Glass bubble,Hollow glass microspheres , Glass sphere beads, Manufacturer & suppliers

The development of the times has put forward higher requirements for materials, shoes are lighter, cars are more fuel-efficient, plastic products are more environmentally friendly, processing performance is better, cost is lower, and quality is better…
These are the source of material innovation and the driving force of the development of the times. As a new type of functional filler, hollow glass microspheres have gradually come under the spotlight of the material industry, bringing possibilities for more innovations.

Application of hollow glass microspheres in resin system
High-strength, low-density hollow glass microspheres can be used as lightweight additives in a variety of polymers and applications, while maintaining or improving processability and material physical properties, including:
1) Polyolefins, nylon composites and other thermoplastics
2) Thermosetting materials, liquids and pastes
3) Sheet molding and bulk molding composites
4) Elastomers
5) Substitute wood/polymer composites

Performance improvement of hollow glass microspheres for resin systems
The hollow microspheres can withstand processing conditions such as temperature and pressure of blending, injection molding, extrusion and other manufacturing processes. Correct use can improve product quality:

reduce weight
First of all, the density of glass beads is 0.4-0.75g/cm3, which reduces the density of the composite material to achieve the effect of weight reduction. Secondly, due to the hollow characteristics, the use of resin is reduced while meeting the performance; The development of aviation lightweight.

Improved dielectric properties
Since the interior of the glass beads is air, the dielectric constant of the air is 1, which makes the dielectric constant of the hollow glass beads very low as a whole, reducing the loss of high-frequency signals, which is very useful in the 5G industry and autonomous vehicles. .

Improve flow performance
Hollow glass microspheres are tiny spheres that play the role of miniature ball bearings in the resin, and have better fluidity than flake, needle or irregular shaped filler particles. The resulting microsphere effect makes mixing The viscosity of the material decreases, the filling performance is naturally excellent, and the good processing performance can increase the production efficiency by 15% to 20%.

Reduce shrinkage and warpage of products
Since spherical objects are isotropic, filled microbeads can overcome the disadvantage of inconsistent shrinkage rates of different parts caused by orientation, ensure the dimensional stability of the product, reduce warpage, and solve the problem that has always existed in the molding of special-shaped materials and large injection molding products. deformation problem. In addition, hollow glass microspheres are used as fillers to improve the processing speed of filling and modified materials and improve production efficiency.

lower oil absorption
The oil absorption rate of hollow glass microspheres is 0.20~0.60cc/g, because of its spherical structure, the specific surface area per unit volume is lower, and the oil absorption value is lower.

Volume cost is more economical
The density of high-performance hollow glass microspheres is only 1/5~1/2 of the resin density, and only a small amount of hollow glass microspheres can be used to replace other heavier powder materials under the same volume. When considering the cost per unit volume, the weight of the product can be reduced after filling, thereby reducing the amount of the main raw material resin and rubber, and reducing the cost of the product.

Reinforced resin rigidity, sound insulation and noise reduction
Hollow glass microspheres are rigid particles themselves, which can improve the compressive strength and modulus of the material after being added to the resin.
At the same time, because the interior of the glass beads is air, the air thermal conductivity is low, and the porous material will absorb the vibration of the sound wave, thereby reducing the heat and hindering the transmission of the sound wave.

FROM:Eighth Element Plastic Edition

White roof coatings have existed in hot countries for a long time. These coatings help to reflect solar energy back into the atmosphere, rather than heating up the building. To achieve this white finish, pigments and fillers like titanium dioxide and calcium carbonate are used.

This article demonstrates that, with the use of hollow glass microspheres in a coating, one can achieve a high level of total solar reflection with the dry film. This helps to reduce the need for energy-intensive cooling systems.

It is worth noting that there are many coating applications possible with this technology and that it is not just restricted to improving the energy efficiency of buildings. Other examples that would benefit from the use of solar heat reflective coatings include caravans, mobile homes, cold storage distribution centres, refrigerated vehicles, oil and gas storage tanks, cryogenic tanks and tankers, and deck coatings.

Total solar emission comprises UV, visible and IR radiation – the latter responsible for heating. In this article, we will show that hollow glass bubbles offer an excellent level of reflection in both the visible and IR regions of the spectrum.

Testing hollow glass microspheres for Total Solar Reflectance when incorporated into a coating
A waterborne coating was formulated for the subsequent TSR testing. Glass bubbles are compared with calcium carbonate on a volume replacement basis. For this study, 22.5% by volume of glass bubbles or calcium carbonate were used.

A Perkin-Elmer spectrophotometer was used to analyse the Total Solar Reflectance of the subsequent coating at 400 microns. hollow glass microspheres outperformed the reference filler (calcium carbonate). Conventionally filled roof coatings absorb over 50% more solar energy compared to systems containing the novel, small particle size glass bubbles. This correlates to impressive temperature reduction. These coatings can also be applied with an airless sprayer, without breakage of the hollow glass microspheres.

How does Total Solar Reflectance correlate with the reflection of heat?
Each coating was painted onto an aluminium panel and exposed to an IR lamp. A thermocouple on the other side of a supporting polystyrene box was monitored over time, to investigate the thermal barrier presented by the coating.

A good correlation is found between Total Solar Reflectance and the level to which heat transfer is reduced through the coating. with a reduction of 10°C when compared to the coating containing only calcium carbonate.

What other benefits can hollow glass bubbles impart to your coating?
Additionally, hollow glass bubbles reduce microcracks forming in the coating, due to the reduction of shrinkage and warpage under temperature fluctuations. These cracks can form thermal bridges through the coating and areas for water infusion, leading to subsequent algae and fungal growth. Glass bubbles reduce crack formation when using nails or screws.

Author: Adam Morgan , Ph.D.

We will take a closer look at how the unique morphology of Glass Bubbles translates to benefits in modern composite systems. We will also explore the latest in Glass Bubbles technology for composites systems.

What are Glass Bubbles?
Glass Bubbles are tiny, hollow glass microspheres. They appear as a white free-flowing powder and are made from a water-resistant and chemically stabile soda-lime-borosilicate glass. Originally developed by 3M in the 1960s, they can nowadays be found almost everywhere: from the deep seas to the stratosphere, from specialist industrial applications to consumer goods. Cars, airplanes, bowling balls, fishing line, snowboards, deck chairs, and so on, all make use of the unique properties of Glass Bubbles.

The composites sector recognised early on that Glass Bubbles have an exceptional ability to reduce the weight of composite parts. Compared to conventional fillers such as talc or calcium carbonate, the density of Glass Bubbles can be 20 times lower (depending on the grade). Glass Bubbles have since become ubiquitous in resin systems including polyesters, polyurethanes, and epoxies.

Glass Bubbles are hollow glass microspheres that behave like free-flowing powders. The automotive industry has embraced these materials for their unique ability to lightweight parts as well as add other benefits.
The automotive industry in particular embraced Glass Bubble technology as lighter parts translate to improved fuel economy. In cars and trucks, Glass Bubbles can be found in composite parts such as exterior body panels, roofs, headlight reflectors, wind deflectors, fenders, floorboards, access doors, and internal panels such as engine housings and spare tire wells.

While Glass Bubbles are best known for their ability to reduce the weight of parts, this is far from their only feature. Modern applications in composites rely on the ability of Glass Bubbles to improve processing and to enhance the properties of the final composite parts. Processing improvements generally refer to the ability to produce parts at increased production speed and with greater ease. Property enhancements refer to complementary functionalities brought on by the Glass Bubbles. These can be extremely diverse, ranging from mechanical properties (stiffening) to fire-retardant properties, acoustics & dampening, and thermal insulative properties.

Glass Bubbles are lightweight
The density of Glass Bubbles ranges from 0.15 g/cc to 0.60 g/cc. In contrast to other mineral fillers such as chopped glass fibre, calcium carbonate and talc, the volume per unit of weight is therefore much greater. Replacing inorganic fillers with Glass Bubbles therefore results in composite parts with reduced density. For example, 1 kg of typical Glass Bubble material (K20) has a volume of 5000 cm3, while the equivalent weight of CaCO3 displaces only 370.4 cm3. Due to the extremely low densities of Glass Bubbles, formulation, therefore, needs to be on a volume basis rather than a weight basis. If one were simply to substitute an equal weight of Glass Bubbles for the calcium carbonate in a formulation, the volume ratio of all other ingredients would be reduced substantially. Formulating by volume instead of weight allows the proper balance of resin, filler, and reinforcement, so components can be made lighter while still maintaining a good balance of physical properties.

An older but useful example of the use of Glass Bubbles to precisely control the weight of the final part can be found in the manufacturing of bowling balls. Here, the inner cores of bowling balls are prepared using a cast polyester resin. The more Glass Bubbles used in the resin, the lower the density of the bowling ball. Therefore, the final weight of the bowling ball can be adjusted precisely and easily by adjusting the volume concentration of Glass Bubbles in the resin. Importantly, the addition of Glass Bubbles does not affect the stability of the resin, and the resin mixture remains free-flowing. As this simple example highlights, Glass Bubbles have more to offer advanced composite materials besides the obvious density reduction. In the next section, we will explore the secondary benefits and how they relate to the unique physical characteristics of Glass Bubbles.

When incorporating Glass Bubbles into a composite, one is essentially replacing a fraction of resin and/or solid fillers with uniform and microscopic pockets of air. The replacement of resin by air results in some unique side effects.

For example, the reduction of mass in turn reduces the heat capacity of the resin, which in turn results in shorter cooling times allowing parts to be produced faster. Moreover, the composite’s coefficient of linear thermal expansion (CLTE) decreases. The low CLTE means that larger composite parts can be manufactured, and these are less prone to deformation during cooling, also known as warpage.

The low CLTE can also provide benefits in the finished parts. For example, solid parts engineered using Glass Bubbles (e.g. roofing trims) will be less prone to cracking when exposed to hot/cold cycles.

In a similar vein, the thermal conductivity is lowered by the presence of Glass Bubbles. The resulting thermally insulative parts find extensive use in energy-saving applications (e.g. bathtubs which keep water warm for longer) and also add value to various consumer goods (e.g. steering wheels or shower trays which are warm to the touch).

Replacing resin and solid fillers with hollow Glass Bubbles also lowers the calorific content of the composite part. A useful side effect of this property is that fire retardant performance is improved by the introduction of hollow Glass Bubbles – simply put there is less material to burn – resulting in better fire ratings. Recently researchers also discovered secondary mechanisms by which the hollow nature of Glass Bubbles leads to a fire hazard reduction, for example in rigid foams.
The hollow nature of the Glass Bubbles further impacts the composite’s interaction with light and sound waves. This property finds its use in specialised applications such as acoustic damping.

Glass Bubbles, as the name implies, are perfectly spherical. Glass Bubbles therefore have the lowest possible surface to volume ratio of any filler. As a result, Glass Bubbles require less resin to be wetted out compared to non-spherical fillers. In many cases this means that the resin content can be lowered, resulting in cost savings and reduction of VOC emissions.

Another side effect of the spherical nature of Glass Bubbles is that the effect on the viscosity of the resin is minimised. This property is often described as a ‘ball-bearing’ effect. A better flowing resin not only allows parts to be produced more quickly, but it also results in a more isotropic filling of the mould. This in turn leads to composite parts in which stresses are more uniformly distributed. In contrast, angular fillers such as talc or glass fibres tend to interlock at higher loadings resulting in stress concentrations and fracture points in the cured part.

A great example of a technology that has successfully exploited the low viscosity impact of Glass Bubbles is Reaction Injection Moulding (RIM). RIM is a manufacturing process in which liquid polyurethane or polyurea precursors are combined, injected into a mould, and subsequently polymerised to produce the part. Since the resin is introduced into the mould as a liquid, flowability of the resin is key to ensure the precise reproduction of components with thin walls and complex geometries. Glass Bubbles work in this application to maintain flowability and to reduce the density of the parts, typically alongside heavier reinforcing fillers such as acicular Wollastonites.

Glass Bubbles are closed spheres consisting of a chemically stable soda-lime-borosilicate ‘shell’, so they are intrinsically stable toward heat damage and chemical degradation. Glass Bubbles can therefore be added into most resin systems including polyester, epoxy, and polyurethane. Their size, shape, and chemistry will not be affected by processing conditions such as temperature, humidity, nor will their properties change over time, such as during storage. The dimensional and chemical stability of Glass Bubbles is a unique advantage over other lightweight fillers such as plastic microspheres.

The stability of Glass Bubbles is particularly useful in applications in which there is some delay between mixing and curing of the resin formulation, which includes epoxy or polyester marine putties, adhesives, sealants, and polyurethane structural foams.

Glass Bubbles can withstand high external pressures due to their spherical shape and chemical make-up. The strength of Glass Bubbles quantified as the isostatic crush strength, which is dependent on the grade and varies between 100 to 30 000 PSI. Since the crush strength of a specific grade depends greatly on the wall thickness, the crush strength and density of the grade are inversely related. As a result, the selection of a grade of Glass Bubble for a specific application is usually determined by the crush strength required to survive the processing during manufacturing of the part.
Sheet moulding compound (SMC), the most prominent mass manufacturing technique to produce large composites structures, is a great example of a process in which the high strength of Glass Bubbles is of benefit. SMC is produced in sheets that consist of a thermosetting resin combined with glass fibres and other fillers. The SMC is moulded by part manufacturers under high pressure and subsequently cured. As described in the introduction, the automotive industry relies on SMC to fabricate both external surfaces (body panels, roofs), as well as internal panels (engine housing, spare tire wells, floorboards). SMC is also widely used in structural applications ranging from trench covers to lightweight roofing panels.

Author: Koen Nickmans , Ph.D.

Hollow Glass Microspheres is a Free Flowing White Powder and showed to be hollow sealed sphere under microscope. Application Hollow glass microspheres have a significant effect to reduce weight and noise insulation, make the products have good anti-cracking performance and re-processing performance, is widely used in glass, steel, artificial marble, artificial agate and other composite materials, and the oil industry, aerospace , new high-speed train, car ferry, insulation coatings and other fields.

Low density drilling fluids made with hollow glass microspheres:
1) Adjustable density in a wide range
2) Incompressible and uniform in density
3) Good lubricity, Reduce drilling tool wear
4) No pollution for reservoir
5) Good stability at high temperature and pressure
6) No loss of MWD signal
7) Mud cake quality improved

Low density cement slurries made with hollow glass microspheres:
1) Density can be decreased to as low as 0.90g/cm³
2) Low porosity
3) High compressive strength
4) Good stability at high temperature and pressure
5) Low fluid loss rate
6) Adjustable thickening time

FROM:chnchemical

Hollow Glass Microspheres‘ applications are in the fields of Thermal insulation coating, putty, plastic casting polyester, FRP ,SMC, synthetic foam, adhesives, printed circuit board substrate, RTM, bowling, fan blades, & caulking materials, emulsion explosives, golf, sealant, pipeline insulation materials, artificial marble, PVC foam, low density oil drilling, light cement, and other deep-sea buoy etc.

FROM:chnchemical

Hollow glass microspheres ( also known as glass bubbles ) are hollow glass spheres made of chemically stable Soda-lime-borosilicate glass with thin walls(wall thickness 1~3.5μm). We have several grades available with true density ranging from 0.20g/cc~0.60g/cc, Sinosteel hollow glass microspheres can be used as lightweight functional additives for Composites,Thermal insulation paints/coatings, Sealant/adhesives, Low density cementing slurries and many more applications with very competitive quality and price.

Sinosteel Maanshan New Material Technology Co., Ltd., a wholly owned subsidiary of Sinosteel Maanshan Institute of Mining Research Co. Ltd., is a comprehensive high-tech company that specializes in research&development 、production and sales of high-performance Hollow Glass Microspheres.

Established in 1963, Sinosteel Maanshan Institute of Mining Research Co., Ltd (Hereafter, The Institute) used to be a key scientific research institute under the former Ministry of Metallurgical Industry. The Institute has been authorized to grant master’s degree (first-level discipline) by the Academic Degree Committee of the State Council since early times. The Institute, now as a national innovation-oriented company and a key high-tech company under the National Torch Program, is attached to Sinosteel Group Corporation Limited. The Institute has undertaken and completed a number of major national science and technology projects successfully, and won more than 680 awards of scientific and technological achievements at national or provincial levels by far.

Glass bubble, made of Soda Lime Borosilicate Glass, are hollow spheres which grain size is 10-250microns, wall-thickness 1-2 microns, filled with inert air or gas.
glass bubble are produced at the high temperature of 700-800 degrees Celsius through complicated chemical and physical transformation. glass bubbles are white and the specific gravity of them is about 0.25-0.60g/cc.
Hollow glass microshpere have much merit, such as lightweight, great buoyancy, hard, rigid, waterproof, innoxious, insulative, low heat conductivity, higher mechanical strength and excellent chemical stability,etc. glass bubble surface was treated by the special way and the products are dispersed very easily in organic materials such as resin.

glass bubble are widely used in composite materials such as FRP, man made marble and man made agate. glass bubble can decrease the weight of the composite materials and the composite materials have excellent performance of sound insulation and heat preservation, and they can improve the mechanical performance of the composite materials such as strengthened rigidity, enhanced anti-impact property, excellent anti-breaking property and re-processing function.

Features of Lightweight Hollow Glass Microspheres for Paint Additives
– Light specific gravity and large volume
– High disperion and good fluidity
– Heat insulation, sound insulation
– Low rate of absorbing oil

Application of Lightweight Hollow Glass Microspheres for Paint Additives
PLASTICS: BMC, SMC, Injection Molding, Extruding, PVC flooring, Film, Nylon, High Density Polyethylene, Low Density Polyethylene, Polypropylene
CERAMICS: Refractory, Tile, Firebricks, Aluminum Cement, Insulating Materials, Coatings.
ROCK OIL: Oil well construction, Heat preservation of oil pies, Materials used again erosion
SPACE: Aerospace coatings, Aerospace composites
AUTOMOTIVE: Composites, Undercoating, Engine parts, Brake pads, Trim molding, Body fillers, Plastics, Sound proofing materials
CONSTRUCTION: Specialty cements, Mortars, Grouts, Stucco, Roofing materials, Acoustical panels.

FROM:chnchemical

Hollow Glass Microspheres H46

How do you make glass microspheres?
1. Glass powder method
The glass powder method uses pre-prepared glass powder containing gases such as SO3 to pass through the flame at the temperature of 1100-1500℃. At this time, SO3 and other gases dissolved in the glass powder overflow from the inside of the glass due to the decrease in solubility and the change in the atmosphere of the kiln. At the same time, the glass powder becomes spherical under high temperature due to the surface tension. The spillage gas is sealed in the spherical particles to form hollow glass beads.
2. Spray granulation method
Spray granulation method is made in advance with special auxiliary reagent (boric acid, urea, ammonium pentaborate) aqueous solution of sodium silicate, and then through the nozzle to the solution injection into the spray dryer, is expected to drop after drying to get a certain particle size of powder particles, the final will be powder particle heating foam-forming hollow glass beads.
3. The droplet method
The liquid drop method adopts the same raw materials as the spray granulation method. The raw materials are 500 copies of sodium silicate (M (SiO2): M (Na2O) =2), and the same amount of 10% ammonium perborate aqueous solution is added. After mixing evenly, the hollow glass beads are sprayed into the spray drying tower.
4. Dry gel method
The alkyl salt was added to dilute hydrochloric acid and decompose with water. After gelation, the gel was dried in two stages at 60℃ and 150℃ and then crushed by a ball mill. After grading, the dried gel powder was obtained, which was foamed in a vertical electric furnace at 1280℃ to prepare hollow glass microspheres.

Applications of Hollow Glass Sphere :
Hollow glass microspheres are widely used in glass fiber reinforced plastic products, composite foam plastic, artificial marble, compound wood, sound insulation heat preservation material, atomic ash, deep-sea buoyancy, bowling, low-density cement, sealing material, lightweight, resin handicraft, the mural wall hanging frame, wall plate sandwich layer structure of lightweight packaging materials, electronic industry, absorbing material, lightweight concrete, such as emulsion explosive.
Hollow glass microspheres also provide a conductive coating. Conductive coatings of optimized thickness provide spherical particles with excellent conductivity and shielding properties while maintaining the weight savings associated with hollow, low-density materials. These conductive microbubbles are suitable for military applications, biotechnology, medical devices, electronics and other special industries.
Hollow glass beads have obvious weight reduction and sound insulation and heat preservation effect so that the products have good cracking resistance and reprocessing performance, is widely used in engineering plastics, insulation materials, rubber, buoyancy material, FRP, artificial marble, man-made agate, generation of composite materials such as wood, and the oil industry, aerospace, communications, 5 g new high-speed trains, cars, ships, in areas such as thermal insulation coatings, adhesives, vigorously promote the development of science and technology.

FROM:TRUNNANO

Hollow glass microspheres, sometimes termed microballoons or glass bubbles, have diameters ranging from 10 to 300 micrometers. Hollow spheres are used as lightweight fillers in composite materials such as syntactic foam and lightweight concrete. The hollow glass bead is a kind of specially processed glass bead, which is mainly characterized by smaller density and poorer thermal conductivity than glass bead. It is a new kind of micron-grade light material developed in the 1950s and 1960s. Its main component is borosilicate, with a general particle size of 10~250μm and a wall thickness of 1~2μm. Hollow glass beads are characterized by high compressive strength, high melting point, high resistivity, small thermal conductivity and thermal shrinkage coefficient, etc., and they are known as the “space-age material” in the 21st century.
Hollow glass microspheres, also known as bubbles, microbubbles, or micro balloons, are usually formulated from borosilicate – sodium salt glass mixtures and offer the advantages of low density, high heat and chemical resistance. The walls of glass microspheres are rigid and are usually about 10% thick of the diameter of the spheres. At present, spherical particles have a wide range of densities, from as low as 0.06g/ C3 to as high as 0.80g/ C3, with particle sizes ranging from 5um to 180um. The compressive strength of the hollow sphere is determined by the wall thickness of the hollow sphere and, as expected, the greater the density of the sphere, the higher the compressive strength.The lightweight hollow glass sphere is chemically stable, non-flammable, non-porous, excellent water resistance.

Product Performance of Hollow Glass Sphere:
Hollow glass microspheres are micron-level hollow glass microspheres with a smooth surface. The main chemical component is borosilicate glass, and it is a hollow transparent sphere under the electron microscope. Hollow glass beads have low density, high strength, high temperature resistance, acid and alkali resistance, low thermal conductivity, electrical insulation and other properties. They have good fluidity and chemical stability, and they are multi-functional frontier new materials across fields.

FROM:TRUNNANO

hollow glass microspheres can be used in paints and coatings, sealants and adhesives, rubber, plastic, FRP, artificial stone, putty and other products as filler and weight-reducing agent. The glass bubbles can also be used to produce high-strength, low-density cement slurry and low-density drilling fluidity in oil and gas extraction industry. more and more industries are trying to test the hollow glass spheres as additives to improve the products’ properties.

1. 1. 1. a. lightweight cement, low-density oil well cementing slurry & low-density drilling fluids additive.
   1. 1. b. low-density FRP(fiberglass-reinforced plastic), SMC, BMC composites.
   1. 1. c. Nylon, PA, PA6, PA66 for reducing weight.
   1. 1. d. low-density adhesives & sealants.
   1. 1. e. heat insulation paints and coatings.
   1. 1. f.  Construction (reducing warpage/shrinkage).
   1. 1. g. Insulation and Buoyancy.
   1. 1. h. artificial marble.