JP2010078570A - Vibration prediction device and vibration prediction program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily predict an influence to a vibration isolation device by construction. <P>SOLUTION: By executing a vibration environment prediction program, a basic screen is displayed (100), and distance from a construction position, the type of construction, and an evaluation reference value are input along the basic screen (102-118). Then, when the display of a prediction vibration value is instructed, vibration at a position where the vibration isolation device has been disposed is calculated for prediction, based on a database for each of the input distance from the construction position, construction type, and a construction machine type stored in advance, thus displaying prediction results and the evaluation reference value on a display (120-126). <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a vibration prediction device and a vibration prediction program, and in particular, a person who occurs when performing construction on an existing building such as seismic isolation repair work, seismic control repair work, seismic reinforcement work, etc. The present invention relates to a vibration prediction apparatus and a vibration prediction program that predict vibrations that cannot be felt.

  In recent years, when a building such as an office building is renewed, the form in which the building is continuously used during construction is increasing. However, when a construction machine is used in a renovation work or the like, vibration and noise are generated on the floor where the construction work is being performed or another floor because the vibration applied to the building frame propagates through the structure. For this reason, in the construction work in which the building is continuously used during construction work, an area that can be used continuously during the construction period is appropriately determined in the building, or construction machines that can be used in the construction work are appropriately selected. Therefore, there is a demand for predicting the magnitude of vibration and noise generated in each part of the building as the construction machine is used before the construction work.

  Therefore, in the technique described in Patent Document 1, the acceleration level of vibration and the sound pressure level of noise generated at a plurality of locations in a building when a construction work is performed on an existing building using a predetermined construction machine. Measure the acceleration level using the assumed value of the excitation force of a given construction machine, calculate the level difference from the measured value, and use the estimated acceleration level to determine the sound pressure level of the noise. Estimate and calculate the level difference from the actual measurement value for each octave band at each location, and calculate the energy average value of the level difference between the acceleration level and the sound pressure level for each octave band. Then, by correcting the assumed value of the excitation force, the excitation force of the predetermined construction machine is estimated, and vibration and noise at an arbitrary place when the predetermined construction machine is used are estimated for the excitation force. Proposed to estimate using values It has been.

On the other hand, in factories that manufacture precision equipment such as semiconductors and liquid crystals, there are increasing demands for seismic isolation repairs, seismic retrofits, seismic retrofitting work, etc. that can be done while you are. In such a case, there is a case where it is advantageous for the client of the construction to carry out the construction without stopping the operation of the factory by using the building as it is during the construction, and there are cases where it is a condition to start the construction. When performing construction while operating the factory, the slight vibration generated by the construction becomes a problem. Especially in factories that manufacture precision equipment such as semiconductors and liquid crystals, micro-vibration due to construction propagates to the production equipment that is in operation, causing a decrease in yield.
JP 2003-42836 A

  However, since the technique described in Patent Document 1 is intended for vibration and noise of 31.5 Hz or more that can be heard as noise by a person, the excitation force of the excitation source is corrected to reproduce the noise. Therefore, it is not intended to predict the influence of construction on a production apparatus (hereinafter referred to as a vibration isolator) that dislikes vibration by evaluating vibrations of 20 Hz or less that cannot be heard by humans.

  For seismic isolation repair work, seismic control repair work, and seismic retrofitting work that is carried out while using a building, the impact of vibration during construction on the vibration isolator becomes a problem in a factory where the construction site does not like vibration. . In such renovation work, it is required to predict how much vibration will affect before the construction starts.

  The present invention has been made in consideration of the above-described facts, and an object thereof is to make it possible to easily predict the influence of the construction on the vibration isolator.

  In order to achieve the above object, the vibration prediction apparatus according to claim 1 is configured to detect vibration at a specific position in the building for each type of construction machine when construction is performed on the existing building using the construction machine. Storage means for storing measured values measured in advance, a setting screen for setting conditions necessary for predicting vibration due to the construction at the position where the vibration evaluation target device is arranged, and prediction of vibration at the position From the display means for displaying the result and the setting screen displayed on the display means, the type of construction machine used when performing the construction, and the excitation point to the position where the evaluation target device is arranged Based on the input means for inputting the distance as the condition, the type and the distance of the construction machine input by the input means, and the measured value stored in the storage means, Is characterized by comprising a prediction means for predicting the vibration due to the construction in the location, the.

  According to the first aspect of the present invention, the storage means is constructed on an existing building using construction machinery (for example, seismic isolation repair work, seismic retrofit work, seismic reinforcement work, etc.). The measured value which measured beforehand the vibration in the specific position in the building for every kind of construction machine is memorized.

  The display means displays a setting screen for setting conditions necessary for predicting vibration due to construction at the position where the vibration evaluation target device is arranged and a vibration prediction result.

  In addition, the input means, on the setting screen displayed on the display means, is the condition of the type of construction machine used when carrying out the construction and the distance from the excitation point to the position where the evaluation target device is placed. Entered.

  Then, the predicting means predicts the vibration due to the construction at the position where the evaluation target device is arranged, based on the type and distance of the construction machine input by the input means and the measured value stored in the storage means. Then, the prediction result predicted by the prediction means is displayed on the display means.

  In other words, just by inputting the type of construction machine used when carrying out the construction and the distance from the excitation point to the position where the evaluation target device is placed, using the input means, the position at which the evaluation target device is placed Since the vibration prediction result can be displayed, it is possible to easily predict the influence on the evaluation target device (vibrating device that dislikes vibration).

  Note that, as in the second aspect of the invention, the storage unit may further store the vibration specification of the evaluation target device as a condition, and the display unit may further display the vibration specification together with the prediction result. Thereby, it can be easily confirmed whether or not the evaluation target apparatus is affected by the construction start.

  Further, as in the invention described in claim 3, the input means further inputs whether the position where the evaluation target device is arranged is on the beam or the slab, and the prediction means inputs the condition input by the input means. The vibration generated by the construction may be predicted using the amplification value stored in advance in the storage means corresponding to the above. In other words, since the propagation characteristics of vibration differ depending on whether the evaluation target device is arranged on a beam or slab, the vibration propagating to the evaluation target device can be predicted more accurately by predicting the vibration in consideration of this. .

  Further, as in the invention according to claim 4, the prediction means uses the measurement result stored in the storage means as the power level of the excitation point, and multiplies the number of hierarchies where the evaluation target device is arranged by a predetermined attenuation value. By subtracting the calculated value as the vertical attenuation from the power level of the excitation point and calculating the horizontal vibration attenuation using the distance attenuation formula of the vibration propagation characteristics in the enclosure, the vibration due to the construction is predicted. It may be. That is, vibrations of 20 Hz or less that cannot be heard even if the vibration becomes noise can be calculated using the distance attenuation formula of the vibration propagation characteristics within the housing, and by using the distance attenuation formula, the vibration with respect to the distance can be calculated. Therefore, it is possible to predict vibration (particularly vibration of 20 Hz or less) that is propagated to the position where the evaluation target device is disposed. In addition, since the propagation of vibration in the vertical direction has a predetermined attenuation value per layer, it can be easily evaluated by subtracting the vertical direction from the excitation source power level as the number of layers x the predetermined attenuation value. Vibrations that are propagated to the location where the device is located can be predicted.

  The vibration prediction program according to claim 5 is for predicting vibration due to the construction at a position where a vibration evaluation target device is arranged when construction is performed on an existing building using a construction machine. A setting display step for displaying a setting screen for setting necessary conditions on a display means, and a construction machine used when performing the construction on an existing building with respect to the setting screen displayed in the setting display step. An input step for inputting the type and the distance from the excitation point to the position where the evaluation target device is arranged using the input means as the condition, the type and distance of the construction machine input in the input step, and the Predicting the vibration at the specific position in the building based on the measured value measured in advance for each type of construction machine. A method is characterized in that to execute a result displaying step of displaying on display means a prediction result predicted by said prediction step comprises the process to the computer.

  According to the invention described in claim 5, in the setting display step, construction (for example, seismic isolation repair work, seismic retrofit work, seismic reinforcement work, etc.) is performed on an existing building using a construction machine. At this time, a setting screen for setting conditions necessary for predicting vibration due to construction at the position where the vibration evaluation target device is arranged is displayed on a display means such as a display.

  Subsequently, in the input step, from the setting screen displayed in the setting display step to the position where the evaluation target device is arranged from the type of the construction machine used when performing construction on the existing building and the excitation point The input is performed using an input means such as a mouse or a keyboard on the condition of the distance. That is, the analyst inputs conditions on the setting screen using an input means such as a keyboard or a mouse.

  Accordingly, in the prediction step, the type and distance of the construction machine input in the input step and the vibration at a specific position in the existing building when the construction is performed are based on the measured values measured in advance for each type of construction machine. Then, the vibration at the position where the evaluation target device is arranged is predicted, and in the result display step, the prediction result predicted in the prediction step is displayed on a display means such as a display.

  In other words, by causing the computer to execute the vibration prediction program, it is only necessary to use the input means to input the type of construction machine used when performing the construction, and the distance from the excitation point to the position where the evaluation target device is placed. Since the vibration prediction result at the position where the evaluation target device is arranged can be displayed, the influence on the evaluation target device (vibration-aversion device that dislikes vibration) can be easily predicted.

  As described above, according to the present invention, the evaluation target device is arranged only by inputting the type of the construction machine used when performing the construction and the distance from the excitation point to the position where the evaluation target device is arranged. Since it is possible to display the prediction result of the vibration at the position, there is an effect that it is possible to easily predict the influence on the evaluation target device (vibrating device that dislikes vibration).

  Hereinafter, an example of an embodiment of the present invention will be described in detail with reference to the drawings. FIG. 1 is a block diagram showing a schematic configuration of a vibration prediction apparatus 10 according to an embodiment of the present invention.

  The vibration prediction apparatus 10 according to the embodiment of the present invention is configured such that a plurality of vibration pickups 12 can be connected. Each vibration pickup 12 can be installed at an arbitrary position in the building, and is generated at a measurement location with use of the construction machine 14 (an example of the construction machine is indicated by the reference numeral “14” in FIG. 1). Measure vibration.

  The vibration pickup 12 is connected to the data recorder 16 when vibration is actually measured, and the vibration measurement result is output to the data recorder 16 and recorded as vibration data in the data recorder 16. The data recorder 16 can be connected to the frequency analyzer 18, and the vibration data recorded in the data recorder 16 is output to the frequency analyzer 18.

  The frequency analyzer 18 performs frequency analysis on the vibration data input from the data recorder 16, and an acceleration level that represents the acceleration level of the generated vibration in units of 1/3 octave band from the vibration data at each measured vibration location. Generate data. In the present embodiment, acceleration level data expressed in units of 1/3 octave band is generated mainly for frequencies of 20 Hz or less.

  The vibration prediction apparatus 10 includes a personal computer (PC) 20. The PC 20 includes a CPU 22, a ROM 24, a RAM 26, and an input / output port 28. These are connected to each other via a bus 30 such as an address bus, a data bus, and a control bus. Connected to the input / output port 28 are a display 32, a mouse 34, a keyboard 36, a hard disk (HDD) 38, and a CD-ROM drive 40 for reading information from the CD-ROM 42, as various input / output devices. Yes.

  The frequency analyzer 18 can be connected to the PC 20, and the acceleration level data described above is input from the frequency analyzer 18 to the PC 20. Then, it is stored in the HDD 38.

  A vibration environment prediction program for predicting vibration described later is installed in the HDD 38 of the PC 20. The vibration environment prediction program of the present embodiment dislikes vibrations used in the building when performing construction (seismic isolation repair, seismic retrofit, seismic reinforcement, etc.) while using the building. It predicts and evaluates vibrations (especially vibrations of 20 Hz or less) transmitted to the production apparatus. That is, it is a program for predicting how much vibration will affect before the start of construction such as seismic isolation repair work, seismic control repair work, and seismic reinforcement work. In the following description, the case of seismic isolation repair will be described as an example.

  There are several methods for installing the vibration environment prediction program on the PC 20. For example, the vibration environment prediction program is recorded on the CD-ROM 42 together with the setup program, and the CD-ROM 42 is stored in the CD-ROM drive of the PC 20. If the CPU 22 is instructed to execute the setup program, the vibration environment prediction program is sequentially read from the CD-ROM 42 and the read program is written in the HDD 38, so that the vibration environment prediction program Installation is performed. In addition, the vibration environment prediction program is stored in a storage device of another information processing device (for example, a network server) connected to the PC 20 via a public telephone line or a computer network (for example, a LAN, the Internet, a wireless communication network, or the like). It is also possible to adopt a configuration in which the PC 20 communicates with the information processing device, is transmitted from the information processing device to the PC 20, is installed in the HDD 38, and is executed by the PC 20.

  Next, actual measurement of vibration necessary for executing the vibration environment prediction program will be described as an operation of the present embodiment.

  In this embodiment, in order to predict vibrations that occur when performing seismic isolation repair work on existing buildings, vibration data generated for each type of construction machine is required. Measure the vibration using the building of each structural type) as a model. In addition, you may make it measure for every kind of building.

  The use location of the construction machine in the building used for the actual measurement (construction site / excitation point by the construction machine) is determined, and the vibration pickup 12 is installed at the location of the construction site. For example, the vibration pickup 12 can be respectively installed on a pillar, a floor, and a wall corresponding to the construction site in the vicinity of the construction site (the same floor as the construction site) and in each floor above the construction site.

  In order to record the actual measurement result of the vibration pickup 12, a data recorder 16 is installed in the vicinity of the vibration pickup 12 (for example, installed on each floor), and each vibration pickup 12 is connected to the data recorder 16. Then, construction (vibration) is performed on the construction site for each type of construction machine (wire saw, wall saw, breaker, baby crusher, etc.).

  As a result, the vibration generated by the construction machine propagates through the solid body (body) to generate a vibration at each measured location, and the vibration measured by each vibration pickup 12 is recorded in the data recorder 16 as vibration data.

  After the actual measurement of vibration, the vibration data recorded in the data recorder 16 is output to the frequency analyzer 18. In the frequency analyzer 18, the vibration data is frequency-analyzed for each 1/3 octave band, output to the PC 20 as acceleration level data, and stored in the HDD 38 as an acceleration database for each type of construction machine.

  As described above, when the vibration environment prediction program is executed in a state where the database is stored in the HDD 38 by actual measurement, when an existing building is subjected to seismic isolation repair work, a predetermined position in the building (the vibration isolator is arranged). The vibration propagating to (position) is predicted. That is, as shown in FIG. 2, the vibration propagating to a predetermined position in the building (the position of the vibration isolator 44) is propagated using the construction machine 14 used in the seismic isolation repair work as an excitation source. Vibration is expected.

  The vibration is predicted by inputting and setting the distance from the construction machine to the prediction target position, the type of the construction machine, and the like.

  Specifically, the vibration prediction is based on the distance attenuation formula of the vibration propagation characteristics in the enclosure by Matsuda et al. Prediction is made using the following equation (1).

L _r = P ₀ −N · log ₁₀ r−α · √f · r (1)

Where L _r is the acceleration at a position r (m) away from the excitation point, P ₀ is the excitation source power level (dB), N is a coefficient (5, 10, 20, etc.) according to the excitation method, and f is Frequency (Hz), α is an attenuation constant, and r is a propagation distance (m). The attenuation constant α is a constant that varies depending on the building structure. For example, the attenuation constant α1 is used in the case of the S structure, and the attenuation constant α2 is used in the case of the RC structure.

  In the present embodiment, each coefficient of equation (1) is determined based on vibration data stored for each type of construction machine in the HDD 38 as a database. Then, by inputting and setting the distance from the excitation point to the prediction point, the type of construction machine to be used, etc., the vibration is predicted by calculating the vibration at the prediction point from Equation (1). In addition, the determination of each coefficient of Formula (1) is determined in advance before the execution of the vibration environment prediction program.

  When each coefficient is determined using the actual measurement value, it is calculated by comparing the acceleration level calculated from (1) with the actual measurement value. At this time, the actual measurement value Ls is calculated for each of the column, wall, and floor. Use the energy average of the measurements. Further, in the present embodiment, the constant N representing the attenuation due to the geometric diffusion among the unknowns in the equation (1) is broken by the vibration state and breaker close to the steady vibration when the RC column is cut. The numerical value of N is changed so as to match the actual measurement in the state of excitation of impact vibration as in

  Here, an example of various screens displayed on the display 32 when the vibration environment prediction program is executed will be briefly described.

  When the vibration environment prediction program is executed, first, a basic screen 46 shown in FIG. 3 is displayed on the display 32 as an initial screen. On the basic screen 46, input items for predicting the vibration environment (in FIG. 3, “distance from construction position”, “selection of seismic isolation work type”, “selection of evaluation reference value”, “display predicted vibration value”). ")" Is displayed for selection.

  When the distance from the construction position is selected and instructed from the basic screen 46, a distance input screen 48 shown in FIG. On the distance input screen 48, “the number of hierarchies between the construction position and the predicted vibration point” as the vertical distance from the construction machine (construction place) to the prediction target position (vibrating device), and “the construction position and “Distance from predicted vibration point”, “Selection on beam or slab” as predicted point state (if vibration propagates from the column, select because the amplitude of vibration is different between beam and slab), “Plotting frequency range” (selection is made to change the output frequency range because the frequency range in which the vibration specifications are specified by the device manufacturer of the vibration isolator 44 may be different), and selection of the vibration attenuation value to be used ( If automatic calculation attenuation is selected, a predetermined default value is given, and the display item for performing the attenuation value can be arbitrarily calculated at the discretion of the analyst instead of the default value). It is displayed in the playing 32.

  In addition, when selection of the type of seismic isolation work is selected from the basic screen 46, the display 32 is displayed on the display 32 of the type of seismic isolation work selection screen 50 shown in FIG. On the seismic isolation work type selection screen 50, vibration data for each 1/3 octave band, which is measured and stored in advance for each type of construction machine to be used, is displayed on the display 32.

  When selection of the evaluation reference value is selected from the basic screen 46, the evaluation reference value selection screen 52 shown in FIG. On the evaluation reference value selection screen 52, a screen for selecting a file stored in advance is displayed on the display 32. In this embodiment, two types of vibration specifications of 1 μm, 1 gal, 2 μm, and 2 gal that are frequently used are prepared up to 100 Hz and up to 200 Hz, and the prediction result can be displayed on the display 32 only by selecting. . In addition, when selecting vibration specifications, each analyst can create them. When creating, it is necessary to pay attention to the display of frequency range, amplitude value, frequency analysis method, etc. For example, for frequency analysis, 1/3 octave analysis, FET analysis, etc. As for amplitude value, attention should be paid to effective value (rms), half amplitude (0-P), full amplitude (P-P), etc. To do.

  When the display of the predicted vibration value is selected from the basic screen 46, the result of vibration prediction is displayed on the display 32. As an example of the vibration prediction result, a prediction result screen 54 in which the vibration environment prediction result shown in FIG. 7 is plotted on the tripartite is displayed on the display 32. FIG. 7 is a prediction result screen of a place at a horizontal distance of 5 m on the five layers when the heavy machinery moves on the pressure plate. The solid line represents the vibration specifications of 1 μm and 1 gal. In this example, the frequency specification of the prediction result is lower than the vibration specifications, so it can be seen that there is no influence on the vibration isolator due to heavy equipment movement.

  Subsequently, the CPU 22 of the PC 20 executes the vibration environment prediction program in accordance with an instruction from the operator in a state where the acceleration database (acceleration level for each type of construction machine serving as the excitation source) is stored in the HDD 38 of the PC 20. The realized vibration prediction process will be described. FIG. 8 is a flowchart showing an example of a flow of vibration prediction processing performed by the vibration prediction apparatus 10 according to the embodiment of the present invention.

  When the execution of the vibration environment prediction program is instructed, first, at step 100, the basic screen 46 shown in FIG. That is, it is possible to predict vibration at a desired position by inputting and setting each item on the basic screen 46 in FIG. 3 in order and selecting and displaying “display predicted vibration value”.

  Next, in step 102, it is determined whether or not an instruction for inputting a distance from the construction position has been issued. In this determination, it is determined whether or not the “distance from the construction position” shown in FIG. 3 has been selected and instructed by the mouse 34, the keyboard 36, or the like. If the determination is affirmed, the process proceeds to step 104, and is denied. If YES, go to step 108.

  In step 104, the distance input screen 48 shown in FIG. As a result, input settings can be made for each item on the distance input screen 48.

  In step 106, it is determined whether or not the distance input is completed. This determination, whether or not the input for each display item on the distance input screen 48 shown in FIG. 4 is finished, determines whether or not the “return button” has been selected by the mouse 34, the keyboard 36, etc., and the determination is affirmed. Wait until the process proceeds to step 128.

  In step 108, it is determined whether or not a construction type input instruction has been issued. The determination is made as to whether or not “selection of seismic isolation work type” shown in FIG. 3 has been instructed to be selected by the mouse 34, the keyboard 36, or the like. If the determination is affirmative, the process proceeds to step 110, If not, the process proceeds to step 114.

  In step 110, the seismic isolation work type selection screen 50 shown in FIG. This makes it possible to select different vibration levels depending on the type of seismic isolation work.

  In step 112, it is determined whether or not the construction type input has been completed. This determination is made by determining whether or not the column number on the seismic isolation work type selection screen 50 shown in FIG. Wait until the process proceeds to step 128.

  In step 114, it is determined whether or not a reference value input instruction has been issued. This determination is made as to whether or not “selection of evaluation reference value” shown in FIG. 3 has been instructed to be selected by the mouse 34, the keyboard 36, or the like. If the determination is affirmative, the process proceeds to step 116, and is denied. If YES, go to step 120.

  At step 116, the evaluation reference value selection screen 52 shown in FIG. 6 is displayed, and the routine proceeds to step 118. Thereby, an evaluation reference value as a vibration specification of the vibration isolator 44 can be selected.

  In step 118, it is determined whether or not a file serving as an evaluation reference value has been selected. The determination is made by selecting an evaluation standard value file stored in advance in the HDD 38, the CD-ROM 42, or the like on the evaluation standard value selection screen 52 in FIG. It is determined whether or not the instruction has been instructed, and the process waits until the determination is affirmed and proceeds to step 128.

  In step 120, it is determined whether or not an instruction to display the predicted vibration value has been issued. This determination is made as to whether or not the “predicted vibration value display” shown in FIG. 3 has been selected and instructed by the mouse 34, the keyboard 36, or the like. If the determination is affirmative, the routine proceeds to step 122, and is denied. If YES, go to step 128.

  In step 122, it is determined whether or not all inputs have been completed. In this determination, it is determined whether or not each input has been completed in each of the steps. If the determination is affirmative, the process proceeds to step 124. If the determination is negative, the process returns to step 100 to return to the basic screen. 46 is displayed. It should be noted that when the basic screen 46 is displayed when all inputs have not been completed, items that are not set for input may be notified. For example, processing such as changing the color of an item that has not been set for input may be performed.

In step 124, vibration prediction calculation is performed, and the routine proceeds to step 126. Specifically, the vibration prediction calculation uses the above-described equation (1) as an acceleration measured in advance for each ３ octave band (vibration data for each type of construction machine to be used selected in step 110). by substituting to ₀ to calculate the _{L r.} At this time, using the number of hierarchies input on the distance input screen 48 in FIG. 4, the number of hierarchies × predetermined value (in this embodiment, the predetermined value is obtained because the attenuation per layer is a constant value regardless of the frequency). Is subtracted from the reference acceleration P ₀ , thereby calculating the vertical attenuation, and substituting the horizontal distance into r in equation (1) to calculate L _r . Thus, the vibration of the target position is predicted.

In addition, since the degree of amplification (amplification value) of vibration from the column differs depending on whether the position of the predicted point is on the beam or the slab, the calculated L _r is set according to the state of the predicted point input on the distance input screen 48. Then, a predetermined correction is performed. For example, by performing the correction of such adds a different value depending on the state of the prediction point relative to the calculated L _r, it is possible to consider the amplification degree of the vibration caused by or on the beam on or slab. In the present embodiment, the calculated _Lr is corrected. However, the present invention is not limited to this. For example, the coefficient of equation (1) may be different on the beam or slab. Other correction methods may be applied.

  In step 126, the calculated vibration prediction result screen is displayed, and the process proceeds to step 128. For example, as shown in FIG. 7, a prediction result screen 54 on which the calculated vibration predicted value and the evaluation reference value selected on the evaluation reference value selection screen 52 in FIG. 6 are displayed. Thus, the predicted vibration level and the vibration specification of the vibration isolation device 44 can be confirmed on the displayed screen, and it can be evaluated whether the vibration isolation device is affected by the construction.

  In step 128, it is determined whether an instruction to end the program has been issued. The determination is made as to whether or not “END OF PROGRAM” on the basic screen 46 in FIG. 3 has been instructed to be selected by the mouse 34, the keyboard 36, or the like. If the process is repeated and the determination is affirmed, the series of processes ends.

  As described above, by simply inputting the type of the construction machine 14 of the vibration source, the information about the distance from the vibration source to the vibration isolator 44, and the evaluation reference value of the vibration isolator 44, the seismic isolation work The vibration of 20 Hz or less propagated to the position where the vibration isolator 44 is disposed can be mainly predicted. As a result, it is possible to easily evaluate the influence of vibration on the vibration isolator 44 by the construction machine 14 that has been difficult to measure accurately so far.

  In addition, since the vibration specifications of the vibration isolator 44 are simultaneously displayed on the display 32 together with the vibration prediction results, it is possible to easily compare the vibration prediction results with the vibration specifications of the vibration isolation device 44 and start construction. The degree of influence on the vibration isolator 44 can be grasped in advance, and a construction plan can be made such as when the vibration isolator 44 is not used when the vibration influence is concerned.

  In the above embodiment, the evaluation reference value is set in order to display the evaluation reference value together with the prediction result on the prediction result screen 54. However, the setting of the evaluation reference value is omitted and the vibration prediction result is set. May be displayed on the prediction result screen 54.

It is a block diagram which shows schematic structure of the vibration prediction apparatus concerning embodiment of this invention. It is a figure which shows the outline of the vibration which propagates from the construction machine of a vibration source to the vibration isolator in a building. It is a figure which shows an example of the basic screen displayed when a vibration environment prediction program is performed. It is a figure which shows an example of the distance input screen displayed when "distance from construction position" of a basic screen is instruct | indicated. It is a figure which shows an example of the type selection screen of seismic isolation work displayed when selection selection of "type selection of seismic isolation construction" of a basic screen is carried out. It is a figure which shows an example of the selection screen of the evaluation reference value displayed when "selection of evaluation reference value" of a basic screen is instruct | indicated. It is a figure which shows the prediction result of the place 5 m apart on the 5th layer when the heavy machinery moves on a pressure-resistant plate. It is a flowchart which shows an example of the flow of the vibration prediction process performed with the vibration prediction apparatus concerning embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Vibration prediction apparatus 12 Vibration pickup 14 Construction machine 16 Data recorder 18 Frequency analyzer 20 PC
32 Display 34 Mouse 36 Keyboard 38 HDD
44 Vibration isolation device 46 Basic screen 48 Distance input screen 50 Seismic isolation type selection screen 52 Evaluation standard value selection screen 54 Prediction result screen

Claims (5)

Storage means for storing a measurement value obtained by previously measuring, for each type of construction machine, vibration at a specific position in the building when construction is performed on an existing building using a construction machine;
A setting screen for setting conditions necessary for predicting vibration due to the construction at a position where a vibration evaluation target device is arranged, and a display means for displaying a prediction result of vibration at the position;
On the setting screen displayed on the display means, the type of construction machine used when performing the construction and the distance from the excitation point to the position where the evaluation target device is arranged are input as the condition. Input means for,
Prediction means for predicting vibration due to the construction at the position based on the type and distance of the construction machine input by the input means, and the measurement value stored in the storage means;
A vibration prediction apparatus comprising: The storage means further stores a vibration specification of the evaluation target device as the condition,
The vibration prediction apparatus according to claim 1, wherein the display unit further displays the vibration specification stored together with the prediction result. The input means further inputs as the condition whether the position where the evaluation target device is arranged is on a beam or a slab,
The prediction unit predicts vibration generated by the construction at the position using an amplification value stored in advance in the storage unit corresponding to the condition input by the input unit. The vibration prediction apparatus described.   The prediction means uses the measurement result stored in the storage means as the power level of the excitation point, and the value obtained by multiplying the number of hierarchies where the evaluation target device is arranged by a predetermined attenuation value as the attenuation in the vertical direction. The vibration due to the construction at the position is predicted by calculating the attenuation of the vibration in the horizontal direction by subtracting from the power level of the excitation point and using the distance attenuation formula of the vibration propagation characteristic in the housing. The vibration prediction apparatus according to claim 1. Means for displaying a setting screen for setting conditions necessary for predicting vibration due to the construction at the position where the vibration evaluation target device is placed when performing construction on an existing building using a construction machine Setting display step to be displayed on
For the setting screen displayed in the setting display step, the type of construction machine used when performing the construction on an existing building, and the distance from the excitation point to the position where the evaluation target device is arranged are An input step for inputting using an input means as a condition;
Based on the measurement value measured in advance for each type of construction machine, the type and distance of the construction machine input in the input step, and the vibration at a specific position in the building when the construction was performed. A prediction step for predicting vibration;
A result display step of displaying the prediction result predicted in the prediction step on a display means;
A vibration prediction program for causing a computer to execute a process including: