GLOBAL AUTOMOTIVE CERAMIC FILTER MARKET

INTRODUCTION

In exhaust systems, ceramics are frequently employed as a pollution filter, particularly in diesel particle filters. Ceramic filters are excellent for use in both road vehicles and agricultural machinery since they are inexpensive, simple to make, durable, and long-lasting. 

GLOBAL AUTOMOTIVE CERAMIC FILTER MARKET SIZE AND FORECAST

The Global automotive ceramic filter market accounted for $XX Billion in 2022 and is anticipated to reach $XX Billion by 2030, registering a CAGR of XX% from 2023 to 2030.

RECENT PRODUCT DEVELOPMENT AND INNOVATION

In order to remove particles from the exhaust of cars with direct-injection gasoline engines, NGK also intends to start its first mass manufacturing of gasoline particulate filters.

GPFs are ceramic filters used to capture fine particles generated by gasoline engines with direct injection. They are developed with DPF technology.

The Flowrox Ceramic Disc Filter has been introduced by Flowrox. A cost-effective alternative for many concentrator and tailings operations is the Flowrox Ceramic disc filter, which operates continuously with high capacity.

It uses around 90% less energy than standard vacuum filters. The Flowrox Ceramic Disc Filter has a minimal investment cost and produces  clear filtrate.

The CERAFIL ceramic filter range from Murata provides compact, lightweight filters and traps that treat intermediate frequencies used in AV and telecom equipment by utilising the piezoelectric capabilities of ceramics.

Impurities from molten metal are eliminated throughout the casting process using CoorsTek Flow-Rite ceramic filters. Aluminum, copper-based alloys, and all forms of cast irons can be applied with filters.

An effective balance of refractoriness and affinity for attachment of metallic oxide inclusions is provided by the alumina-silicate composition used in the manufacturing of FlowRite ceramic foundry filters.

RECENT DEVELOPMENT

In order to lower non-exhaust particulate matter (PM) from automobiles, the manufacturing process and filtering effectiveness of ceramic filters were developed. Excellent strength at high temperatures, resistance to chemicals, and a low coefficient of thermal expansion are features of ceramic filters.

There are several ways to make ceramic filters: direct foaming, pore-forming agent addition, partial sintering, and replica template approach. Because of its ability to produce an interconnected open porous structure, the replica template method is one of the most popular among them.

Additionally, one benefit of creating porous filters via replica approach is that porosity and pore shape may be effectively controlled.In contrast to other manufacturing techniques, the high porosity porous ceramic filters made using the replica approach feature a hollow body with an empty strut, which reduces their strength and filtering efficiency.

Anisotropic materials are used in the production of the ceramic foams, which can increase the density of the empty strut. Moreover, anisotropic materials create bridges with one another that serve as supports and boost mechanical strength.

The development of ceramic nanorods and whiskers can improve filtration efficiency and mitigate the drawbacks of porous ceramic filters made using the replica technique. The development of ceramic nanorods and whiskers can improve filtration efficiency and mitigate the drawbacks of porous ceramic filters made using the replica technique.

MARKET DYNAMICS

The fundamental component of ceramic water filters, which are used to treat water, is a ceramic filter candle or cartridge. By employing a network of tiny pores, this component efficiently eliminates impurities like bacteria, viruses, turbidity, protozoa, microbial cysts, and more.

The main ingredients of these filters are fine silica powder and other kinds of clay, such as black clay, red terracotta, and white kaolin. They fulfil several functions and are frequently used as portable filtration systems or placed in homes.

These movable filters can be used with gravity or pressure-fed systems, placed on counters, under sinks, or even in light industrial environments. They offer access to safe and clean materials for a range of uses, and they represent an efficient and sustainable method of air and water purification.

The need for ceramic filters is growing as health concerns over industrial and vehicle emissions grow. Lung cancer, ischemic heart disease, stroke, and acute lower respiratory infections are just a few of the illnesses that are linked to air pollution, according to the World Health Organisation. Industries purify water and lower emissions by using ceramic filters.

In addition, the usage of honeycomb ceramic air filters to reduce air pollution from smoke, aerosols, dust, fly ash, and odours is also causing the growth. Additionally, the market is expanding as a result of the adoption of ceramic filters to offer safe drinking water and combat waterborne illnesses like cholera, typhoid, and diarrhoea

THIS REPORT WILL ANSWER FOLLOWING QUESTIONS

1. How many Automotive Ceramic Filter are manufactured per annum globally? Who are the sub-component suppliers in different regions?
2. Cost breakup of a Global Automotive Ceramic Filter and key vendor selection criteria
3. Where is the Automotive Ceramic Filter  manufactured? What is the average margin per unit?
4. Market share of Global Automotive Ceramic Filter market manufacturers and their upcoming products
5. Cost advantage for OEMs who manufacture Global  Automotive Ceramic Filter in-house
6. key predictions for next 5 years in Global  Automotive Ceramic Filter market
7. Average B-2-B Automotive Ceramic Filter market price in all segments
8. Latest trends in Automotive Ceramic Filter market, by every market segment
9. The market size (both volume and value) of the Automotive Ceramic Filter market in 2023-2030 and every year in between?
10. Production breakup of Automotive Ceramic Filter market, by suppliers and their OEM relationship