The URL can be used to link to this page

Home My WebLink AboutAppendix G_Noise Report CARLSBAD CLOVIS IRVINE LOS ANGELES PALM SPRINGS POINT RICHMOND RIVERSIDE ROSEVILLE SAN LUIS OBISPO 157 Park Place, Pt. Richmond, California 94801 510.236.6810 www.lsa.net MEMORANDUM DATE: June 8, 2023 TO: Aaron Anderson, Public Storage FROM: J.T. Stephens, Principal Moe Abushanab, Noise Engineer SUBJECT: Noise and Vibration Impact Analysis: Proposed Public Storage Redevelopment Project in Fontana, California INTRODUCTION AND PROJECT DESCRIPTION This noise and vibration impact analysis has been prepared to evaluate the potential impacts associated with the proposed Public Storage Redevelopment Project (project) in the City of Fontana (City), San Bernardino County, California . This report is intended to satisfy the City’s requirement for a project-specific noise and vibration impact analysis and examines the impacts of the proposed project to the existing noise-sensitive uses adjacent to the project site. To properly account for the impacts associated with the proposed project, existing noise levels are assessed based on noise measurement data gathered in the vicinity of the project site (from October 24, 2022, to October 25, 2022) and project-related noise and vibration levels generated are based on estimated construction equipment. Traffic volumes from the Trip Generation Analysis for the Public Storage Fontana Project1 and additional stationary sources on the project site were also evaluated. Location and Description The 5.33-acre project site is located at 17173 Valley Boulevard in Fontana. Figure 1 shows the project location and Figure 2, Site Plan, provides an overview of the proposed site plan (all figures are in Attachment A). Public Storage owns and operates the self-storage facility at 17173 Valley Blvd. The property includes a vacant portion on the west side of the existing facility. This vacant portion is partially paved and is used for truck parking for the adjacent hotel, which was approved as part of Design Review No. 94- 036. This area sits behind the SureStay Hotel, between the hotel parking and the freeway. The proposed project includes construction of a new three-story self-storage building on the vacant portion of the property including new parking, landscaping, and lighting. The project includes demolition of the existing two-story building at the existing entrance to the self-storage facility and construction of a new one-story office. Parking and access in the entrance area will be reconfigured to meet the City’s form-based code. Landscaping will also be added to this area. 1 LSA. 2022. Trip Generation Analysis for the Public Storage Fontana. November. 6/8/23 «\\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx» 2 The existing buildings include about 90,170 SF of self-storage including the rental office. One existing two story self-storage building of 9,298 SF would be demolished to provide for fire access to the new three-story building of approximately 109,566 SF. The proposed building will be climate controlled and all the storage units in the new building will be accessible only from the inside of the building. In addition, the new building would be all electric and would not use natural gas. The existing two-story self-storage building of 5,724 SF that includes the existing rental office, as well as portions of two one-story self-storage buildings totaling 1,432 SF will be demolished to provide room for the new one-story rental office building. The new rental office will include 1,268 SF. The parking and circulation at the entrance to the facility on Valley Boulevard will also be reconfigured to a better layout for customers. Parking for the new three-story building will be provided on the east side of the building, adjacent to the loading lobby for the building. Parking for the new three-story self-storage building would be provided on the east side of the building, adjacent to the loading lobby. The operational noise analysis for the proposed project anticipates truck loading and unloading activities associated with the project would occur only in the parking stalls located east of the proposed building. Nine semi-trailer truck parking stalls currently located at the southwestern portion of the project site serve patrons of the neighboring hotel and are not part of the self-storage facility. The proposed three-story self-storage building would be constructed in the area currently occupied by the truck parking stalls, so they would be relocated to the north of the new three-story self-storage building in order to facilitate an existing shared easement agreement between the Project Applicant and hotel owner. Truck parking and loading and unloading activities in the semi-trailer truck parking stalls to be relocated north of the proposed self- storage building would result from hotel operations and not from operation of the proposed project. Therefore, these activities are not included in the operational noise analysis. It is expected that construction of the project would start in May 2024 and be completed in April 2025. Based on the preliminary grading plans, 1,000 cubic yards of soil would be imported. Demolition, grading, and building activities would involve the use of construction equipment such as rubber-tired dozers, tractors/loaders/backhoes, excavators, graders, scrapers, cranes, forklifts, generators, welders, air compressors, and paving equipment. METHODOLOGY The evaluation of noise impacts associated with the proposed project includes the following: • A determination of the short-term construction noise and vibration levels at off-site noise- sensitive uses and comparison to the City’s General Plan and Municipal Code Ordinance requirements; • A determination of the long-term noise levels at off-site noise sensitive uses and comparison of those levels to the City's pertinent noise standards; and • If necessary, a determination of required mitigation measures, such as noise barriers, to reduce long-term noise impacts from all sources. 6/8/23 «\\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx» 3 CHARACTERISTICS OF SOUND Noise is usually defined as unwanted sound. Noise consists of any sound that may produce physiological or psychological damage and/or interfere with communication, work, rest, recreation, and sleep. To the human ear, sound has two significant characteristics: pitch and loudness. Pitch is generally an annoyance, while loudness can affect the ability to hear. Pitch is the number of complete vibrations, or cycles per second, of a wave resulting in the tone’s range from high to low. Loudness is the strength of a sound that describes a noisy or quiet environment and is measured by the amplitude of the sound wave. Loudness is determined by the intensity of the sound waves combined with the reception characteristics of the human ear. Sound intensity refers to how hard the sound wave strikes an object, which in turn produces the sound’s effect. This characteristic of sound can be precisely measured with instruments. The analysis of a project defines the noise environment of the project area in terms of sound intensity and its effect on adjacent sensitive land uses. Measurement of Sound Sound intensity is measured through the A-weighted scale to correct for the relative frequency response of the human ear. That is, an A-weighted noise level de-emphasizes low and very high frequencies of sound similar to the human ear’s de-emphasis of these frequencies. Unlike linear units (e.g., inches or pounds), decibels are measured on a logarithmic scale representing points on a sharply rising curve. For example, 10 decibels (dB) is 10 times more intense than 1 dB, 20 dB is 100 times more intense than 1 dB, and 30 dB is 1,000 times more intense than 1 dB. Thirty decibels (30 dB) represent 1,000 times as much acoustic energy as 1 dB. The decibel scale increases as the square of the change, representing the sound pressure energy. A sound as soft as human breathing is about 10 times greater than 0 dB. The decibel system of measuring sound gives a rough connection between the physical intensity of sound and its perceived loudness to the human ear. A 10 dB increase in sound level is perceived by the human ear as only a doubling of the loudness of the sound. Ambient sounds generally range from 30 dB (very quiet) to 100 dB (very loud). Sound levels are generated from a source, and their decibel level decreases as the distance from that source increases. Sound dissipates exponentially with distance from the noise source. For a single-point source, sound levels decrease approximately 6 dB for each doubling of distance from the source. This drop-off rate is appropriate for noise generated by stationary equipment. If noise is produced by a line source (e.g., highway traffic or railroad operations), the sound decreases 3 dB for each doubling of distance in a hard site environment. Similarly, line sources with intervening absorptive vegetation or line sources that are located at a great distance to the receptor would decrease 4.5 dB for each doubling of distance. There are many ways to rate noise for various time periods, but an appropriate rating of ambient noise affecting humans also accounts for the annoying effects of sound. The equivalent continuous sound level (Leq) is the total sound energy of time-varying noise over a sample period. However, the predominant rating scales for human communities in the State of California are the Leq and Community Noise Equivalent Level (CNEL) or the day-night average noise level (Ldn) based on 6/8/23 «\\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx» 4 A-weighted decibels (dBA). CNEL is the time-varying noise over a 24-hour period, with a 5 dBA weighting factor applied to the hourly Leq for noises occurring from 7:00 p.m. to 10:00 p.m. (defined as relaxation hours), and a 10 dBA weighting factor applied to noises occurring from 10:00 p.m. to 7:00 a.m. (defined as sleeping hours). Ldn is similar to the CNEL scale but without the adjustment for events occurring during the evening hours. CNEL and Ldn are within 1 dBA of each other and are normally interchangeable. The City uses the CNEL noise scale for long-term noise impact assessment. Other noise rating scales of importance when assessing the annoyance factor include the maximum instantaneous noise level (Lmax), which is the highest exponential time-averaged sound level that occurs during a stated time period. The noise environments discussed in this analysis for short-term noise impacts are specified in terms of maximum levels denoted by Lmax, which reflects peak operating conditions and addresses the annoying aspects of intermittent noise. Lmax is often used together with another noise scale or noise standards in terms of percentile noise levels in noise ordinances for enforcement purposes. For example, the L10 noise level represents the noise level exceeded 10 percent of the time during a stated period. The L50 noise level represents the median noise level (i.e., half the time the noise level exceeds this level, and half the time it is less than this level). The L90 noise level represents the noise level exceeded 90 percent of the time and is considered the background noise level during a monitoring period. For a relatively constant noise source, the Leq and L50 are approximately the same. Noise impacts can be described in three categories. The first category is audible impacts that refer to increases in noise levels noticeable to humans. Audible increases in noise levels generally refer to a change of 3.0 dB or greater because this level has been found to be barely perceptible in exterior environments. The second category, potentially audible, refers to a change in the noise level between 1.0 and 3.0 dB. This range of noise levels has been found to be noticeable only in laboratory environments. The last category is changes in noise levels of less than 1.0 dB, which are inaudible to the human ear. Only audible changes in existing ambient or background noise levels are considered potentially significant. Physiological Effects of Noise Physical damage to human hearing begins at prolonged exposure to noise levels higher than 85 dBA. Exposure to high noise levels affects the entire system, with prolonged noise exposure in excess of 75 dBA increasing body tensions, thereby affecting blood pressure and functions of the heart and the nervous system. In comparison, extended periods of noise exposure above 90 dBA would result in permanent cell damage. When the noise level reaches 120 dBA, a tickling sensation occurs in the human ear even with short-term exposure. This level of noise is called the threshold of feeling. As the sound reaches 140 dBA, the tickling sensation is replaced by the feeling of pain in the ear. This is called the threshold of pain. A sound level of 160–165 dBA will result in dizziness or loss of equilibrium. The ambient or background noise problem is widespread and generally more concentrated in urban areas than in outlying less developed areas. Table A lists full definitions of acoustical terms, and Table B shows common sound levels and their sources. 6/8/23 «\\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx» 5 Table A: Definitions of Acoustical Terms Term Definitions Decibel, dB A unit of level that denotes the ratio between two quantities proportional to power, the number of decibels is 10 times the logarithm (to the base 10) of this ratio. Frequency, Hz Of a function periodic in time, the number of times that the quantity repeats itself in one second (i.e., number of cycles per second). A-Weighted Sound Level, dBA The sound level obtained by use of A-weighting. The A-weighting filter deemphasizes the very low and very high frequency components of the sound in a manner similar to the frequency components of the sound in a manner similar to the frequency response of the human ear and correlates well with subjective reactions to noise. All sound levels in this assessment are A-weighted, unless reported otherwise. L01, L10, L50, L90 The fast A-weighted noise levels equaled or exceeded by a fluctuating sound level for 1 percent, 10 percent, 50 percent, and 90 percent of a stated time period. Equivalent Continuous Noise Level, Leq The level of a steady sound that, in a stated time period and at a stated location, has the same A-weighted sound energy as the time varying sound. Community Noise Equivalent Level, CNEL The 24-hour A-weighted average sound level from midnight to midnight, obtained after the addition of 5 dB to sound levels occurring in the evening from 7:00 p.m. to 10:00 p.m. and after the addition of 10 dB to sound levels occurring in the night between 10:00 p.m. and 7:00 a.m. Day/Night Noise Level, Ldn The 24-hour A-weighted average sound level from midnight to midnight, obtained after the addition of 10 dB to sound levels occurring in the night between 10:00 p.m. and 7:00 a.m. Lmax, Lmin The maximum and minimum A-weighted sound levels measured on a sound level meter, during a designated time interval, using fast time averaging. Ambient Noise Level The all-encompassing noise associated with a given environment at a specified time, usually a composite of sound from many sources at many directions, near and far; no particular sound is dominant. Intrusive The noise that intrudes over and above the existing ambient noise at a given location. The relative intrusiveness of a sound depends upon its amplitude, duration, frequency, and time of occurrence and tonal or informational content, as well as the prevailing ambient noise level. Source: Handbook of Acoustical Measurements and Noise Control (Harris, Cyril M., 1991). 6/8/23 «\\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx» 6 Table B: Common Sound Levels and Noise Sources Source: LSA. (2016). CHARACTERISTICS OF VIBRATION Vibration refers to ground-borne noise and perceptible motion. Ground-borne vibration is almost exclusively a concern inside buildings and is rarely perceived as a problem outdoors, where the motion may be discernible. Typically, there is more adverse reaction to effects associated with the shaking of a building. Vibration energy propagates from a source through intervening soil and rock layers to the foundations of nearby buildings. The vibration then propagates from the foundation throughout the remainder of the structure. Building vibration may be perceived by occupants as the motion of building surfaces, the rattling of items on shelves or hanging on walls, or a low-frequency rumbling noise. The rumbling noise is caused by the vibration of walls, floors, and ceilings that radiate sound waves. Typical sources of ground-borne vibration are construction activities (e.g., blasting, pile driving, and operating heavy-duty earthmoving equipment), steel-wheeled trains, and occasional traffic on rough 6/8/23 «\\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx» 7 roads. Problems with both ground-borne vibration and noise from these sources are usually localized to areas within approximately 100 feet (ft) of the vibration source, although there are examples of ground-borne vibration causing interference out to distances greater than 200 ft (FTA 2018)2. When roadways are smooth, vibration from traffic, even heavy trucks, is rarely perceptible. It is assumed for most projects that the roadway surface will be smooth enough that ground-borne vibration from street traffic will not exceed the impact criteria; however, the construction of the project could result in ground-borne vibration that may be perceptible. Ground-borne vibration has the potential to damage buildings. Although it is very rare for typical construction activities to cause even cosmetic building damage, it is not uncommon for construction processes such as blasting and pile driving to cause vibration of sufficient amplitudes to damage nearby buildings (FTA 2018)2. Ground-borne vibration that may resulting in damage is usually measured in terms of peak particle velocity (PPV). APPLICABLE NOISE STANDARDS The applicable noise standards governing the project site include the criteria in the City’s Noise Element of the General Plan (Noise Element) and the City of Fontana Municipal Code (FMC). City of Fontana Noise Element of the General Plan The Noise Element provides the City’s goals and policies related to noise, including the land use compatibility guidelines for community exterior noise environments. The City has identified the following policies in the Noise Element: Policy. Residential land uses and areas identified as noise-sensitive shall be protected from excessive noise from non-transportation sources including industrial, commercial, and residential activities and equipment. Actions. a. Projects located in commercial areas shall not exceed stationary- source noise standards at the property line of proximate residential or commercial uses. b. Industrial uses shall not exceed commercial or residential stationary source noise standards at the most proximate land uses. c. Non-transportation noise shall be considered in land use planning decisions. 2 Federal Transit Administration (FTA). 2018. Office of Planning and Environment. Transit Noise and Vibration Impact Assessment Manual (FTA Manual). FTA Report 0123. September. 6/8/23 «\\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx» 8 d. Construction shall be performed as quietly as feasible when performed in proximity to residential or other noise sensitive land uses. City of Fontana Municipal Code Operational Noise Standards. This project utilizes the City’s residential noise control guidelines for determining and mitigating non-transportation or stationary noise source impacts from operations found in Section 30-469. For residential zoning districts, Section 30-469 indicates that “no use shall create or cause to be created any sound that exceeds the ambient noise standards outlined in Table 30-469” (Table C below). The performance standards found in Section 30-469 limit the exterior noise level to 65 dBA Leq during the daytime and nighttime hours at sensitive receiver locations. Table C: Operational Noise Standards Noise Level Descriptor Daytime (7:00 a.m. to 10:00 p.m.) Nighttime (10:00 p.m. to 7:00 a.m.) Hourly Equivalent Level (Leq), dBA 65 65 Source: City of Fontana (2021). dBA = A-weighted decibels Leq = equivalent continuous sound level Construction Noise Standards. The City has set restrictions to control noise impacts associated with the construction of the proposed Project. According to Section 18-63(b)(7), Construction or repairing of buildings or structures, construction activity is limited: between the hours of 7:00 a.m. and 6:00 p.m. on weekdays and between the hours of 8:00 a.m. and 5:00 p.m. on Saturdays except in the case of urgent necessity. State of California Green Building Standards Code The State of California’s Green Building Standards Code (CALGreen) contains mandatory measures for non-residential building construction in Section 5.507 on Environmental Comfort. These noise standards are applied to new construction in California for controlling interior noise levels resulting from exterior noise sources. The regulations specify that acoustical studies must be prepared when non-residential structures are developed in areas where the exterior noise levels exceed 65 dBA CNEL, such as within a noise contour of an airport, freeway, railroad, and other noise source. If the development falls within an airport or freeway 65 dBA CNEL noise contour, buildings shall be construction to provide an interior noise level environment attributable to exterior sources that does not exceed an hourly equivalent level of 50 dBA Leq in occupied areas during any hour of operation. Federal Transit Administration Though the City does not have daytime construction noise level limits for activities that occur with the specified hours of Section 18-63(b)(7), to determine potential CEQA noise impacts, construction noise was assessed using criteria from the Transit Noise and Vibration Impact Assessment Manual (FTA 6/8/23 «\\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx» 9 2018) (FTA Manual)3. Table D shows the FTA’s Detailed Assessment Construction Noise Criteria based on the composite noise levels per construction phase. Table D: Detailed Assessment Daytime Construction Noise Criteria Land Use Daytime 1-hour Leq (dBA) Residential 80 Commercial 85 Industrial 90 Source: Transit Noise and Vibration Impact Assessment Manual (FTA 2018). dBA = A-weighted decibels Leq = equivalent continuous sound level APPLICABLE VIBRATION STANDARDS The following information provides standards to which potential vibration impacts will be compared. City of Fontana General Plan Update As discussed in the The City does not specify the vibration level that can be felt but indicates predicted vibration levels that would occur during construction hours specified pursuant to Municipal Code Section 18-63(b)(7) (between the hours of 7:00 a.m. and 6:00 p.m. on weekdays and between the hours of 8:00 a.m. and 5:00 p.m. on Saturdays) are considered “an acceptable intrusion of the ambient noise within that project area.”4 Federal Transit Administration Vibration standards included in the Federal Transit Administration’s (FTA) Transit Noise and Vibration Impact Assessment Manual (2018) (FTA Manual) are used in this analysis for ground-borne vibration impacts on surrounding buildings. The criteria for environmental impacts resulting from ground-borne vibration are based on the maximum levels for a single event. The City’s Municipal Code does not include specific criteria for assessing vibration impacts associated with damage. Therefore, for the purpose of determining the significance of vibration impacts experienced at sensitive uses surrounding the project site, the guidelines within the 2018 FTA Manual have been used to determine vibration impacts (refer to Table E, below). 3 Federal Transit Administration. 2018. Transit Noise and Vibration Impact Assessment Manual – FTA Report No. .0123. September. 4 City of Fontana. Fontana Forward General Plan Update 2015-2035. Draft Environmental Impact Report. SCH #2016021099. Page 5.10-7. June 8, 2018. 6/8/23 «\\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx» 10 Table E: Construction Vibration Damage Criteria Building Category PPV (in/sec) Reinforced concrete, steel, or timber (no plaster) 0.50 Engineered concrete and masonry (no plaster) 0.30 Non-engineered timber and masonry buildings 0.20 Buildings extremely susceptible to vibration damage 0.12 Source: Transit Noise and Vibration Impact Assessment Manual (FTA 2018). in/sec = inches per second PPV = peak particle velocity The FTA Manual (2018) guidelines show that a vibration level of up to 0.2 in/sec in PPV is considered safe for non-engineered timber and masonry buildings which are the types of buildings located on properties adjacent to the project site. Accordingly, the 0.2 in/sec in the PPV threshold was used to evaluate vibration impacts at the nearest structures to the site. THRESHOLDS OF SIGNIFICANCE Based on Guidelines for the Implementation of the California Environmental Quality Act (CEQA), Appendix G, Public Resources Code, Sections 15000–15387, a project will normally have a significant effect on the environment related to noise if it will substantially increase the ambient noise levels for adjoining areas or conflict with adopted environmental plans and the goals of the community in which it is located. The State CEQA Guidelines indicate that a project would have a significant impact on noise if it would result in: • Generation of a substantial temporary or permanent increase in ambient noise levels in the vicinity of the project in excess of standards established in the local general plan or noise ordinance, or applicable standards of other agencies; • Generation of excessive ground-borne vibration or ground-borne noise levels; or • For a project located within the vicinity of a private airstrip or an airport land use plan or, where such a plan has not been adopted, within two miles of a public airport or public use airport, expose people residing or working in the project area to excessive noise levels. OVERVIEW OF THE EXISTING NOISE ENVIRONMENT The primary existing noise sources in the project area are transportation facilities, including Valley Boulevard and San Bernardino Freeway (I-10). In addition, periodic storage operations such as loading and unloading are audible at the project site. In order to assess the existing noise conditions in the area, long-term noise measurements were conducted at the project site. Two long-term, 24-hour measurements were taken from October 24, 2022, to October 25, 2022. The locations of the noise measurements are shown on Figure 3, and the results are summarized in Table F. Noise measurement data information are provided in Attachment B of this analysis. 6/8/23 «\\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx» 11 Table F: Existing Noise Level Measurements Location Number Location Description Daytime Noise Levels1 (dBA Leq) Evening Noise Levels2 (dBA Leq) Nighttime Noise Levels3 (dBA Leq) Average Daily Noise Levels (dBA CNEL) Primary Noise Sources LT-1 At the northwest corner of project site, approximately 200 ft from Valley Boulevard, near a storage unit. 59.1 – 66.0 59.1 – 61.4 60.5 – 66.7 70.0 Traffic on Valley Blvd. Loading/unloading. Vehicle pass by. LT-2 At the southwest corner of project site, on a light pole, approximately 70 feet from edge of I-10 77.3 – 79.5 77.1 – 77.7 74.4 – 78.8 83.5 Traffic on I-10. Heavy duty truck training operations. Source: Compiled by LSA (October 2022). 1 Daytime Noise Levels = noise levels during the hours of 7:00 a.m. to 7:00 p.m. 2 Evening Noise Levels = noise levels during the hours of 7:00 p.m. to 10:00 p.m. 3 Nighttime Noise Levels = noise levels during the hours of 10:00 p.m. to 7:00 a.m. CNEL = Community Noise Equivalent Level dBA = A-weighted decibels ft = foot/feet Leq = equivalent continuous sound level AIRCRAFT NOISE The project site is approximately 8.8 miles east of Ontario International Airport (ONT). Based on a review of the maps within the Los Angeles County Airport Land Use Commission [ALUC] website5, the project site is located well outside the 65 dBA CNEL contour of ONT. Therefore, there would be no impact from aircraft noise, and no further analysis is necessary. Sensitive Land Uses in the Project Vicinity Certain land uses are considered more sensitive to noise than others are. Examples of these include residential areas, educational facilities, hospitals, childcare facilities, and senior housing. Land uses adjacent to the project site include the following: • Northwest: Fontana Medical Center opposite Valley Boulevard, approximately 480 ft from the project site property line. • East: Existing Extra Space Storage adjacent to the project site and single-family residential units located approximately 190 ft from the project site property line. • South: San Bernardino Freeway (I-10). 5 County of Los Angeles Airport Land Use Commission. (ALUC). 2003. Airport Influence Area Maps. Website: https://planning.lacounty.gov/aluc/airports (accessed June 2022). 6/8/23 «\\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx» 12 • West: Existing SureStay Hotel, approximately 10 ft from the project site property line, and commercial uses approximately 165 ft from project site property line. The nearest sensitive receptors are: • West: Existing SureStay Hotel approximately 10 ft from the project site property line • East: Existing single-family residential units (Sierra Mobile Estates) approximately 190 ft from the project site property line. PROJECT IMPACT ANALYSIS The proposed project would result in short-term construction noise and vibration impacts and long- term mobile source noise and vibration impacts as described below. Short-Term Construction-Related Impact Analysis Project construction would result in short-term noise and vibration. Maximum construction noise would be short-term, generally intermittent depending on the construction phase, and variable depending on receiver distance from the active construction zone. The duration of various types of construction noise and vibration would vary from one day to several weeks depending on the phase of construction. The levels and types of impacts that may occur during construction are described below. Construction Noise Analysis Two types of short-term noise would occur during project construction, including: (1) equipment delivery and construction worker commutes; and (2) project construction operations. The first type of short-term construction noise would result from the transport of construction equipment and materials to the project site and construction worker commutes. These transportation activities would incrementally raise noise levels on access roads leading to the site. It is expected that larger trucks used in equipment delivery would generate higher noise impacts than trucks associated with worker commutes. The single-event noise from equipment trucks passing at a distance of 50 ft from a sensitive noise receptor would reach a maximum level of 84 dBA Lmax. However, the pieces of heavy equipment for construction activities would be moved on site just one time and would remain on site for the duration of each construction phase. This one-time trip, when heavy construction equipment is moved on and off site, would not add to the daily traffic noise in the project vicinity. The total number of daily vehicle trips would be minimal when compared to existing traffic volumes on the affected streets, and the long-term noise level changes associated with these trips would not be perceptible. Therefore, equipment transport noise and construction- related worker commute impacts would be short term and would not result in a significant off-site noise impact. No mitigation is required. The second type of short-term noise impact is related to noise generated during demolition, site preparation, grading, building construction, architectural coating, and paving on the project site. Construction is undertaken in discrete steps, each of which has its own mix of equipment, and 6/8/23 «\\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx» 13 consequently, its own noise characteristics. These various sequential phases would change the character of the noise generated on the project site. Therefore, the noise levels vary as construction progresses. Despite the variety in the type and size of construction equipment, similarities in the dominant noise sources and patterns of operation allow construction-related noise ranges to be categorized by work phase. Table G lists the maximum noise levels recommended for noise impact assessments for typical construction equipment based on a distance of 50 ft between the construction equipment and a noise receptor. Typical operating cycles for these types of construction equipment may involve 1–2 minutes of full power operation followed by 3–4 minutes at lower power settings. Table G: Typical Construction Equipment Noise Levels Equipment Description Acoustical Usage Factor (%) Maximum Noise Level (Lmax) at 50 ft Compressor 100 81 Concrete Mixer 40 85 Concrete Pump 40 85 Crane 16 83 Dozer 40 80 Forklift 20 75 Front [End] Loader 40 79 Generator 100 78 Grader 8 85 Scraper 40 88 Welder 40 74 Sources: Noise from Construction Equipment and Operations, Building Equipment, and Home Appliances (USEPA 1971); Roadway Construction Noise Model (FHWA 2006). ft = foot/feet Lmax = maximum instantaneous sound level In addition to the reference maximum noise level, the usage factor provided in Table G is utilized to calculate the hourly noise level impact for each piece of equipment based on the following equation:   −+=50log20.).log(10..)(DFULEequipLeq where: Leq (equip) = Leq at a receiver resulting from the operation of a single piece of equipment over a specified time period E.L. = Noise emission level of the particular piece of equipment at a reference distance of 50 ft U.F. = Usage factor that accounts for the fraction of time that the equipment is in use over the specified period of time D = Distance from the receiver to the piece of equipment 6/8/23 «\\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx» 14 Each piece of construction equipment operates as an individual point source. Utilizing the following equation, a composite noise level can be calculated when multiple sources of noise operate simultaneously: 𝐿𝐿𝐿𝐿𝐿𝐿 (𝑐𝑐𝑐𝑐𝑐𝑐𝑐𝑐𝑐𝑐𝑐𝑐𝑐𝑐𝑐𝑐𝐿𝐿)=10 ∗log10 ��10𝐿𝐿𝐿𝐿10𝐿𝐿 1 � Table H shows the composite noise levels of the pieces of equipment for each construction phase at a distance of 50 ft from the construction area. Once composite noise levels are calculated, reference noise levels can then be adjusted for distance using the following equation: 𝐿𝐿𝐿𝐿𝐿𝐿 (𝑎𝑎𝑐𝑐 𝑑𝑑𝑐𝑐𝑐𝑐𝑐𝑐𝑎𝑎𝑑𝑑𝑐𝑐𝐿𝐿 𝑋𝑋)=𝐿𝐿𝐿𝐿𝐿𝐿 (𝑎𝑎𝑐𝑐 50 𝑓𝑓𝐿𝐿𝐿𝐿𝑐𝑐)−20 ∗lo g10 �𝑋𝑋50� In general, this equation shows that doubling the distance would decrease noise levels by 6 dBA while halving the distance would increase noise levels by 6 dBA. Table H: Construction Noise Levels by Phase Phase Duration (days) Equipment Composite Noise Level at 50 ft (dBA Leq) Distance to Sensitive Receptor (ft)1 Noise Level at Receptor (dBA Leq) Demolition 15 1 concrete/industrial saw, 2 dozer, 3 tractors 87 160 77 Site Preparation 10 3 dozer, 4 tractor 88 160 78 Grading 10 1 excavator, 1 grader, 1 dozer, 3 tractors 87 160 77 Building Construction 210 1 crane, 3 forklift, 1 generator set, 3 tractor, 1 welder 86 160 76 Paving 15 2 pavers,2 paving equipment, 2 rollers 86 160 76 Architectural Coating 105 1 air compressor 74 160 64 Source: Compiled by LSA (2023). 1 Distances are from the average location of construction activity for each phase, assumed to be center of project site. Hotel uses would be within 10 ft of the edge of construction activity. dBA Leq = average A-weighted hourly noise level ft = foot/feet As presented above, Table H shows the construction phases, the expected duration of each phase, the equipment expected to be used during each phase, the composite noise levels of the equipment at 50 ft, the distance of the nearest sensitive receptor from the average location of construction activities (a distance of 160 ft from center of project site), and noise levels expected during each phase of construction. These noise level projections do not take into account intervening topography or barriers. Attachment C provides construction noise calculations. 6/8/23 «\\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx» 15 It is expected that average noise levels during construction at the nearest sensitive receptor, hotel to the west, would approach 78 dBA Leq during the site preparation phase, which would take place for a duration of approximately 10 days. Average noise levels during other construction phases would range from 64 dBA Leq to 77 dBA Leq. Noise levels at the nearest off-site commercial uses (Extra Space Storage) to the east would reach an average noise level of 79 dBA Leq during the daytime hours. These predicted noise levels would only occur when all construction equipment is operating simultaneously and, therefore, these noise levels are assumed to be conservative in nature. Although the project construction-related short-term noise levels have the potential to be higher than the ambient noise in the project vicinity, it would cease to occur once the project construction is completed. Furthermore, the construction-related noise levels would be below the 80 dBA Leq and 85 dBA Leq criteria established by FTA for residential and commercial uses, respectively. Compliance with the requirements of the City of Fontana Noise Ordinance, which states that construction activities shall only occur between the hours of 7:00 a.m. and 6:00 p.m., Monday through Friday, and between 8:00 a.m. and 5:00 p.m. on Saturday, and with incorporation of best business practices for noise reduction, the overall noise levels generated will be minimized, and construction noise impacts would be less than significant. No mitigation is required. Construction Vibration Building Damage Potential Ground-borne noise and vibration from construction activity would be low. Table I provides reference PPV values and vibration levels (in terms of VdB) from typical construction vibration sources at 25 ft. While there is currently limited information regarding vibration source levels specific to the equipment which would be used for the project, to provide a comparison of vibration levels expected for a project of this size, a large bulldozer would generate 0.089 PPV (in/sec) of ground-borne vibration when measured at 25 ft, based on the FTA Manual. As shown previously in Table E, it would take a minimum of 0.2 PPV (in/sec) to cause any potential building damage to non- engineered timber and masonry buildings. Table I: Vibration Source Amplitudes for Construction Equipment Equipment Reference PPV/LV at 25 ft PPV (in/sec) LV (VdB)1 Hoe Ram 0.089 87 Large Bulldozer 0.089 87 Caisson Drilling 0.089 87 Loaded Trucks 0.076 86 Jackhammer 0.035 79 Small Bulldozer 0.003 58 Source: Transit Noise and Vibration Impact Assessment Manual (FTA 2018). 1 RMS VdB re 1 µin/sec. µin/sec = micro-inches per second ft = foot/feet FTA = Federal Transit Administration in/sec = inches per second LV = velocity in decibels PPV = peak particle velocity RMS = root-mean-square VdB = vibration velocity in decibels 6/8/23 «\\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx» 16 The distance to the nearest buildings for vibration impact analysis is measured between the nearest off-site buildings and the project construction boundary (assuming the construction equipment would only be used at or near the project setback line). The formula for vibration transmission is provided below: PPVequip = PPVref x (25/D)1.5 The closest structure to external construction activities is the hotel to the west, approximately 8 ft from the western project construction boundary. Construction activities on the eastern portion of the project would only include tenant improvement within existing buildings which are not expected to generate noticeable vibration levels to the Extra Space Storage facility immediately adjacent to the east. Using the reference data from Table I and the equation above, it is expected that vibration levels generated by dump trucks and other large equipment would generate ground-borne vibration levels of 0.352 PPV (in/sec) or higher at the closest structures to the project site. This vibration level would exceed the 0.2 in/sec PPV threshold considered safe for non-engineered timber and masonry buildings, which would result in a potentially significant impact. The distance from large construction equipment with a reference vibration level of 0.089 in/sec PPV at 25 feet for which the 0.2 in/sec threshold would no longer be exceeded is 15 feet. Vibration levels at all other buildings would be lower. Therefore, construction would not result in any vibration damage, and impacts would be less than significant with the incorporation of Mitigation Measure NOI-1, as detailed below. Mitigation Measure NOI-1 Construction Vibration Damage. Due to the close proximity to surrounding structures, the City of Fontana (City) Director of Community Development, or designee, shall verify prior to issuance of demolition or grading permits, that the approved plans require that the construction contractor shall implement the following mitigation measures during project construction activities to ensure that damage does not occur at surrounding structures: • Identify structures that are located within 15 feet (ft) of heavy construction activities and that have the potential to be affected by ground-borne vibration. This task shall be conducted by a qualified structural engineer as approved by the City’s Director of Community Development, or designee. • Once the construction equipment list finalized, a comparison of the proposed equipment to be used and the assumed equipment vibration levels presented in Table 7-4 of the Federal Transit Administration Noise and Vibration Impact Assessment Manual – FTA Report No. .0123 shall be completed. If it is determined that the proposed equipment would generate lower vibration levels than assumed, further vibration mitigation would not be necessary. However, if levels would potentially exceed the FTA Damage Criteria presented in Table 7-5 of the Federal Transit Administration Noise and Vibration Impact Assessment Manual – 6/8/23 «\\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx» 17 FTA Report No. .0123, the applicant shall develop a vibration monitoring and construction contingency plan for approval by the City Director of Community Development, or designee, to identify structures where monitoring would be conducted; set up a vibration monitoring schedule; define structure-specific vibration limits; and address the need to conduct photo, elevation, and crack surveys to document before and after construction conditions. Construction contingencies would be identified for when vibration levels approached the limits. • If a vibration monitoring and construction contingency plan is deemed necessary, monitor vibration during initial construction activities would be required. Monitoring results may indicate the need for more or less intensive measurements. • When vibration levels approach limits, suspend construction and implement contingencies as identified in the approved vibration monitoring and construction contingency plan to either lower vibration levels or secure the affected structures. Long-Term Off-Site Traffic Noise Impact Analysis In order to assess the potential traffic impacts related to the proposed project, LSA estimates that the proposed project would result in a net increase of 137 average daily trips (ADT) based on the proposed increase in square footage. Based on the ADTs provided in Exhibit 9.5, Average Daily Trips, of the Community Mobility and Circulation Element of the Fontana General Plan (Community Mobility and Circulation Element 2018)6, the ADT along Valley Boulevard in the vicinity of the project is approximately between 20,001 – 30,000 based on projections for the year 2016. While the existing ADT is likely higher, using 20,001 ADT as the existing count would be a conservative approach. The following equation was used to determine potential impacts of the project: Change in CNEL = 10 log10 [Ve+p/Vexisting] Where: Vexisting = the existing daily volume Ve+p = existing daily volumes plus project Change in CNEL = the increase in noise level due to the project The results of the calculations show that an increase of less than 0.03 dBA CNEL is expected along Valley Boulevard. A noise level increase of less than 3 dBA would not be perceptible to the human ear; therefore, the traffic noise increase along Valley Boulevard resulting from the proposed project would be less than significant. No mitigation is required. 6 City of Fontana. 2018. General Plan Community Mobility and Circulation Element. November 13 6/8/23 «\\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx» 18 Long-Term Operational Noise Impact Analysis Adjacent off-site land uses would be potentially exposed to stationary-source noise impacts from the proposed on-site heating, ventilation, and air conditioning (HVAC) equipment and truck deliveries and loading and unloading activities. The potential noise impacts to off-site sensitive land uses from the proposed operations are discussed below. To provide a conservative analysis, it is assumed that within any given hour, 5 heavy trucks would maneuver to park near the loading zone east of the proposed building. HVAC equipment is expected to run continuously for the duration of a 24-hour period. To determine the future noise impacts from project operations to the noise sensitive uses, a 3-D noise model, SoundPLAN, was used to incorporate the site topography as well as the shielding from the proposed building on-site. A graphic representation of the operational noise impacts is presented in Attachment D. Heating, Ventilation, and Air Conditioning Equipment The project is estimated to have three (3) banks of four (4) rooftop HVAC units (total of 12 units) on the proposed storage building to provide ventilation. The HVAC equipment could operate 24 hours per day and would generate sound power levels (SPL) of up to 87 dBA SPL or 72 dBA Leq at 5 feet, based on manufacturer data (Trane)7. Truck Deliveries and Truck Loading and Unloading Activities Noise levels generated by delivery trucks would be similar to noise readings from truck loading and unloading activities, which generate a noise level of 75 dBA Leq at 20 ft based on measurements taken by LSA (Operational Noise Impact Analysis for Richmond Wholesale Meat Distribution Center [LSA 2016]). During this process, noise levels are associated with the truck engine noise, air brakes, and back-up alarms. These noise levels would occur for a shorter period of time (less than 5 minutes). Maximum noise levels that occur during the truck movement process taken by LSA were measured to be 86 dBA Lmax at a distance of 20 feet. Tables J and K below show the combined hourly noise levels generated by HVAC equipment and truck delivery activities at the closest off-site land uses. The project-related noise level impacts would range from 52.0 dBA Leq to 55.9 dBA Leq at the surrounding sensitive receptors. These levels would be well below the City’s exterior noise standard of 65 dBA Leq. Because project noise levels would not generate a noise level by 3 dBA or more or exceed the City’s thresholds, the impact would be less than significant, and no noise reduction measures are required. 7 Trane. Fan Performance - Product Specifications RT-PRC023AU-EN. 6/8/23 «\\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx» 19 Table J: Daytime Exterior Noise Level Impacts Receptor Direction Existing Quietest Daytime Noise Level (dBA Leq) Project Generated Noise Levels (dBA Leq) Potential Operational Noise Impact?1 SureStay Hotel (17133 Valley Blvd) West 59.1 46.8 No Residential – Sierra Mobile Estates East 59.1 50.2 No Source: Compiled by LSA (2023). 1 A potential operational noise impact would occur if (1) the quietest daytime ambient hour is less than 65 dBA Leq and project noise impacts are greater than 65 dBA Leq, OR (2) the quietest daytime ambient hour is greater than 65 dBA Leq and project noise impacts are 3 dBA greater than the quietest daytime ambient hour. dBA = A-weighted decibels Leq = equivalent noise level Table K: Nighttime Exterior Noise Level Impacts Receptor Direction Existing Quietest Nighttime Noise Level (dBA Leq) Project Generated Noise Levels (dBA Leq) Potential Operational Noise Impact?1 SureStay Hotel (17133 Valley Blvd) West 60.5 46.8 No Residential – Sierra Mobile Estates East 60.5 50.2 No Source: Compiled by LSA (2023). 1 A potential operational noise impact would occur if (1) the quietest nighttime ambient hour is less than 65 dBA Leq and project noise impacts are greater than 65 dBA Leq, OR (2) the quietest nighttime ambient hour is greater than 65 dBA Leq and project noise impacts are 3 dBA greater than the quietest nighttime ambient hour. dBA = A-weighted decibels Leq = equivalent noise level Long-Term Ground-Borne Noise and Vibration from Vehicular Traffic Because the rubber tires and suspension systems of buses and other on-road vehicles provide vibration isolation and reduce noise, it is unusual for on-road vehicles to cause ground-borne noise or vibration. When on-road vehicles cause such effects as the rattling of windows, the source is almost always airborne noise. Most problems with on-road vehicle-related noise and vibration can be directly related to a pothole, bump, expansion joint, or other discontinuity in the road surface. Smoothing the bump or filling the pothole will usually solve the problem. The proposed project would have roads with smooth pavement and would not result in significant ground-borne noise or vibration impacts from vehicular traffic. No mitigation is required. Attachment A: Figures Attachment B: Noise Measurement Data Attachment C: Construction Noise Calculations Attachment D: SoundPLAN Noise Model Printouts NOISE AND VIBRATION IMPACT ANALYSIS JUNE 2023 PUBLIC STORAGE REDEVELOPMENT PROJECT FONTANA, CALIFORNIA \\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx «06/08/23» ATTACHMENT A FIGURES 304.80 SOURCE: ESRI Streets, 2022 I:\PUB2202\GIS\MXD\Proj_Loc.mxd (1/13/2023) FIGURE 1 Public Storage Fontana Project Location 0 1000 2000 FEET LEGEND Project Location SanBernardinoCounty RiversideCounty ÃÃ330 ÃÃ38 ÃÃ71 ÃÃ18 ÃÃ173 ÃÃ210 ÃÃ60 ÃÃ91 Project Location §¨¦15 §¨¦215 §¨¦10 Project Vicinity SOURCE: KSP Studios FIGURE 2 I:\PUB2202\G\Site_Plan_Fontana.ai (1/13/2023) Site Plan Public Storage Fontana FEET 120600 30' 30 ' 23' - 8 " LOBBY 30' AE R I A L A C C E S S 30 ' FIR E A C C E S S 151 ' - 4 " 241'-4" PROPOSED SELF-STORAGEBUILDING3-STORY109,566 S.F. V A L L E Y B O U L E V A R D S A N B E R N A D I N O F R E E W A Y 25 S H A R E D A C C E S S E A S E M E M T 62' 26 ' 15 ' - 3 0 ' MIN F I R E R E Q ' D 70'CLEAR TO OBSTRUCTIONS 132' 9 13' - 4 " TYP SECURITY GATE &FENCE. FOR FIREDEPT ACCESSONLY SEMI-TRAILERPARKING DEMO PORTION OFEXISTING WALL UPTO NEW SECURITYGATE FIRE DEPT. SECONDPOINT OF ACCESS FIRE DEPT. FIRSTPOINT OF ACCESS (E) TRASHENCLOSURE 72'-8" 112'-2" 22'- 1 0 " 105' 9'TYP 17 ' TY P 5 (2) SHORT TERMBIKES (2) LONG TERMBIKES K E K E C K M M (E) BUILDING4000 (E) BUILDING3000 (E) BUILDING2000 (E) BUILDING6000 (E) BUILDING5000 (E) BUILDING8000 (E) BUILDING8000 (E)BUILDING9000 (E) HOTELNOT A PART (E) RETAILNOT A PART (E) RETAILNOT A PART (E) RETAILNOT A PART (E) PARKINGNOT A PART (E) PARKINGNOT A PART (E) PARKINGNOT A PART PROPERTY LINE PROPERTY LINE PROPERTY LINE PR O P E R T Y L I N E PRO P E R T Y L I N E PRO P E R T Y L I N E PR O P E R T Y L I N E 687'-10" 6' 2' EV CHARGINGONLY ADA POLE SIGN,TYP (2)EV CHARGING 24" DECORATIVECONCRETE, TYP 9'12'-8"9'14'-2" 18' 9'8'9'12'5' CLEAN AIR/VANPOOLEV CLEAN AIR/VANPOOLEV CLEAN AIR/VANPOOLEV 19' 6' 10'10' (E) DRAINAGEEASEMENT 20' 70' R28' 26' (E) 2-STORY TOBE DEMOLISHED9,298 S.F. HAMMERHEAD TURNAROUNDPER DIAGRAM A-1.12 OF THESAN BERNADINO COUNTY F.D. 6' 19'37'-11" (E) SIGNAGEEASEMENT (E) FH(E) FH (E) FH (E) FH (E) FH 34'-4" 12' WIDE SIGNMAINTENANCEACCESS GATE (E) BUILDING7000 20' EXI T O N L Y 7'-2"(E)CART STORAGE 20 ' EN T R Y 24 HOURDRIVE-UPS ABANDON (E)HYDRANT PROPOSED BUILDINGMOUNTED FDC PROPOSED FIRESERVICE (E) CURB PROPOSEDCURB PROPOSEDHYDRANT23' - 9 " 20 ' - 1 0 " 22 ' - 2 " UNDERGROUNDGATE SENSOR (E) BLOCK WALL TOREMAIN ST O P STO P (E) POLE SIGN (E) POWERPOLE 150' (E) FH(E) FH (E) FH (E) FH (E) FH 30' 9'-8"(E) LIMIT OF WORK 18' - 6 " 7 LANDSCAPE,TYP 34'-10" PROPOSEDUNDERGROUNDINFILTRATIONBASIN PROPOSEDUNDERGROUNDINFILTRATIONBASINPROPERTY LINE R19' R45' (E) CELLTOWER (E) CELLTOWER CELL TOWER & MAIN SITEELECTRICAL GEAR (4 METERS)1,000 AMP, 208 V T T TRASHENCLOSURE 10'-8"2'2'2'2'2'2'5'5' 17 ' 24" DECORATIVECONCRETE, TYP 2' DEMO (E)2-STORY OFFICE5,724 S.F. DEMO (E)BLDG 2000644 S.F. DEMO (E)BLDG 3000788 S.F. SECURITY RA C K FP SECURITY RA C K E T$I A CCCCSAFE 18"X48" RACKS 18"X48" RACKS18"X48" RACKS18"X48" RACKS 15"X12"LCKS 18"X48" RACKS OFFICE 8'9'TYP 30 ' - 4 " CANOPY ABOVE 21'-5" 7' 7'-6"2'5' 8' SLIDING GATE SHEET 2 17173 VALLEY BOULEVARD | FONTANA, CA CONCEPTUAL SITE PLAN 08.09.22 0 30'15'60' scale: 1" = 30'-0" NORTH EXISTING STREET VIEW LT-1LT-1 LT-2LT-2 I:\PUN2202\G\Noise_Locs.ai (1/13/2023) SOURCE: Google Earth, 2022 FEET 3001500 LEGEND - Project Site Boundary - Long-term Noise Monitoring Loca�onLT-1LT-1 FIGURE 3 Noise Monitoring Loca�ons Public Storage Fontana 10 Valley BlvdValley Blvd Ma n g o A v e Ma n g o A v e NOISE AND VIBRATION IMPACT ANALYSIS JUNE 2023 PUBLIC STORAGE REDEVELOPMENT PROJECT FONTANA, CALIFORNIA \\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx «06/08/23» ATTACHMENT B NOISE MEASUREMENT DATA Noise Measurement Survey – 24 HR Project Number: PUB2202 Test Personnel: Kevin Nguyendo Project Name: Public Storage Fontana Equipment: Spark 706RC (SN:905) Site Number: LT-1 Date: 10/24/22 Time: From 12:00 p.m. To 12:00 p.m. Site Location: Northwest corner of the project site near a storage unit. Primary Noise Sources: Traffic noise on Valley Boulevard. Storage operation noises Such as loading and unloading and vehicles passing by. Comments: Approximately 80 inch retaining wall west of the project site. Photo: Long-Term (24-Hour) Noise Level Measurement Results at LT-1 Start Time Date Noise Level (dBA) Leq Lmax Lmin 12:00 PM 10/24/22 61.3 77.1 54.3 1:00 PM 10/24/22 61.5 79.9 51.1 2:00 PM 10/24/22 59.9 76.7 50.5 3:00 PM 10/24/22 60.4 79.3 49.9 4:00 PM 10/24/22 60.4 79.4 49.6 5:00 PM 10/24/22 61.1 82.0 50.5 6:00 PM 10/24/22 60.8 77.1 51.8 7:00 PM 10/24/22 61.4 80.5 55.9 8:00 PM 10/24/22 60.2 73.2 53.1 9:00 PM 10/24/22 59.1 72.3 52.8 10:00 PM 10/24/22 62.6 77.3 51.9 11:00 PM 10/24/22 60.5 74.7 53.1 12:00 AM 10/25/22 62.2 74.2 55.7 1:00 AM 10/25/22 61.3 70.3 54.2 2:00 AM 10/25/22 62.0 74.3 54.5 3:00 AM 10/25/22 63.0 74.2 57.7 4:00 AM 10/25/22 65.6 76.6 59.9 5:00 AM 10/25/22 65.6 79.3 60.6 6:00 AM 10/25/22 66.7 77.3 63.0 7:00 AM 10/25/22 66.0 82.9 59.6 8:00 AM 10/25/22 61.7 76.7 56.0 9:00 AM 10/25/22 60.1 76.9 52.5 10:00 AM 10/25/22 59.4 73.6 51.9 11:00 AM 10/25/22 59.1 79.7 51.5 Source: Compiled by LSA Associates, Inc. (2022). dBA = A-weighted decibel Leq = equivalent continuous sound level Lmax = maximum instantaneous noise level Lmin = minimum measured sound level Noise Measurement Survey – 24 HR Project Number: PUB2202 Test Personnel: Kevin Nguyendo Project Name: Public Storage Fontana Equipment: Spark 706RC (SN:906) Site Number: LT-2 Date: 10/24/22 Time: From 12:00 p.m. To 12:00 p.m. Site Location: Located at the southwest corner of the project site on a light pole near a Parking lot. Primary Noise Sources: Traffic noise on the I10 freeway. Heavy duty truck training operation Noise. Comments: Heavy duty truck training operation operates Monday through Friday. Photo: Long-Term (24-Hour) Noise Level Measurement Results at LT-2 Start Time Date Noise Level (dBA) Leq Lmax Lmin 12:00 PM 10/24/22 79.5 91.5 67.2 1:00 PM 10/24/22 78.2 86.3 66.9 2:00 PM 10/24/22 78.1 88.2 69.2 3:00 PM 10/24/22 77.9 88.1 67.5 4:00 PM 10/24/22 77.3 85.9 65.9 5:00 PM 10/24/22 77.6 85.2 67.5 6:00 PM 10/24/22 78.0 87.4 69.0 7:00 PM 10/24/22 77.7 86.1 69.9 8:00 PM 10/24/22 77.7 88.9 69.9 9:00 PM 10/24/22 77.1 89.1 66.4 10:00 PM 10/24/22 75.9 84.4 61.8 11:00 PM 10/24/22 74.7 87.4 59.9 12:00 AM 10/25/22 74.4 84.7 61.1 1:00 AM 10/25/22 75.0 88.2 58.8 2:00 AM 10/25/22 75.3 86.0 56.4 3:00 AM 10/25/22 76.5 87.1 60.2 4:00 AM 10/25/22 78.6 88.1 65.7 5:00 AM 10/25/22 78.8 89.0 68.7 6:00 AM 10/25/22 77.0 88.9 69.7 7:00 AM 10/25/22 77.5 90.4 68.0 8:00 AM 10/25/22 78.1 89.9 71.1 9:00 AM 10/25/22 79.2 91.5 72.3 10:00 AM 10/25/22 79.3 90.5 70.9 11:00 AM 10/25/22 79.1 93.4 70.0 Source: Compiled by LSA Associates, Inc. (2022). dBA = A-weighted decibel Leq = equivalent continuous sound level Lmax = maximum instantaneous noise level Lmin = minimum measured sound level NOISE AND VIBRATION IMPACT ANALYSIS JUNE 2023 PUBLIC STORAGE REDEVELOPMENT PROJECT FONTANA, CALIFORNIA \\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx «06/08/23» ATTACHMENT C CONSTRUCTION NOISE CALCULATIONS Phase: Demolition Lmax Leq Concrete Saw 1 90 20 50 0.5 90 83 Dozer 2 82 40 50 0.5 82 81 Excavator 3 81 40 50 0.5 81 82 Combined at 50 feet 91 87 Combined at Receptor 140 feet 82 78 Phase: Site Preparation Lmax Leq Dozer 3 82 40 50 0.5 82 83 Tractor 4 84 40 50 0.5 84 86 Combined at 50 feet 86 88 Combined at Receptor 140 feet 77 79 Phase: Grading Lmax Leq Excavator 1 81 40 50 0.5 81 77 Grader 1 85 40 50 0.5 85 81 Dozer 1 82 40 50 0.5 82 78 Tractor 3 84 40 50 0.5 84 85 Combined at 50 feet 89 87 Combined at Receptor 140 feet 80 78 Phase:Building Construstion Lmax Leq Crane 1 81 16 50 0.5 81 73 Man Lift 3 75 20 50 0.5 75 73 Generator 1 81 50 50 0.5 81 78 Tractor 3 84 40 50 0.5 84 85 Welder / Torch 1 74 40 50 0.5 74 70 Combined at 50 feet 87 86 Combined at Receptor 140 feet 79 77 Phase:Paving Lmax Leq Paver 2 77 50 50 0.5 77 77 All Other Equipment > 5 HP 2 85 50 50 0.5 85 85 Roller 2 80 20 50 0.5 80 76 Combined at 50 feet 87 86 Combined at Receptor 140 feet 78 77 Phase:Architectural Coating Lmax Leq Compressor (air)1 78 40 50 0.5 78 74 Combined at 50 feet 78 74 Combined at Receptor 140 feet 69 65 Sources: RCNM 1- Percentage of time that a piece of equipment is operating at full power. dBA – A-weighted Decibels Lmax- Maximum Level Leq- Equivalent Level Distance to Receptor (ft) Usage Factor1 Reference (dBA) 50 ft LmaxQuantityEquipment QuantityEquipment Noise Level (dBA)Ground Effects Distance to Receptor (ft) Usage Factor1 Reference (dBA) 50 ft LmaxQuantityEquipment Noise Level (dBA)Ground Effects Distance to Receptor (ft) Usage Factor1Reference (dBA) 50 ft Lmax Distance to Receptor (ft) Noise Level (dBA) Ground Effects Noise Level (dBA) Construction Calculations Equipment Quantity Reference (dBA) 50 ft Lmax Usage Factor1 Distance to Receptor (ft) Ground Effects Noise Level (dBA) Ground Effects Noise Level (dBA)Equipment Quantity Reference (dBA) 50 ft Lmax Usage Factor1 Ground EffectsEquipment Quantity Reference (dBA) 50 ft Lmax Usage Factor1 Distance to Receptor (ft) NOISE AND VIBRATION IMPACT ANALYSIS JUNE 2023 PUBLIC STORAGE REDEVELOPMENT PROJECT FONTANA, CALIFORNIA \\lsaazfiles.file.core.windows.net\projects\PUB2202\Technical Studies\Noise\Product\Noise and Vibration Memo_060823.docx «06/08/23» ATTACHMENT D SOUNDPLAN NOISE MODEL PRINTOUTS Public Storage Fontana Project No. PUB2202 Project Operational Noise Levels Hourly Noise Level (dBA Leq) <=40.0 40.0<<=43.0 43.0<<=46.0 46.0<<=49.0 49.0<<=52.0 52.0<<=55.055.0<<=58.0 58.0<<=61.0 61.0<<=64.064.0<<=67.0 67.0<<=70.0 70.0< Scale 0 35 70 140 210 280feet Signs and symbols Point source Main building 65 dBA Leq C:\Users\JStephens\OneDrive - LSA Associates\DESKTOP\SOUNDPLAN\PUB2202 - Public Storage Fontana - Copy\Ops.sgs - last edit 1/12/2023