Transforming a room from noisy and cluttered to calm and classy starts with the right walls—literally. Whether you’re outfitting a home theater, office, restaurant, or living room, acoustic wood panels marry sound control with warm, natural style. But not all panels are created equal: density, core material, NRC rating, finish, and installation method all affect performance and price.
In this guide you’ll learn what to look for so you can choose panels that actually improve sound quality without sacrificing design. We’ll walk through key technical specs in plain language, compare popular wood types and finishes, highlight installation tips, and show how to balance budget, durability, and sustainability. Read on to discover how to pick acoustic wood panels that look great, work smarter, and fit your space—whether you’re a DIYer, a designer, or a facilities manager.
Benefits
- Effective sound absorption and control: Acoustic wood panels are designed to reduce reverberation and unwanted reflections. Many panels are perforated or slotted and paired with an absorptive core (mineral wool or acoustic foam) and a cavity behind the panel; this combination converts sound energy into heat and lowers the room’s reverberation time. Depending on the panel design and backing, NRC (Noise Reduction Coefficient) values can range roughly from 0.2 for thin decorative panels to 0.9 for deeply-cavitied, high-performance systems. This makes them useful for spaces where clear speech and reduced noise are important.
- Sound diffusion options: Not all wood panels are strictly absorptive. Diffusive patterns—varying depths, staggered slats, and irregular perforation layouts—scatter sound waves to prevent “dead” acoustics and maintain liveliness. A well-designed acoustic wood panel wall can provide a balanced blend of absorption and diffusion for natural-sounding rooms.
- Thermal and insulation benefits: The cavity and absorptive material behind panels add thermal resistance, offering marginal improvements to a wall’s insulating performance. While not a replacement for dedicated thermal insulation, acoustic panels can help in creating more stable indoor temperatures when integrated into a multi-layer wall build-up.
- Visual warmth and design flexibility: Wood brings natural grain, color, and texture that many other acoustic materials lack. Panels are available in solid wood, veneer over engineered substrates (MDF, plywood), and a variety of finishes (stains, lacquers, oils). Slatted, perforated, grooved, and sculpted profiles support diverse aesthetic goals—from minimalist linear patterns to complex geometric features—making an acoustic wood panel wall as much a design element as a technical solution.
- Customization and modularity: Panels can be manufactured to size, assembled in modules, and combined with lighting, HVAC diffusers, and concealed wiring for integrated interiors. Modular systems speed installation and allow for future access behind the panels without destructive work.
- Durability and low maintenance: Quality wood panels, when finished appropriately, withstand daily wear in commercial and residential settings. They are easy to clean (light dusting or damp wiping) and can be refinished if they become scratched or faded, extending the life of the installation.
- Sustainability and indoor air quality: Many acoustic wood products are offered with sustainable certifications (FSC, PEFC) and low-VOC finishes, which is important for healthy indoor environments. Engineered substrates can use recycled content, and responsible sourcing reduces environmental impact.
- Fire and code compliance: Many manufacturers provide fire-rated options (ASTM E84/Class A or Euroclass B-s1,d0, depending on the system and finishes). Selecting panels with appropriate fire performance is fundamental for public and commercial projects.
Common applications
- Corporate offices and meeting rooms: Open-plan offices and conference rooms benefit from acoustic wood panel walls to control background noise, improve speech intelligibility during meetings, and add a premium look in lobbies and boardrooms. Targeted placement behind presenter areas and at first reflection points enhances clarity.
- Auditoriums, lecture halls, and worship spaces: These rooms require careful balance between reverberation for natural resonance and absorption to avoid muddiness. Acoustic wood panels are used on side walls, rear walls, and ceilings as part of a comprehensive acoustic strategy, often combined with diffusers and bass treatments.
- Recording and broadcast studios: While critical control rooms often require specialized, non-parallel surfaces and very specific absorption targets, acoustic wood panels (especially diffusive slatted versions) are frequently used in live rooms and client-facing spaces to marry acoustic performance with a professional aesthetic.
- Hospitality and restaurants: Background noise management is essential in restaurants, bars, and hotel lobbies. Acoustic wood panel walls reduce overall noise levels while contributing to a warm, upscale interior—improving guest comfort without hiding the architectural intent.
- Education and healthcare facilities: Classrooms, lecture spaces, and waiting areas see better speech intelligibility and reduced noise distractions when acoustic wood panel walls are used. In healthcare environments, controlled acoustics contribute to calmer patient areas and more discreet conversations.
- Residential applications: Home theaters, open-plan living areas, and bedrooms benefit from bespoke acoustic wood panel walls that control echo, improve music and movie listening, and act as accent features that elevate interior design.
- Retail and cultural spaces: Showrooms, galleries, and exhibition spaces use acoustic wood panels to tune the environment for appointments, displays, and performances, while maintaining a high-quality visual backdrop.
Design and installation considerations
- Choose the right construction: Perforated or slatted face with an absorptive core and defined cavity depth provides predictable performance. For bass management, integrate corner or wall-mounted bass traps and low-frequency absorbers.
- Specify acoustic targets: Work with NRC/STC goals or an acoustic consultant for critical spaces. Not every room requires the same level of absorption; over-damping can make a space feel lifeless.
- Fire rating and finish: Confirm fire classification and select finishes compatible with local codes. Low-VOC finishes protect indoor air quality.
- Humidity and movement: Solid wood can expand and contract with humidity; engineered veneers and controlled backing materials minimize movement for a long-lasting acoustic wood panel wall.
- Maintenance and access: Plan for cleaning and occasional refinishing; design for service access to systems hidden behind panels when needed.
Choosing an acoustic wood panel wall combines measurable acoustic performance with architectural warmth and flexibility, making it a preferred option across diverse interiors where both sound control and aesthetics matter.
When evaluating an acoustic wood panel wall for a project—whether a recording studio, office, restaurant, classroom, or home theater—understanding both acoustic performance and the material properties that drive that performance is essential. “Acoustic wood panel wall” is a product category that blends aesthetics with function, but not all panels are created equal. Below are the key acoustic and material properties you should evaluate to make an informed purchase.
Acoustic performance metrics
- Sound absorption (NRC, SAA, frequency charts): Look beyond a single Noise Reduction Coefficient (NRC) number. NRC and SAA summarize mid-frequency absorption, but acoustic wood panel systems are frequency-dependent—performance at 125–250 Hz (bass) is very different from performance at 1000–4000 Hz (speech clarity). Ask manufacturers for full absorption coefficient charts measured to standards such as ASTM C423 or ISO 354, not just a headline NRC.
- Sound transmission (STC, Rw): If you need the wall to block sound between rooms, check Sound Transmission Class (STC) or the ISO equivalent (Rw). A decorative wood facing alone does little to stop airborne transmission; the core, cavity, and backing matter. Request third-party test data (ASTM E90) for assemblies comparable to what you will install.
- Reverberation control and RT60 targets: Decide the target reverberation time for your space and ensure the panel system’s absorption characteristics will help you achieve that RT60. For speech-focused spaces, mid-frequency absorption is most important; for music or mixed-use rooms you’ll need broader-band control.
- Diffusion vs. absorption: Some wood panels incorporate diffusive geometries or relief patterns to scatter sound rather than absorb it. Diffusion can reduce bad echoes without deadening a room; choose diffusive patterns for music spaces and absorption-heavy layouts for control rooms or call centers.
Wood and substrate properties
- Veneer vs. solid wood vs. laminates: A real wood veneer on a substrate provides the aesthetic and some dimensional stability; solid wood can look luxurious but will move more with humidity. Laminates can be durable and consistent but may lack the natural grain that many buyers prefer.
- Substrate type: Medium density fiberboard (MDF), plywood, or engineered boards are common substrates. MDF is easy to machine for slots/perforations but can off-gas formaldehyde if not CARB-compliant; plywood is stronger and more dimensionally stable in humid conditions.
- Porosity, perforations, and slot geometry: Many acoustic wood panels rely on surface perforations or slots that couple with absorptive backing to attenuate sound. Hole diameter, spacing, and pattern influence which frequencies are absorbed—tighter perforations and specific slot widths are used to tune mid-high frequency absorption.
- Core/backing material: The core behind a wood face can be mineral wool, fiberglass, acoustic foam, or engineered absorptive boards. Denser, more resilient backing tends to deliver broader-band absorption and better fire performance; always check the manufacturer’s specified backing material and whether it’s included or optional.
Durability, finish, and environmental factors
- Finishes and coatings: Clear lacquer, oil, or hard-wearing polyurethane change both appearance and maintenance needs. Some finishes can slightly reduce the effectiveness of perforated panels if they seal pores—ask about how finishes affect acoustic performance.
- Fire ratings and code compliance: Verify surface-burning characteristics (ASTM E84) or Euroclasses (EN 13501-1) as required by local code. Many commercial projects demand Class A finishes or noncombustible cores.
- Humidity and dimensional stability: Solid wood expands and contracts with humidity. Engineered veneers on stable substrates are better for humid environments; if installing in bathrooms or exterior-adjacent walls, choose engineered products or specific exterior-rated systems.
- VOCs and health: Inquire about formaldehyde emissions and volatile organic compound (VOC) certifications. Look for CARB Phase 2, TSCA Title VI compliance, or low-VOC product data if indoor air quality is a concern.
- Sustainability and certification: If responsible sourcing matters, ask for FSC or PEFC certification on the veneer and details about recycled content or end-of-life recyclability.
Installation and practical considerations
- Mounting system and air gap: Performance changes significantly with installation. Many acoustic wood panel walls perform better when mounted over an air cavity (1–4 inches) and with absorptive backing. Confirm whether the quoted acoustic data assumes a specific cavity depth and mounting method.
- Seams, joints, and edge details: Tight seams reduce flanking paths. Edge profiles and installation tolerances affect both aesthetics and acoustic continuity.
- Maintenance and repairability: Veneers can be refinished, but perforated patterns complicate repairs. Check warranties and availability of replacement panels.
- Third-party testing and real-world demos: Ask for third-party lab reports and, if possible, see installed examples or request sample panels to test in your space.
As you evaluate options for an acoustic wood panel wall, combine the technical data (absorption curves, STC, fire ratings) with practical material considerations (substrate, backing, finish, installation) to ensure the product meets both your acoustic goals and long-term durability, aesthetic, and environmental requirements.
When shopping for an acoustic wood panel wall, choices about design, finish, and installation are as important as the acoustic performance itself. These three aspects determine how well the wall integrates visually with a space, how durable and maintainable it will be, and whether it will meet the actual sound-control goals for the room. Below is a practical, detailed guide to help you decode the options and decide what matters most for your specific project.
Design options: patterns, profiles, and performance
The visual language of an acoustic wood panel wall is driven by profile, spacing, and pattern. Profiles range from simple flat-faced panels and slatted systems to rounded battens, chamfered slats, and three-dimensional geometric modules. Slatted and perforated panels are the most common because they allow sound to pass into an absorptive backing while keeping a warm wood aesthetic. Slot width, slot spacing (or gap), and slat thickness directly affect both the look and the acoustic behavior. Narrow slots create a refined, contemporary appearance; wider gaps give a stronger linear rhythm and increase exposed absorptive area.
Perforation patterns vary from standard round holes to micro-perforations and decorative arrays. Micro-perforations can provide smoother visual continuity while still allowing meaningful absorption when combined with the right backing. For rooms that need both absorption and diffusion (for lively, natural sound rather than overly “dead” rooms), consider alternating absorptive slats with diffusors — differently profiled blocks that scatter energy, or panels with varying slot depths. For low-frequency control, a wall of standard panels may not be enough; bass traps or dedicated low-frequency absorbers should be integrated into corners or behind deeper cavities.
Material choices influence both design and feel. Solid hardwood slats offer authentic wood grain and can be profiled for distinct shadow-lines; engineered veneers on MDF or plywood are more stable and cost-effective for large areas. Thermoformed or laminated options can produce curved installations. For sustainable projects, look for FSC-certified wood or panels with recycled cores like PET wool.
Finish options: aesthetics, protection, and acoustic implications
Finishes do more than change color. They protect, affect reflectivity, and sometimes alter the acoustic behavior of an acoustic wood panel wall. Factory-applied, UV-cured lacquers or conversion varnishes provide a hard, consistent finish with minimal VOCs and better scratch resistance than many site-applied coatings. Hardwax oils create a natural, tactile feel but may require more maintenance and periodic re-oiling. Water-based polyurethanes are increasingly popular for their balance of durability and low odor.
Opaque paints offer color flexibility but conceal the wood grain; waterborne paints maintain lower VOC levels. Veneers stained to match a palette maintain natural patterns while being more dimensionally stable than solid wood. If fire-safety is a concern, ask for fire-retardant-treated panels or finishes that comply with local codes; many manufacturers can supply panels meeting higher reaction-to-fire classifications.
Acoustically, the finish should not fully seal perforations or micro-vents. Ask whether the specified finish will clog holes or seal the surface — factory micro-perforation often comes with masking techniques to avoid blockage. Also consider backing and infill: common absorptive cores include mineral wool, fiberglass, PET polyester, and foam. The thickness and density of the backing plus the air cavity depth behind the panel determine the frequency range and overall NRC (Noise Reduction Coefficient). Typical perforated wood systems with appropriate backing can achieve NRCs in the 0.5–0.85 range, but check manufacturer test data.
Installation options: mounting systems and practical tips
Installation choice affects speed, serviceability, and overall finish quality. Options fall into adhesive-only, mechanical, and hybrid systems.
- Concealed clip systems and Z-clips: Panels are attached to a continuous rail or furring strips with hidden clips for a clean reveal and easy removal for maintenance or service access. Ideal for commercial and finished residential work.
- French cleats and keyed hangers: Good for heavier or modular panels; allow for fast placement and removal without visible fasteners.
- Direct-to-substrate with adhesive: Quicker and simpler but makes panels non-removable and may cause difficulty if you need to access behind-wall services.
- Screw or face-fix methods: Simple but visually intrusive unless the fixings are coordinated into the design as part of the aesthetic.
For curved surfaces, look for flexible slat systems, segmented panels, or pre-bent plywood options. Consider expansion gaps — solid wood and veneered panels expand and contract with humidity. Allow roughly 3–6 mm (1/8”–1/4”) at perimeter joints in typical interior conditions; check the manufacturer’s recommendations for precise tolerances.
Substrate preparation is crucial: walls must be plumb and load-bearing elements sized to hold panel weights. For performance-driven rooms (studios, theaters), decoupling or resilient channels may be required to isolate vibrations; also confirm whether the installation will affect HVAC grills, lighting, or diffusers. Coordinate mounting locations for lights and speakers early so the panel layout aligns with functional elements.
Practical buying considerations
- Determine the acoustic goal: absorption (NRC), isolation (STC), or diffusion.
- Request test data: manufacturer NRC and, if needed, specific lab tests for your configuration.
- Ask about factory finishing and whether perforations are masked during finishing.
- Check for fire-rating options and compliance with local building codes.
- Consider reversibility and access: hidden clip systems are best for spaces that may need future service.
- Budget for professional installation if tolerances, curves, or decoupling are required; DIY-friendly systems exist for simpler installations.
Maintenance and long-term care
Factory-finished panels are easiest to maintain — wipe with a damp cloth and mild detergent as needed. Avoid abrasive cleaners and exposure to direct water. For oil-finished surfaces, periodic reapplication will keep the finish vibrant. Keep humidity levels stable to minimize movement and seams.
Choosing an acoustic wood panel wall requires balancing aesthetics, finish durability, and the right installation approach to meet acoustic goals and practical needs. Consider the full system — panel profile, perforation pattern, backing material, finish, and mounting hardware — rather than the face material alone, and work with manufacturers who provide detailed acoustic data and installation support tailored to your space.
Optimizing placement, sizing, and room performance for an acoustic wood panel wall starts with understanding that the panels do two jobs: they shape sound and define the room visually. The best outcome comes from combining measured targets with practical placement strategies so the “acoustic wood panel wall” becomes both an effective acoustic treatment and a durable, attractive surface.
Begin with objectives and measurements
- Decide the room’s primary use: critical listening and control rooms need tighter reverberation control than a living room; home theaters need controlled bass and reduced slap echoes; offices and conference rooms prioritize speech intelligibility.
- Measure the room or at least note dimensions, ceiling height, floor material, window and door locations. If possible, make a baseline acoustic measurement (RT60 and frequency response) using a simple measurement microphone and free software (e.g., Room EQ Wizard). That data will guide placement and how much treatment is required.
Placement: focus on first reflections, bass control, and rear-wall treatment
- First reflection points: The most impactful placement for an acoustic wood panel wall is at the first reflection points on the side walls and ceiling relative to the listening/listener position. Use the mirror trick (have someone slide a mirror along the wall while you sit at the listening spot; mark where you see the speakers in the mirror) to locate the spots where early reflections arrive. Treat those points with panels or absorptive-backed wood panels to reduce comb filtering and improve clarity.
- Speaker and source placement: Panels behind speakers and behind the listener (rear wall) are important. A wood panel wall behind the speakers can control early mid/high reflections; a treated rear wall reduces flutter echoes and unwanted early energy bouncing back into the listening position.
- Ceiling and floor interactions: Don’t ignore the ceiling — a cloud or panel array above the listening position can cut early reflections. For rooms with hard floors, use rugs or rugs under seating to tame high-frequency reflections.
Sizing and coverage: how many panels and where
- Start with coverage guidelines, not exact prescriptions. Begin with treating 15–30% of the primary reflective wall areas (side walls, front wall, and ceiling) as a baseline for typical home and living spaces. For critical listening rooms or small home theaters, aim higher — 30–50% total surface treatment and more corner bass trapping.
- Panel depth and thickness matter. Thin wood slat panels (about 12–25 mm) with absorptive cores perform well at mid/high frequencies. To increase low-frequency performance, choose thicker panels (50–100+ mm) or use an air gap behind the panel — even a 25–100 mm gap increases low-frequency effectiveness significantly.
- Panel width and pattern influence diffusion. If you want diffusion alongside absorption, use variable groove widths or alternating slat spacing. Panels sized to break up wavelengths in the midband help avoid strong beam reflections. Modular sizes that align with standard stud spacing and mounting hardware simplify installation and can reduce waste.
Integrating function with aesthetics and structure
- Combine absorption and diffusion in your “acoustic wood panel wall” design: alternating absorptive-backed wood panels with diffusive wood or perforated panels can preserve warmth while maintaining clarity. Staggered placements, vertical slats, or chequerboard patterns can be both attractive and acoustically effective.
- Keep openings and ventilation in mind. Don’t block HVAC returns or emergency egress. If you place panels on doors or near windows, ensure they’re removable for maintenance.
- Fire and indoor-air safety: choose panels with appropriate fire ratings and low-VOC finishes. Many acoustic wood panels are composite constructions — check manufacturer specs for flame spread and emissions.
Tuning room performance: measure, listen, iterate
- After installation, re-measure RT60 across octave bands. Target values differ by use: conversational spaces may be comfortable around 0.4–0.7 seconds; home theaters and critical listening rooms often target lower and more uniform RT60 across mid-high bands. Use the measurements to add or relocate panels.
- Fine-tune with position changes. Sometimes moving seating, adding a rug, or shifting a panel by a few centimeters produces noticeable improvements. If bass is still an issue, add thicker panels, floor-to-ceiling traps, or corner-mounted absorbers.
- Aesthetics-driven compromises are common. If you can’t cover all first reflection points visually, prioritize the side wall first reflections, then the ceiling, then the rear wall. Use high-performance panels in high-priority spots and visually matched but thinner panels elsewhere.
Practical installation tips
- Leave an air gap where possible: mounting acoustic wood panels on battens or cleats an inch or more off the wall increases effectiveness at low frequencies without changing the front appearance.
- Secure mounting and structural support: large panels are heavy; anchor into studs or use appropriate fixings. Consider removable mounting methods if you may need to access behind the panels later.
- Modular vs. bespoke: modular panels are easier to replace and expand; bespoke continuous wood panel walls look seamless but are more expensive to modify.
Optimizing placement, sizing, and room performance for an acoustic wood panel wall is a balance between measurement-driven acoustics and practical design. Treat the early reflections, invest in bass control for low-end rooms, and use measurements and listening tests to guide iterative improvements so the finished acoustic wood panel wall delivers both sonic benefits and visual harmony.
Budgeting, warranties, and long-term maintenance considerations are critical when choosing an acoustic wood panel wall. These panels are both a functional acoustic treatment and a visible architectural element, so upfront costs are only the beginning of what you should plan for. Thinking beyond sticker price to installation, expected lifetime, repairability, and warranty coverage will save money and headaches later while ensuring the panel system continues to perform and look good for years.
Budgeting realistically
The cost of an acoustic wood panel wall varies widely depending on materials, acoustic core type, finish, complexity of layout, and labor. For budgeting, break the project into clear line items: materials (panels, trim, adhesives or mechanical fasteners), installation labor, finishing work (staining, sealing, trim), acoustic engineering or design fees (if needed), and contingency for waste and unforeseen site work.
Typical cost drivers:
- Material type: solid wood veneer panels over an acoustic core or engineered wood panels generally cost more than laminate-faced options. High-end hardwood veneers and specialty acoustic cores are premium-priced.
- Core and performance: panels with thicker absorptive cores or additional diffusion elements cost more but achieve better low‑frequency control. If you need strict acoustic specs, factor in testing or consultant fees.
- Installation: complex patterns, curves, integrated lighting, or on-site finishing increase labor time. Expect higher labor in retrofit situations on uneven walls.
- Extras: mounting hardware, fire treatment or certification fees, shipping for heavy or custom panels, and the cost to modify HVAC or electrical work around panels.
A useful rule of thumb is to estimate both initial cost per square foot and “lifecycle cost” per year. Lifecycle cost includes expected maintenance, refinishing cycles, and potential replacement of damaged panels. This will help you compare options with different upfront vs long-term expenses.
What to look for in warranties
A robust warranty protects your investment and reflects the manufacturer’s confidence. When shopping for an acoustic wood panel wall, carefully examine warranty details rather than relying on marketing claims.
Key warranty elements to check:
- Duration and scope: How many years does the warranty cover, and which components are covered (veneer finish, substrate/core, adhesives, mounting hardware)? Some suppliers offer separate warranties for finish and structural integrity.
- Coverage specifics: Does the warranty cover delamination, warping, finish fading, or acoustic performance degradation? Many warranties exclude natural changes in wood or color shift from UV exposure.
- Exclusions and conditions: Understand what conditions void the warranty—improper installation, high humidity, exposure to water, or use in commercial high-traffic settings are common exclusions. Often manufacturers require installation by certified professionals to keep the warranty valid.
- Transferability and service: Can the warranty transfer if the property changes owners? What is the claims process and expected turnaround for repairs or replacements?
- Fire and VOC certifications: Confirm warranties or guarantees related to fire ratings, formaldehyde or VOC emissions, and that any required treatments won’t void acoustic performance.
If warranty terms seem limited, ask for written clarifications or negotiate extended coverage, especially for high-investment projects.
Long-term maintenance and care
Maintenance needs depend on surface finish, core materials, and the environment. Wood veneers with clear finishes will need protection from UV and moisture; engineered surfaces might be easier to clean but harder to refinish.
Maintenance points to plan for:
- Routine cleaning: Dusting and soft wiping with manufacturer-recommended cleaners typically suffice. Avoid abrasive cleaners or excessive water. For high-traffic commercial areas, schedule regular cleaning intervals.
- Climate control: Maintain stable indoor humidity and temperature. Wood and composite panels can warp, swell, or delaminate in consistently damp environments. Use dehumidification where needed.
- UV protection: Direct sunlight can fade veneers or finishes. Consider UV-resistant coatings, window films, or strategic placement.
- Periodic refinishing: Solid veneer panels can often be sanded and refinished to refresh appearance; laminated options cannot. Budget for a refinishing cycle every 7–15 years depending on wear and finish.
- Minor repairs and replacements: Ask whether the supplier stocks matching panels for future patching, and whether individual panels can be removed and replaced without disturbing the whole wall. Having spare panels on hand simplifies repairs.
- Acoustic performance over time: While wood surfaces don’t typically lose absorption properties quickly, damage to the absorptive core or blockage of perforations and slots can reduce effectiveness. Inspect and clean perforations as part of maintenance.
Consider lifecycle planning: set aside a percentage of initial costs annually for maintenance and potential repairs, and document installation details, serial numbers, and finish codes to aid future servicing.
By factoring in realistic budgeting, scrutinizing warranty provisions, and planning for ongoing maintenance, you ensure your acoustic wood panel wall remains an effective acoustic solution and a long-lasting design feature.
Choosing the right acoustic wood panel wall means balancing sound performance, materials, installation and design—and after 40 years in this industry we know which tradeoffs matter. From evaluating NRC ratings, fire- and sustainability-certifications, and mounting systems to selecting the right wood species, finish and maintenance plan, the best outcome is a solution tailored to your space and budget. If you’d like confidence and clarity for your next project, our experienced team can help with product selection, samples, specifications and installation guidance—so your room not only looks beautiful, but sounds its best.
Customized Acoustic Materials Manufacturer
+86 156 0066 5034
