Global Absolute Pressure Transmitter and Differential Pressure Transmitter Competitive Landscape Professional Research Report 2024
Research Summary
An absolute pressure transmitter is a device used to accurately measure and transmit the absolute pressure of a system or environment. Absolute pressure is the pressure measured relative to a perfect vacuum. Absolute pressure transmitters consist of a sensing element, usually a diaphragm, that detects the pressure and converts it into an electrical signal. This electrical signal is then conditioned and amplified within the transmitter, and finally, transmitted to a control system or display device. Absolute pressure transmitters are frequently used in applications such as HVAC systems, industrial processes, pneumatic systems, and environmental monitoring.
A differential pressure transmitter, on the other hand, measures the difference in pressure between two points in a system and transmits that information as an electrical signal. It consists of two pressure sensing elements, often in the form of diaphragms or Bourdon tubes, with one exposed to the high-pressure side and the other to the low-pressure side. The difference in pressure between the two sensing elements is converted into an electrical signal, which is then processed and transmitted to the control system or display device. Differential pressure transmitters find application in flow rate measurement, level measurement, filter monitoring, and other situations where detecting a pressure difference is crucial for system control and monitoring.
Both absolute pressure transmitters and differential pressure transmitters play vital roles in various industries, providing accurate and reliable pressure measurements to ensure the smooth operation and efficiency of systems and processes.
According to DIResearch's in-depth investigation and research, the global Absolute Pressure Transmitter and Differential Pressure Transmitter market size will reach XX US$ Million in 2024, and is expected to reach XX US$ Million in 2030, with a CAGR of XX% (2025-2030). Among them, the China market has changed rapidly in the past few years. The market size in 2024 will be XX US$ Million, accounting for approximately XX% of the world. It is expected to reach XX US$ Million in 2030, and the global share will reach XX%.
The major global manufacturers of Absolute Pressure Transmitter and Differential Pressure Transmitter include Emerson, Yokogawa, Schneider Electric, ABB, Endress + Hauser, Siemens, Fuji Electric, Azbil (Yamatake), Honeywell, Shanghai Guanghua Instrument, Shanghai Automation Instrument etc. The global players competition landscape in this report is divided into three tiers. The first tiers is the global leading enterprise, which occupies a major market share, is in a leading position in the industry, has strong competitiveness and influence, and has a large revenue scale; the second tiers has a certain share and popularity in the market, actively follows the industry leaders in product, service or technological innovation, and has a medium revenue scale; the third tiers has a smaller share in the market, has a lower brand awareness, mainly focuses on the local market, and has a relatively small revenue scale.
This report studies the market size, price trends and future development prospects of Absolute Pressure Transmitter and Differential Pressure Transmitter. Focus on analysing the market share, product portfolio, prices, sales volume, revenue and gross profit margin of global major manufacturers, as well as the market status and trends of different product types and applications in the global Absolute Pressure Transmitter and Differential Pressure Transmitter market. The report data covers historical data from 2019 to 2023, based year in 2024 and forecast data from 2025 to 2030.
The regions and countries in the report include North America, Europe, China, APAC (excl. China), Latin America and Middle East and Africa, covering the Absolute Pressure Transmitter and Differential Pressure Transmitter market conditions and future development trends of key regions and countries, combined with industry-related policies and the latest technological developments, analyze the development characteristics of Absolute Pressure Transmitter and Differential Pressure Transmitter industries in various regions and countries, help companies understand the development characteristics of each region, help companies formulate business strategies, and achieve the ultimate goal of the company's global development strategy.
The data sources of this report mainly include the National Bureau of Statistics, customs databases, industry associations, corporate financial reports, third-party databases, etc. Among them, macroeconomic data mainly comes from the National Bureau of Statistics, International Economic Research Organization; industry statistical data mainly come from industry associations; company data mainly comes from interviews, public information collection, third-party reliable databases, and price data mainly comes from various markets monitoring database.
Global Key Manufacturers of Absolute Pressure Transmitter and Differential Pressure Transmitter Include:
Emerson
Yokogawa
Schneider Electric
ABB
Endress + Hauser
Siemens
Fuji Electric
Azbil (Yamatake)
Honeywell
Shanghai Guanghua Instrument
Shanghai Automation Instrument
Absolute Pressure Transmitter and Differential Pressure Transmitter Product Segment Include:
Pressure Transmitter
Differential Pressure Transmitter
Absolute Pressure Transmitter and Differential Pressure Transmitter Product Application Include:
Chemical
Power
Petroleum and Natural Gas
Water Treatment
Food and Beverage
Metal Products
Pulp and Paper
Chapter Scope
Chapter 1: Product Research Range, Product Types and Applications, Market Overview, Market Situation and Trends
Chapter 2: Global Absolute Pressure Transmitter and Differential Pressure Transmitter Industry PESTEL Analysis
Chapter 3: Global Absolute Pressure Transmitter and Differential Pressure Transmitter Industry Porter’s Five Forces Analysis
Chapter 4: Global Absolute Pressure Transmitter and Differential Pressure Transmitter Major Regional Market Size (Revenue, Sales, Price) and Forecast Analysis
Chapter 5: Global Absolute Pressure Transmitter and Differential Pressure Transmitter Market Size and Forecast by Type and Application Analysis
Chapter 6: North America Absolute Pressure Transmitter and Differential Pressure Transmitter Competitive Analysis (Market Size, Key Players and Market Share, Product Type and Application Segment Analysis, Countries Analysis)
Chapter 7: Europe Absolute Pressure Transmitter and Differential Pressure Transmitter Competitive Analysis (Market Size, Key Players and Market Share, Product Type and Application Segment Analysis, Countries Analysis)
Chapter 8: China Absolute Pressure Transmitter and Differential Pressure Transmitter Competitive Analysis (Market Size, Key Players and Market Share, Product Type and Application Segment Analysis, Countries Analysis)
Chapter 9: APAC (Excl. China) Absolute Pressure Transmitter and Differential Pressure Transmitter Competitive Analysis (Market Size, Key Players and Market Share, Product Type and Application Segment Analysis, Countries Analysis)
Chapter 10: Latin America Absolute Pressure Transmitter and Differential Pressure Transmitter Competitive Analysis (Market Size, Key Players and Market Share, Product Type and Application Segment Analysis, Countries Analysis)
Chapter 11: Middle East and Africa Absolute Pressure Transmitter and Differential Pressure Transmitter Competitive Analysis (Market Size, Key Players and Market Share, Product Type and Application Segment Analysis, Countries Analysis)
Chapter 12: Global Absolute Pressure Transmitter and Differential Pressure Transmitter Competitive Analysis of Key Manufacturers (Sales, Revenue, Market Share, Price, Regional Distribution and Industry Concentration)
Chapter 13: Key Company Profiles (Product Portfolio, Sales, Revenue, Price and Gross Margin)
Chapter 14: Industrial Chain Analysis, Include Raw Material Suppliers, Distributors and Customers
Chapter 15: Research Findings and Conclusion
Chapter 16: Methodology and Data Sources