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Glass brick
Glass brick
Glass brick
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Exterior view of the illuminated facade of Maison Hermès in Tokyo, made of glass bricks.

Glass brick, also known as glass block, is an architectural element made from glass. The appearance of glass blocks can vary in color, size, texture and form. Glass bricks provide visual obscuration while admitting light. The modern glass block was developed from pre-existing prism lighting principles in the early 1900s to provide natural light in manufacturing plants. Glass bricks have several attributes that make them useful as a building material, providing insulation and admitting light while still allowing for privacy.

The first hollow glass block was patented in France on November 11th, 1886 by Swiss architect Gustave Falconnier [fr].[1][2] Mass production of glass blocks began in 1932, with the construction of the Owens-Illinois Glass Block building.[2][3] It has had a varied popularity since, appearing in Streamline Moderne[2] and Brutalist architecture. Today glass blocks are used in walls, skylights, and sidewalk lights.

History

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19th century precursors (1850s-1890s)

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Vault lights made of load-bearing glass bricks and embedded into a sidewalk in Burlington House, London.

Vault lights in sidewalks, which utilized prism lighting, were one of the first steps towards the modern hollow glass brick. At the end of the nineteenth century glass prisms became a popular way to diffuse light into spaces that would otherwise be difficult or unsafe to light via flame-based oil lamps (e.g. basements underneath sidewalks).[4]

Modern glass bricks were preceded by the hollow glass bricks patented by Gustave Falconnier in the 1880s.[1] Falconnier Bricks were blown glass bricks available in multiple colors and were formed in molds while the glass was molten.[5] They could be used for walls or roofs and were joined with wire and cement. The suggested use for Falconnier glass bricks was in greenhouse construction due to the non-conductivity of the glass for temperature control and lack of porosity of glass for moisture control. They were touted for not tarnishing, trapping dust, or retaining water.

20th century

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A Greyhound station located in Richmond, Virginia and constructed 1938-1939. Curved glass blocks are prominent along the front exterior of the building, demonstrating the Streamline Moderne architectural style endemic to the period.

In 1914, glass bricks (as well as several other kinds of glass furnishings) were used in Bruno Taut's Glass Pavilion, a significant building exemplary of the greater use of glass during the period.[6]

In the 1930s, glass blocks flourished among buildings built in the Art Deco and Streamline Moderne style. When used in forming a large, diffuse panel of glass, the bricks allowed light to pass into the building in daytime as well as pass out from the building at night, creating a glowing effect.[2]

Glass brick saw use as a building material throughout the rest of the 20th century. In the 1970s, architect Tadao Ando utilized glass block for the construction of the courtyards of several houses in Osaka, Japan.[2]

21st century

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While glass bricks have a reduced popularity in modern architecture,[2] it remains a common material for use in lavatories due to its ability to spread light while maintaining privacy via diffraction. Glass bricks are also used in art installations, such as the Crown Fountain in Chicago which features twin glass brick towers.[7][8]

Attributes

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Appearance

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The texture and color of glass blocks can vary in order to provide a range of transparency. Patterns can be pressed into either the inner void or the outside surface of the glass when it is cooling in order to provide differing effects. Glazes or inserts may also be added in order to create a desired private or decorative effect.

Standards and grading

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Glass blocks in Europe are manufactured in accordance with the European Standard EN1052-2. The International Standard is ISO TC 160/SG1. The Standards allow for variation in sizes and production irregularity. Blocks fall within three classifications; Class 1, Class 2 and Class 3 with Class 1 being the highest and best rating with a maximum permissible deviation from designed size and rectangularity of 1 mm.

Insulation

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Glass brick has an r value between 1.75 and 1.96, close to that of thermopane windows.[9][10] There are newer glass blocks injected with argon gas and having a layer of low-emissivity glass between the halves, which increases the insulative (U) value to 1.5 W/m2·K, which is between triple glazed windows (1.8 W/m2·K) and specialty double glazed windows with advanced frame and coatings(1.2 W/m2·K).[11]

Applications

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Wall blocks

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Glass block wall in Chicago.

Glass blocks can provide light and serve as a decorative addition to an architectural structure, but hollow glass blocks are non load-bearing unless stated otherwise. Hollow glass wall blocks are manufactured as two separate halves and, while the glass is still molten, the two pieces are pressed together and annealed. The resulting glass blocks will have a partial vacuum at the hollow center. Due to the hollow center, wall glass blocks do not have the load-bearing capacity of masonry bricks and therefore are utilized in curtain walls.[12] Glass block walls are constrained based on the framing in which they are set. If a masonry or steel frame exists, the maximum area of the wall can be 144 square feet (13.4 m2), whereas the maximum area without a frame is 100 square feet (9.3 m2).[13]

The William Lescaze House and Office at 211 East 48th Street in New York City, built in 1934, was the city's first house to use glass blocks as walls.[14]

Skylights and sidewalk lights

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Glass blocks used in flooring are normally manufactured as a single solid piece, or as a hollow glass block with thicker side walls than the standard wall blocks. These blocks are normally cast into a reinforced concrete gridwork or set into a metal frame, allowing multiple units to be combined to span over openings in basements and roofs to create skylights. Glass wall blocks should not be used in flooring applications because the way in which they are manufactured does not allow them to support a load.

Construction methods

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Glass wall blocks are fixed together to form complete walls by several methods – the most common method of construction is to bed the blocks together in a Portland cement-based mortar with reinforcing rods of steel placed within the mortar as recommended by the project architect or block manufacturer.

Other methods of construction include several proprietary systems whereby the mortar is replaced by timber or PVC extrusions.

Specialty types

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Specialist glass blocks are produced for various applications including:

Bullet and vandal resistance

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Bullet and vandal resistant blocks are generally solid glass or have very thick side walls similar to pavement blocks.

Fire resistant

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Fire resistance of varying degrees can be achieved by several methods. Standard production hollow wall block will offer little fire resistance; however, resistance is improved by utilizing specially produced hollow blocks with thicker sidewalls, or the inclusion of a special layer of fire-resisting material between the two halves of the block during manufacture. Some manufacturers of glass blocks have developed a method of bonding two glass blocks together with adhesive, producing blocks of up to 160 mm (6+12 in) thick with enhanced fire resistance. It is important that the block manufacturer's recommendations are followed with regards to the installation of fire resisting glass block walls, as without special construction techniques, the wall will not achieve the desired fire resistance.

Gas insulated

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A recent innovation in the manufacture of glass blocks is the inclusion of argon gas within the hollow center of glass wall blocks. This advancement in production technique has resulted in a glass block which is able to offer significantly improved thermal insulation properties.

Colored

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Some hollow glass wall blocks are available in colored variants. These colored variants fall into two categories. The first type is manufactured with UV stable colored glass and can be used in the same locations as standard clear glass blocks. The second type utilizes a colored material (dye or transparent paint) which is injected into the hollow center of the blocks to form a permanent coating, enabling vibrant colors to be achieved which are not possible with colored glass. However, the colored coating may not be UV stable and can fade in bright sunshine over time, and may therefore not be suitable for all locations.

Examples of architectural use

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  • Crown Fountain is composed of glass brick towers.
    Crown Fountain is composed of glass brick towers.
  • Glass brick labyrinths, used to obscure clear visual line of sight into women's washroom on the left, and men's washroom on the right.
    Glass brick labyrinths, used to obscure clear visual line of sight into women's washroom on the left, and men's washroom on the right.
  • Glass block floor in the Michigan State Capitol
    Glass block floor in the Michigan State Capitol
  • Glass block staircase towers at Ibrox Stadium
    Glass block staircase towers at Ibrox Stadium
  • Load-bearing prism lights in the banking hall of the Österreichische Postsparkasse in Vienna.
    Load-bearing prism lights in the banking hall of the Österreichische Postsparkasse in Vienna.
  • Glass block curtain walls at Raphael's Refuge outside of Flatonia, Texas
    Glass block curtain walls at Raphael's Refuge outside of Flatonia, Texas
  • Glass blocks in the form of bricks in the school in Bernau.
    Glass blocks in the form of bricks in the school in Bernau.
  • Glass bricks forming ceiling, stairs and wall in an apartment building Immeuble Clarté in Geneva.
    Glass bricks forming ceiling, stairs and wall in an apartment building Immeuble Clarté in Geneva.

See also

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References

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Revisions and contributorsEdit on WikipediaRead on Wikipedia

Glass brick

View on Grokipedia
from Grokipedia
A glass brick, also known as a glass block, is a prefabricated architectural element consisting of two molded halves of that are fused together to form a hollow, partially evacuated unit, typically measuring between 3¾ inches and 11¾ inches in maximum dimension, with various patterns, textures, and shapes available for aesthetic and functional purposes. These blocks are engineered for non-load-bearing applications, such as walls and panels, where they transmit diffuse while maintaining visual and offering resistance to impacts, sound, and thermal transfer. Constructed from soda-lime glass, often incorporating recycled content, glass bricks provide a durable, fire-resistant alternative to traditional or windows, with a lifespan exceeding 50 years under normal conditions. The invention of the modern glass brick traces back to 1886, when Swiss Gustave Falconnier patented the first hollow version, blown into a mold with a plugged end to create an air-filled cavity for insulation. It gained prominence in 1933, when the Owens-Illinois Glass Company showcased nearly 25,000 blocks at the Exposition, aligning with and styles that emphasized light diffusion and modernity. Popularity surged in the mid- for industrial and residential projects, waned in the late due to shifting design trends, and has seen a resurgence since the , driven by sustainable manufacturing and innovative applications in contemporary architecture. In architectural use, glass bricks excel in facades, interior partitions, enclosures, and feature walls, where they balance with performance by allowing up to 80% light transmission while blocking direct views and most B rays. Their benefits include enhanced energy efficiency through (R-values up to 1.5–2.0), superior sound attenuation (up to 45 dB reduction), and impact resistance meeting standards like ASTM E-1886 for hurricane-prone areas, making them suitable for both commercial and residential settings. Installation follows building codes requiring mortar joints and reinforcement for stability, ensuring compliance with non-load-bearing limits such as maximum wall areas of 144 square feet for exterior openings.

History

Early precursors and inventions (19th century)

The concept of using glass elements to transmit light into enclosed spaces originated with deck prisms in the 1840s, which were installed in ship decks to safely illuminate lower areas without relying on open flames. These cast glass pieces, often hexagonal pyramids, refracted sunlight below decks and served as precursors to building applications by demonstrating the feasibility of durable, light-directing glass in structural contexts. Early adaptations for terrestrial use appeared in the mid-19th century, with prism tiles and vault lights designed for industrial and subterranean lighting. In 1845, American inventor Thaddeus Hyatt patented vault covers featuring multiple small bull's-eye lenses embedded in iron frames, enabling light to penetrate basements and sidewalks while supporting foot traffic. By the 1850s, these evolved into prism-based systems for factories, where large sheets of glass with refractive facets directed daylight deeper into interiors, reducing dependence on artificial illumination. European experiments followed suit, including British firm Hayward Brothers' 1871 patent for semi-prism pavement lights that enhanced light distribution in urban settings. A pivotal advancement came in 1886 when Swiss architect Gustave Falconnier patented the first hollow block, known as "briques de verre," in (Patent No. 179,595). These blocks were produced via mold-blowing, similar to bottle-making, with a hollow center sealed airtight using a molten to create a partial , thereby reducing weight while improving insulation and . The design incorporated recessed sides for mortar bonding and optional internal metal reinforcements, making them suitable as modular building elements for walls and partitions. Falconnier's invention gained recognition at the 1889 International Exposition, where his blocks earned a medal and were showcased in architectural displays, highlighting their potential for aesthetic and functional lighting in structures. By the , early installations appeared in European buildings, such as basement walls and exhibition pavilions, marking the transition from experimental prisms to standardized glass bricks.

Commercialization and peak usage (early to mid-20th century)

The commercialization of glass bricks began in the early , building on 19th-century patents for hollow blocks by inventors like Gustave Falconnier in 1886. Early 20th-century advancements included processes for strengthening hollow glass blocks, addressing earlier limitations in fragility and paving the way for broader adoption in . Mass production in the United States commenced in 1933 with the Owens-Illinois Glass Company, which showcased the material at the Exposition by constructing the Owens-Illinois Glass Block Building using nearly 25,000 blocks. This event marked the first large-scale demonstration of glass bricks as a modular building element, highlighting their ability to transmit light while providing and insulation. Owens-Illinois's efforts established the material's viability for commercial use, with initial applications in industrial and structures. Pittsburgh Corning Corporation entered the market in the late 1930s, founding in 1937 and beginning large-scale production in 1938 as a competitor to Owens-Illinois. The company developed standardized blocks measuring 8 inches by 8 inches by 4 inches, which became a common size for easy installation akin to traditional . Corning aggressively marketed these blocks for and styles, emphasizing their aesthetic appeal in curved facades and decorative panels that diffused light elegantly. Glass bricks reached peak popularity from through the in the United States and , particularly in bathrooms, basements, and commercial spaces where natural light was needed without sacrificing . This surge was fueled by post-World War II housing booms, as the material's affordability, ease of maintenance, and insulating properties aligned with rapid suburban and urban construction. By 1940, over seven million blocks had been installed in U.S. industrial projects alone, reflecting substantial production growth. Early architectural integrations served as precursors and direct applications, such as the prism glass tiles in Chicago's from 1888, which transmitted light to lower levels and foreshadowed modern glass brick functionality. In the 1930s, Pittsburgh Corning's local influence led to widespread use in the city's buildings, including storefronts, lobbies, and warehouses that featured the blocks for both practical illumination and stylistic flair.

Revival and innovations (late 20th to 21st century)

Following a period of declining popularity in the and , often associated with shifting design tastes toward more minimalist aesthetics, glass bricks saw a notable revival in the , spurred by evolving building energy codes and a growing emphasis on . Updated energy efficiency standards, such as those evolving from the 1983 Model Energy Code to more stringent requirements by the , highlighted glass bricks' potential for natural daylighting and thermal performance, aligning with broader initiatives. This resurgence positioned glass bricks as a viable option for reducing in both residential and commercial projects, contrasting with their mid-20th-century role primarily as decorative elements. Key innovations in the late 20th and early 21st centuries enhanced glass bricks' functionality and appeal. By the , manufacturers introduced argon-filled glass blocks, which improved insulation by filling the internal cavity with gas to reduce , achieving U-values as low as 0.5 W/m²K compared to standard air-filled blocks. In a landmark advancement, in 2024 developed 3D-printed structural glass bricks using the Glass 3D Printer 3 (G3DP3), enabling customizable, interlocking forms from recycled glass that match the compressive strength of blocks (up to 20 MPa) while promoting recyclability and circular . Seves Glass Block, a leading producer, launched high-performance lines post-2000, including thicker-faced and solid variants that extended fire ratings to 90 minutes and incorporated low-emissivity coatings for superior energy efficiency. From 2020 to 2025, the glass block market expanded significantly, expected to grow by USD 666.4 million from 2024 to 2029, with a (CAGR) of 10.2%, driven by demand in sustainable and -focused designs. In 2025, glass blocks continued their resurgence in , with innovative applications in features and sustainable accents, as highlighted in design publications. Glass bricks made a strong comeback in interior applications, such as walls in bathrooms and offices, valued for diffusing while maintaining opacity and . Their integration into green buildings accelerated, contributing to certification through low , recyclability, and daylight optimization, with products like energy-efficient blocks earning credits under the and Atmosphere category. In , particularly , adoption grew for earthquake-resistant facades, where polymer-reinforced glass bricks with flexible mortar systems complied with seismic standards, enhancing structural resilience in high-risk zones.

Manufacturing and Materials

Production processes

The production of glass bricks primarily involves the melting of soda-lime glass raw materials, such as silica sand, soda ash, and lime, in a furnace at temperatures ranging from 1300°C to 1500°C to form a homogeneous molten mass. This molten glass, with a suitable for forming at around 1000-1200°C, is then processed using automated methods to create either hollow or solid blocks. For the most common hollow glass bricks, the process begins with automated pressing of the molten glass into two symmetrical halves using multi-station hydraulic or pneumatic presses, typically equipped with 10 to 12 stations. Each half is molded with a smooth outer face and an inner face featuring patterns or designs to facilitate assembly; air may be injected during pressing to help define the internal cavity. The edges of these halves are then preheated and melted at high temperatures to ensure fusion, after which they are coupled under pressure in a hot station to form a sealed hollow unit with a partial inside. Solid glass bricks follow a similar initial melting stage but are formed by pouring the molten glass directly into full molds via thermal fusion, allowing for denser, non-cavitied structures without the need for half-assembly. In both cases, the formed bricks are transferred to an annealing lehr—a continuous —for controlled cooling to relieve internal stresses and prevent cracking. This slow cooling process, often automated with anthropomorphic robots for precise handling, ensures structural integrity. Variations in production include hand-blown methods for early or custom artisanal glass bricks, where skilled workers shape molten glass using blowpipes and molds for unique forms, though this is less common in modern automated lines. For colored or patterned blocks, additives are incorporated during melting, followed by optional surface treatments. Patterns are created through mold texturing during production, with optional surface treatments such as acid etching applied post-annealing to create frosted or decorative effects on the outer faces. Final quality steps include visual and mechanical inspections to verify uniformity, dimensions, and strength—such as testing to at least 25 MPa for solid blocks—before packaging for distribution. These processes enable high-volume output, with modern lines capable of producing up to 25,000 units per day.

Composition and basic types

Glass bricks are primarily composed of soda-lime-silica glass, a versatile material valued for its transparency and ease of molding. This composition typically includes approximately 70-75% silica (SiO₂) as the primary network former, 10-15% soda (Na₂O) to lower the , and 5-10% lime (CaO) to enhance chemical and stability. Minor additives such as (around 4%) may also be incorporated to refine properties like . The basic types of glass bricks fall into three main categories: hollow, solid, and patterned. Hollow glass bricks, which dominate traditional applications, feature an internal cavity that makes them lightweight while providing insulation; these are formed by sealing two molded glass halves, resulting in a structure that is largely air-filled for reduced weight. Solid glass bricks, in contrast, are fully dense without internal voids, offering greater structural strength and suitability for load-bearing uses. Patterned variants introduce textured surfaces through mold texturing during production, with common designs including wavy for diffused , ice for subtle opacity, and fluted for directional control, enhancing aesthetic and privacy functions. Standard dimensions for glass bricks are typically 190 mm × 190 mm × 95 mm (approximately 8 in × 8 in × 4 in), which accounts for the majority of production and facilitates modular installation in walls and partitions. Specialized shapes, such as corner or end blocks, are available to accommodate curved or terminating configurations in designs. In modern eco-friendly formulations, recycled content can reach up to 50%, incorporating post-consumer cullet to reduce use and environmental impact without compromising core performance. These sustainable variants maintain the standard soda-lime-silica base while promoting principles in construction.

Physical Properties

Optical and aesthetic attributes

Glass bricks are designed to provide high translucency, typically transmitting 70-90% of while diffusing it to ensure by preventing clear view-through. This arises from the block's internal structure and surface treatments, allowing natural daylight to penetrate spaces without direct visibility, making them ideal for partitions in residential and commercial settings. Common patterns and textures enhance these optical qualities, with the ice pattern featuring a crackled, frosted surface that scatters evenly for maximum and a soft, ambient glow. The wavy pattern introduces undulating ridges for directional , distorting views while maximizing passage. In contrast, the clear pattern offers minimal distortion, approaching near-transparency within the block's diffused framework. Color options are achieved through the addition of metal oxides or pigments during , enabling hues like , or to tint the without significantly reducing transmission. Aesthetically, glass bricks create "walls of light" that produce a mottled, ethereal glow, transforming solid barriers into luminous elements that add depth and visual interest to interiors. Standard thicknesses of 4 inches contribute to this opacity by increasing the path length for , enhancing while maintaining structural integrity. For daylighting applications, glass bricks exhibit a solar heat gain coefficient (SHGC) of approximately 0.7, balancing admission with moderate heat control.

Thermal, acoustic, and structural performance

Glass bricks, particularly standard hollow variants, exhibit moderate properties due to their air-filled cavities, which trap air to reduce . The U-value for these blocks typically ranges from 0.5 to 0.8 BTU/hr-ft²-°F, indicating a reasonable resistance to conductive heat flow compared to single-pane glass. Correspondingly, the R-value measures between 1.2 and 2.0, providing basic heat retention suitable for non-extreme climates, though enhancements like inserted films can improve performance further. In terms of acoustic performance, glass bricks offer effective sound insulation, with a (STC) rating of 34 to 40 dB for standard installations, which can attenuate by 30 to 50% depending on and configuration. This makes them valuable for partitioning in urban or noisy environments, where the hollow design contributes to airborne without requiring additional layers. Structurally, glass bricks demonstrate compressive strengths of 1000 to 2000 psi, allowing them to support vertical loads in non-bearing walls when properly mortared. They also provide wind load resistance up to 50 psf in panel assemblies, enabling use in exterior applications with appropriate framing and safety factors. Regarding durability, glass bricks are inherently UV-resistant, as their soda-lime composition blocks most harmful UV-B and UV-C rays while maintaining clarity over time. Their non-porous surface prevents absorption and mold growth, contributing to a lifespan exceeding 50 years with minimal .

Standards and Specifications

Regulatory standards

In the United States, regulatory standards for glass bricks, also known as glass unit masonry, are primarily governed by the International Building Code (IBC), Section 2110, which requires compliance with Chapter 13 of the TMS 402 Building Code Requirements for Masonry Structures for design, construction, dimensions, and strength requirements of hollow and solid units. As of the 2024 IBC, references to TMS 402/602 have been updated to the 2022 editions. In seismic zones, assemblies must meet ASCE 7 provisions for seismic design categories, with product-specific evaluations provided through ICC Evaluation Service (ICC-ES) reports to verify performance under lateral loads. In , glass bricks are regulated under EN 1051-1, which defines shapes, dimensional tolerances, and material characteristics for use in non-load-bearing walls, with additional parts of the EN 1051 series covering test methods for mechanical, thermal, and acoustic properties. For load-bearing applications, is mandatory under the Construction Products Regulation (CPR), ensuring conformity with essential requirements for safety, health, and energy performance. Globally, ISO 21690:2021 establishes specifications and test methods for glass bricks in non-load-bearing walls and horizontal panels, including requirements for dimensions, , water tightness, and thermal performance. Fire ratings for glass brick assemblies are evaluated per NFPA 257, which outlines standardized fire endurance and hose stream tests to classify protection levels up to 90 minutes. Recent updates in the , such as the 2021 International Energy Conservation Code (IECC), incorporate glass bricks into fenestration requirements, mandating maximum U-values of 0.50 Btu/h·ft²·°F or less in various climate zones to promote energy efficiency in commercial and residential buildings. The 2024 IECC maintains these fenestration U-factor limits.

Grading systems and quality assurance

Glass bricks undergo grading primarily through to assess clarity, surface quality, and dimensional accuracy, ensuring uniformity across production batches. Units are inspected for visible defects such as bubbles, chips, or inclusions to ensure compliance with ASTM standards, with size tolerances of +/- 1/16 inch (approximately 1.6 mm). Testing protocols form a core component of , evaluating performance under simulated stresses. Impact resistance is assessed via drop tests, where a weighted is dropped from a specified height to verify the brick's ability to withstand breakage without shattering. Thermal cycling tests expose samples to temperature fluctuations to check for cracking or deformation, while water penetration resistance is measured according to applicable ASTM methods such as E331, applying static air pressure and water spray to fenestration assemblies. Manufacturers implement comprehensive measures, including ISO 9001 certification for standardized production processes that cover material sourcing, molding, and annealing. Batch tracing systems enable from raw materials to finished products, supporting efficient recalls and accountability in case of defects. Common production issues, such as bowing from uneven cooling or from mortar interactions in assemblies, are addressed through inline inspections and process controls to minimize occurrences.

Applications

Structural and partitioning uses

Glass bricks are primarily employed in non-load-bearing applications, serving as effective partitions within interior spaces. These units can form walls up to 20 feet in height and 25 feet in width, with a maximum panel area of 250 square feet, providing durable dividers that enhance without compromising structural integrity. In settings such as offices and bathrooms, they function as privacy screens, allowing controlled light passage while obscuring direct views, which supports functional separation in commercial and residential environments. For shower enclosures, are configured into curved or straight panels, offering a waterproof barrier when joints are sealed with to prevent infiltration. This application leverages the material's inherent resistance to while maintaining aesthetic appeal in wet areas. On exteriors, contribute to facades in low-rise , particularly for light wells that admit into interior spaces. Building codes limit stackable exterior panels to 144 , with maximum dimensions of 20 feet in height or 25 feet in width, ensuring stability in these non-load-bearing roles. A key advantage of glass brick partitions over solid is their lighter weight—approximately 20 pounds per compared to 38-40 pounds per for equivalent-thickness brick walls—resulting in 30-50% weight savings that reduce foundation loads and simplify handling. This combination of light diffusion for and reduced mass makes them ideal for partitioning without the structural demands of traditional .

Lighting and decorative uses

Glass bricks have long been employed in architectural designs to facilitate daylighting, particularly through applications like skylights and lights that illuminate otherwise dark subterranean spaces. These floor-embedded elements, often integrated into pavements or building floors, allow to penetrate basements and underground areas, enhancing visibility without compromising surface integrity. Typical clear glass bricks in such setups achieve visible light transmission rates of 50-70%, diffusing sunlight effectively while their optical attributes provide even illumination and reduce glare. In decorative contexts, glass bricks form striking panels that serve as feature walls in high-profile settings such as lobbies and commercial entrances, where their translucent quality adds visual interest and spatial depth. These panels can incorporate or patterned bricks to create artistic backdrops, and modern installations often integrate LED behind the blocks for dynamic accent illumination, enabling color shifts or glowing effects that enhance ambiance during evenings. The evolution of glass bricks in lighting and decorative roles spans from their industrial origins in the 1930s, when they symbolized modernity in and buildings by bringing light into factories and urban structures, to contemporary applications in the 2020s that align with principles. In wellness-oriented spaces like spas and offices, glass brick installations mimic patterns, fostering a connection to the outdoors and supporting occupant well-being through diffused daylight. Key benefits of these uses include substantial savings, with glass bricks reducing reliance on artificial by 20-30% through efficient daylight harnessing, alongside providing in high-traffic areas by obscuring direct views while permitting light passage. This combination promotes sustainable practices and enhances user comfort without sacrificing aesthetic appeal.

Modern Alternatives

In contemporary architecture, several materials serve as alternatives to glass bricks for structural, partitioning, lighting, and decorative applications, offering similar benefits in light diffusion, privacy, and aesthetics while addressing limitations such as weight, cost, or installation complexity. Acrylic blocks and sheets provide a lightweight, shatter-resistant option that mimics the translucent appearance of glass bricks, suitable for interior partitions and decorative panels with high impact resistance. Polycarbonate sheets, up to 200 times stronger than glass, are increasingly used for large-scale translucent facades and roofing, enabling efficient daylighting and privacy in non-load-bearing walls with superior durability against impacts and weathering. Frosted glass panels offer enhanced privacy through light diffusion in shower enclosures and office dividers, often combined with modern framing systems for easier installation compared to traditional glass brick assemblies. Additionally, window types such as casement, awning, and sliding vinyl windows provide functional replacements for glass block installations in exterior light wells and interior partitions, allowing operable ventilation and customizable frosting for privacy while reducing maintenance needs.

Installation and Construction

Preparation and assembly methods

Preparation of the installation site begins with ensuring the substrate is clean, level, and structurally sound to support the weight of the glass blocks. Substrate leveling is critical, typically achieved by applying a full mortar bed or using shims to create an even base, preventing uneven settling or misalignment during assembly. Expansion joints, filled with resilient materials such as fibrous glass or cork and caulked with non-hardening sealant to a minimum depth of 1/2 inch, must be incorporated at the sides and top of panels, with intermediate supports spaced to limit panel dimensions to no more than 25 feet horizontally and 20 feet vertically for non-bearing interior applications using standard units. For mortar preparation, a standard mix consists of 1 part , 1 part hydrated lime, and 4 to 6 parts , blended to a nearly dry, plastic-like consistency without additives like anti-freeze; pre-mixed white glass block mortars, such as those from Quikrete, require 4 to 5 quarts of per 50-pound bag for a stiff workable texture. Assembly methods for glass blocks primarily involve mortar bedding, where a 1/2-inch thick layer of mortar is applied to the base or sill as the initial bed, followed by setting blocks with buttered ends to form uniform 1/4-inch to 1/2-inch horizontal and vertical joints. Reinforcing rods or ladder-type wire are inserted in every horizontal joint at a maximum spacing of 16 inches vertically (typically every other row for standard blocks), and panel anchors secure the structure to the frame through expansion strips. For curved installations, channel systems using specialized kits like Seves Quicktech provide perimeter framing and spacers to accommodate radii as small as 1.55 meters, allowing blocks to follow the contour while maintaining joint integrity. Dry-stack techniques, suitable for faster assembly, employ plastic or vinyl spacers (typically 1/4-inch thick) to position blocks without mortar between them initially, enabling an "all-glass" appearance before applying sealant; these spacers ensure consistent gaps and are removed or left in place depending on the system. Essential tools for the process include margin trowels for applying mortar, spirit levels for checking alignment, rubber mallets for tapping blocks into place, and diamond-tipped saws or blades for precise cuts on blocks when custom fitting is required, as these tools minimize chipping on the edges. Curing requires 24 to 48 hours undisturbed for the mortar to set fully, with misting recommended in hot, dry, or windy conditions to prevent cracking and ensure strength development. Best practices emphasize maintaining vertical plumb throughout assembly using levels on each course to avoid cumulative misalignment, and applying silicone around the perimeter joints after mortar curing to provide and flexibility against moisture ingress. Dry-fitting blocks prior to mortaring confirms the layout and , while cleaning excess mortar with a damp immediately prevents staining on the surfaces.

Integration with building systems

Glass bricks integrate seamlessly with electrical systems, particularly for aesthetic enhancements like backlighting, where recessed wiring can be routed through cavities behind the blocks to illuminate the translucent surfaces without compromising the material's integrity; wiring must not breach the blocks themselves to avoid safety risks. This approach is common in interior partitions or feature walls, allowing low-voltage LED strips or fixtures to create diffused effects while maintaining the blocks' non-conductive properties. In wet environments, such as bathrooms or showers, all integrated electrical components must utilize IP-rated fixtures—typically IP65 or higher—to protect against moisture ingress and ensure electrical safety, aligning with requirements for damp or wet locations. Plumbing integration with glass bricks focuses on waterproofing to accommodate moisture exposure, especially in shower enclosures where blocks form semi-transparent walls. Sealed surrounds are essential, achieved by applying silicone caulk around the perimeter joints after mortar curing to create a watertight barrier that prevents water penetration into the block voids or surrounding structure. For floor-level applications, such as bases in shower pans, installations must incorporate a minimum slope of 1/4 inch per foot toward the drain to facilitate proper water runoff and avoid pooling, often in conjunction with a pre-sloped waterproof membrane beneath the blocks. These measures ensure durability and hygiene in high-humidity settings without altering the blocks' aesthetic diffusion of light. Structurally, glass bricks serve as non-load-bearing elements but require reinforcement throughout all assemblies, such as with ladder-type wire (e.g., two 9-gauge wires with cross ties at 16 inches on center) or Ø6-8 mm rods embedded in horizontal and vertical joints to enhance stability against lateral loads. For exterior or multi-story applications, compatibility with curtain wall systems is achieved via aluminum channels or panel anchors that isolate the blocks with 3/8-inch expansion joints, limiting deflection to L/600 and accommodating thermal movement while adhering to maximum vertical dimensions of 20 feet for standard reinforced panels per TMS 402 (referenced in IBC Section 2113), with local code variations possible. Compliance with building codes is paramount for safe integration, with in glass brick assemblies governed by NFPA 70 (), which mandates protected conduits and grounding to mitigate hazards in both dry and wet installations. Furthermore, glass bricks contribute to ADA compliance by offering clear visual paths through their high light transmittance—typically over 70%—ensuring that partitions do not obstruct sightlines in accessible routes, such as in public or residential bathrooms, while meeting visibility guidelines for enclosed spaces.

Specialty Variants

Security and impact-resistant types

Security and impact-resistant glass bricks are engineered variants of traditional glass blocks, specifically designed to withstand physical assaults including vandalism, forced entry, and ballistic threats. These bricks typically employ laminated constructions with multiple layers of bonded by shatterproof interlayers such as (PVB) films, or solid fused glass forms that distribute impact forces more effectively across the structure. To meet rigorous standards, these bricks are manufactured with increased thicknesses, often ranging from 4 to 8 inches in nominal dimensions for panel systems, as seen in products like VISTABRIK® blocks. This design enables compliance with standards that evaluate resistance through repeated impacts. Performance characteristics emphasize high energy absorption, with these bricks capable of withstanding impacts equivalent to 150–200 ft-lb, suitable for vandal and forced-entry scenarios as defined in related safety glazing tests like ANSI Z97.1 Class B. For ballistic resistance, advanced models integrate inserts or laminates within the layers, achieving UL 752 Level 3 ratings that stop handgun rounds without penetration or spalling, or equivalents to NIJ Level III for rifle threats like 7.62 mm ammunition. Compared to standard glass bricks, which provide baseline impact resistance through their inherent glass composition and compressive strength of around 400–600 psi, security variants offer substantially greater durability due to and thickness. Applications focus on high-risk environments, particularly windows and partition walls in urban high-crime areas such as banks, police stations, correctional facilities, and commercial storefronts, where they balance with .

Fire-rated and insulated types

Fire-rated glass blocks are engineered to meet stringent safety standards for containing flames and heat during a fire event. These variants achieve fire resistance ratings ranging from 45 to 120 minutes according to ASTM E119 testing protocols, which evaluate performance under controlled exposure to fire conditions. For instance, products like the VISTABRIK series provide a 120-minute rating for wall assemblies, ensuring structural integrity and limiting heat transfer. Insulated glass blocks enhance thermal performance through advanced cavity fillings, such as or gas, which significantly lower heat conduction. These gas-filled designs achieve U-values between 0.19 and 0.3 BTU/hr·ft²·°F, offering superior insulation compared to air-filled counterparts. Some models incorporate foam cores to further boost insulating properties, attaining R-values of 3 or higher, which helps maintain stable indoor temperatures. In terms of overall performance, these blocks can prevent flame passage and minimize radiant . Additionally, insulated variants reduce energy loss by up to 40% relative to standard glass blocks, contributing to lower heating and cooling demands in buildings. Recent developments include the DuraTherm series introduced in 2025 by Glass Block Association products, featuring a solar heat gain coefficient (SHGC) of 0.29 alongside its low U-value and of 2500 psi, optimizing both energy efficiency and daylight control. This series represents a high-impact advancement in combining with sustainable insulation for modern architectural applications.

Decorative and sustainable variants

Decorative variants of bricks enhance architectural through tinted and frosted finishes that diffuse while adding color and texture. Tinted options include emerald and , which provide subtle hues for interior partitions and feature walls, allowing to filter through with a softened glow. Frosted surfaces, often combined with these tints, offer privacy without complete opacity, making them ideal for bathrooms, offices, and retail spaces. Modular shapes further expand decorative possibilities, enabling custom configurations for installations and sculptural elements. Available in curved, corner, and forms, these bricks support geometric patterns or free-form designs that transform walls into dynamic light sculptures, as seen in retail environments like upscale stores where eclectic arrangements create focal points. Such versatility promotes creative expression in modern interiors, blending functionality with visual appeal. Sustainable variants prioritize environmental responsibility, with many glass bricks produced from 100% recycled , such as post-consumer bottles, ensuring full recyclability at the end of their lifecycle and diverting waste from landfills. This approach minimizes resource extraction compared to traditional , while production processes using recycled reduce demands relative to virgin . Although standard glass bricks rely on rather than binders, emerging composites incorporate bio-based elements to further lower environmental impact, though low-VOC emissions are inherent in the inert composition. Recycled bricks exhibit a lower embodied than blocks, potentially saving significant CO2 emissions through reduced use in alternatives like compressed blocks enhanced with glass powder. Innovations in sustainable glass bricks include 2024 advancements in , where engineers at MIT developed interlocking bricks from recycled , achieving structural strength comparable to while enabling modular, reusable . These figure-eight-shaped blocks, printed layer by layer from molten recycled , support circular building practices by allowing disassembly and reconfiguration, thus extending material lifespan and cutting waste. Although primarily clear in initial prototypes, the technology paves the way for colored variants to integrate decorative elements with eco-benefits. Glass bricks contribute to certifications like by facilitating daylighting, which qualifies for credits under Indoor Environmental Quality categories, such as achieving minimum illumination levels in occupied spaces for up to 2 points in LEED v4. Patterns that optimize light diffusion enhance energy efficiency by reducing reliance on artificial , supporting broader goals. The market for eco-variants, particularly recycled glass bricks, is expanding rapidly, with projections estimating growth to $2.5 billion by 2025 at a of approximately 22% from 2023 levels, driven by demand for low-carbon materials in .

Architectural Significance

Notable historical and modern examples

One of the earliest notable applications of glass elements akin to modern glass bricks appears in the in , completed in 1888, where prism glass blocks were integrated into the mezzanine floor to diffuse to lower levels, enhancing interior illumination in a pioneering design. In the 1920s, the Reebie Storage Warehouse in exemplified the decorative and functional use of glass blocks in its Egyptian Revival facade, where the blocks permitted penetration into storage areas while contributing to the building's ornate aesthetic. Turning to modern applications, the chalet in , designed by Elliot Barnes in the 2020s, employs glass blocks to clad a passageway leading to an indoor pool, creating a luminous transition space that blends privacy with light diffusion. In 2024, developed innovative 3D-printed recycled glass bricks, with plans to demonstrate them in experimental pavilions, showcasing their potential for sustainable, reconfigurable structures strong enough to rival . On a global scale, the Optical Glass House in , , completed in the 2010s by Nakamura, utilizes over 6,000 bespoke glass bricks in its facade to filter earthquake-prone region's sunlight into a central , dramatically enhancing natural illumination and casting dynamic patterns throughout the interior. This installation highlights the material's role in large-scale applications, where thousands of blocks collectively amplify daylighting effects for both aesthetic and practical benefits. Glass bricks exerted a profound influence on early 20th-century architectural movements, particularly through their adoption in and styles during the 1930s, where they diffused light and added geometric elegance to facades and interiors without ornate detailing. This material's ability to create luminous, patterned walls aligned with the era's emphasis on modernity and streamline aesthetics, as seen in exhibition pavilions at the . Earlier visionary ideas, such as those in Paul Scheerbart's 1914 Glasarchitektur, envisioned as a medium for utopian transparency, promoting buildings that dissolved boundaries between interior and exterior to foster a more enlightened society through pervasive light and color. In contemporary design, glass bricks have experienced a resurgence by 2025, integrating into biophilic and interior trends that prioritize diffusion to enhance occupant and connect spaces to the outdoors. This revival supports sustainable by facilitating passive solar strategies, where the blocks' translucency allows controlled daylighting while minimizing heat loss in energy-efficient structures. Designers often balance and illumination by employing frosted or patterned variants, enabling light penetration in private areas like bathrooms without visual exposure. Hybrid applications further evolve these trends, pairing glass bricks with metals or woods to introduce textural contrasts that enrich spatial depth and material dialogue in modern interiors. Culturally, glass bricks have shifted from their utilitarian role in industrial and public applications—prioritizing function over form—to a luxurious vintage element in the , symbolizing retro-futurism and high-end customization in residential and designs. This resurgence of glass bricks coincides with the rise of modern alternatives that influence design trends toward greater sustainability and innovation. Emerging substitutes, such as bio-glass and sustainable composites, provide comparable functions like light diffusion, privacy, and structural support while addressing environmental concerns. Bio-glass, exemplified by Thames Glass cladding tiles made from ground-up quagga mussel shells, sand, and waste wood ash, offers an eco-sensitive option with unique handmade textures and colors, reducing reliance on unsustainable traditional glass production. Sustainable composites, incorporating bio-based fibers like mycelium and hemp with recycled polymers, enable lightweight, recyclable panels for insulating and light-filtering applications, promoting circular economy principles in architecture and encouraging hybrid material strategies that balance performance and ecological impact.

References

  1. https://up.codes/s/glass-blocks
  2. https://www.iso.org/standard/75042.html
  3. https://sevesglassblockinc.com/wp-content/uploads/2025/07/SEVES_EPD_2025-05-20_AN.pdf
  4. https://www.uniccm.com/blog/glass-blocks-uses-installation-methods-and-benefits
  5. https://sevesglassblockinc.com/history-of-glass-block-in-architectural-design/
  6. https://www.archdaily.com/941686/glamorous-glass-bricks-are-booming-nil-again
  7. https://www.evermadeglass.com/blogs/why-glass-block-walls-are-making-a-comeback-in-modern-design.html
  8. https://www.qualityglassblock.com/wp-content/uploads/2021/08/08-88-56-LWA-Ballistic.pdf
  9. https://www.thoughtco.com/does-glass-block-uv-light-608316
  10. https://sevesglassblockinc.com/products/hurricane-resistant-windows/
  11. https://www.asttile.com/blog/do-glass-blocks-reduce-noise-793361.html
  12. https://glassian.org/Prism/Deck/index.html
  13. https://glassian.org/Prism/
  14. https://glassian.org/Patent/4266/page1.html
  15. https://glassian.org/Patent/GB18712014/page1.html
  16. https://academiccommons.columbia.edu/doi/10.7916/D8765NZK/download
  17. https://glassian.org/Falconnier/
  18. https://glassian.org/Prism/Patent/402073/page1.html
  19. https://glassian.org/Falconnier/quittenbaum.html
  20. http://forgottenchicago.com/features/chicagos-glass-block-part-i-1893-early-glass-block-and-prism-glass/
  21. https://beavertownblock.com/2022/08/the-history-of-glass-blocks/
  22. https://www.wesa.fm/development-transportation/2024-01-16/pittsburgh-glass-block-windows
  23. https://www.architecturaldigest.com/gallery/glass-blocks-are-having-a-comeback
  24. https://www.lifeofanarchitect.com/la-mort-aux-blocs-de-verre-death-to-glass-blocks/
  25. https://sustainableenergyaction.org/resources/energy-codes-then-and-now-1983-2021/
  26. https://www.gbaproducts.com/blog/the-resurgence-of-glass-block-a-timeless-and-versatile-design-choice
  27. https://sevesglassblockinc.com/energy-saving-glass-blocks/
  28. https://www.qualityglassblock.com/glass-block/high-performance-line/energy-block/
  29. https://news.mit.edu/2024/engineers-3d-print-sturdy-glass-bricks-building-structures-0920
  30. https://sevesglassblockinc.com/products/product-series/high-performance/
  31. https://www.sevesglassblock.com/high-performance-sustainability-glass-block/
  32. https://www.technavio.com/report/glass-blocks-market-industry-analysis
  33. https://www.qualityglassblock.com/new-ways-to-utilize-glass-blocks-in-2025-innovating-with-modern-glass-block-designs/
  34. https://glassblockwarehouse.com/why-glass-bricks-are-making-a-comeback-in-interior-design/
  35. https://architizer.com/blog/practice/details/material-lab-glass-block/
  36. https://www.360iresearch.com/library/intelligence/glass-bricks
  37. https://shdcrystal.com/blogpost-of-solid-glass-block/
  38. https://www.continentaltrade.com.pl/en/our-offer/technical-glass/types-of-materials/soda-lime-glass
  39. https://www.ocmigroup.com/project/glass-blocks/
  40. https://patents.google.com/patent/WO2003018492A1/en
  41. https://patents.google.com/patent/US2068798A
  42. https://www.hhglass.com/news/Manufacturing-process-of-colored-glass.html
  43. https://www.walkerglass.com/acid-etched-glass-a-versatile-product-that-opens-endless-possibilities/
  44. https://advancedtechnicalprod.com/industry-news-blog/all-about-soda-lime-glass-composition-and-properties/
  45. https://www.shannieartandglass.com/blog/softvsboro
  46. https://archihunger.wordpress.com/tag/glass-blocks/
  47. https://www.qualityglassblock.com/what-is-glass-brick/
  48. https://glassblocksupply.com/glass-bricks-for-sale/
  49. https://easternglassblock.com/glass-block-styles-patterns-shapes-sizes/
  50. https://asiandavinci.com/product/190x190x95mm-clear-glass-block-high-quality-glass-brick-use-in-bathroom-or-washroom-decoration-or-partition-wall/
  51. https://www.eco-outdoor.com/en-us/stone-walling/mano-bricks/glass
  52. https://www.sevesglassblock.com/wp-content/uploads/2018/03/Technical_Guide_en.pdf
  53. https://sevesglassblockinc.com/products/glass-block/high-tech-options/high-performance-high-tech-options/frosted-block/clear-8x8x3
  54. https://glassblockwarehouse.com/product/glass-block/basic-line/clear-glass/wave/1919-8-wave/
  55. https://www.gpi.org/glass-coloring
  56. https://sevesglassblockinc.com/products/product-series/basic-line/injected-colors/
  57. https://continuingeducation.bnpmedia.com/courses/pittsburgh-corning/designing-with-glass-block-abundant-applications-provide-practical-aesthetic-and-green-solutions/
  58. https://cincinnatiglassblock.com/glass-block-collection/standard-4/
  59. https://www.energy.ca.gov/sites/default/files/2024-03/2022%2520Single-Family%2520Envelope%2520Final%2520ADA.pdf
  60. https://cdn.websites.hibu.com/fe58892a8e7d441d966b38c0f36a2835/files/uploaded/%28A%29%20Seves%20North%20America%20Catalog.pdf
  61. https://sweets.construction.com/swts_content_files/778/0980_042300-PIT_08.pdf
  62. https://thebottledepot.co/blogs/articles/does-glass-block-uv-light
  63. https://www.qualityglassblock.com/glass-block-beautiful-functional-durable/
  64. https://codes.iccsafe.org/content/IBC2021P1/chapter-21-masonry#IBC2021P1_Ch21_Sec2110
  65. https://masonrysociety.org/product/tms-402-602-2016/
  66. https://standards.iteh.ai/catalog/standards/cen/9b14966b-da12-4550-9ec8-2680e09ff7ae/en-1051-1-2003
  67. https://glassblocksupply.com/wp-content/uploads/2018/11/SEVES-North-American-Glass-Block-Design-Guide-2018.pdf
  68. https://www.astm.org/e0331-00r16.html
  69. https://www.willamettegraystone.com/pdf/Architectural_products.pdf
  70. https://www.asttile.com/blog/what-are-the-common-defects-in-glass-blocks-846675.html
  71. https://www.qualityglassblock.com/wp-content/uploads/2021/09/TYPICAL-DETAIL-INFORMATION-AND-CODE-LIMITATIONS.pdf
  72. https://www.familyhandyman.com/project/how-to-install-a-glass-block-shower/
  73. https://glassblockblogger.com/2011/12/30/design-criteria-glass-block-new-jersey-new-york-boston-philadelphi/
  74. https://glassblockwarehouse.com/glass-blocks-a-light-enhancing-design-solution/
  75. https://www.kqed.org/news/11791667/what-are-those-grids-of-glass-in-the-sidewalk-and-why-are-they-purple
  76. https://www.gbaproducts.com/blog/vaulted-sidewalk-vault-lights
  77. https://sevesglassblockinc.com/products/basic-line/clear-glass/wave/wave-19198-frosted-2s/
  78. https://www.asttile.com/blog/can-glass-blocks-be-used-in-a-hotel-lobby-1091570.html
  79. https://www.gbaproducts.com/glass-block
  80. https://glassblocksupply.com/glass-brick-wall/
  81. https://www.accio.com/plp/colored-glass-bricks
  82. https://www.circleredmont.com/transforming-interiors-with-glass-bricks-a-timeless-design-element/
  83. https://sevesglassblockinc.com/glass-block-and-daylighting/
  84. https://www.acplasticsinc.com/informationcenter/r/plastic-materials-that-are-replacing-glass
  85. https://homeworlddesign.com/why-polycarbonate-sheets-are-the-latest-trend-in-building-design/
  86. https://www.sabinplastic.com/6-creative-ways-to-use-polycarbonate-sheets-in-modern-architecture/
  87. https://nicholasdesignbuild.com/5-glass-block-window-alternatives/
  88. https://www.southwestexteriors.com/blog/2023/december/3-best-window-types-to-replace-glass-block-windo/
  89. https://glassblocksupply.com/how-to-install-glass-block/
  90. https://masonrysociety.org/wp-content/uploads/2022/06/TMS_402-602_Public_Comment_Draft_2021-05-31.pdf
  91. https://www.quikrete.com/pdfs/data_sheet-glass%20block%20mortar%201610.pdf
  92. https://www.tecspecialty.com/hbfuller-media/3044/pds_tec_363_glassblockmortar_r1120.pdf
  93. https://www.youtube.com/watch?v=rBVHWICnzu4
  94. https://www.sierraglassblock.com/uploads/i1GHrOBf/stack_grout_mortar_r.pdf
  95. https://ukam.com/everything-you-wanted-to-know-about-cutting-glass-with-diamond-blades/
  96. https://www.thisoldhouse.com/bathrooms/21163358/how-to-install-glass-block-in-the-bathroom
  97. https://www.gbaproducts.com/blog/security-glass-block
  98. https://www.constructionspecifier.com/through-the-window-security-glass-magnified/
  99. https://www.researchgate.net/publication/349276443_Mechanical_properties_of_solid_glass_bricks
  100. https://glassblocksupply.com/product-category/glass-block/technology-line/bullet-resistant/
  101. https://www.gbaproducts.com/fire-rated-glass-block-windows
  102. https://glassblockwarehouse.com/2-hour-fire-rated-wall-glass-block-combining-safety-style-and-natural-light/
  103. https://www.wric.com/business/press-releases/ein-presswire/841136877/gba-unveils-duratherm-energy-block-a-new-era-of-glass-block-performance
  104. https://glassblocksdirect.co.uk/technology-line/energy-saving-glass-blocks
  105. https://www.onedayglass.com/products/firelite-fire-rated-glass/?srsltid=AOmBOoqkKu1KtByXJKPsaL8qsqKco8DQjfKNDWAkty4hlPBenKUz9mif
  106. https://www.gbaproducts.com/blog/duratherm-energy-glass-block
  107. https://innovatebuildingsolutions.com/product/colored-frosted-glass-blocks/
  108. https://www.archiexpo.com/architecture-design-manufacturer/colored-glass-brick-20741.html
  109. https://espacioeslava.com/Bricks-Colorful-Architectural-Blocks-For-Walls-Dividers-372029/
  110. https://steadfastentities.com/sustainable-glass-brick-construction/
  111. https://www.letsrecycle.com/news/recycled-glass-could-replace-cement-in-construction-study-finds/
  112. https://www.epa.gov/sciencematters/recycled-glass-epa-funded-technology-provides-renewable-alternative-concrete-new
  113. https://parametric-architecture.com/mit-3d-printed-glass-bricks/
  114. https://www.usgbc.org/credits/eq8
  115. https://www.archivemarketresearch.com/reports/recycled-glass-bricks-371020
  116. https://www.therookerybuilding.com/the-architecture
  117. https://debradobbs.com/glass-blocks-and-prisms-chicago-architecture/
  118. https://www.dezeen.com/2013/01/27/optical-glass-house-by-hiroshi-nakamura-nap/
  119. https://www.artdeco.org/art-deco-architecture-materials
  120. https://open.clemson.edu/cgi/viewcontent.cgi?article=1005&context=archetecture_pubs
  121. https://www.dayhousestudio.com/your-biophilic-design-resource/interior-design-trends
  122. https://www.shchanson.com/post/light-utility-and-art-the-early-history-of-glass-blocks
  123. https://archinect.com/news/article/150311676/design-team-develops-bio-glass-cladding-tiles-made-from-mussel-shells
  124. https://www.archdaily.com/1036916/circular-composites-designing-for-a-sustainable-future
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