise level Lo as the first noise evaluation value E1. The first noise evaluation value calculation unit 17 sends information of the calculated first noise evaluation value E1 to the first noise determination unit 18.
When calculating the first noise evaluation value E1 and using the internal noise level Li as it is without using the radiated sound noise level Lr, the internal noise level input unit 12 sends the internal noise level Li to the first noise evaluation value calculation unit 17. Information on the noise level Li is directly input.

  When the first noise evaluation value E1 is received from the first noise evaluation value calculation unit 17, the first noise determination unit 18 performs a first reference in which the first noise evaluation value E1 is a predetermined reference value as a process related to the noise evaluation. It is determined whether or not the ratio is exceeded (first noise determination step S305). The first noise determination unit 18 sends information on the determination result to the output unit 22.

  When the information on the determination result is received from the first noise determination unit 18, the output unit 22 displays and outputs the determination result to the operator via the display display as a process related to noise evaluation (output step S306).

  After fixing the soundproof box 1 to the outer surface 501, as shown in FIG. 4, the vibration characteristic of the outer surface 501 is measured as a surface vibration value v in the measurement space Am by the vibration measuring unit 4 (vibration measuring step S402). . In the present embodiment, the vibration speed is measured as the surface vibration value v. The vibration measuring unit 4 outputs the measured surface vibration value v as information to the surface vibration value input unit 13 of the noise evaluation control unit 101.

When the surface vibration value v is input, the noise evaluation control unit 101 performs control processing related to noise evaluation based on the external noise level Lo (noise evaluation processing step S10). Specifically, the surface vibration value input unit 13 sends information on the surface vibration value v to the theoretical noise level calculation unit 19.
When the theoretical noise level Lt is input, as a process related to the noise evaluation, the theoretical noise level calculation unit 19 calculates the noise directly propagated from the outer surface 501 to the internal noise measurement unit 3 based on the information of the surface vibration value v. The noise level is calculated (theoretical noise level calculation step S403). The theoretical noise level calculation unit 19 of the present embodiment calculates and converts the theoretical sound power Pt that is the strength of the theoretical noise from the surface vibration value v that is the vibration speed of the vibration of the outer surface 501, and converts the theoretical noise level Lt. Ask. The theoretical noise level calculation unit 19 sends information on the calculated theoretical noise level Lt to the second noise evaluation value calculation unit 20.

Upon receiving the theoretical noise level Lt and the radiated sound noise level Lr calculated from the internal noise level Li, the second noise evaluation value calculator 20 calculates the radiated sound noise level Lr relative to the theoretical noise level Lt as a process related to noise evaluation. The ratio is calculated as the second noise evaluation value E2 (second noise evaluation value calculation step S404). The second noise evaluation value calculation unit 20 of the present embodiment uses the radiated sound noise level Lr calculated from the internal noise level Li among the internal noise levels Li. That is, the second noise evaluation value calculation unit 20 calculates the ratio of the radiated sound noise level Lr to the theoretical noise level Lt as the second noise evaluation value E2. The second noise evaluation value calculation unit 20 sends information of the calculated second noise evaluation value E2 to the second noise determination unit 21.
When the second noise evaluation value E2 is calculated and the internal noise level Li is used as it is without using the radiated sound noise level Lr, the internal noise level input unit 12 sends the internal noise level Li to the second noise evaluation value calculation unit 20. Information on the noise level Li is sent directly.
When the second noise evaluation value E2 is received from the second noise evaluation value calculation unit 20, the second noise determination unit 21 performs a second reference in which the second noise evaluation value E2 is a predetermined reference value. It is determined whether or not the ratio is exceeded (second noise determination step S405). The second noise determination unit 21 sends determination result information to the output unit 22.

When the information on the determination result is received from the second noise determination unit 21, the output unit 22 displays and outputs the determination result to the operator via the display display as processing relating to noise evaluation (output step S406).
Based on the determination result from the first noise determination unit 18 displayed on the output unit 22, the operator confirms whether or not the measurement position X is greatly affected by noise emitted from the noise measurement object 500. Then, when the operator determines from the first noise determination unit 18 that the determination result exceeds the first reference ratio, the operator measures the noise so that the external noise level Lo at the measurement position X decreases. Noise countermeasures are applied to 500. On the contrary, when the determination result from the first noise determination unit 18 indicates that the determination result does not exceed the first reference ratio, the operator does not need to reduce the external noise level Lo at the measurement position X. No noise countermeasures.
Further, the operator confirms whether or not the vibration of the measured outer surface 501 of the noise measurement object 500 is easily converted into noise based on the determination result from the second noise determination unit 21 displayed on the output unit 22. . When the operator determines that the determination result from the second noise determination unit 21 exceeds the second reference ratio, the material of the part that is easily changed in design, such as the piping of the noise measurement object 500 By changing or changing the plate thickness, the coincidence frequency is changed to take noise countermeasures. Conversely, if the determination result from the second noise determination unit 21 indicates that the determination result does not exceed the second reference ratio, the operator does not take noise countermeasures on the noise measurement object 500.

According to the noise evaluation apparatus 100 or the noise evaluation method as described above, the internal noise level Li is measured by the internal noise measurement unit 3 in the measurement space Am formed by the soundproof box 1, so that the noise measurement object 500. Noise from the surrounding environment can be eliminated. Therefore, the noise emitted from the noise measurement object 500 can be measured with high accuracy by the internal noise measurement unit 3.
In addition, the external noise level Lo is measured by the external noise measurement unit 5 at the measurement position X in the surrounding environment outside the measurement space Am formed inside the soundproof box 1, so that noise emitted from the noise measurement object 500 is measured. It can be measured including noise from the surrounding environment. Then, the first noise evaluation value calculation unit 17 calculates the first noise evaluation value E1 that is the ratio of the radiated sound noise level Lr of the internal noise level Li to the external noise level Lo, thereby being measured at the measurement position X. It is possible to acquire highly accurate information indicating how much noise is affected by noise emitted from the noise measurement object 500.

Further, as with the internal noise measuring unit 3, the vibration measuring unit 4 measures the vibration velocity of the outer surface 501 as the surface vibration value v in the measurement space Am, thereby corresponding to the noise measured by the internal noise measuring unit 3. The vibration of the outer surface 501 can be measured. The theoretical noise level calculation unit 19 can calculate a theoretical noise level Lt that is the magnitude of noise theoretically generated from this vibration. The second noise evaluation value calculation unit 20 calculates the acoustic radiation efficiency, which is the ratio between the theoretical noise level Lt and the radiated sound noise level Lr of the internal noise level Li, as the second noise evaluation value E2, thereby calculating the theoretical value. The noise level resulting from the vibration of the upper and outer surfaces 501 can be compared with the actually measured noise level. For this reason, information on whether or not the internal noise level Li, which is the noise level of the noise emitted from the noise measurement object 500 and actually measured, is close to the theoretical noise level Lt, which is the theoretical noise level, is acquired. Can do. This indicates that the closer the internal noise level Li is to the theoretical noise level Lt, the more the vibration of the outer surface 501 of the noise measurement object 500 is converted into noise. Therefore, it is possible to acquire highly accurate information indicating that the vibration of the outer surface 501 of the noise measurement object 500 is easily converted into noise. As a result, it is possible to easily acquire information regarding high-accuracy noise necessary for evaluating noise generated by the two noise measurement objects 500, ie, the first noise evaluation value E1 and the second noise evaluation value E2.

  In addition, by providing the sound absorbing member 2 inside the soundproof box 1, it is possible to suppress the radiated sound emitted from the noise measurement object 500 from being reflected in the measurement space Am, and the diffused sound measured by the internal noise measuring unit 3. The noise level can be reduced. Then, the diffused sound calculation unit 15 theoretically calculates the noise level of the diffused sound in the measurement space Am as the diffused sound noise level Ld, and the radiated sound calculating unit 16 calculates the internal noise level Li and the diffused sound noise level Ld. The noise level component due to the diffused sound that cannot be removed by the sound absorbing member 2 from the internal noise level Li measured by the internal noise measuring unit 3 can be removed. Therefore, the noise level of the noise directly emitted from the noise measurement object 500 can be acquired with high accuracy. Thereby, the information regarding the noise required for evaluation of the noise emitted from the noise measurement object 500 can be acquired as more accurate information.

  Furthermore, by attaching the soundproof box 1 in contact with the outer surface 501 of the noise measurement object 500 via the elastic member 1a, the soundproof box 1 and the outer surface 501 can be attached in close contact with each other without providing a gap. it can. Thereby, the measurement space Am formed by the soundproof box 1 and the outer surface 501 can be easily made a space isolated from the surrounding environment. Thereby, the influence of the noise from the surrounding environment can be sufficiently suppressed, and the noise measurement by the internal noise measurement unit 3 in the measurement space Am can be performed with high accuracy.

  Further, by determining whether or not the first noise evaluation value E1 exceeds a predetermined first reference ratio by the first noise determination unit 18, the noise measured at the measurement position X is the noise measurement object 500. It can be determined whether or not it is greatly affected by the noise emitted from the. Therefore, it can be determined that the noise level at the measurement position X is increased by the noise emitted from the noise measurement object 500. That is, it can be easily determined that the measurement position X has a noise level that exceeds the standard to be guaranteed by the noise emitted from the noise measurement object 500. As a result, it is possible to take effective noise countermeasures on the noise measurement object 500 without taking unnecessary noise countermeasures by simply taking noise countermeasures so that the noise level at the measurement position X is reduced.

  Furthermore, the second noise determination unit 21 determines whether or not the second noise evaluation value E2 exceeds a predetermined second reference ratio, so that the vibration of the outer surface 501 of the noise measurement object 500 becomes noise. It can be determined whether or not the state is easily converted. Accordingly, it is possible to easily determine whether or not noise countermeasures are necessary for the noise measurement object 500. Even if it is determined that noise countermeasures are necessary, the coincidence frequency can be adjusted by changing the Young's modulus or density by changing the material for the noise measurement object 500 or changing the plate thickness. By making such a design change, more effective noise countermeasures can be taken for the noise measurement object 500.

  Also, by calculating and determining the acoustic radiation efficiency as the second noise evaluation value E2, the operator makes a design change that changes the coincidence frequency, so that whether or not the design change is effective as a noise countermeasure. Can be determined. The acoustic radiation efficiency is a value determined by the coincidence frequency, and the coincidence frequency is a value determined by the plate thickness, Young's modulus, and density of the noise measurement object 500. Therefore, for example, the second noise evaluation that is the acoustic radiation efficiency is made by making a design change such as changing three parameters such as changing the material of the noise measurement object 500 or partially changing the plate thickness. By calculating and determining the value E2, it can be easily determined whether or not the design change is effective as a noise countermeasure. Thereby, an effective noise countermeasure can be performed by an easy design change by changing only three parameters.

  Furthermore, whether or not a noise countermeasure is necessary to reduce the noise level at the measurement position X where the noise is measured by the external noise measurement unit 5 by having the first noise determination unit 18 and the second noise determination unit 21. An effective noise countermeasure can be easily performed on the noise measurement object 500 while making the determination.

<< Second Embodiment >>
Next, a noise evaluation apparatus 200 according to the second embodiment will be described with reference to FIGS. 5 and 6.
In the second embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted. In the noise evaluation apparatus 200 of the second embodiment, the vibration measurement unit 4 is attached to the soundproof box 1 via the vibration isolation unit 6 and the measurement positions X at which the external noise measurement unit 5 measures noise are plural. There is a difference from the first embodiment.

That is, the noise evaluation apparatus 200 of the second embodiment changes the measurement position X every time the external noise level Lo is measured, and measures the external noise level Lo at a plurality of measurement positions Xn. As shown in FIG. 5, the noise evaluation apparatus 200 includes an anti-vibration unit 6 which is attached while suppressing vibration transmitted to the vibration measurement unit 4 in the soundproof box 1, and external noise levels measured at a plurality of measurement positions Xn. And a noise evaluation control unit 201 that performs control processing related to noise evaluation based on Lo.
In the second embodiment, a case where the external noise measurement unit 5 measures the external noise level Lo at the measurement positions Xa, the measurement positions Xb, and the measurement positions Xc, which are the three measurement positions X, will be described as an example.

The vibration isolator 6 is attached with the vibration measuring unit 4 while suppressing propagation of vibration from the soundproof box 1 in the measurement space Am. The vibration isolator 6 of this embodiment includes an elastic support 61 that supports the vibration measurement unit 4 by applying an elastic force via a spring, and the vibration measurement unit 4 so as to attenuate the force applied to the elastic support 61. And a damping support portion 62 for supporting the. Specifically, the vibration isolator 6 according to the present embodiment is configured so that, for example, the resonance frequency of the vibration measurement unit 4 and the vibration isolator 6 is set to 20 Hz or less, which is a human audible range. It is a structure that suppresses transmission of vibrations at a frequency of.
The elastic support part 61 is fixed to the inner wall surface of the soundproof box 1 and supports the vibration measurement part 4 via a spring. The elastic support 61 of the present embodiment absorbs vibration transmitted from the soundproof box 1 to the vibration measurement unit 4 to the vibration measurement unit 4 by being elastically deformed like a suspension.
The damping support part 62 is fixed to the inner wall surface of the soundproof box 1 in parallel with the elastic member 1 a and supports the vibration measuring part 4. The damping support part 62 attenuates the force applied to the elastic support part 61. The damping support part 62 of this embodiment is an oil damper, for example.

The noise evaluation control unit 201 in the second embodiment receives information on the external noise level Lo measured at a plurality of measurement positions Xn, and determines the first noise evaluation value E1 at the plurality of measurement positions Xn. The noise evaluation control unit 201 of the present embodiment includes an external noise level input unit 14a to which position information of a plurality of external noise levels Lo and measurement positions Xn is input, and a first noise evaluation value E1 for each of the plurality of external noise levels Lo. A first noise evaluation value calculation unit 17a for calculating a plurality of first noise evaluation values E1, a plurality of first noise evaluation values E1, and position information of a plurality of measurement positions Xn Are stored in association with each other, and a rank assigning unit 24 that ranks the position information based on the information stored in the storage unit 23 is provided.
In addition, the 2nd noise evaluation value calculation part 20a and the 2nd noise determination part 21a of 2nd embodiment send information to the memory | storage part 23. FIG. The output unit 22a outputs information sent from the storage unit 23 to the operator. About another structure, it is the same as that of the noise evaluation control part 101 of 1st embodiment.

  The external noise level input unit 14a receives information on the external noise level Lo measured at the plurality of measurement positions Xn by the external noise measurement unit 5 and position information on the measured measurement positions Xn. Specifically, the external noise level input unit 14a of the second embodiment, when the external noise measurement unit 5 measures the external noise level Lo, the information of the measured external noise level Lo and the position of the measurement position Xn when measured. Information is entered. For example, when the external noise measurement unit 5 performs measurement at the measurement position Xa, the external noise level Lo at the measurement position Xa and the position information of the measurement position Xa are input to the external noise level input unit 14a. Similar information is also input to the external noise level input unit 14a for the different measurement positions Xb and Xc. The external noise level input unit 14 a sends information on the external noise level Lo to the first noise evaluation value calculation unit 17 a and sends position information on the measurement position X to the storage unit 23 each time it is input.

  The first noise evaluation value calculation unit 17a calculates, as the first noise evaluation value E1, the ratio of the radiated sound noise level Lr to the external noise level Lo for each received information of the plurality of external noise levels Lo. Similarly to the first embodiment, the first noise evaluation value calculation unit 17a of the second embodiment has a magnitude of radiated sound excluding diffused sound in the internal noise level Li that is the magnitude of noise in the measurement space Am. The radiated sound noise level Lr is used. That is, the first noise evaluation value calculation unit 17a calculates the ratio of the radiated sound noise level Lr to the external noise level Lo as the first noise evaluation value E1. The first noise evaluation value calculation unit 17a sends information of the calculated first noise evaluation value E1 to the first noise determination unit 18a and the storage unit 23. For example, when the first noise evaluation value calculation unit 17a receives information on the external noise level Lo at the measurement position Xa, the first noise evaluation value calculation unit 17a calculates a first noise evaluation value E1 at the measurement position Xa. The data is sent to the storage unit 23. The first noise evaluation value calculation unit 17a similarly calculates the first noise evaluation value E1 for the measurement position Xb and the measurement position Xc, and sends the respective information to the first noise determination unit 18a and the storage unit 23.

  Whenever the first noise determination unit 18a receives the first noise table value that is the calculation result of the first noise evaluation value calculation unit 17a, whether or not the first noise table value exceeds a predetermined first reference ratio. Determine. The first reference ratio in the second embodiment is predetermined by the operator regardless of the measurement position Xn. The first noise determination unit 18 a sends information on the determination result to the output unit 22 and the storage unit 23. For example, the first noise determination unit 18a determines whether or not the first noise evaluation value E1 corresponding to the external noise level Lo at the measurement position Xa exceeds the first reference ratio, and determines the determination result as the first noise determination unit. 18a and the storage unit 23. Similarly, the first noise evaluation value E1 corresponding to the external noise level Lo at the measurement position Xb and the first noise evaluation value E1 corresponding to the external noise level Lo at the measurement position Xc are also exceeded in comparison with the first reference ratio. And the determination results are sent to the first noise determination unit 18a and the storage unit 23.

The second noise evaluation value calculation unit 20a of the second embodiment sends the calculated second noise evaluation value E2 to the storage unit 23 together with the second noise determination unit 21a.
The second noise determination unit 21a of the second embodiment sends determination result information to the storage unit 23 instead of the output unit 22a.

  The storage unit 23 includes information on the plurality of first noise evaluation values E1 calculated by the first noise evaluation value calculation unit 17a based on the external noise levels Lo measured at the plurality of measurement positions Xn by the external noise measurement unit 5. The information of the determination result of each first noise evaluation value E1 and the position information of the plurality of measurement positions Xn are stored in association with each other. Furthermore, the storage unit 23 of the present embodiment also includes information on the second noise evaluation value E2 calculated by the second noise evaluation value calculation unit 20a and information on the determination result of the second noise evaluation value E2, in a plurality of measurement positions Xn. Is stored in correspondence with the position information.

  Specifically, when receiving the position information of the measurement position Xn, the storage unit 23 of the present embodiment receives information on the first noise evaluation value E1 corresponding to the received position information and the first noise evaluation value E1. The determination result of one noise determination unit 18a is sent, and the plurality of pieces of information are stored in association with the position information of the measurement position Xn. In addition, the storage unit 23 stores information on the second noise evaluation value E2 and information on the determination result of the second noise evaluation value E2 in addition to the information stored in association with each other.

  For example, when the external noise level Lo is measured at the measurement position Xa, the position information of the measurement position Xa is sent from the external noise level input unit 14a and stored in the storage unit 23. The first noise evaluation value E1 corresponding to the external noise level Lo at the measurement position Xa is sent from the first noise evaluation value calculation unit 17a and stored in the storage unit 23 in association with the position information of the measurement position Xa. In the storage unit 23, the determination result of the first noise evaluation value E1 corresponding to the external noise level Lo at the measurement position Xa is sent from the first noise determination unit 18a and stored in association with the position information of the measurement position Xa. In addition, the same information on the second noise evaluation value E2 and information on the determination result of the second noise evaluation value E2 are sent to the storage unit 23, regardless of the measurement position Xa. And store these information.

  Based on the first noise evaluation values E1 of the plurality of measurement positions Xn stored in the storage unit 23, the rank assigning unit 24 ranks the position information of the corresponding plurality of measurement positions Xn. The rank assigning unit 24 of the present embodiment compares the first noise evaluation values E1 that are the acoustic radiation efficiencies calculated for each of the plurality of measurement positions Xn, and ranks the first noise evaluation values E1 in descending order. . The ranking assigning unit 24 sends the ranking result to the output unit 22a. For example, the first noise evaluation value E1 corresponding to the external noise level Lo at the measurement position Xa is 0.4, the first noise evaluation value E1 corresponding to the external noise level Lo at the measurement position Xb is 0.8, and the measurement position Xc. When the first noise evaluation value E1 corresponding to the external noise level Lo is 0.6, the rank assigning unit 24 sequentially determines the position information of the measurement position Xc, the position information of the measurement position Xa, and the rank from the position information of the measurement position Xb. The result of this ranking is sent to the output unit 22a.

  The output unit 22a is the position information of the measurement position Xn in which the first noise evaluation value E1 and the second noise evaluation value E2 and the determination results of the first noise determination unit 18a and the second noise determination unit 21 are ranked. And output to the operator. The output unit 22a of the present embodiment ranks information on the first noise evaluation value E1, the second noise evaluation value E2, the determination result of the first noise determination unit 18a, and the determination result of the second noise determination unit 21a. It has a display for displaying and outputting together with the position information of the attached measurement position X.

Next, a noise evaluation method using the noise evaluation apparatus 200 described above will be described with reference to a process diagram shown in FIG.
FIG. 6 shows an example of an operation flow using the noise evaluation apparatus 200 in the noise evaluation method of the second embodiment. In the description of this operation flow, FIG. The operation flow for calculating the second noise evaluation value E2 is the same as the operation flow shown in FIG. 4 of the first embodiment.

  As shown in FIG. 5, after the soundproof box 1 is fixed to the outer surface 501, the noise level at the measurement position Xa that is one of a plurality of predetermined measurement positions Xn outside the soundproof box 1 by the external noise measurement unit 5. Is measured as the external noise level Lo (external noise measurement step S502). The external noise measurement unit 5 outputs the external noise level Lo at the measured measurement position Xa as information to the external noise level input unit 14a of the noise evaluation control unit 201.

  When the external noise level Lo at the measurement position Xa is input, the noise evaluation control unit 201 performs control processing related to noise evaluation based on the external noise level Lo (noise evaluation processing step S20). The external noise level input unit 14a sends information on the external noise level Lo to the first noise evaluation value calculation unit 17a and the storage unit 23.

  When the external noise level Lo at the measurement position Xa and the radiated sound noise level Lr calculated from the internal noise level Li are received, the first noise evaluation value calculation unit 17a performs processing related to noise evaluation by the external noise level at the measurement position Xa. The ratio of the radiated sound noise level Lr to Lo is calculated as the first noise evaluation value E1 (first noise evaluation value calculation step S504). The first noise evaluation value calculation unit 17a of the present embodiment uses the radiated sound noise level Lr calculated from the internal noise level Li instead of the internal noise level Li. That is, the first noise evaluation value calculation unit 17a calculates the ratio of the radiated sound noise level Lr to the external noise level Lo as the first noise evaluation value E1 at the measurement position Xa. The first noise evaluation value calculation unit 17a sends the first noise evaluation value E1 at the calculated measurement position Xa to the first noise determination unit 18a and the storage unit 23.

  When the first noise evaluation value E1 at the measurement position Xa is received from the first noise evaluation value calculation unit 17a, the first noise determination unit 18a receives the first noise evaluation value E1 at the measurement position Xa as the first process as noise evaluation processing. It is determined whether or not the reference ratio is exceeded (first noise determination step S505). The first noise determination unit 18 a sends information on the determination result to the output unit 22 a and the storage unit 23.

  When the position information of the measurement position Xa is received from the external noise level input unit 14a, the storage unit 23 stores this position information as processing related to noise evaluation. Thereafter, when receiving information on the first noise evaluation value E1 at the measurement position Xa from the first noise evaluation value calculation unit 17a, the storage unit 23 obtains information on the first noise evaluation value E1 at the measurement position Xa as the position of the measurement position Xa. It is stored in association with information. Further, when receiving the determination result information from the first noise determination unit 18a, the storage unit 23 displays the determination result information of the first noise determination unit 18a for the first noise evaluation value E1 at the measurement position Xa at the position of the measurement position Xa. It is stored in association with information. In addition, the information of the second noise evaluation value E2 calculated by the second noise evaluation value calculation unit 20a and the information of the determination result by the second noise determination unit 21 are stored in association with the position information of the measurement position Xa. (Memory step S506).

  When information based on the measurement result is stored in the external noise measurement unit 5 at the first measurement position Xa in the storage unit 23, the operator confirms whether the number of pieces of position information at the measurement position Xn is sufficient. (Measurement position number confirmation step S507). If the predetermined number is not sufficient, the external noise measuring unit 5 is moved to another measurement position Xb or measurement position Xc (measurement position changing step S508). Thereafter, the noise levels at the other measurement positions Xb and Xc are measured again. Specifically, in the present embodiment, the predetermined number is 3 because there are three measurement positions Xn. Therefore, the operator moves the external noise measuring unit 5 from the measurement position Xa to the measurement position Xb, and measures the external noise level Lo at the measurement position Xb. When information based on the external noise level Lo at the measurement position Xb is stored in the storage unit 23 by repeating the same process, the same process is also performed on the external noise level Lo at the measurement position Xc.

  When the external noise level Lo is measured at a plurality of predetermined measurement positions Xn and information based on the plurality of external noise levels Lo is stored in the storage unit 23, the first noise evaluation is performed by the rank assigning unit 24 as a process related to noise evaluation. Based on the value E1, ranking is performed on the position information of the corresponding plurality of measurement positions Xn (rank assignment step S509). In the present embodiment, the first noise evaluation value E1 that is the acoustic radiation efficiency calculated for each of the plurality of measurement positions Xn by the rank assigning unit 24 is compared, and the first noise evaluation value E1 is ranked in descending order. . As a result of ranking, the rank assigning unit 24 includes information on the second noise evaluation value E2 corresponding to the position information on the plurality of measurement positions Xn ranked in descending order of the first noise evaluation value E1, and the first noise determination. Information on the determination results of the unit 18a and the second noise determination unit 21 is sent to the output unit 22a.

When the information from the rank assigning unit 24 is received, as a process related to the noise evaluation, the output unit 22a outputs the information on the first noise evaluation value E1, the information on the second noise evaluation value E2, and the determination result of the first noise determination unit 18a. The information and information on the determination result of the second noise determination unit 21 are output to the operator together with the ranked position information (output step S510).
In the second embodiment, information on the first noise evaluation value E1, information on the second noise evaluation value E2, information on the determination result of the first noise determination unit 18a, and determination result of the second noise determination unit 21 in the output unit 22a. Is displayed together with the positional information of the measured measurement positions Xn, and a display is provided for output.

  According to the noise evaluation apparatus 200 or the noise evaluation method as described above, the first information for noise evaluation calculated by the storage unit 23 based on the external noise level Lo measured at a plurality of predetermined measurement positions Xn. Position information of the measurement position X includes information on the noise evaluation value E1, information on the second noise evaluation value E2, information on the determination result of the first noise determination unit 18a, and information on the determination result of the second noise determination unit 21. , The results measured at a plurality of measurement positions Xn can be managed as information for each measurement position Xn. Based on the first noise evaluation value E <b> 1 stored in the storage unit 23, the rank assigning unit 24 ranks the position information of the plurality of measurement positions Xn, so that the noise generated from the noise measurement target object 500 is used. Position information of a plurality of measurement positions Xn can be ranked in order of influence. That is, it is possible to easily determine the measurement position Xn having a high contribution rate of noise emitted from the noise measurement object 500 and being greatly influenced. Therefore, it is possible to prioritize the measurement positions Xn in the order in which noise countermeasures are required, and noise countermeasures can be taken from a place where more noise countermeasures are required among the plurality of measurement positions Xn.

  Further, by attaching the vibration measurement unit 4 to the soundproof box 1 via the vibration isolation unit 6, it is possible to suppress the vibration of the soundproof box 1 from being propagated to the vibration measurement unit 4. When the vibration measurement unit 4 measures the vibration of the outer surface 501 of the noise measurement target object 500, the vibration of the noise measurement target object 500 is propagated to the vibration measurement unit 4 by being attached to the soundproof box 1. In particular, when the internal noise level Li is to be measured with high accuracy, the soundproof box 1 is attached in close contact with the outer surface 501 via the elastic member 1a or the like, so that the vibration of the outer surface 501 directly causes the soundproof box 1 to vibrate. Will be propagated. As a result, the soundproof box 1 vibrates greatly, and vibrations of the soundproof box 1 other than the vibration of the outer surface 501 are included in the result measured by the vibration measuring unit 4. However, since the vibration measurement unit 4 is supported by the elastic support unit 61 and the damping support unit 62 of the vibration isolation unit 6, the vibration transmitted from the soundproof box 1 is absorbed and the vibration measurement unit 4 itself vibrates. Can be suppressed. Thereby, the vibration of the outer surface 501 of the noise measurement object 500 can be easily measured with high accuracy by the vibration measuring unit 4.

In the present embodiment, the noise level at the plurality of measurement positions Xn is measured by one external noise measurement unit 5, but the present invention is not limited to this. In other words, a plurality of external noise measuring units 5 may be provided, and the external noise measuring units 5 may be arranged and measured for a plurality of measurement positions Xn.
Moreover, the vibration isolator 6 is not limited to this embodiment, and should just be able to suppress the vibration transmitted from the soundproof box 1. For example, it is good also as a structure which suppresses the vibration transmitted from the soundproof box 1 by detecting the vibration of a vibrationproof box and causing the vibration of an antiphase.

  Although the embodiments of the present invention have been described in detail with reference to the drawings, the configurations and combinations of the embodiments in the embodiments are examples, and the addition and omission of configurations are within the scope not departing from the gist of the present invention. , Substitutions, and other changes are possible. Further, the present invention is not limited by the embodiments, and is limited only by the scope of the claims.

The sound absorbing member 2 is not limited to a sheet-like one as in this embodiment. In other words, it is sufficient if it has a predetermined sound absorption coefficient α, and it may be a device that cancels noise of a certain frequency. Further, the same effect as that of the sound absorbing member 2 may be obtained by utilizing resonance.
Furthermore, the soundproof box 1 is not limited to the structure in which the outer surface 501 side is completely opened as in the present embodiment, and a hole is opened in a part, and only a part of the outer surface 501 is opened. It may be a structure.
Further, the output units 22 and 22a are not limited to those that are displayed on the display and output as in the present embodiment, but may be output by informing the operator by voice or the like.

  DESCRIPTION OF SYMBOLS 500 ... Noise measurement object 501 ... Outer surface 100, 200 ... Noise evaluation apparatus 1 ... Soundproof box 1a ... Elastic member Am ... Measurement space 2 ... Sound absorption member 3 ... Internal noise measurement part 4 ... Vibration measurement part 5 ... External noise measurement part X ... Measurement position 101, 201 ... Noise evaluation control unit 11 ... Manual input unit 12 ... Internal noise level input unit Li ... Internal noise level 13 ... Surface vibration value input unit v ... Surface vibration value 14, 14a ... External noise level input unit Lo ... External noise level 15 ... Diffusion sound calculation part S ... Surface area α ... Sound absorption rate Ld ... Diffusion sound noise level 16 ... Radiation sound calculation part Lr ... Radiation sound noise level 17, 17a ... First noise evaluation value calculation part E1 ... No. One noise evaluation value 18, 18a ... first noise determination unit 19 ... theoretical noise level calculation unit Lt ... theoretical noise level Pt ... theoretical acoustic power 20, 20a ... second noise Sound evaluation value calculation unit E2 ... second noise evaluation value 21, 21a ... second noise determination unit 22, 22a ... output unit S101 ... manual input step S10, S20 ... noise evaluation processing step S102 ... diffuse sound calculation step S201 ... measurement space Formation process S202 ... Internal noise measurement process S203 ... Radiated sound calculation process S302, S502 ... External noise measurement process S304, S504 ... First noise evaluation value calculation process S305, S505 ... First noise determination process S306, S406, S510 ... Output process S402 ... Vibration measurement step S403 ... Theoretical noise level calculation step S404 ... Second noise evaluation value calculation step S405 ... Second noise determination step 6 ... Anti-vibration unit 61 ... Elastic support unit 62 ... Damping support unit 23 ... Storage unit 24 ... Rank Giving part S506 ... Storage step S507 ... Number of measurement position confirmation step S508 ... Measurement position Changing step S509 ... order application process

Claims (12)

A soundproof box that is attached to a noise measurement target that is a noise measurement target, covers a part of the outer surface of the noise measurement target, and forms a measurement space in which propagation of noise from the outside is suppressed;
An internal noise measurement unit that is attached to the soundproof box and measures the noise level of the noise in the measurement space as an internal noise level;
A vibration measurement unit attached to the soundproof box and measuring the vibration characteristics of the outer surface as a surface vibration value in the measurement space;
An external noise measurement unit that measures the noise level of noise at a predetermined measurement position outside the soundproof box as an external noise level;
A noise evaluation control unit that performs control processing related to noise evaluation based on the internal noise level, the surface vibration value, and the external noise level;
The noise evaluation control unit
A first noise evaluation value calculation unit that calculates and outputs a ratio of the internal noise level to the external noise level as a first noise evaluation value;
Based on the surface vibration value, a theoretical noise level calculation unit that calculates a noise level of noise directly propagated from the outer surface as a theoretical noise level;
A noise evaluation apparatus comprising: a second noise evaluation value calculation unit that calculates and outputs a ratio of the internal noise level to the theoretical noise level as a second noise evaluation value. Provided inside the soundproof box, comprising a sound absorbing member having a predetermined sound absorption rate,
The noise evaluation control unit
Based on the shape of the soundproof box and the sound absorption rate of the sound absorbing member, a diffused sound calculating unit that calculates a noise level of noise reflected at least once in the measurement space as a diffused sound noise level;
A radiated sound calculation unit for calculating a difference between the diffuse sound noise level and the internal noise level as a radiated sound noise level;
The noise evaluation apparatus according to claim 1, wherein the first noise evaluation value calculation unit calculates the first noise evaluation value by using the radiation noise level as the internal noise level.   The noise evaluation apparatus according to claim 1, wherein the soundproof box is attached to the outer surface in contact with an elastic member.   The noise evaluation device according to any one of claims 1 to 3, wherein the vibration measurement unit is attached to the soundproof box via a vibration isolation unit that suppresses propagation of vibration from the soundproof box. The noise evaluation control unit
The noise evaluation apparatus according to claim 1, further comprising a first noise determination unit that determines whether the first noise evaluation value exceeds a predetermined first reference ratio. The noise evaluation control unit
The noise evaluation apparatus according to claim 1, further comprising a second noise determination unit that determines whether or not the second noise evaluation value exceeds a predetermined second reference ratio. The noise evaluation control unit
The plurality of first noise evaluation values calculated by the first noise evaluation value calculation unit based on the external noise levels measured at the plurality of measurement positions by the external noise measurement unit, and the positions of the plurality of measurement positions A storage unit for storing information in association with each other;
7. The apparatus according to claim 1, further comprising: a rank assigning unit that ranks position information of a plurality of corresponding measurement positions based on the plurality of first noise evaluation values stored in the storage unit. The noise evaluation device according to crab. A measurement space forming step of attaching a soundproof box to a noise measurement object to be measured for noise and covering a part of the outer surface of the noise measurement object to form a measurement space in which the propagation of noise from the outside is suppressed; ,
An internal noise measurement step of measuring the noise level of the noise in the measurement space as an internal noise level;
A vibration measuring step of measuring the vibration characteristics of the outer surface as a surface vibration value in the measurement space;
An external noise measurement step of measuring the noise level of noise at a predetermined measurement position outside the measurement space as an external noise level;
A noise evaluation processing step for performing processing related to noise evaluation based on the internal noise level, the surface vibration value and the external noise level;
The noise evaluation processing step
A first noise evaluation value calculating step of calculating and outputting a ratio of the internal noise level to the external noise level as a first noise evaluation value;
A theoretical noise level calculation step for calculating a noise level of noise directly propagated from the outer surface based on the surface vibration value as a theoretical noise level;
And a second noise evaluation value calculating step of calculating and outputting a ratio of the internal noise level to the theoretical noise level as a second noise evaluation value. A sound absorbing member having a predetermined sound absorption rate is provided inside the soundproof box,
The noise evaluation processing step
Based on the shape of the soundproof box and the sound absorption rate of the sound absorbing member, a diffuse sound calculation step for calculating a noise level of noise reflected at least once in the measurement space as a diffuse sound noise level;
A radiated sound calculation step of calculating a difference between the diffused sound noise level and the internal noise level as a radiated sound noise level,
The noise evaluation method according to claim 8, wherein the first noise evaluation value calculation step calculates the first noise evaluation value by using the radiation noise level as the internal noise level. The noise evaluation processing step
The noise evaluation method according to claim 8 or 9, further comprising a first noise determination step of determining whether or not the first noise evaluation value exceeds a predetermined first reference ratio. The noise evaluation processing step
The noise evaluation method according to any one of claims 8 to 10, further comprising a second noise determination step of determining whether or not the second noise evaluation value exceeds a predetermined second reference ratio. The noise evaluation processing step
The plurality of first noise evaluation values calculated by the first noise evaluation value calculation step based on the plurality of external noise levels measured at the plurality of measurement positions by the external noise measurement step, and the plurality of measurement positions A storage process for storing the positional information in association with each other,
12. The method according to claim 8, further comprising: an ordering step of ranking the position information of the plurality of corresponding measurement positions based on the plurality of first noise evaluation values stored in the storage step. The noise evaluation method according to claim 1.

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