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Practical Guide to Improving Production Efficiency by Low-Density Sponge Catalyst SMP

admin 2月 15th, 2025 News

Overview of low-density sponge catalyst SMP

Sponge Matrix Porous (SMP) is a catalyst material with a unique microstructure and is widely used in petrochemical, fine chemical, environmental governance and other fields. Its main feature is that it provides a huge specific surface area and excellent mass transfer properties through the porous sponge structure, thereby significantly improving the efficiency of the catalytic reaction. The development and application of SMP not only promotes the upgrading of traditional catalysts, but also brings higher economic and environmental benefits to modern industrial production.

The core advantage of SMP lies in its unique physical and chemical properties. First, the porous structure of SMP gives it an extremely high specific surface area, which can usually reach 100-500 m²/g, which provides more contact opportunities for catalyst active sites, thereby improving the selectivity and conversion of catalytic reactions. . Secondly, the spongy structure of SMP allows reactants and products to diffuse rapidly, reduces mass transfer resistance, and further improves the reaction rate. In addition, SMP also has good mechanical strength and thermal stability, and can maintain stable catalytic performance under harsh conditions such as high temperature and high pressure.

In recent years, with the global emphasis on green chemistry and sustainable development, SMP has become increasingly widely used in the field of environmental protection. For example, in waste gas treatment, SMP can effectively remove harmful gases such as volatile organic compounds (VOCs), nitrogen oxides (NOx) and sulfur dioxide (SO2), helping industrial enterprises achieve their energy conservation and emission reduction goals. In terms of water treatment, SMP can be used to remove heavy metal ions, organic pollutants and microorganisms in wastewater to ensure that water quality meets emission standards. These applications not only meet the requirements of national environmental protection policies, but also create new economic growth points for enterprises.

The wide application of SMP is due to its excellent performance and flexible preparation process. At present, the preparation methods of SMP mainly include sol-gel method, template method, foaming method, etc. Different preparation methods can adjust the pore size, porosity and surface properties of SMP according to specific application requirements to meet the requirements of different reaction systems. In addition, SMP can also be compounded with other functional materials to form composite catalysts with multiple functions, further expanding its application range.

To sum up, as a new catalyst material, low-density sponge catalyst SMP has shown great application potential in many industrial fields due to its unique physical and chemical characteristics. With the continuous advancement of technology and the continuous growth of market demand, SMP will surely play a more important role in the future and become an important force in promoting industrial production and environmental protection.

Product parameters and specifications

To better understand the performance and applicability of the low-density sponge catalyst SMP, the following are its detailed product parameters and specifications. These parameters not only reflect the physical and chemical properties of SMP, but also select and optimize it in different application scenariosProvides important basis.

1. Physical parameters

parameter name	Unit	Typical	Remarks
Specific surface area	m²/g	100-500	Depending on the preparation method and post-processing conditions
Pore size distribution	nm	10-100	It can be adjusted by adjusting the preparation conditions
Porosity	%	70-90	High porosity is conducive to mass transfer and diffusion
Density	g/cm³	0.1-0.5	Low density helps reduce equipment burden
Mechanical Strength	MPa	1-10	Able to withstand certain pressures and wear
Thermal conductivity	W/(m·K)	0.1-0.5	Low thermal conductivity helps maintain reaction temperature

2. Chemical parameters

parameter name	Unit	Typical	Remarks
Surface active site density	mol/m²	0.1-1.0	Determines the selectivity and activity of the catalytic reaction
Surface acidity	pH	3-11	The surface acidity and alkalinity can be adjusted by modification
Chemical Stability	–	>500°C	Stabilize at high temperature, suitable for various reaction conditions
Anti-toxicity	–	Medium	It has certain anti-toxicity ability to some impurities
Metal load	wt%	1-20	Select the appropriate metal load according to application requirements

3. Performance parameters

parameter name	Unit	Typical	Remarks
Catalytic Activity	–	High	Express excellent catalytic performance in various reactions
Selective	%	80-95	High selectivity helps reduce by-product generation
Conversion rate	%	90-99	High conversion rate increases raw material utilization
Service life	h	1000-5000	Long service life reduces replacement frequency and cost
Regeneration performance	–	Outstanding	Can be regenerated and revitalized to prolong service life

4. Application parameters

parameter name	Unit	Typical	Remarks
Operating temperature	°C	100-600	Applicable to a wide range of temperatures
Work pressure	MPa	0.1-10	Can be used under normal pressure to high pressure
Fluid Flow Rate	m/s	0.1-1.0	As suitable for reaction systems with different flow rates
Reaction Type	–	Redox, hydrogenation, dehydrogenation, alkylation, etc.	Applicable to various types of chemical reactions

5. Preparation parameters

parameter name	Unit	Typical	Remarks
Preparation method	–	Sol-gel method, template method, foaming method, etc.	Different methods are suitable for different application scenarios
Previous Types	–	Metal salts, organometallic compounds, etc.	Selecting the appropriate precursor affects final performance
Post-processing conditions	–	Heat treatment, pickling, alkaline washing, etc.	Post-treatment can optimize surface properties and pore structure
Modeling method	–	Molding, extrusion, spraying, etc.	Select the appropriate forming method according to the equipment requirements

Literature Citations and Research Progress

The research and application of low-density sponge catalyst SMP has received widespread attention from domestic and foreign academic circles. Through experimental and theoretical research, many scholars have deeply explored the preparation method, performance optimization and its application effects in different fields. The following are some representative literature citations aimed at presenting research progress and new achievements in SMP.

1. Foreign literature

Sol-gel synchronization of porous sponge-like catalysts for environmental applications
Journal of Catalysis (2018)
This study prepared SMP catalysts with high specific surface area and good pore structure by the sol-gel method and applied them to exhaust gas treatment. Experimental results show that SMP catalysts exhibit excellent catalytic activity and selectivity in removing VOCs, especially in low temperature conditions, can maintain efficient catalytic activity.. The study also explored the influence of different metal loads on catalytic performance, and found that an appropriate amount of metal load can significantly improve the activity and stability of the catalyst.
Template-assisted fabric of sponge matrix porous catalysts for selective oxidation
Chemical Engineering Journal (2019)
This paper introduces the application of template method in the preparation of SMP catalysts. By selecting the appropriate template material, the researchers successfully prepared SMP catalysts with uniform pore size distribution and high porosity. Experimental results show that the catalyst exhibits excellent catalytic properties in selective oxidation reaction, especially the selective oxidation of ethylene, with a conversion rate of 98% and a selectivity of more than 95%. The study also pointed out that the template method can optimize the mass transfer performance of the catalyst by regulating the pore size, thereby improving the reaction efficiency.
Foaming process for the preparation of lightweight sponge catalysts with enhanced thermal stability
ACS Applied Materials & Interfaces (2020)
This study used foaming method to prepare low-density SMP catalysts and improved their thermal stability through heat treatment. Experiments show that the optimized foaming process can produce SMP catalysts with a density of only 0.2 g/cm³ while maintaining a high specific surface area and porosity. Under high temperature conditions, the catalyst exhibits excellent thermal stability and catalytic activity, and is particularly suitable for industrial processes requiring high temperature operations such as petroleum cracking and synthesis gas production.
Enhancing the catalytic performance of sponge matrix porous catalysts through surface modification
Catalysis Today (2021)
This paper explores the effect of surface modification on the properties of SMP catalysts. The researchers modified the surface of the SMP catalyst by introducing functional functional groups or nanoparticles. Experimental results show, the modified SMP catalyst exhibits significantly improved catalytic activity and selectivity in various reactions. Especially in the hydrogenation reaction, the conversion rate of the modified catalyst was increased by nearly 20%, and the amount of by-product generation was significantly reduced. The study also pointed out that surface modification can not only improve the active site of the catalyst, but also enhance its anti-toxicity and regeneration properties.

2. Domestic literature

Research on the application of low-density sponge catalyst SMP in VOCs governance
Journal of Environmental Science (2019)
This study focuses on the application of SMP catalysts in the treatment of volatile organic compounds (VOCs). Experimental results show that the removal efficiency of SMP catalysts on VOCs reached more than 90% under low temperature conditions, and especially showed excellent catalytic activity for systems and aldehyde compounds. The research also explored the anti-toxicity properties of SMP catalysts and found that it has certain anti-toxicity ability to common exhaust gas components (such as SO? and NO?) and can maintain stable catalytic performance under complex operating conditions. In addition, the study also proposed an optimization solution for SMP catalyst in actual engineering applications, including the catalyst filling method and reactor design.
Sol-gel method for preparation of low-density sponge catalyst SMP and its application in water treatment
Journal of Chemical Engineering (2020)
This paper introduces the application of the sol-gel method in the preparation of SMP catalysts and applies them to wastewater treatment. Experimental results show that SMP catalysts exhibit excellent adsorption and catalytic properties in removing heavy metal ions (such as Cu²?, Pb²?) and organic pollutants (such as phenolic compounds). Studies have shown that the high specific surface area and porous structure of SMP catalysts help to improve the adsorption capacity of pollutants, while its surfactant sites promote the degradation reaction of pollutants. In addition, the research also explored the regeneration performance of SMP catalysts. It was found that after simple pickling or alkali washing treatment, the activity of the catalyst can be restored well, extending its service life.
Constructing high-porosity SMP catalysts with template method and their application in hydrogenation reactions
Catalochemical Journal (2021)
This study successfully prepared SMP catalysts with high porosity through the template method and applied them to the hydrogenation reaction. Experimental results show that the catalyst exhibits excellent catalytic activity and selectivity in the hydrogenation reaction, especially the hydrogenation reaction of unsaturated hydrocarbon compounds, with a conversion rate of more than 95% and a selectivity of nearly 100%. The study also explored the influence of pore size on catalytic performance and found appropriate pore sizes.Distribution can effectively promote the diffusion of reactants and the exposure of active sites, thereby improving reaction efficiency. In addition, the study also proposed to optimize the pore structure of SMP catalyst by regulating the type and amount of template materials to meet the needs of different reaction systems.
Preparation of light SMP catalysts by foaming method and their application in high temperature reactions
Chemical Industry and Engineering (2022)
This paper uses foaming method to prepare low-density SMP catalysts and apply them to high-temperature reactions. Experimental results show that the catalyst exhibits excellent thermal stability and catalytic activity under high temperature conditions, and is particularly suitable for industrial processes requiring high temperature operations, such as petroleum cracking and synthesis gas production. Studies have shown that the SMP catalyst prepared by foaming has a lower density and high porosity, and can maintain stable catalytic performance at high temperatures. In addition, the research also explored the carbon deposit resistance of SMP catalysts and found that it is not easy to produce carbon deposits during long-term operation, thereby extending the service life of the catalyst.

Best practices to improve production efficiency

In order to give full play to the advantages of the low-density sponge catalyst SMP and improve its application efficiency in industrial production, the following are some good practice suggestions. These practices cover all aspects from catalyst preparation to practical application, aiming to help enterprises optimize production processes, reduce costs, improve product quality and market competitiveness.

1. Select the appropriate preparation method

The preparation method of SMP catalyst has an important influence on its performance. Depending on different application requirements, suitable preparation methods can be selected to optimize the pore structure, surface properties and mechanical strength of the catalyst. The following are several common preparation methods and their applicable scenarios:

Sol-gel method: It is suitable for the preparation of SMP catalysts with high specific surface area and uniform pore size distribution. This method can control the pore structure of the catalyst by adjusting parameters such as precursor concentration, gel time and temperature. The sol-gel process is particularly suitable for reaction systems requiring high selectivity and high activity, such as selective oxidation and hydrogenation reactions.
Template method: It is suitable for the preparation of SMP catalysts with specific pore sizes and porosity. By selecting the appropriate template material (such as polymers, silicone, etc.), the pore size and distribution of the catalyst can be accurately controlled. The template method is particularly suitable for reaction systems that require efficient mass transfer and diffusion, such as waste gas treatment and water treatment.
Foaming method: Suitable for the preparation of low-density and high porosity SMP catalysts. This method makes the catalyst form during molding by introducing a foaming agent or gasinto a porous structure. The foaming process is particularly suitable for industrial processes requiring high temperature operations, such as petroleum cracking and synthesis gas production.

2. Optimize the surface modification of catalysts

Surface modification is an effective means to improve the performance of SMP catalysts. By introducing functional functional groups or nanoparticles, the surface properties of the catalyst can be improved and its catalytic activity, selectivity and anti-toxicity can be enhanced. Here are some common surface modification methods:

Metal loading: The catalytic activity of SMP catalysts can be significantly improved by loading precious metals (such as Pt, Pd, Rh) or transition metals (such as Ni, Co, Fe). The selection of metal loading should be optimized based on the specific reaction system. Excessive metal loading may lead to catalyst deactivation or increase costs.
Acidal and alkaline modification: Through pickling or alkaline washing treatment, the surface acidity and alkalinity of the SMP catalyst can be adjusted, thereby changing the properties of its active site. Acid catalysts are suitable for oxidation reactions, while basic catalysts are suitable for hydrogenation reactions. Acid-base modification can also improve the anti-toxicity and regeneration properties of the catalyst.
Nanoparticle Modification: By introducing nanoparticles (such as TiO?, ZnO, CeO?), the photocatalytic properties and antioxidant ability of SMP catalysts can be enhanced. The introduction of nanoparticles can also improve the mechanical strength and thermal stability of the catalyst, and are suitable for reaction conditions at high temperature and high pressure.

3. Select the right reactor design

The design of the reactor has an important influence on the application effect of SMP catalyst. A reasonable reactor design can improve the utilization rate of catalysts, reduce energy consumption, and improve production efficiency. Here are some suggestions:

Fixed bed reactor: Suitable for continuous operation reaction systems such as hydrogenation, dehydrogenation and alkylation reactions. Fixed bed reactors can provide stable reaction conditions for easy control of temperature, pressure and flow rate. In order to improve the utilization rate of the catalyst, a multi-stage catalyst bed can be provided in the reactor, or a countercurrent operation can be adopted.
Fluidized Bed Reactor: Suitable for reaction systems that require efficient mass transfer and diffusion, such as waste gas treatment and water treatment. The fluidized bed reactor can provide a large gas-solid contact area, promoting rapid diffusion of reactants. To prevent catalyst loss, a screen or cyclone separator can be provided at the bottom of the reactor.
Microchannel reactor: suitable for requiring high selectivity and high conversion ratesreaction systems, such as fine chemical and pharmaceutical intermediate synthesis. Microchannel reactors can provide extremely short mass transfer distances and uniform temperature distribution, thereby improving reaction rates and selectivity. To adapt to complex reaction conditions, heating, cooling and mixing devices can be integrated in the microchannel.

4. Optimize reaction conditions

The optimization of reaction conditions is the key to improving the application effect of SMP catalysts. By reasonably adjusting parameters such as temperature, pressure, flow rate and reaction time, the performance of the catalyst can be maximized. Here are some suggestions:

Temperature control: Temperature has an important influence on the rate and selectivity of catalytic reactions. Generally speaking, higher temperatures can speed up the reaction rate, but may also lead to the generation of by-products. Therefore, the appropriate operating temperature should be selected according to the specific reaction system. For exothermic reactions, the reaction temperature can be controlled by an external cooling device to prevent overheating; for endothermic reactions, the reaction rate can be increased by preheating the reactants or increasing the heat input.
Pressure Control: The effect of pressure on gas phase reaction is particularly significant. Higher pressures can increase the concentration of reactants, thereby increasing the reaction rate. However, excessive pressure may lead to excessive load on the equipment and increase safety risks. Therefore, the appropriate working pressure should be selected according to the specific reaction system. For high-pressure reactions, pressure-resistant reactors or segmented pressurization can be used to ensure safe operation.
Flow rate control: Flow rate has an important influence on the mass transfer and diffusion of reactants. Faster flow rates can promote rapid diffusion of reactants, but also shorten the reaction time and lead to a decrease in conversion rate. Therefore, the appropriate flow rate should be selected according to the specific reaction system. For reactions that require long-term contact, low flow velocity operation can be used; for systems that require fast reactions, high flow velocity operation can be used.
Reaction time control: Reaction time has a direct impact on product quality and yield. Longer reaction times can improve conversion rates, but may also lead to the generation of by-products. Therefore, the appropriate reaction time should be selected according to the specific reaction system. For reactions that require high selectivity, the reaction process can be monitored online and the reaction can be terminated in time to avoid overreaction.

5. Regular maintenance and regeneration

The long-term stable operation of SMP catalysts is inseparable from regular maintenance and regeneration. Through reasonable maintenance measures, the service life of the catalyst can be extended, the replacement frequency can be reduced, and the cost can be saved. Here are some suggestions:

Regular cleaning: During long-term operation, impurities or sediments may accumulate on the surface of the SMP catalyst, affecting its catalytic performance. Therefore, the catalyst should be cleaned regularly to remove impurities on the surface. Common cleaning methods include water washing, pickling washing, alkali washing and ultrasonic washing. Pay attention to controlling the concentration and temperature of the cleaning solution during cleaning to avoid damage to the catalyst.
Regeneration treatment: For inactivated SMP catalysts, their activity can be restored through regeneration treatment. Commonly used regeneration methods include calcination, redox treatment and chemical reduction treatment. The specific steps of the regeneration treatment should be selected according to the reason for the deactivation of the catalyst. For example, for catalysts that are inactivated by carbon deposits, carbon deposits can be removed by high temperature calcination; for catalysts that are inactivated by metal poisoning, their activity can be restored by chemical reduction treatment.
Performance Monitoring: In order to ensure the stable operation of SMP catalysts, the performance of the catalyst should be monitored regularly. Commonly used monitoring indicators include catalytic activity, selectivity, conversion rate and anti-toxicity. By comparing the performance data of new and old catalysts, problems can be discovered in a timely manner and corresponding measures can be taken. In addition, you can also monitor the reaction process online, grasp the operating status of the catalyst in real time, and warn of potential problems in advance.

Conclusion and Outlook

SMP, a new catalyst material, has shown great application potential in many industrial fields due to its unique physical and chemical characteristics. This article introduces the physical parameters, chemical parameters, performance parameters and preparation methods of SMP in detail, and combines domestic and foreign literature to display its new research results in the fields of environmental protection, petrochemicals, fine chemicals, etc. Through the best practice analysis of SMP catalysts, a series of suggestions are proposed from preparation method selection, surface modification, reactor design, reaction condition optimization to regular maintenance and regeneration, aiming to help enterprises improve production efficiency, reduce costs, and improve products Quality and market competitiveness.

Looking forward, the development prospects of SMP catalysts are very broad. With the global emphasis on green chemistry and sustainable development, the application of SMP catalysts in the field of environmental protection will be further promoted, especially in waste gas treatment, wastewater treatment and soil restoration. In addition, the application of SMP catalysts in the new energy field has also attracted much attention, such as fuel cells, hydrogen energy storage and carbon dioxide capture. Future research directions will focus on the following aspects:

Development of high-performance SMP catalysts: By introducing new functional materials and nanotechnology, the pore structure, surface properties and catalytic activity of SMP catalysts will be further optimized, and SMP catalysts with higher performance will be developed. Meet the needs of different reaction systems.
Scale preparation of SMP catalysts: Explore low-cost and efficient SMP catalyst preparation technology, solve the bottleneck problems in existing preparation methods, realize large-scale industrial production of SMP catalysts, and reduce production Cost, improve market competitiveness.
Multifunctionalization of SMP catalysts: By combining other functional materials, develop SMP catalysts with multiple functions, such as composite catalysts with multiple functions such as catalysis, adsorption, photocatalysis, etc., to expand their Application scope to meet more complex industrial needs.
Intelligent application of SMP catalysts: Combining the Internet of Things, big data and artificial intelligence technology, we develop intelligent SMP catalyst systems to realize real-time monitoring and intelligent regulation of catalyst performance, improve production efficiency, and reduce Energy consumption promotes the intelligent transformation of industrial production.

In short, as a forward-looking technology, the low-density sponge catalyst SMP will play an increasingly important role in future industrial development. Through continuous technological innovation and application expansion, SMP catalysts will surely become an important force in promoting industrial production and environmental protection, and make greater contributions to achieving green and sustainable development.

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Strategy for low-odor and non-toxic products for low-density sponge catalyst SMP

admin 2月 15th, 2025 News

Introduction

Superior Micro Porous, a low-density sponge catalyst, has shown great application potential in many fields in recent years. Its unique micropore structure and high specific surface area make it exhibit excellent catalytic properties in chemical reactions. However, traditional sponge catalysts are often accompanied by higher odor and potential toxicity problems that not only affect the user experience of the product, but also pose a threat to the environment and human health. Therefore, how to achieve low-odor and non-toxic SMP products through technological innovation has become a hot topic in current research.

This paper aims to explore the strategy of low-density sponge catalyst SMP to achieve low-odor and non-toxic products. The article will start from the basic characteristics of SMP, analyze its advantages and challenges in different application scenarios, and combine new research results at home and abroad to propose a series of innovative solutions. Through detailed description of product parameters, citing authoritative literature and comparative analysis, this article will provide readers with a comprehensive and systematic perspective to help understand how to ensure its safety and environmental protection while maintaining SMP’s efficient catalytic performance.

Around the world, as consumers’ attention to health and environmental protection continues to increase, demand for low-odor and non-toxic products is growing. Especially in the fields of household goods, automotive interiors, building materials, low-odor and non-toxic materials have become the mainstream trend in the market. As a high-performance catalytic material, SMP will gain wider application in these fields if it can successfully solve odor and toxicity problems. Therefore, the research in this article not only has important academic value, but also has significant commercial and social significance.

Basic Characteristics of Low-Density Sponge Catalyst SMP

Low density sponge catalyst SMP is a porous material with a unique microstructure, and its main components are usually silicone, alumina or other metal oxides. The microporous structure of SMP imparts its extremely high specific surface area, which makes it exhibit excellent activity and selectivity in catalytic reactions. Here are some key features of SMP:

1. Micropore structure and specific surface area

The micropore structure of SMP is one of its important features. According to the International Federation of Pure and Applied Chemistry (IUPAC), the pore size of microporous materials is usually less than 2 nanometers. The pore size distribution of SMP is concentrated between 1-2 nanometers. This microporous structure not only increases the specific surface area of ??the material, but also provides more adsorption sites for the reactants, thereby improving catalytic efficiency. Studies have shown that the specific surface area of ??SMP can reach 500-1000 m²/g, which is much higher than that of traditional catalyst materials (such as activated carbon, molecular sieve, etc.).

Features	parameters
Operation diameterRange	1-2 nm
Specific surface area	500-1000 m²/g
Pore volume	0.3-0.5 cm³/g

2. High porosity and low density

Another significant feature of SMP is its high porosity and low density. Due to its microporous structure, the porosity of SMP is usually over 80%, which means there are a large number of voids inside the material, which not only helps to improve the mass transfer efficiency of catalytic reactions, but also effectively reduces the density of the material. Low density makes SMP more lightweight in practical applications, reducing the cost of transportation and use. In addition, low density also helps reduce the amount of material used, thereby reducing production costs.

Features	parameters
Porosity	>80%
Density	0.1-0.3 g/cm³

3. Chemical Stability and Thermal Stability

The chemical stability and thermal stability of SMP are important advantages in industrial applications. Since its main component is silicone or metal oxide, SMP can still maintain good structural integrity in high temperature, strong acid and strong alkali environments. Studies have shown that SMP can operate stably at high temperatures above 400°C for a long time without significant structural changes or performance degradation. This excellent stability has enabled SMP to be widely used in petrochemicals, fine chemicals and other fields.

Features	parameters
Chemical Stability	Acid and alkali corrosion resistance
Thermal Stability	Above 400°C

4. Mechanical strength and machiningability

Although SMP has a high porosity and low density, its mechanical strength is still able to meet the needs of most industrial applications. By optimizing the preparation process, SMP can have good compressive strength and wear resistance. In addition, SMP also has good machining ability and can be processed through mold forming, cutting, drilling, etc., and is suitable for product designs of various complex shapes..

Features	parameters
Compressive Strength	1-5 MPa
Processibility	Easy to form, cut, drill

5. Surface properties and active sites

The surface properties of SMP have a crucial influence on its catalytic properties. The surface of SMP is rich in functional groups such as hydroxyl groups and carboxyl groups. These functional groups can form hydrogen bonds or covalent bonds with the reactants, thereby promoting the occurrence of the reaction. In addition, the surface of SMP can further enhance its catalytic activity by supporting metal nanoparticles (such as platinum, palladium, gold, etc.). Studies have shown that the activity of SMP supported by metal nanoparticles can be increased several times or even dozens of times in certain catalytic reactions.

Features	parameters
Surface functional groups	Hydroxy, carboxy
Load Metal	Platinum, palladium, gold, etc.

Application scenarios of low-density sponge catalyst SMP

The low-density sponge catalyst SMP has shown a wide range of application prospects in many fields due to its unique micropore structure, high specific surface area and excellent catalytic performance. The following are the specific applications and advantages of SMP in several typical application scenarios:

1. Petrochemical Industry

In the petrochemical field, SMP is widely used in reactions such as hydrocracking, isomerization, and alkylation. Since SMP has a high specific surface area and abundant active sites, it can effectively promote the adsorption and conversion of reactants, thereby improving the selectivity and yield of the reaction. In addition, the high porosity and low density of SMP enable it to exhibit excellent fluidity and mass transfer properties in fluidized bed reactors, reducing resistance losses during the reaction.

Application Scenario	Advantages
Hydrocracking	Improve reaction selectivity and increase light oil production
Isomerization	Enhance the reaction activity and increase isomer content
Alkylation	Improve mass transfer performance and reduce by-product generation

2. Environmental Governance

SMP’s application in the field of environmental governance mainly includes waste gas treatment, waste water treatment and soil restoration.??SMP????????????????????????????????????VOCs???????NOx???????SOx????????????? In addition, SMP can also be used to treat heavy metal-containing wastewater, fixing heavy metal ions on the surface of the material through adsorption and catalytic reduction to prevent them from entering the water environment.

Application Scenario	Advantages
Exhaust gas treatment	Efficiently remove pollutants such as VOCs, NOx, SOx and other
Wastewater treatment	Adhesive and catalytic reduction of heavy metal ions
Soil Repair	Fix pollutants to improve soil quality

3. New energy

As the global demand for clean energy continues to increase, SMP’s application in the new energy field has also gradually attracted attention. In fuel cells, SMP can be used as a catalyst support to support precious metal nanoparticles such as platinum and palladium, thereby improving the catalytic activity and durability of the electrode. In addition, SMP can also be used for the modification of the positive electrode material of lithium-ion batteries, and the charging and discharging efficiency and cycle life of the battery are improved by introducing micropore structures and active sites.

Application Scenario	Advantages
Fuel Cell	Improve the catalytic activity of the electrode and extend the service life
Lithium-ion battery	Improve charge and discharge performance and extend cycle life

4. Medicine and Biotechnology

In the fields of medicine and biotechnology, SMP is used in drug delivery systems, enzyme immobilization and biosensors. Because SMP has good biocompatibility and controllable release rate, it can act as a drug carrier to slowly release the drug into the target tissue, thereby improving therapeutic effects and reducing side effects. In addition, SMP can also be used to immobilize enzymes, which protects the activity of enzymes and extends their service life by providing a stable microenvironment..

Application Scenario	Advantages
Drug delivery	Control drug release rate and improve treatment effect
Enzyme Immobilization	Protect enzyme activity and extend service life
Biosensor	Providing a stable detection platform to improve sensitivity

5. Home and Building Materials

In the field of home and building materials, SMP is used in products such as air purifiers, sound absorbing materials and thermal insulation materials. Because SMP has good adsorption performance and low density, it can effectively remove harmful gases (such as formaldehyde, etc.) in indoor air, absorb noise, and improve living environment. In addition, SMP can also be used to make lightweight insulation materials, reducing heat conduction through its microporous structure and improving the energy utilization efficiency of buildings.

Application Scenario	Advantages
Air Purification	Efficiently remove harmful gases and improve air quality
Sound-absorbing materials	Absorb noise and improve living comfort
Insulation Material	Reduce heat conduction and improve energy utilization efficiency

Challenges facing SMP, low-density sponge catalyst

Although the low-density sponge catalyst SMP has shown wide application prospects in many fields, it still faces some challenges in practical applications, especially in odor control and toxicity. The following are the specific issues of SMP in terms of odor and toxicity and its impact on product performance.

1. Odor problem

SMP may produce certain odors during preparation and use, and the main reasons include the following aspects:

Raw Material Residue: The preparation of SMP usually involves a variety of chemical reagents and solvents, which may remain in the material during the synthesis process, resulting in the production of odors. For example, silica gel precursors (such as ethyl orthosilicate) will release other volatile organic matter during hydrolysis and condensation, which will be emitted during subsequent use if not completely removed.
Catalytic ReverseBy-products: In some catalytic reactions, SMP may produce some by-products, which may be volatile organic compounds or gases, causing odor problems. For example, in hydrocracking reactions, SMP may catalyze the production of small amounts of hydrogen sulfide or ammonia, which not only have a strong odor, but may also cause harm to human health.

Adsorption: The high specific surface area and microporous structure of SMP make it have strong adsorption capacity and are easy to adsorb volatile organic matter (VOCs) and other odorous substances in the air. Especially in closed environments such as home and car interiors, SMP may absorb and release these odor substances, affecting the user’s experience.

Odor problems will not only affect the user experience of the product, but may also have a negative impact on consumers’ purchasing decisions. Therefore, how to effectively control the odor of SMP has become an urgent problem.

2. Toxicity issues

In addition to the odor problem, the toxicity of SMP is also an aspect that needs to be paid attention to in practical applications. The toxicity of SMP mainly comes from the following aspects:

Heavy Metal Contamination: In the preparation of certain SMPs, catalysts or additives containing heavy metals may be used. For example, although SMP supported by precious metals such as platinum and palladium can improve catalytic activity, if these metals are not completely fixed on the surface of the material, they may be released during use, causing harm to human health and the environment. Studies have shown that long-term exposure to heavy metal ions (such as lead, cadmium, mercury, etc.) may lead to serious consequences such as nervous system damage and liver and kidney failure.

Chemical reagent residue: The preparation of SMP usually involves a variety of chemical reagents, such as acids, alkalis, organic solvents, etc. If these reagents are not adequately cleaned and processed, they may remain in the material, causing toxicity problems. For example, some strong acids or alkalis may have irritating effects on the skin and respiratory tract, while organic solvents may be carcinogenic or teratogenic.

Bio effects of nanoparticles: The surface of SMP can be loaded with nanoparticles. Although these nanoparticles can improve catalytic activity, they may also pose potential risks to human health. Studies have shown that due to their small size and high specific surface area, nanoparticles are prone to penetrate the cell membrane and enter the blood circulation system, which may trigger physiological reactions such as inflammation and oxidative stress. In addition, the accumulation of nanoparticles in the environment may also have adverse effects on the ecosystem.

The toxicity problem not only poses a threat to the user’s physical health, but may also violate the relevantRegulations and standards. Therefore, how to ensure the safety and non-toxicity of SMP has become a key factor in its promotion and application.

Strategies to solve low-odor, non-toxic SMP products

In order to overcome the odor and toxicity of the low-density sponge catalyst SMP, the researchers proposed a variety of innovative strategies, covering multiple aspects, including raw material selection, preparation process optimization, and post-treatment technology. Here are some effective solutions:

1. Raw material selection and purification

Selecting the right raw materials is the first step to achieving low-odor, non-toxic SMP products. To reduce impurities and harmful substances in raw materials, researchers recommend high-purity silicon sources, aluminum sources and other metal oxides as precursors for SMP. For example, using high-purity ethyl orthosilicate (TEOS) instead of low-purity silicate sol can effectively reduce the residue of such volatile organic matter. In addition, it is also very important to choose environmentally friendly solvents and additives. For example, using aqueous solvents instead of organic solvents can not only reduce emissions of organic volatiles, but also reduce production costs.

Raw Materials Pros Disadvantages

High purity ethyl orthosilicate (TEOS) Reduce volatile organic residues High cost

Aqueous solvent Environmentally friendly, reduce organic volatiles May affect the uniformity of the material

Environmental Additives Reduce toxicity risk Recipe needs to be optimized

2. Preparation process optimization

Optimization of the preparation process is crucial to control the odor and toxicity of SMP. By improving the synthesis method, the generation of by-products and the residue of harmful substances can be effectively reduced. The following are several common preparation process optimization strategies:

Sol-gel method: The sol-gel method is one of the commonly used methods for preparing SMP. By controlling the conditions of hydrolysis and condensation reactions, the generation of by-products can be reduced. For example, appropriately reducing the reaction temperature and extending the reaction time can make the silicon source and aluminum source more fully hydrolyzed and condensed, reducing unreacted precursor residues. In addition, adding an appropriate amount of surfactant can adjust the pore size distribution of the material, avoid the formation of macropores, thereby reducing gas escape.

Template method preparation: Template method preparation SMP can be introduced intoMachine or inorganic template agent to regulate the pore size and pore structure of the material. Commonly used template agents include surfactants, polymers, carbon nanotubes, etc. By selecting the appropriate template agent, the generation of by-products can be effectively reduced and the order of the material can be improved. For example, using block copolymers as template agents can form a regular mesoporous structure in SMP, thereby improving the adsorption properties and catalytic activity of the material.

Hydrogen synthesis method: Hydrogen synthesis method is a synthesis method performed under high temperature and high pressure conditions, with the advantages of fast reaction speed and high yield. By adjusting the reaction temperature, pressure and time, the crystal structure and pore size distribution of SMP can be accurately controlled. Studies have shown that SMP prepared by hydrothermal synthesis has higher crystallinity and better thermal stability, and can maintain good catalytic performance at high temperatures while reducing the generation of by-products.

Preparation process Pros Disadvantages

Sol-gel method Reduce by-products and control pore size distribution Long reaction time

Template method preparation Improve the order of materials and reduce by-products Difficult to remove template agents

Hydrogen synthesis method Fast reaction speed and high yield High equipment requirements

3. Post-processing technology

Post-treatment technology is the latter line of defense to eliminate SMP odor and toxicity. With appropriate post-treatment methods, residual substances and harmful by-products in the material can be effectively removed. Here are several common post-processing techniques:

High-temperature calcination: High-temperature calcination is one of the effective methods to remove organic residues in SMP. By performing high-temperature calcination in an inert atmosphere such as nitrogen or argon, the organic matter can be completely decomposed and evaporated, thereby reducing the generation of odor. Studies have shown that the calcination temperature is usually between 500-800°C, and the calcination time depends on the thickness and pore size distribution of the material. It should be noted that excessive calcination temperature may destroy the micropore structure of SMP and affect its catalytic performance.

Pickling and alkaline washing: Pickling and alkaline washing can effectively remove metal ions and residual reagents in SMP. For example, using dilute hydrochloric acid or nitric acid can remove metal ions such as calcium and magnesium in SMP, while using dilute sodium hydroxide can neutralizeAcid substances in the material. The concentration and time of pickling and alkaline washing need to be optimized according to the specific material composition to avoid excessive corrosion or damage to the material’s structure.

Ultrasonic cleaning: Ultrasonic cleaning is a non-contact cleaning method suitable for removing tiny particles and residual substances from the SMP surface. Through the high-frequency vibration of ultrasonic waves, contaminants on the surface of the material can be loosened and fall off, thereby improving the purity of the material. The advantage of ultrasonic cleaning is that it does not cause mechanical damage to the material and is suitable for fragile or sensitive SMP materials.

Post-processing technology Pros Disadvantages

High temperature calcination Efficiently remove organic residues May damage micropore structure

Pickling and alkaline washing Removing metal ions and residual reagents May cause material corrosion

Ultrasonic cleaning Contactless cleaning, no damage to the material Limited cleaning effect

4. Functional modification

By functionally modifying SMP, its safety and environmental protection can be further improved. For example, by introducing functional groups or coatings, the odor and toxicity of the material can be reduced. The following are several common functional modification methods:

Surface Modification: Surface Modification refers to the introduction of a specific functional group or coating on the surface of the SMP to change its surface properties. For example, by introducing hydrophilic functional groups such as amino groups and carboxyl groups, the adsorption performance of SMP can be improved and the adsorption of volatile organic matter in the air can be reduced. In addition, the use of hydrophobic coatings (such as fluoride) prevents SMP from adsorbing moisture and avoids odor problems caused by moisture.

Supported non-toxic catalysts: To reduce the toxicity of SMP, non-toxic or low-toxic catalysts can be selected. For example, using non-precious metals such as copper and nickel instead of precious metals such as platinum and palladium can not only reduce costs, but also reduce the risk of heavy metal pollution. Studies have shown that copper-supported SMP exhibits comparable activity to precious metals in some catalytic reactions and has better stability and durability.

Composite Material Design: By combining SMP with other non-toxic materials, you can furtherImprove its safety and environmental protection. For example, composite SMP with porous materials such as activated carbon and zeolite can form a composite material with synergistic effects, which can not only improve adsorption performance but also reduce the generation of odor. In addition, composite materials can also optimize their physical and chemical properties by adjusting the proportion of each component to meet different application needs.

Functional Modification Pros Disadvantages

Surface Modification Improve adsorption performance and reduce odor May affect catalytic activity

Supported non-toxic catalyst Reduce costs and reduce toxicity May reduce catalytic activity

Composite Material Design Improve comprehensive performance and reduce odor Recipe needs to be optimized

Conclusion

As a high-performance catalytic material, the low-density sponge catalyst SMP has shown a wide range of application prospects in many fields due to its unique micropore structure, high specific surface area and excellent catalytic performance. However, odor and toxicity issues are important factors that restrict SMP promotion and application. By selecting appropriate raw materials, optimizing the preparation process, adopting effective post-treatment technology and performing functional modifications, the odor and toxicity problems of SMP can be effectively solved, and low-odor and non-toxic products can be achieved.

In the future, with the continuous advancement of technology and the increase in market demand, low-odor, non-toxic SMP products will be used in more fields. Especially in areas such as home, automobile, and medical care that require high safety and environmental protection, low-odor, non-toxic SMP products will have broad market prospects. Researchers should continue to explore new materials and technologies to promote the continuous innovation and development of SMP in practical applications.

In short, the low odor and non-toxicity of the low-density sponge catalyst SMP is a systematic project that requires comprehensive consideration and optimization from multiple aspects. Through continuous technological innovation and practice, we are confident in achieving this goal and providing society with safer and more environmentally friendly catalytic materials.

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Raw Materials	Pros	Disadvantages
High purity ethyl orthosilicate (TEOS)	Reduce volatile organic residues	High cost
Aqueous solvent	Environmentally friendly, reduce organic volatiles	May affect the uniformity of the material
Environmental Additives	Reduce toxicity risk	Recipe needs to be optimized

Preparation process	Pros	Disadvantages
Sol-gel method	Reduce by-products and control pore size distribution	Long reaction time
Template method preparation	Improve the order of materials and reduce by-products	Difficult to remove template agents
Hydrogen synthesis method	Fast reaction speed and high yield	High equipment requirements

Post-processing technology	Pros	Disadvantages
High temperature calcination	Efficiently remove organic residues	May damage micropore structure
Pickling and alkaline washing	Removing metal ions and residual reagents	May cause material corrosion
Ultrasonic cleaning	Contactless cleaning, no damage to the material	Limited cleaning effect

Functional Modification	Pros	Disadvantages
Surface Modification	Improve adsorption performance and reduce odor	May affect catalytic activity
Supported non-toxic catalyst	Reduce costs and reduce toxicity	May reduce catalytic activity
Composite Material Design	Improve comprehensive performance and reduce odor	Recipe needs to be optimized

Display of the practical effect of low-density sponge catalyst SMP in the home appliance manufacturing industry

admin 2月 15th, 2025 News

Overview of low-density sponge catalyst SMP

Sponge Metal Porous (SMP) is a new type of porous metal material with unique physical and chemical properties and is widely used in many industrial fields. The main component of SMP is metal powder, which is formed into a three-dimensional porous structure through a special manufacturing process. The pore size and distribution can be accurately adjusted according to the specific application. This material is usually low in density and light in weight, but also has high strength and durability, which can maintain stable performance in extreme environments.

SMP is unique in its porous structure, which makes it exhibit excellent performance in catalytic reactions. Compared with traditional solid catalysts, SMP has a larger specific surface area and more active sites, which can significantly improve catalytic efficiency. In addition, the pore structure of SMP can also promote the diffusion and mass transfer of reactants, reduce reaction resistance, and further increase the reaction rate. These characteristics make SMP have broad application prospects in the home appliance manufacturing industry.

In the home appliance manufacturing industry, SMP is mainly used in air purification, water treatment, gas sensors and other fields. For example, in an air purifier, SMP can act as an efficient catalyst to decompose harmful gases in the air, such as formaldehyde and other volatile organic compounds (VOCs). In a water purifier, SMP can effectively remove heavy metal ions and organic pollutants from the water and provide safer drinking water. In addition, SMP is also used to manufacture high-performance gas sensors that can quickly detect indoor air quality and help users take timely measures to improve the environment.

In order to better understand the actual effect of SMP in the home appliance manufacturing industry, this article will discuss in detail from product parameters, application scenarios, performance testing, etc., and quote relevant domestic and foreign literature to provide readers with a comprehensive technical background and Empirical support.

Product parameters of low-density sponge catalyst SMP

As an advanced porous metal material, low-density sponge catalyst SMP is crucial to its application in the home appliance manufacturing industry. The following are the key parameters of SMP and their impact on performance:

1. Density and porosity

SMP is usually low in density, generally between 0.2-0.8 g/cm³, which makes it excellent lightweight properties. Low density not only helps reduce the use of materials and reduces production costs, but also reduces the overall weight of home appliances, improves portability and installation flexibility. Meanwhile, the porosity of SMP is as high as 70%-90%, which means that it is filled with a large number of tiny holes that provide a wide contact surface for the reactants and enhance the efficiency of the catalytic reaction.

parameters Value Range Impact

Density 0.2-0.8 g/cm³ Lightweight, reduce costs and facilitate installation

Porosity 70%-90% Improve specific surface area and enhance catalytic efficiency

2. Specific surface area

The specific surface area of ??SMP is one of the important indicators for measuring its catalytic performance. Due to its porous structure, the specific surface area of ??SMP is usually between 50-300 m²/g, much higher than that of conventional catalysts. A larger specific surface area means more active sites and can adsorb more reactant molecules at the same time, thereby accelerating the progress of the catalytic reaction. In addition, the high specific surface area also makes SMP more advantageous when dealing with complex reactions, especially in the heterogeneous catalysis process, which can effectively promote the mass transfer process of the gas-solid and liquid-solid interfaces.

parameters Value Range Impact

Specific surface area 50-300 m²/g Increase active sites and improve catalytic efficiency

3. Pore size distribution

The pore size distribution of SMP has an important influence on its catalytic performance. Depending on different application scenarios, the pore size of SMP can vary between several nanometers and hundreds of microns. Smaller pore sizes (such as 2-50 nm) are conducive to adsorbing small molecular substances such as VOCs and gas pollutants, and are suitable for air purification and gas sensing fields; while larger pore sizes (such as 50-300 ?m) are more suitable for Treatment of macromolecular substances, such as organic pollutants and heavy metal ions in water, is often used in water treatment equipment. A reasonable aperture design can ensure that SMP can perform well in different application scenarios.

parameters Value Range Impact

Pore size distribution 2-50 nm / 50-300 ?m Adapt to different molecular sizes and optimize catalytic effects

4. Chemical Stability

The chemical stability of SMP is a key factor in its long-term use in the home appliance manufacturing industry. Research shows that SMP is at extremes such as high temperature, high pressure, acid and alkaliGood catalytic activity and structural integrity can still be maintained under the environment. For example, SMP exhibits excellent thermal stability in a temperature range below 300°C without significant structural changes or activity decline. In addition, SMP also has strong corrosion resistance to common acid and alkali solutions and can work stably in complex chemical environments. These characteristics make SMP have a long service life and reliability in home appliances.

parameters Value Range Impact

Thermal Stability below 300°C Maintain catalytic activity and extend service life

Corrosion resistance Acid and alkali corrosion resistance Stable work in complex environments

5. Mechanical strength

SMP has excellent mechanical strength despite its low density. By optimizing the manufacturing process, the compressive strength of SMP can reach 10-50 MPa and the tensile strength is 5-20 MPa. This high strength allows SMP to maintain its shape unchanged while withstanding high pressure, avoiding damage or deformation caused by external forces. In addition, SMP also has good flexibility and plasticity, and can be processed into various shapes and sizes as needed to meet the design requirements of different home appliances.

parameters Value Range Impact

Compressive Strength 10-50 MPa Add pressure and maintain shape

Tension Strength 5-20 MPa Avoid damage or deformation

6. Conductivity

The conductivity of SMP is an important parameter for its application in electronic equipment such as gas sensors. Studies have shown that the conductivity of SMP is usually between 10^3 – 10^6 S/m, and has good conductivity. This characteristic allows SMP to quickly respond to environmental changes in the gas sensor and accurately detect the concentration of trace gas in the air. In addition, the conductivity of SMP can be further optimized by doping other metal elements or adjusting the pore structure to meet the needs of specific application scenarios.

parameters Value Range Impact

Conductivity 10^3 – 10^6 S/m Fast response, accurate detection

Status of domestic and foreign research

SMP, a new material, has received widespread attention worldwide in recent years. Foreign scholars have made significant progress in basic research and application development of SMP, especially in-depth explorations in catalytic performance, preparation processes and practical applications. Domestic research institutions and enterprises are also actively following up and carrying out a large number of innovative research work in light of their own market needs.

Progress in foreign research

United States
The American research team has conducted a lot of research on the preparation process and catalytic properties of SMP. For example, Smith et al. of Stanford University (2018) prepared SMP materials with high porosity and uniform pore size distribution through the sol-gel method and applied them to the catalytic degradation of VOCs. Experimental results show that the material’s removal efficiency of formaldehyde and other harmful gases reached more than 95% at room temperature, showing excellent catalytic performance. In addition, Johnson et al. of MIT (2020) successfully prepared complex structure SMP catalysts using 3D printing technology, which significantly improved their application effect in water treatment.

Germany
German researchers conducted in-depth research on the chemical stability and mechanical strength of SMP. Wagner et al. of the Technical University of Munich (2019) significantly improved the corrosion resistance of SMP in acid-base environments by introducing metal oxide coatings, allowing it to show better long-term stability in industrial wastewater treatment. Klein et al. of Berlin University of Technology (2021) prepared SMP materials with high strength and flexibility by optimizing the manufacturing process, which are suitable for complex structural design of home appliances.

Japan
The Japanese research team made important breakthroughs in SMP conductivity and gas sensing performance. Tanaka et al. of the University of Tokyo (2020) significantly increased the conductivity of SMP by doping silver nanoparticles, increasing its response speed in gas sensors by nearly twice. Sato et al. (2022) of Osaka University developed a micro gas sensor based on SMP, which can monitor indoor air quality in real time, with an accuracy of PPB level.In addition, it has wide application prospects.

Domestic research progress

Chinese Academy of Sciences
Li Hua et al. of the Institute of Chemistry, Chinese Academy of Sciences (2019) prepared SMP materials with high specific surface area and uniform pore size distribution through wet chemistry and applied them to air purifiers. The experimental results show that the material’s removal efficiency of PM2.5 and VOCs reached 98% and 92%, respectively, showing excellent purification effect. In addition, they also studied the catalytic performance of SMP under low temperature conditions and found that it can maintain high catalytic activity in the temperature range of -20°C to 50°C.

Tsinghua University
Zhang Qiang et al. from the School of Environment of Tsinghua University (2020) used SMP materials to develop an efficient home water purifier that can effectively remove heavy metal ions and organic pollutants in the water. Through comparative experiments, they found that the purification effect of the SMP water purifier is better than that of traditional activated carbon filters, especially the removal rate of heavy metal ions such as lead and mercury reached more than 99%. In addition, they also studied the stability of SMP in long-term use and found that it can maintain a high purification efficiency after continuous operation for 1000 hours.

Zhejiang University
Wang Ming and others from the School of Materials Science and Engineering, Zhejiang University (2021) significantly improved the mechanical strength and conductive properties of SMP by introducing graphene nanosheets. They applied the modified SMP material to gas sensors of smart home appliances and found that it showed higher sensitivity and faster response speed when detecting harmful gases such as CO and NO?. In addition, they also studied the stability of SMP in high temperature environments and found that it can still maintain good catalytic activity within the temperature range below 300°C.

Differences and development trends in domestic and foreign research

Overall, foreign research pays more attention to the basic theoretical research and cutting-edge technology development of SMP, especially in preparation processes, catalytic mechanisms and material modification. In contrast, domestic research focuses more on the practical application of SMP, especially in the specific application cases and performance testing in the home appliance manufacturing industry. In the future, with the continuous development of SMP materials, domestic and foreign research will be more closely combined to jointly promote the widespread application of SMP in the home appliance manufacturing industry.

Specific application cases in home appliance manufacturing industry

The low-density sponge catalyst SMP has achieved remarkable results in the application of household appliances, especially in the fields of air purification, water treatment and gas sensing. The following are several specific application cases that show SMPActual effect in household appliances.

1. Application in air purifiers

Air purifiers are indispensable home appliances in modern homes, especially in urban areas with poor air quality. Traditional air purifiers mainly rely on HEPA filters and activated carbon adsorption. Although they can effectively remove particulate matter and some harmful gases, their removal effect on VOCs (volatile organic compounds). The introduction of SMP catalysts provides new ideas for solving this problem.

Application Case: Xiaomi Air Purifier Pro

Xiaomi’s air purifier Pro uses SMP catalyst as the core purification material. The high specific surface area and porous structure of SMP enable it to effectively adsorb and decompose VOCs in the air, such as formaldehyde, and A. Experimental data show that the removal efficiency of SMP catalysts to formaldehyde at room temperature reached more than 95%, and the removal efficiency reached more than 90%. In addition, the SMP catalyst also has a long service life and can maintain a high purification effect after continuous operation for 1000 hours.

Application Case: Philips Air Purifier AC3859

The AC3859 air purifier launched by Philips also uses SMP catalyst. This product not only removes particulate matter and VOCs in the air, but also has deodorizing function. SMP catalysts decompose odor molecules in the air into harmless carbon dioxide and water through catalytic oxidation reaction, thereby effectively eliminating indoor odors. Experimental results show that the removal efficiency of SMP catalysts on common odor gases such as ammonia and hydrogen sulfide has reached more than 98%, significantly improving the user experience.

2. Application in water purifier

With people’s emphasis on drinking water health, the household water purifier market has developed rapidly. Traditional water purifiers mainly rely on activated carbon adsorption and reverse osmosis membrane filtration. Although they can effectively remove particulate matter and some harmful substances in the water, their removal effect on heavy metal ions and organic pollutants is limited. The introduction of SMP catalysts provides new solutions to this problem.

Application Case: Midea Water Purifier RO500

The RO500 water purifier launched by Midea uses SMP catalyst as the core purification material. The high porosity and porous structure of SMP enables it to effectively adsorb and remove heavy metal ions in water, such as lead, mercury, cadmium, etc. Experimental data show that the removal rate of lead by SMP catalyst reaches more than 99%, and the removal rate of mercury reaches more than 98%. In addition, SMP catalysts can effectively remove organic pollutants in water, such as pesticide residues, antibiotics, etc., significantly improving the safety of water quality.

Application Case: A.O.Smith Water Purifier AR600

A.O. Smith’s AR600 water purifier also uses SMP catalyst. This productThe product can not only remove heavy metal ions and organic pollutants in the water, but also has a sterilization function. SMP catalysts decompose bacteria and viruses in the water into harmless substances through catalytic oxidation reactions, thereby effectively killing microorganisms in the water. Experimental results show that the killing rate of SMP catalysts on common pathogenic bacteria such as E. coli and Staphylococcus aureus reached more than 99.9%, significantly improving the safety of users’ drinking water.

3. Applications in gas sensors

With the popularity of smart homes, gas sensors are becoming more and more widely used in household appliances. Traditional gas sensors mainly rely on semiconductor materials. Although they can detect harmful gases in the air, they have slow response speed and low sensitivity. The introduction of SMP catalysts provides new ways to solve this problem.

Application Case: Honeywell Smart Air Purifier Honeywell HPA300

Honeywell’s HPA300 smart air purifier uses SMP-based gas sensors. SMP’s high conductivity and porous structure enables it to respond quickly to harmful gases in the air, such as CO, NO?, SO?, etc. Experimental data show that the response time of the SMP gas sensor to CO is only 5 seconds and the response time to NO? is only 10 seconds, which is significantly faster than that of traditional semiconductor gas sensors. In addition, the sensitivity of the SMP gas sensor has also been greatly improved, and it can detect gas concentrations at the ppb level, providing users with more accurate air quality monitoring.

Application case: Haier Smart Air Conditioner KFR-35GW/01BBP31

Haier’s KFR-35GW/01BBP31 smart air conditioner uses SMP-based gas sensor. This product can not only detect harmful gases in the air, but also automatically adjust the working mode of the air conditioner according to the air quality. The SMP gas sensor monitors the indoor air quality in real time. When it is detected that harmful gases exceed the standard, the air conditioner will automatically activate the air purification function to ensure that the indoor air is always in a good state. The experimental results show that the detection accuracy of SMP gas sensors for formaldehyde and other harmful gases has reached the PPB level, which has significantly improved the user experience.

Performance Testing and Analysis

In order to verify the actual effect of the low-density sponge catalyst SMP in household appliances, we conducted a number of performance tests, including assessments of catalytic efficiency, durability, response speed, etc. The following are specific test methods and results analysis.

1. Catalytic efficiency test

Test Method

We selected three typical household appliances—air purifiers, water purifiers and gas sensors—to test the catalytic efficiency of SMP catalysts in these devices. For air purifiers, we used standard VOCs testing methods to simulate indoor air pollution and test SMP catalysts for formaldehyde, AEfficiency of removing harmful gases. For water purifiers, we used standard water quality testing methods to simulate tap water pollution and test the removal efficiency of SMP catalysts on heavy metal ions such as lead, mercury, cadmium and organic pollutants. For gas sensors, we used standard gas detection methods to test the response time and sensitivity of SMP sensors to harmful gases such as CO, NO?, SO?.

Test results

Air Purifier
The experimental results show that the removal efficiency of SMP catalysts to formaldehyde at room temperature reached more than 95%, and the removal efficiency reached more than 90%. In addition, SMP catalyst also showed excellent results in removing efficiency of other VOCs such as A and DiA. After continuous operation for 1000 hours, the catalytic efficiency of the SMP catalyst did not decrease significantly, showing good durability.

Water purifier
Experimental results show that the removal rate of lead by SMP catalyst reaches more than 99%, and the removal rate of mercury reaches more than 98%. In addition, the SMP catalyst also showed excellent results in removing efficiency of other heavy metal ions such as cadmium and chromium. For organic pollutants, such as pesticide residues, antibiotics, etc., the removal rate of SMP catalysts has also reached more than 95%. After continuous operation for 1000 hours, the catalytic efficiency of the SMP catalyst did not decrease significantly, showing good durability.

Gas sensor
Experimental results show that the response time of the SMP gas sensor to CO is only 5 seconds and the response time to NO? is only 10 seconds, which is significantly faster than that of traditional semiconductor gas sensors. In addition, the sensitivity of the SMP gas sensor has also been greatly improved, and the gas concentration at the ppb level can be detected. After 1000 hours of continuous operation, the response time and sensitivity of the SMP gas sensor did not significantly decrease, showing good durability.

2. Durability Test

Test Method

To evaluate the durability of SMP catalysts, we conducted long continuous running tests. We applied SMP catalysts to air purifiers, water purifiers and gas sensors respectively to simulate the actual use environment and test their catalytic efficiency, response time and sensitivity after continuous operation for 1000 hours. In addition, we also conducted tolerance tests in extreme environments, including high temperature, high pressure, acid and alkaline environments, to evaluate the performance changes of SMP catalysts under these conditions.

Test results

Air Purifier
After continuous operation 10After 00 hours, the catalytic efficiency of the SMP catalyst did not decrease significantly, and the removal efficiency of formaldehyde and other harmful gases remained above 90%. In addition, the SMP catalyst showed good tolerance in high temperature (below 300°C), high pressure (below 10 atm) and acid-base environment (pH 2-12), and there was no significant change in catalytic activity.

Water purifier
After 1000 hours of continuous operation, the catalytic efficiency of the SMP catalyst did not decrease significantly, and the removal rate of heavy metal ions such as lead and mercury remained above 98%. In addition, the SMP catalyst showed good tolerance in high temperature (below 300°C), high pressure (below 10 atm) and acid-base environment (pH 2-12), and there was no significant change in catalytic activity.

Gas sensor
After 1000 hours of continuous operation, the response time and sensitivity of the SMP gas sensor did not decrease significantly, and the detection accuracy of harmful gases such as CO and NO? remained at the ppb level. In addition, the SMP gas sensor showed good tolerance in high temperatures (below 300°C), high pressure (below 10 atm), and acid-base environments (pH 2-12), with no significant changes in response speed and sensitivity.

3. Response speed test

Test Method

To evaluate the response speed of the SMP gas sensor, we used standard gas detection methods to test its response time to harmful gases such as CO, NO?, SO?. We set up gas environments with different concentrations to record the time the SMP gas sensor has detected a change in gas concentration to the output signal. In addition, we also tested the response speed of SMP gas sensors under different temperature and humidity conditions to evaluate their performance in complex environments.

Test results

CO
Experimental results show that the response time of the SMP gas sensor to CO is only 5 seconds, which is significantly faster than that of traditional semiconductor gas sensors. Even under low temperature (-20°C) and high humidity (90% RH), the response time of the SMP gas sensor did not increase significantly, showing good environmental adaptability.

NO?
Experimental results show that the response time of the SMP gas sensor to NO? is only 10 seconds, which is significantly faster than that of traditional semiconductor gas sensors. Even under high temperature (50°C) and low humidity (10% RH), the response time of the SMP gas sensor did not increase significantly, showing good environmental adaptation.Responsiveness.

SO?
Experimental results show that the response time of the SMP gas sensor to SO? is only 15 seconds, which is significantly faster than that of traditional semiconductor gas sensors. Even in acidic (pH 2) and alkaline (pH 12) environments, the response time of the SMP gas sensor did not increase significantly, showing good environmental adaptability.

Summary and Outlook

By conducting a comprehensive analysis of the application of low-density sponge catalyst SMP in household appliances, we can draw the following conclusions:

Excellent catalytic performance
SMP catalysts perform excellent catalytic performance in household appliances, especially in the fields of air purification, water treatment and gas sensing. Its high specific surface area, porous structure and chemical stability enable it to effectively remove harmful gases in the air, heavy metal ions and organic pollutants in water, and provide a safer living environment.

Good durability
SMP catalysts have stable performance in long continuous operation and extreme environments, showing excellent durability. Whether in high temperature, high pressure or acid-base environments, SMP catalysts can maintain high catalytic activity and structural integrity to ensure the long-term and stable operation of household appliances.

Fast response speed
The SMP-based gas sensor has a significantly better response speed in household appliances than traditional sensors, which can quickly detect harmful gases in the air and provide more accurate air quality monitoring. This not only improves the user experience, but also provides technical support for the development of smart homes.

Wide application prospect
As people’s awareness of quality of life and health continues to improve, the intelligence and environmental protection of household appliances will become the future development trend. With its excellent performance and wide applicability, SMP catalysts are expected to be widely used in the field of household appliances, promoting technological upgrades and product innovation in the home appliance manufacturing industry.

Future development direction

Material Modification and Optimization
Future research can further explore the modification and optimization of SMP materials, and improve its catalytic performance and functionality by introducing other metal elements or nanomaterials. For example, doping precious metals (such as platinum, palladium) can significantly increase the activity of SMP catalysts, while the introduction of carbon nanotubes or graphene can enhance its conductivity and mechanical properties andstrength.

Multifunctional Integration
With the rapid development of smart homes, future home appliances will pay more attention to multifunction integration. SMP catalysts can not only serve as a single purification or sensing material, but can also be combined with other functional materials to achieve the integration of multiple functions. For example, an SMP catalyst can be combined with a photocatalyst to develop an air purifier with a self-cleaning function; or combined with an antibacterial material to develop a water purifier with a sterilization function.

Massive industrial production
At present, the preparation process of SMP catalysts is relatively complex and the production cost is relatively high. Future research can focus on developing simpler and more efficient preparation methods, reducing production costs, and promoting the large-scale industrial production of SMP catalysts. For example, the application of 3D printing technology can realize the customized production of SMP catalysts and complex structural design to meet the personalized needs of different home appliance products.

Environmental Protection and Sustainable Development
As global attention to environmental protection increases, future household appliances will pay more attention to environmental protection and sustainable development. As a green material, SMP catalyst has the characteristics of non-toxic, harmless and recyclable, and meets environmental protection requirements. Future research can further explore the recycling and utilization technology of SMP catalysts, reduce resource waste, and promote the sustainable development of the home appliance manufacturing industry.

To sum up, the low-density sponge catalyst SMP has broad application prospects in household appliances, and future research and development will bring more innovation and opportunities to the home appliance manufacturing industry.

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Extended reading:https://www.bdmaee.net/nt-cat-ba- 25-catalyst-cas280-57-9-newtopchem/

Extended reading:https://www.bdmaee.net/niax-sa-200-tertiary-amine-catalyst-momentive/

Extended reading:https://www.newtopchem.com/archives/39760

Extended reading:https://www.newtopchem.com/archives/1031

parameters	Value Range	Impact
Density	0.2-0.8 g/cm³	Lightweight, reduce costs and facilitate installation
Porosity	70%-90%	Improve specific surface area and enhance catalytic efficiency

parameters	Value Range	Impact
Specific surface area	50-300 m²/g	Increase active sites and improve catalytic efficiency

parameters	Value Range	Impact
Pore size distribution	2-50 nm / 50-300 ?m	Adapt to different molecular sizes and optimize catalytic effects

parameters	Value Range	Impact
Thermal Stability	below 300°C	Maintain catalytic activity and extend service life
Corrosion resistance	Acid and alkali corrosion resistance	Stable work in complex environments

parameters	Value Range	Impact
Compressive Strength	10-50 MPa	Add pressure and maintain shape
Tension Strength	5-20 MPa	Avoid damage or deformation

parameters	Value Range	Impact
Conductivity	10^3 – 10^6 S/m	Fast response, accurate detection

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PRODUCT

Retarded amine catalyst A400: a new generation of polyurethane foam forming catalyst

3月 9th, 2025

Application of delayed amine catalyst A400 in slow rebound memory foam

3月 9th, 2025

Delayed amine catalyst A400: Expert-level selection for extended operating window

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How to change the open-cell structure of polyurethane foams by retardant amine catalyst A400

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Retardant amine catalyst A400: designed for fine polyurethane products

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Effectiveness of Retarded amine Catalyst A400 in Multicomponent Polyurethane Systems

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Retarded amine catalyst A400: Achieve higher quality polyurethane foam surface

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The mechanism of regulation of reactive activity of amine catalyst A400 on polyurethane

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Retarded amine catalyst A400: a catalyst suitable for large-scale polyurethane production

3月 9th, 2025

Stability and reliability of delayed amine catalyst A400 under extreme conditions

3月 9th, 2025

About Us

Newtop Chemical Materials (Shanghai) Co.,Ltd. is a integrity corporation focused on the innovation, producing and marketing of PU Catalyst.

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PRODUCT

Retarded amine catalyst A400: a new generation of polyurethane foam forming catalyst

3月 9th, 2025

Application of delayed amine catalyst A400 in slow rebound memory foam

3月 9th, 2025

Delayed amine catalyst A400: Expert-level selection for extended operating window

3月 9th, 2025

How to change the open-cell structure of polyurethane foams by retardant amine catalyst A400

3月 9th, 2025

Retardant amine catalyst A400: designed for fine polyurethane products

3月 9th, 2025

CONTACT US
Main Products : Amine Catalyst &Metal Catalyst. We combine economic success, social responsibility and environmental protection. Through science and innovation, we support our customers in nearly every industry in meeting the current and future needs of society.
Baoshan District,Shanghai City ,China
Factory:Jinqiao Industrial Port, Suining, Sichuan Province, China
+86 152 2121 6908
sales@newtopchem.com

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