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市場調查報告書

聚乙烯觸媒的全球市場 (2015∼2020年)

Global Polyethylene Catalysts Markets 2015-2020

出版商 TZ Minerals International Pty Ltd 商品編碼 357188
出版日期 內容資訊 英文
商品交期: 最快1-2個工作天內
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聚乙烯觸媒的全球市場 (2015∼2020年) Global Polyethylene Catalysts Markets 2015-2020
出版日期: 2016年03月31日 內容資訊: 英文
簡介

低壓法聚乙烯 (LPPE) 主要使用Ziegler-Natta觸媒和單點觸媒等傳統觸媒生產。LPPE的生產方法有幾個種類 (氣相反應設備,Slurry loop反應設備,CSRT (連續攪拌槽反應器)等) ,不過,許多企業並用複數的製造手法,以聚乙烯的加工性和機械性特性的最佳化為目標。由於PE的最終用途廣泛,需要選擇適合各用途的觸媒。

本報告提供全球聚乙烯觸媒的市場相關分析,聚乙烯觸媒的特性、功能和生產方法,應克服的主要課題,現在、未來的需求數量和供給量,產品開發的動向,主要供應商的概要、生產能力,產業相關人員的建議的內容等彙整,為您概述為以下內容。

第1章 簡介、分析方法

  • 簡介
  • 分析對象
  • 分析方法與方法
  • 分析地區

第2章 摘要整理

第3章 聚乙烯的加工方法分析

  • 簡介
  • LPPE (低壓法聚乙烯) 的加工方法的概要
  • LPPE生產能力的概要

第4章 全球聚乙烯市場及最終用途分析

  • 簡介
  • 聚乙烯 (PE)
  • 鎖狀低密度聚乙烯 (LLDPE)
  • LLDPE的最終用途
  • 高密度聚苯乙烯 (HDPE)
  • HDPE的最終用途
  • 結論

第5章 聚乙烯 (PE) 觸媒的必要條件

  • 簡介
  • PE觸媒的歷史沿革與趨勢
  • 觸媒的化學反應
  • 觸媒系相關必要條件
  • PE觸媒的生產量 (最新值、預測值)
  • 結論

第6章 PE觸媒製造商簡介

  • 簡介
  • 觸媒供應商簡介
  • 產業結構
  • 結論

第7章 策略分析

  • 簡介
  • 聚乙烯觸媒市場概況
  • 分析結果概要
  • 策略分析
  • PE觸媒產業的評估:波特分析組成架構
  • 整體結論與考察事項

附錄1:近幾年的專利趨勢

附錄2:用語、簡稱一覽

附錄3:重要的觸媒的特質

圖表一覽

目錄

Chemical Market Resources, Inc. (CMR) has undertaken a strategic analysis of the global polyethylene (PE) catalysts industry.

Low Pressure Polyethylenes (LPPEs) are typically produced with conventional catalysts like Ziegler-Natta and Chromium catalyst) or single site catalyst (like metallocene and constrained geometry catalyst). The processes to produce LPPEs are well established with gas-phase reactors, slurry loop reactors or continuous stirred tank reactors (CSTR). Most licensors promote multiple reactors to optimize the processability and mechanical properties of PEs. Each end-use-application requires specific PE resin attributes, microstructure, and processability, which are often satisfied by only the right combination of a specific PE process and a suitable catalyst. LPPE technology is ripe for innovation to satisfy many of the process/ product requirements and improvements. One of the goals of this study is to understand recent innovations in PE catalysts made by licensors, catalysts suppliers and major PE producers.

CMR expects the average annual growth rate (AAGR) of the LPPE industry to be approximately 4.2-4.9% from 2015 to 2020. With the shale gas ‘explosion' in the US, a significant increase in PE capacity is expected in North America during the next three years. New capacities are currently being installed in the Middle East. In spite of a slowdown of growth in China, new plant start-ups have continued.

Expansions in some regions of the world and slowdown in other regions will create a shift in catalyst demand and global PE capacity.

Another goal of this study is to review the catalyst needs per region and per process technology in 2020. The number of PE catalyst suppliers, especially third-party suppliers, has increased during the recent years. Each catalyst supplier has a specific catalyst portfolio. This study will assess the relative position of each catalyst supplier in this niche but dynamic and high-margin market based on CMR's interviews with both PE catalyst suppliers and resin producers.

FEATURES;

  • Analysis of global PE catalyst markets, related technologies and emerging trends
  • Global PE supply & demand in 2015 and 2020
  • Markets and end-uses broken down into process and region
  • PE catalyst requirements by type, process, and end-use application
  • In depth survey of PE catalyst users and producers
  • Review of developments in innovation by main PE producers, licensors and catalyst suppliers
  • Comprehensive producer profiles
  • Key issues for the PE industry
  • Complete Excel worksheets included with full report
  • Exclusive Q&A with report author

MAJOR OBJECTIVES

The main objectives of this study is to present a detailed analysis of global PE catalyst markets, related technologies and emerging trends including:

  • PE catalyst technology status
  • PE catalyst process/product relationships
  • key issues related to manufacturing, supply chain, IP, etc
  • current and future needs/priorities of global PE resin manufacturing
  • innovative PE catalyst development
  • in depth analysis of global PE catalysts suppliers
  • strategic recommendations for suppliers and PE producers

KEY ISSUES ADDRESSED

  • Outline of global PE demand
  • Analysis of global processes including PE production by technology and region
  • Analysis of PE markets and end-uses including current/ future demand forecasts by regions
  • PE catalyst requirements by type, process, and end-use applications
  • PE catalysts producers including key participants, profile, product portfolio and position
  • Industry structure including emerging trends
  • The growth in third-party suppliers, the increasing importance of China and the innovative importance of innovative PE catalysts on PE performance and product differentiation.

Table of Contents

1.0. INTRODUCTION AND METHODOLOGY

  • 1.1. INTRODUCTION
  • 1.2. OBJECTIVES
  • 1.3. RESEARCH METHODOLOGY AND APPROACH
  • 1.4. REGIONS ADDRESSED IN THIS STUDY

    2.0. EXECUTIVE SUMMARY

3.0. GLOBAL POLYETHYLENE PROCESS ANALYSIS

  • 3.1. INTRODUCTION
  • 3.2. OVERVIEW OF LPPE PROCESSES
  • 3.3. OVERVIEW OF GLOBAL LPPE CAPACITY

4.0. GLOBAL POLYETHYLENE MARKET AND END-USE ANALYSIS

  • 4.1. INTRODUCTION
  • 4.2. POLYETHYLENE (PE)
  • 4.3. LINEAR LOW DENSITY POLYETHYLENE (LLDPE)
  • 4.4. LLDPE END-USE APPLICATIONS
  • 4.5. HIGH DENSITY POLYETHYLENE (HDPE)
  • 4.6. HDPE END-USE APPLICATIONS
  • 4.7. CONCLUSION

5.0. PE CATALYST REQUIREMENTS

  • 5.1. INTRODUCTION
  • 5.2. HISTORY AND DEVELOPMENT OF PE CATALYSTS
  • 5.3. CATALYST CHEMISTRY
  • 5.4. REQUIREMENTS ON THE CATALYST SYSTEM
  • 5.5. PE CATALYSTS VOLUME IN 2015 AND 2020
  • 5.6. CONCLUSIONS

6.0. PE CATALYST PRODUCER PROFILES

  • 6.1. INTRODUCTION
  • 6.2. REVIEW OF CATALYST SUPPLIERS
  • 6.3. INDUSTRY STRUCTURE
  • 6.4. CONCLUSION

7.0. STRATEGIC ANALYSIS

  • 7.1. INTRODUCTION
  • 7.2. POLYETHYLENE CATALYST MARKET SUMMARY
  • 7.3. SUMMARY OF THE SURVEYS
  • 7.4. STRATEGIC ANALYSIS
  • 7.5. EVALUATING THE PE CATALYST INDUSTRY IN PORTER'S FRAMEWORK
  • 7.6. OVERALL CONCLUSIONS AND GENERAL CONSIDERATIONS

APPENDIX 1: 2013 TO 2015 PATENTS

APPENDIX 2: GLOSSARY AND ABBREVIATIONS

APPENDIX 3: IMPORTANT CATALYST ATTRIBUTES

EXHIBITS

  • Exhibit 1-1: Methodology flowsheet
  • Exhibit 2-1: Capabilities of different low pressure PE processes
  • Exhibit 2-2: HDPE capacity in 2010-2015-2020 by region
  • Exhibit 2-3: HDPE capacity repartition by processes in 2015
  • Exhibit 2-4: Evolution of LLDPE capacity by regions
  • Exhibit 2-5: LLDPE demand by application in 2015
  • Exhibit 2-6: LLDPE demand by region in 2015
  • Exhibit 2-7: HDPE demand by application in 2015
  • Exhibit 2-8: HDPE demand by region in 2015
  • Exhibit 2-9: Maximum demand for catalyst for HDPE production in 2015 and 2020
  • Exhibit 2-10: Demand for Ziegler-Natta catalyst by process technology in 2015
  • Exhibit 2-11: Maximum demand for catalyst for LLDPE production in 2015 and 2020
  • Exhibit 2-12: Distribution of LLDPE capacity by process in 2015
  • Exhibit 2-13: Level of market penetration of mLLDPE by region in 2015 and 2020
  • Exhibit 2-14: Increase in Ziegler-Natta volumes between 2015 and 2020 (high volume range) by regions
  • Exhibit 2-15: Polyolefin catalysts distribution chain
  • Exhibit 2-16: Industry structure for chromium catalysts
  • Exhibit 2-17: Industry structure for Ziegler-Natta PE catalysts
  • Exhibit 2-18: Industry structure for single site PE catalysts
  • Exhibit 2-19: Market value of different catalyst systems in 2015 and 2020
  • Exhibit 2-20: Ziegler-Natta catalysts for HDPE: Opportunity Index vs market attractiveness by region
  • Exhibit 2-21: Chromium catalyst suppliers: Technology position vs market position
  • Exhibit 2-22: SSC suppliers for LLDPE plant: Technology position vs market position
  • Exhibit 3-1: Capabilities of different low pressure PE processes
  • Exhibit 3-2: Phillips' Slurry Loop process
  • Exhibit 3-3: Advanced Double Loop (ADL)
  • Exhibit 3-4: Innovene™ S Process
  • Exhibit 3-5: Hostalen® process
  • Exhibit 3-6: Hostalen® ACP process
  • Exhibit 3-7: Mitsui CX process
  • Exhibit 3-8: Borstar® process
  • Exhibit 3-9: UNIPOL™ Gas-phase process
  • Exhibit 3-10: Innovene™ G Gas-phase process
  • Exhibit 3-11: Spherilene™ C Gas-phase process
  • Exhibit 3-12: Spherilene™ Gas-phase process
  • Exhibit 3-13: Multi-zone Gas-Phase process
  • Exhibit 3-14: HDPE capacity in 2010-2015-2020 by region
  • Exhibit 3-15: HDPE capacity repartition by processes in 2015
  • Exhibit 3-16: Evolution of HDPE capacity repartition by processes
  • Exhibit 3-17: Evolution of LLDPE capacity by regions
  • Exhibit 3-18: Repartition of LLDPE capacity by process in 2015
  • Exhibit 4-1: LLDPE demand by application in 2015
  • Exhibit 4-2: LLDPE demand by region in 2015
  • Exhibit 4-3: HDPE demand by application in 2015
  • Exhibit 4-4: HDPE demand by region in 2015
  • Exhibit 5-1: Chromium compounds developed by Union Carbide
  • Exhibit 5-2: Polymerization mechanism of Ziegler-Natta catalyst
  • Exhibit 5-3: Structure of metallocene
  • Exhibit 5-4: Ionic activation
  • Exhibit 5-5: Constrained geometry catalyst
  • Exhibit 5-6: Mitsui FI Polymerization catalyst
  • Exhibit 5-7: Mitsui FI Oligomerization catalyst
  • Exhibit 5-8: Post-metallocene structures from Univation
  • Exhibit 5-9: Minimum demand for catalyst in HDPE production in 2015 and 2020
  • Exhibit 5-10: Maximum demand for catalyst for HDPE production in 2015 and 2020
  • Exhibit 5-11: Demand for chromium catalyst in 2015 by process
  • Exhibit 5-12: Demand for chromium catalyst in 2020 by process
  • Exhibit 5-13: Increase of chromium catalyst volume between 2015 and 2020 (low volume range)
  • Exhibit 5-14: Increase in chromium catalyst volume between 2015 and 2020 (high volume range)
  • Exhibit 5-15: Demand for Ziegler-Natta catalyst by process technology in 2015 (HDPE)
  • Exhibit 5-16: Demand for Ziegler-Natta catalyst by process technology in 2020 (HDPE)
  • Exhibit 5-17: Increase in Ziegler-Natta catalyst volume between 2015 and 2020 (low volume range) (HDPE)
  • Exhibit 5-18: Increase in Ziegler-Natta catalyst volume between 2015 and 2020 (high volume range) (HDPE)
  • Exhibit 5-19: Minimum demand for catalyst for LLDPE production in 2015 and 2020
  • Exhibit 5-20: Maximum demand for catalyst for LLDPE production in 2015 and 2020
  • Exhibit 5-21: Distribution of LLDPE capacity by process in 2015
  • Exhibit 5-22: Distribution of LLDPE capacity by process in 2020
  • Exhibit 5-23: Level of market penetration of mLLDPE by region in 2015 and 2020
  • Exhibit 5-24: Increase in metallocene volume between 2015 and 2020 (low volume range)
  • Exhibit 5-25: Increase in metallocene volume between 2015 and 2020 (high volume range)
  • Exhibit 5-26: Increase in Ziegler-Natta volumes between 2015 and 2020 (low volume range) by regions (LLDPE)
  • Exhibit 5-27: Increase in Ziegler-Natta volumes between 2015 and 2020 (high volume range) by regions (LLDPE)
  • Exhibit 5-28: Increase in Ziegler-Natta volumes between 2015 and 2020 by process
  • Exhibit 5-29: Consumption of LLDPE film by region in 2020
  • Exhibit 6-1: Univation's PE catalysts and their capability range (MFI and density)
  • Exhibit 6-2: Univation metallocene catalyst capabilities in the processability-film toughness window
  • Exhibit 6-3: Polyolefin catalysts distribution chain
  • Exhibit 6-4: Industry structure for chromium catalysts
  • Exhibit 6-5: Industry structure for Ziegler-Natta PE catalysts
  • Exhibit 6-6: Industry structure for single site PE catalysts
  • Exhibit 7-1: Volume of different catalyst systems in 2015 and 2020
  • Exhibit 7-2: Market value of different catalyst systems in 2015 and 2020
  • Exhibit 7-3: HDPE: Opportunity Index vs market attractiveness for end-use applications
  • Exhibit 7-4: LLDPE: Opportunity Index vs market attractiveness for end-use applications
  • Exhibit 7-5: LLDPE vs mLLDPE film: Opportunity Index vs market attractiveness
  • Exhibit 7-6: Chromium catalysts: Opportunity Index vs market attractiveness by region
  • Exhibit 7-7: Ziegler-Natta catalysts for HDPE: Opportunity Index vs market attractiveness by region
  • Exhibit 7-8: Ziegler-Natta catalysts for LLDPE: Opportunity Index vs market attractiveness by region
  • Exhibit 7-9: Metallocene catalysts for LLDPE: Opportunity Index vs market attractiveness by region
  • Exhibit 7-10: Chromium catalyst suppliers: Technology position vs market position
  • Exhibit 7-11: Ziegler-Natta catalyst suppliers for HDPE plant: Technology position vs market position
  • Exhibit 7-12: Ziegler-Natta catalyst suppliers for LLDPE plant: Technology position vs market position
  • Exhibit 7-13: SSC suppliers for LLDPE plant: Technology position vs market position
  • Exhibit 7-14: Porter 5 forces definition
  • Exhibit A1: Patents and patent applications evolution during the last 10 years
  • Exhibit A2: Metallocene structure
  • Exhibit A3: General structure of a Salan catalyst
  • Exhibit A4: Specific Salan catalyst based on Hafnium
  • Exhibit A5: Example of Dow post-metallocene catalyst
  • Exhibit A6: Patent applications of INEOS
  • Exhibit A7: WIPO patent applications taken by LyondellBasell since 2014
  • Exhibit A8: US patents granted to LyondellBasell since 2013
  • Exhibit A9: WIPO Univation patent applications since 2014
  • Exhibit A10: Univation US patents granted since 2013
  • Exhibit A11: WIPO patent applications filed by Chevron Phillips Chemical since 2014
  • Exhibit A12: Single site catalyst patent applications breakdown by family
  • Exhibit A13: Metallocenes used by Chevron Phillips Chemical
  • Exhibit A14: CPChem's metallocene structures for the production of medium density film
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