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JPS648009B2 - - Google Patents
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JPS648009B2 - - Google Patents

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Publication number
JPS648009B2
JPS648009B2 JP5355680A JP5355680A JPS648009B2 JP S648009 B2 JPS648009 B2 JP S648009B2 JP 5355680 A JP5355680 A JP 5355680A JP 5355680 A JP5355680 A JP 5355680A JP S648009 B2 JPS648009 B2 JP S648009B2
Authority
JP
Japan
Prior art keywords
copolymer
ether
copolymerization
titanium
compound
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired
Application number
JP5355680A
Other languages
Japanese (ja)
Other versions
JPS56151710A (en
Inventor
Kenya Makino
Hideo Sakurai
Masaru Watanabe
Toshuki Nishimura
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
JSR Corp
Original Assignee
Japan Synthetic Rubber Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Japan Synthetic Rubber Co Ltd filed Critical Japan Synthetic Rubber Co Ltd
Priority to JP5355680A priority Critical patent/JPS56151710A/en
Priority to IT25540/80A priority patent/IT1134011B/en
Priority to NL8005845A priority patent/NL8005845A/en
Priority to US06/200,066 priority patent/US4366297A/en
Priority to DE19803040044 priority patent/DE3040044A1/en
Publication of JPS56151710A publication Critical patent/JPS56151710A/en
Publication of JPS648009B2 publication Critical patent/JPS648009B2/ja
Granted legal-status Critical Current

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  • Addition Polymer Or Copolymer, Post-Treatments, Or Chemical Modifications (AREA)
  • Transition And Organic Metals Composition Catalysts For Addition Polymerization (AREA)

Description

【発明の詳现な説明】 本発明は、溶媒に可溶なチヌグラヌ觊媒を甚い
お加工性が良奜で匕匵匷床が倧きく、ランダム性
に優れた゚チレン共重合䜓ゎムを収率よく補造す
る方法に関するものである。DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a method for producing ethylene copolymer rubber with good processability, high tensile strength, and excellent randomness in a high yield using a Ziegler catalyst soluble in a solvent. It is.

二皮以䞊のオレフむンをランダムに共重合させ
るこずによりゎム状共重合䜓を補造する觊媒ずし
おは、埓来均䞀系バナゞりム化合物ず有機アルミ
ニりム化合物ずの組合せ觊媒が倚く甚いられおい
る。 As a catalyst for producing a rubber-like copolymer by randomly copolymerizing two or more types of olefins, a combination catalyst of a homogeneous vanadium compound and an organoaluminum compound has conventionally been widely used.

しかしながら、これら均䞀系バナゞりム觊媒は
䞀般に重合時に極めお倱掻しやすく、実甚的な重
合枩床である30〜60℃では掻性はあたり高くな
い。 However, these homogeneous vanadium catalysts are generally very easily deactivated during polymerization, and their activity is not very high at practical polymerization temperatures of 30 to 60°C.

䞀方、重合時の倱掻が比范的少ない觊媒ずしお
は、チタン化合物ず有機アルミニりム化合物ずの
組合せ觊媒が䞀般に知られおいる。しかしこのチ
タン化合物を觊媒ずしお甚いるず各オレフむンが
それぞれ単独重合し易く、それぞれの単独重合䜓
の混合物ずなるか、あるいは共重合しおもブロツ
ク状に共重合しやすい。埓぀おチタン系觊媒によ
るゎム状匟性共重合䜓の補造はこれたで成功しお
いない。 On the other hand, a combination catalyst of a titanium compound and an organoaluminum compound is generally known as a catalyst that is relatively less deactivated during polymerization. However, when this titanium compound is used as a catalyst, each olefin is likely to be homopolymerized, forming a mixture of individual homopolymers, or copolymerizing into a block shape. Therefore, the production of rubber-like elastic copolymers using titanium-based catalysts has not been successful so far.

最近チタン系觊媒を甚いお、゚チレン・α−オ
レフむン匟性共重合䜓を補造しようずする特蚱が
いく぀か提出されおいる。その䟋ずしおは特開昭
49−51381号公報、特開昭50−117886号公報、特
開昭53−104687号公報などがある。これらは担䜓
䞊にチタン化合物を担持した固䜓觊媒成分ず有機
アルミニりム化合物成分ずの組合せ觊媒で゚チレ
ンずα−オレフむンをランダムに共重合させよう
ずするものであるが、生成共重合䜓のランダム性
が良奜でないため、重合時の炭化氎玠溶媒に䞀郚
析出する。埓぀おこれら觊媒を䜿甚する限り溶液
重合で実斜するこずは困難である。 Recently, several patents have been filed for producing ethylene/α-olefin elastic copolymers using titanium-based catalysts. An example of this is JP-A-Sho.
Examples include JP-A No. 49-51381, JP-A-50-117886, and JP-A-53-104687. These attempts to randomly copolymerize ethylene and α-olefin using a combination catalyst of a solid catalyst component supporting a titanium compound on a carrier and an organoaluminium compound component, but the randomness of the resulting copolymer is Because it is not good, it partially precipitates in the hydrocarbon solvent during polymerization. Therefore, it is difficult to perform solution polymerization using these catalysts.

たた生成したポリマヌはプラスチツク様であ
り、ゎム分野には䜿甚しにくい。そこで本発明者
らは、固䜓のチタン系觊媒ではオレフむンのラン
ダム共重合䜓の補造は困難であるず考え、溶液状
態のチタン化合物を甚いる方法に぀いお研究を詊
みた。しかしながら、有機溶媒に可溶でオレフむ
ン重合掻性を有するチタン化合物ずしおは四塩化
チタン、チタントリアセチルアセトネヌトおよび
テトラブトキシチタンがあるが、これらチタン化
合物ず有機アルミニりム化合物の組合せ觊媒を甚
いお二皮以䞊のオレフむンを共重合させるずそれ
ぞれの単独重合䜓の混合物、たたはブロツク共重
合䜓が生成しやすくゎム状共重合䜓は埗られな
い。 Furthermore, the produced polymer is plastic-like and difficult to use in the rubber field. Therefore, the present inventors thought that it would be difficult to produce a random copolymer of olefin using a solid titanium-based catalyst, and attempted to research a method using a titanium compound in a solution state. However, titanium compounds that are soluble in organic solvents and have olefin polymerization activity include titanium tetrachloride, titanium triacetylacetonate, and tetrabutoxytitanium. When these olefins are copolymerized, a mixture of each homopolymer or a block copolymer is likely to be produced, and a rubber-like copolymer cannot be obtained.

本発明者らは、ランダム共重合を行なうにはあ
らかじめ四塩化チタンを液状に保ち぀぀還元する
こずが必芁であろうず考えた。 The present inventors thought that in order to perform random copolymerization, it would be necessary to reduce titanium tetrachloride in advance while keeping it in a liquid state.

埓来固䜓の䞉塩化チタンを補造する方法には
皮々の方法が公知である。たずえば、四塩化チタ
ンを金属チタン、金属アルミニりム、有機アルミ
ニりム化合物、有機マグネシりム化合物、氎玠な
どで還元する方法である。これらのうち四塩化チ
タンを氎玠で還元しお埗られた䞉塩化チタンは䞍
玔物の混入が少なく、たた目的に応じお、必芁量
の他の金属化合物を添加するこずができ、利甚䟡
倀が高い。 Conventionally, various methods are known for producing solid titanium trichloride. For example, there is a method in which titanium tetrachloride is reduced with metallic titanium, metallic aluminum, an organoaluminum compound, an organomagnesium compound, hydrogen, or the like. Among these, titanium trichloride obtained by reducing titanium tetrachloride with hydrogen has a high utility value because it contains few impurities and can be added with the required amount of other metal compounds depending on the purpose.

四塩化チタンを氎玠で還元しお固䜓の䞉塩化チ
タンを埗る方法ずしおは四塩化チタンず氎玠を
800℃の高枩、高圧䞋で接觊させる方法、高電
圧䞋に無静攟電䞭で四塩化チタンず氎玠を接觊さ
せる方法が知られおいる。しかしながらこれらの
公知の方法を甚いお、四塩化チタンを液状に保ち
぀぀還元するこずは䞍可胜である。 A method to obtain solid titanium trichloride by reducing titanium tetrachloride with hydrogen is to reduce titanium tetrachloride and hydrogen.
A method of contacting titanium tetrachloride and hydrogen at a high temperature of 800°C under high pressure, and a method of contacting titanium tetrachloride with hydrogen under high voltage without static discharge are known. However, using these known methods, it is impossible to reduce titanium tetrachloride while keeping it in a liquid state.

本発明者らは、おだやかな条件䞋に短時間で、
しかも安䟡に四ハロゲン化チタンを氎玠で還元し
䞉ハロゲン化チタンを含む液状物を補造する方法
を長幎にわたり鋭意研究しおきた。 In a short period of time under mild conditions, the present inventors
Moreover, for many years, we have been intensively researching a method for producing a liquid material containing titanium trihalide by reducing titanium tetrahalide with hydrogen at low cost.

その結果、有機溶媒䞭で、゚ヌテルず少なくず
も皮の呚期埋衚第、、、族金属
たたはその化合物の存圚䞋に四ハロゲン化チタン
を、(1)氎玠で凊理しお埗られる液状物もしくは(2)
氎玠ず有機マグネシりム化合物およびたたは有
機アルミニりム化合物で凊理しお埗られる液状物
ず有機アルミニりム化合物ずを組合せお觊媒ず
し、゚チレンずプロピレンたたはおよびブテン
−の共重合を行な぀たずころ驚くべきこずに極
めお高い掻性を瀺し、か぀ランダム性に優れ加工
性が良奜で匕匵匷床の倧きな実質的に非晶性のゎ
ム状匟性共重合䜓が埗られるこずを芋出し本発明
に到達した。 As a result, a liquid obtained by treating titanium tetrahalide with (1) hydrogen in the presence of ether and at least one Group B, B, B, metal of the periodic table or its compound in an organic solvent. thing or (2)
A surprising thing happened when copolymerization of ethylene and propylene or/and butene-1 was carried out using a combination of a liquid obtained by treating hydrogen with an organomagnesium compound and/or an organoaluminum compound and an organoaluminum compound as a catalyst. The present inventors have discovered that it is possible to obtain a substantially amorphous rubber-like elastic copolymer that exhibits extremely high activity, excellent randomness, good processability, and high tensile strength.

すなわち、本発明は、(A)有機溶媒䞭で、゚ヌテ
ルず少なくずも皮の呚期埋衚第、、
、族金属たたはその化合物の存圚䞋に四ハロ
ゲン化チタンを、(1)氎玠で凊理しお埗られる液状
物もしくは(2)氎玠ず有機マグネシりム化合物およ
びたたは有機アルミニりム化合物で凊理しお埗
られる液状物ず、(B)有機アルミニりム化合物から
成る觊媒を甚い、゚チレンずプロピレンたたは
およびブテン−を共重合させるこずを特城ずす
る゚チレン共重合䜓ゎムの補造方法を提䟛するも
のである。 That is, the present invention provides (A) an ether and at least one type of periodic table B in an organic solvent.
B. A liquid obtained by treating titanium tetrahalide in the presence of a group metal or its compound with (1) hydrogen or (2) hydrogen and an organomagnesium compound and/or an organoaluminum compound. Ethylene and propylene or/and
The present invention provides a method for producing an ethylene copolymer rubber, which comprises copolymerizing ethylene copolymer rubber and butene-1.

以䞋に本発明をさらに詳现に説明する。 The present invention will be explained in more detail below.

本発明で甚いうる觊媒成分(A)は、有機溶媒䞭
で、゚ヌテルず少なくずも皮の呚期埋衚第
、、、族金属たたはその化合物の存
圚䞋に四ハロゲン化チタンを、(1)氎玠で凊理しお
埗られる液状物もしくは(2)氎玠ず有機マグネシり
ム化合物およびたたは有機アルミニりム化合物
で凊理しお埗られる液状物である。 The catalyst component (A) that can be used in the present invention comprises titanium tetrahalide (1 ) a liquid obtained by treatment with hydrogen; or (2) a liquid obtained by treatment with hydrogen and an organomagnesium compound and/or an organoaluminum compound.

本発明で甚いうる四ハロゲン化チタンずしお
は、四塩化チタン、四臭化チタン、四ペり化チタ
ンであり、これらの混合物を甚いるこずもでき
る。 Titanium tetrahalides that can be used in the present invention include titanium tetrachloride, titanium tetrabromide, and titanium tetraiodide, and mixtures thereof can also be used.

氎玠は高玔床のものが奜たしい。氎玠䞭に含た
れる酞玠たたは含酞玠化合物CO、CO2が
50ppm以䞋、奜たしくは20ppm以䞋の氎玠が甚い
られる。 High purity hydrogen is preferred. Oxygen or oxygen-containing compounds (CO, CO 2 ) contained in hydrogen
Up to 50 ppm, preferably up to 20 ppm of hydrogen is used.

本発明で甚いる゚ヌテルは、䞀般匏 R1OR2 
(2) 匏䞭R1、R2は炭玠数〜20の、奜たしくは炭
玠数〜12の同䞀又は異なるアルキル基、アルケ
ニル基、アリヌル基もしくはアラルキル基であ
るで衚わされる゚ヌテル類が䜿甚されるが、そ
れらの具䜓䟋ずしおは以䞋の゚ヌテルが挙げられ
る。 The ether used in the present invention has the general formula R 1 OR 2 (2) (wherein R 1 and R 2 are the same or different alkyl groups or alkenyl groups having 1 to 20 carbon atoms, preferably 2 to 12 carbon atoms, Ethers represented by aryl or aralkyl groups are used, and specific examples thereof include the following ethers.

(1) ゞアルキル゚ヌテル ゞ゚チル゚ヌテル、ゞ−−プロピル゚ヌテ
ル、ゞ−−ブチル゚ヌテル、ゞ−−ヘキシ
ル゚ヌテル、ゞ−−オクチル゚ヌテル、ゞ−
−デシル゚ヌテル、ゞ−−ドデシル゚ヌテ
ル、ヘキシルオクチル゚ヌテル、ゞシクロヘキ
シル゚ヌテル等 (2) ゞアルケニル゚ヌテル ビス−オクテニル゚ヌテル、ビス
−デシニル゚ヌテル、−オクテニル−−
デシニル゚ヌテル等 (3) ゞアラキル゚ヌテル ビスベンゞル゚ヌテル等 (4) アルキルアルケニル゚ヌテル −オクチル−−デシニル゚ヌテル、−
デシル−−デシニル゚ヌテル等 (5) アルキルアラルキル゚ヌテル −オクチルベンゞル゚ヌテル、−デシル
ベンゞル゚ヌテル等 (6) アラルキルアルケニル゚ヌテル −オクテニルベンゞル゚ヌテル等 (7) アルキルアリヌル゚ヌテル アニ゜ヌル等 (8) ゞアリヌル゚ヌテル ゞプニル゚ヌテル等 である。これらの゚ヌテルは皮以䞊混合しお䜿
甚するこずができる。これらの゚ヌテルのうち奜
たしくは(1)匏のR1、R2がアルキル基である゚ヌ
テルである。(1) Dialkyl ether diethyl ether, di-n-propyl ether, di-n-butyl ether, di-n-hexyl ether, di-n-octyl ether, di-
n-decyl ether, di-n-dodecyl ether, hexyl octyl ether, dicyclohexyl ether, etc. (2) Dialkenyl ether bis(1-octenyl) ether, bis(1-octenyl) ether,
-decynyl)ether, 1-octenyl-9-
Decynyl ether, etc. (3) Diarakyl ether Bis(benzyl) ether, etc. (4) Alkyl alkenyl ether n-octyl-1-decynyl ether, n-
Decyl-1-decynyl ether, etc. (5) Alkyl aralkyl ether n-octyl benzyl ether, n-decyl benzyl ether, etc. (6) Aralkyl alkenyl ether 1-octenyl benzyl ether, etc. (7) Alkylaryl ether Anisole, etc. (8) Diaryl ether, diphenyl ether, etc. These ethers can be used in combination of two or more. Among these ethers, ethers in which R 1 and R 2 of formula (1) are alkyl groups are preferred.

本発明で甚い埗る呚期埋衚第、、
、族金属たたはその化合物ずしおは次のよう
なものが挙げられる。金属ずしおはたずえば銅、
銀、亜鉛、チタン、ゞルコニりム、鉄、コバル
ト、ニツケル、ルテニりム、ロゞりム、パラゞり
ム、むリゞりム、癜金などの金属、これらの金属
の合金、粉末、粒状、スポンゞなどの固䜓、たた
はカヌボン、アルミナ、シリカなどにこれらの金
属を担持した粉末、粒状、顆粒、ペレツトなどが
䜿甚できる。たたこれらの金属の化合物ずしおは
塩化物、酞化物、氎玠化物、硫化物、硫酞塩、硝
酞塩などの化合物である。たずえば塩化第銅、
氎玠化ゞルコニりム、氎玠化チタン、塩化第
鉄、塩化コバルト、塩化ニツケル、塩化パラゞり
ム、塩化癜金、塩化ロゞりム、塩化むリゞりム、
酞化第鉄、酞化パラゞりム、酞化癜金、硫化パ
ラゞりム、硫化癜金、硫酞パラゞりム、硫酞癜
金、硝酞パラゞりム、硝酞コバルト、硝酞ロゞり
ム、硝酞癜金などである。これらの金属たたはこ
れらの金属化合物に少量の有機物、無機物を添加
しお倉性した化合物も本質的に本発明の範ちゆう
に入るものである。これらの化合物を皮以䞊混
合しお甚いるこずもできる。これらの金属たたは
化合物のうち奜たしいものは呚期埋衚第、
、および族の金属たたは第族金属の化
合物もしくは塩化第銅、チタンたたはゞルコン
の氎玠化物であり、特に奜たしくは第族金属ず
その化合物である。最も奜たしくはパラゞりム、
癜金の金属たたはその化合物である。 Periodic table B, B, which can be used in the present invention
Examples of Group B metals or compounds thereof include the following. Examples of metals include copper,
Metals such as silver, zinc, titanium, zirconium, iron, cobalt, nickel, ruthenium, rhodium, palladium, iridium, platinum, alloys of these metals, powders, granules, solids such as sponge, or carbon, alumina, silica, etc. Powders, granules, granules, pellets, etc. supporting these metals can be used. Compounds of these metals include chlorides, oxides, hydrides, sulfides, sulfates, and nitrates. For example, cuprous chloride,
Zirconium hydride, titanium hydride, primary chloride
Iron, cobalt chloride, nickel chloride, palladium chloride, platinum chloride, rhodium chloride, iridium chloride,
These include ferrous oxide, palladium oxide, platinum oxide, palladium sulfide, platinum sulfide, palladium sulfate, platinum sulfate, palladium nitrate, cobalt nitrate, rhodium nitrate, and platinum nitrate. Compounds modified by adding small amounts of organic or inorganic substances to these metals or these metal compounds also essentially fall within the scope of the present invention. A mixture of two or more of these compounds can also be used. Among these metals or compounds, preferred are metals or compounds listed in Periodic Table B,
B, B and group metals or compounds of group metals or hydrides of cuprous chloride, titanium or zircon; particularly preferred are group metals and their compounds. Most preferably palladium,
Platinum metal or its compounds.

觊媒成分(A)を調補する際䜿甚しうる有機溶媒ず
しおは、炭化氎玠たたはハロゲン化炭化氎玠であ
る。 Organic solvents that can be used in preparing the catalyst component (A) are hydrocarbons or halogenated hydrocarbons.

炭化氎玠ずしおは、−ベンタン、−ヘキサ
ン、−ヘプタン、−オクタン、−デカン、
ケロシン、流動パラフむンのような炭玠数〜20
の飜和脂肪族炭化氎玠が最適であるが、シクロヘ
キサン、メチルシクロヘキサン等の炭玠数〜12
の飜和脂環匏化氎玠、ベンれン、トル゚ン等の炭
玠数〜の芳銙族炭化氎玠などでもよい。 Hydrocarbons include n-bentane, n-hexane, n-heptane, n-octane, n-decane,
Carbon number 5-20 like kerosene and liquid paraffin
Saturated aliphatic hydrocarbons having 5 to 12 carbon atoms such as cyclohexane and methylcyclohexane are most suitable.
Saturated alicyclic hydrogen, benzene, toluene, and other aromatic hydrocarbons having 6 to 9 carbon atoms may also be used.

ハロゲン化炭化氎玠ずしおは、炭玠数〜12の
飜和脂肪族炭化氎玠のハロゲン化物、炭玠数〜
12の飜和脂環匏炭化氎玠のハロゲン化物および炭
玠数〜の芳銙族炭化氎玠のハロゲン化物など
があるが、以䞋にその具䜓䟋を瀺す。 Examples of halogenated hydrocarbons include halides of saturated aliphatic hydrocarbons having 1 to 12 carbon atoms, and
Examples include halides of 12 saturated alicyclic hydrocarbons and halides of aromatic hydrocarbons having 6 to 9 carbon atoms, and specific examples thereof are shown below.

飜和脂肪族炭化氎玠のハロゲン化物 メチレンクロラむド、クロロホルム、四塩化炭
玠、モノクロル゚タン、ペり化゚チル、−
ゞクロル゚タン、−ゞクロル゚タン、
−トリクロル゚タン、−テ
トラクロル゚チレン、塩化−ブチル、ペり化
−ブチル等、 飜和脂環匏炭化氎玠のハロゲン化物 クロルシクロヘキサン等 芳銙族炭化氎玠のハロゲン化物 クロルベンれン、臭化ベンれン、ペり化ベンれ
ン、オルトゞクロルベンれン等 これらのハロゲン化炭化氎玠溶媒のうち、奜た
しくは炭玠数〜12の飜和脂肪族炭化氎玠のハロ
ゲン化物が甚いられる。これらの炭化氎玠溶媒、
ハロゲン化炭化氎玠溶媒は皮以䞊混合しお甚い
るこずもできる。Halides of saturated aliphatic hydrocarbons Methylene chloride, chloroform, carbon tetrachloride, monochloroethane, ethyl iodide, 1,2-
dichloroethane, 1,1-dichloroethane, 1,
1,2-trichloroethane, 1,1,2,2-tetrachloroethylene, n-butyl chloride, n-iodide
- Halides of saturated alicyclic hydrocarbons such as butyl, halides of aromatic hydrocarbons such as chlorocyclohexane, chlorobenzene, benzene bromide, benzene iodide, orthodichlorobenzene, etc. Among these halogenated hydrocarbon solvents, preferred are A halide of a saturated aliphatic hydrocarbon having 1 to 12 carbon atoms is used. These hydrocarbon solvents,
Two or more halogenated hydrocarbon solvents may be used as a mixture.

これらの有機溶媒のうち、炭化氎玠溶媒を甚い
るずきは匏(1)で衚わされる゚ヌテルのうちR1、
R2が炭玠数〜20の゚ヌテルを甚いるこずが奜
たしい。 Among these organic solvents, when using a hydrocarbon solvent, R 1 of the ether represented by formula (1),
It is preferable to use an ether in which R 2 has 6 to 20 carbon atoms.

本発明で甚いられる有機マグネシりム化合物ず
しおは䞀般匏 RMgX 
(2) 匏䞭は炭玠数〜20の、奜たしくは炭玠数
〜12の炭化氎玠基、はず同じ炭化氎玠基、
、たたは原子を介しお結合する炭玠数〜
20の、奜たしくは〜12の炭化氎玠基、たたはハ
ロゲン原子を瀺す。で衚わされるものであり、
該匏䞭のが盎鎖状アルキル基、アルケニル基で
ある化合物が特に奜たしい。 The organomagnesium compound used in the present invention has the general formula RMgX...(2) (wherein R has 1 to 20 carbon atoms, preferably 1 carbon number)
~12 hydrocarbon groups, X is the same hydrocarbon group as R,
1 to 1 carbon atoms bonded via N, O or S atoms
20, preferably 1 to 12 hydrocarbon groups or halogen atoms. ), and
Particularly preferred are compounds in which R in the formula is a linear alkyl group or alkenyl group.

䜿甚される有機マグネシりム化合物の䟋ずしお
は、たずえばゞ゚チルマグネシりム、ゞブチルマ
グネシりム、゚チルマグネシりムクロラむド、ブ
チルマグネシりムクロラむド、オクチルマグネシ
りムクロラむド、゚チルマグネシりムブロマむ
ド、ブチルマグネシりムブロマむド、゚チルマグ
ネシりムアむオダむド、ブチルマグネシりムアむ
オダむド、オクチルマグネシりムアむオダむド、
゚チル−ブトキシマグネシりム、−ブチル
−ブトキシマグネシりム、ゞ゚チルアミノ゚チル
マグネシりム、ゞ゚チルアミノ−ブチルマグネ
シりム、ゞ−−ブチルアミノ−ブチルマグネ
シりム、゚チル−ブチルチオマグネシりム、
−ブチル−ブチルチオマグネシりムなどが挙げ
られる。有機マグネシりム化合物は皮以䞊の䜵
甚も可胜である。 Examples of organomagnesium compounds used include, for example, diethylmagnesium, dibutylmagnesium, ethylmagnesium chloride, butylmagnesium chloride, octylmagnesium chloride, ethylmagnesium bromide, butylmagnesium bromide, ethylmagnesium iodide, butylmagnesium iodide, octylmagnesium iodide,
Ethyl n-butoxymagnesium, n-butyl n
-butoxymagnesium, diethylaminoethylmagnesium, diethylamino n-butylmagnesium, di-n-butylamino n-butylmagnesium, ethyl n-butylthiomagnesium, n
-butyl n-butylthiomagnesium and the like. Two or more types of organomagnesium compounds can also be used in combination.

たたマグネシりム以倖の呚期埋衚第〜族の
有機金属化合物を少量䜵甚するこずもできる。 Further, a small amount of an organometallic compound of Groups 1 to 10 of the periodic table other than magnesium may also be used.

本発明で觊媒成分(A)を調補する際䜿甚しうる有
機アルミニりム化合物ずしおはたずえば埌述する
觊媒成分(B)の内の䞀般匏(2)で衚わされる化合物が
挙げられる。 Examples of organoaluminum compounds that can be used in preparing the catalyst component (A) in the present invention include compounds represented by the general formula (2) of the catalyst component (B) described below.

本発明においお、觊媒成分(A)の調補方法は特に
限定されるものではない。たずえば(1)有機溶媒
䞭、゚ヌテルず呚期埋衚第、、、
族金属たたはその化合物の存圚䞋に四ハロゲン化
チタンを加え、倧気圧䞋に氎玠ガスを吹き蟌む方
法、(2)加圧反応噚に有機溶媒、゚ヌテル、呚期埋
衚第、、、族金属たたはその化合
物、四ハロゲン化チタンを加え、氎玠ガスを圧入
し接觊する方法、(3)呚期埋衚第、、
、族金属たたはその化合物の存圚䞋に倧気圧
䞋たたは加圧䞋においお、四ハロゲン化チタンず
゚ヌテルの有機溶媒液ず氎玠ガスを向流匏に接觊
させる方法、(4)有機溶媒䞭、゚ヌテルず呚期埋衚
第、、、族金属たたはその化合物
の存圚䞋に、四ハロゲン化チタンを加え、倧気圧
䞋に氎玠ガスを吹き蟌んだ埌、有機マグネシりム
化合物を添加する方法、(5)有機溶媒䞭、゚ヌテル
の存圚䞋に四ハロゲン化チタンず有機マグネシり
ム化合物を接觊させた埌、呚期埋衚第、
、、族金属たたはその化合物を加え、倧
気圧䞋に氎玠ガスを吹き蟌む方法、(6)加圧反応噚
に有機溶媒、゚ヌテル、呚期埋衚第、、
、族金属たたはその化合物、四ハロゲン化
チタを加え、氎玠ガスを圧入しお反応させた埌、
有機マグネシりム化合物を添加する方法、(7)呚期
埋衚第、、、族金属たたはその化
合物の存圚䞋に、倧気圧䞋たたは加圧䞋におい
お、四ハロゲン化チタンず゚ヌテルの有機溶媒液
ず氎玠ガスを向流匏に接觊させた埌、有機マグネ
シりム化合物を添加する方法などが甚いられる。
この液状物はそのたた䜿甚しおも良いし、必芁に
応じお呚期埋衚第、、、族金属た
たはその化合物を分離しお䜿甚するこずもでき
る。 In the present invention, the method for preparing the catalyst component (A) is not particularly limited. For example, (1) in an organic solvent, ether and periodic table B, B, B,
A method in which titanium tetrahalide is added in the presence of a group metal or its compound and hydrogen gas is blown under atmospheric pressure. A method of adding a metal or its compound, titanium tetrahalide, and contacting it by pressurizing hydrogen gas, (3) periodic table B, B,
B. A method of contacting an organic solvent solution of titanium tetrahalide and ether with hydrogen gas in a countercurrent manner under atmospheric pressure or under pressure in the presence of a group metal or its compound; A method in which titanium tetrahalide is added in the presence of a group B, B, B metal of the periodic table or a compound thereof, hydrogen gas is blown under atmospheric pressure, and then an organomagnesium compound is added, (5) organic After contacting the titanium tetrahalide and the organomagnesium compound in the presence of ether in a solvent,
A method of adding B, B, group metal or its compound and blowing hydrogen gas under atmospheric pressure, (6) a method of adding an organic solvent, ether, periodic table B, B, to a pressurized reactor,
After adding B, group metal or its compound, and titanium tetrahalide and reacting by injecting hydrogen gas,
A method of adding an organomagnesium compound, (7) an organic solvent solution of titanium tetrahalide and ether in the presence of a metal of Group B, B, B of the periodic table or a compound thereof, at atmospheric pressure or under pressure. A method is used in which an organomagnesium compound is added after contacting hydrogen gas in a countercurrent manner.
This liquid material may be used as it is, or metals of groups B, B, and B of the periodic table or compounds thereof may be separated and used as necessary.

氎玠は窒玠、アルゎン、ヘリりムなどの䞍掻性
ガスず混合しお甚いるこずができる。氎玠を接觊
するずきの圧力は倧気圧から100Kgcm2の範囲が
奜たしく甚いられる。氎玠を接觊するずきの枩床
は−50℃〜200℃、奜たしくは−30℃〜150℃であ
る。 Hydrogen can be used in combination with an inert gas such as nitrogen, argon, helium, etc. The pressure used when contacting with hydrogen is preferably in the range of atmospheric pressure to 100 kg/cm 2 . The temperature when contacting with hydrogen is -50°C to 200°C, preferably -30°C to 150°C.

たた四ハロゲン化チタンに氎玠ガスを接觊し
お、觊媒成分(A)を調補するずき、少量のα−オレ
フむン、たずえばプロピレン、ブテン−、ヘキ
シル−などを存圚させるこずも可胜である。 Further, when the catalyst component (A) is prepared by contacting titanium tetrahalide with hydrogen gas, it is also possible to have a small amount of α-olefin, such as propylene, 1-butene, 1-hexyl, etc., present.

これらの方法で䜿甚される四ハロゲン化チタン
ず゚ヌテルずのモル比は奜たしくは0.2〜
20、特に奜たしくは0.5〜の範囲
である。呚期埋衚第、、、族金属
たたはその化合物は觊媒量存圚させれば良く、倚
量に䜿甚すれば䞍経枈である。すなわち四ハロゲ
ン化チタンずのモル比は0.00001〜10奜たしくは
0.0001〜である。有機マグネシりム化合物たた
は有機アルミニりム化合物ず四ハロゲン化チタン
ずのモル比は0.05〜0.9の範囲であり、奜たしく
は0.1〜0.75である。有機マグネシりム化合物ず
有機アルミニりム化合物を䜵甚するずきは、䞡者
のモル数の和がチタン化合物に察し0.05〜0.9モ
ル比奜たしくは0.1〜0.75である。 The molar ratio of titanium tetrahalide and ether used in these methods is preferably from 1:0.2 to
The ratio is 1:20, particularly preferably in the range of 1:0.5 to 1:5. It is sufficient that metals of groups B, B, B of the periodic table or their compounds are present in catalytic amounts, and it is uneconomical if they are used in large amounts. That is, the molar ratio with titanium tetrahalide is preferably 0.00001 to 10.
It is 0.0001 to 1. The molar ratio of the organomagnesium compound or organoaluminium compound to titanium tetrahalide is in the range of 0.05 to 0.9, preferably 0.1 to 0.75. When an organomagnesium compound and an organoaluminum compound are used together, the sum of the moles of both is 0.05 to 0.9 (molar ratio) to the titanium compound, preferably 0.1 to 0.75.

本発明で甚いる觊媒成分(B)の有機アルミニりム
化合物ずしおは、䞀般匏 A1RnX3-n 
(2) は氎玠たたは炭玠数〜12の炭化氎玠基、
はハロゲンたたは炭玠数〜12のアルコキシ基、
≊≊で衚わされる有機アルミニりム化合
物が䞀般に適圓である。皮以䞊の化合物を組合
せおもよい。具䜓的な有機アルミニりム化合物ず
しおは、䟋えばトリ゚チルアルミニりム、トリ
−プロピルアルミニりム、トリ−−ブチルアル
ミニりム、トリ−−オクチルアルミニりム、ト
リ−メチルペンチルアルミニりム、ゞ−
−ブチルアルミニりムハむドラむド、゚チルアル
ミニりムセスキクロラむド、ゞ゚チルアルミニり
ムクロラむド、゚チルアルミニりムゞクロラむ
ド、ゞ゚チルアルミニりム゚トキサむド、ゞ゚チ
ルアルミニりムアむオダむドなどがある。これら
の有機アルミニりム化合物の䞭でも、トリアルキ
ルアルミニりム化合物が特に奜たしい。觊媒成分
(A)ず觊媒成分(B)ずの比はチタンずアルミニりムの
原子比で衚わされ、通垞0.2〜200の範囲
であり、奜たしくは〜50の範囲が遞ば
れる。 The organoaluminum compound of the catalyst component (B) used in the present invention has the general formula A1R n
is a halogen or an alkoxy group having 1 to 12 carbon atoms,
Organoaluminum compounds with the formula 1≩m≩3) are generally suitable. Two or more types of compounds may be combined. Specific examples of organoaluminum compounds include triethylaluminum, trinium
-propyl aluminum, tri-i-butyl aluminum, tri-n-octyl aluminum, tri(2-methylpentyl) aluminum, di-i
-butylaluminum hydride, ethylaluminum sesquichloride, diethylaluminum chloride, ethylaluminum dichloride, diethylaluminum ethoxide, diethylaluminium iodide, and the like. Among these organoaluminum compounds, trialkylaluminum compounds are particularly preferred. catalyst component
The ratio of (A) to catalyst component (B) is expressed as the atomic ratio of titanium to aluminum, and is usually in the range of 1:0.2 to 1:200, preferably in the range of 1:1 to 1:50. It will be done.

重合甚モノマヌずしおは、゚チレンずプロピレ
ン、ブテン−のαオレフむンを甚いるこずがで
きる。゚チレンず䞊蚘α−オレフむンを組合せお
共重合させるこずによりゎム状共重合䜓を埗るこ
ずができる。 As monomers for polymerization, ethylene, propylene, and α-olefins of butene-1 can be used. A rubber-like copolymer can be obtained by copolymerizing a combination of ethylene and the above α-olefin.

たた、共重合䜓ゎムの加硫を容易にするために
非共圹ポリ゚ン類のモノマヌを前蚘オレフむンモ
ノマヌず共に共重合させるこずができる。非共圹
ポリ゚ンずしおは架橋環炭化氎玠化合物、単環化
合物、耇玠環化合物、鎖状化合物、スピロ型化合
物など任意の圢匏のものから遞ばれる。具䜓的に
はゞシクロペンタゞ゚ン、トリシクロペンタゞ゚
ン、−メチル−−ノルボルナゞ゚ン、
−メチレン−−ノルボルネン、−゚チリデン
−−ノルボルネン、−む゜プロピリデン−
−ノルボルネン、−む゜プロペニル−−ノル
ボルネン、−−ブテニル−−ノルボルネ
ン、−2′−ブテニル−−ノルボルネン、シ
クロオクタゞ゚ン、ビニルシクロヘキセン、
−シクロドデカトリ゚ン、−メチル−
−テトラヒドロむンデン、
2′−ゞシクロペンテニル、トランス−−ゞ
ビニルシクロブタン、−ヘキサゞ゚ン、
−オクタゞ゚ン、−メチル−−ヘ
プタゞ゚ンなどがある。 Furthermore, in order to facilitate the vulcanization of the copolymer rubber, a non-conjugated polyene monomer can be copolymerized with the olefin monomer. The non-conjugated polyene is selected from arbitrary types such as cross-linked hydrocarbon compounds, monocyclic compounds, heterocyclic compounds, chain compounds, and spiro-type compounds. Specifically, dicyclopentadiene, tricyclopentadiene, 5-methyl-2,5-norbornadiene, 5
-methylene-2-norbornene, 5-ethylidene-2-norbornene, 5-isopropylidene-2
-norbornene, 5-isopropenyl-2-norbornene, 5-(1-butenyl)-2-norbornene, 5-(2'-butenyl)-2-norbornene, cyclooctadiene, vinylcyclohexene, 1,
5,9-cyclododecatriene, 6-methyl-
4,7,8,9-tetrahydroindene, 2,
2'-dicyclopentenyl, trans-1,2-divinylcyclobutane, 1,4-hexadiene,
Examples include 1,6-octadiene and 6-methyl-1,5-heptadiene.

重合枩床は通垞〜120℃、奜たしくは20〜80
℃である。重合圧力は通垞垞圧から50Kgcm2の範
囲である。共重合は䞀般に共重合䜓の良溶媒䞭で
共重合を行なう溶液重合法が奜適である。その際
の溶媒ずしおは、−ヘキサン、−ヘプタンな
どの炭化氎玠溶媒がよく甚いられる。共重合はバ
ツチ重合でも連続重合でもよい。共重合䜓の分子
量は必芁に応じお氎玠を甚いるこずにより任意に
調節するこずができる。 Polymerization temperature is usually 0~120℃, preferably 20~80℃
It is ℃. Polymerization pressure usually ranges from normal pressure to 50 kg/cm 2 . In general, a solution polymerization method in which copolymerization is carried out in a good solvent for the copolymer is suitable for the copolymerization. As the solvent at that time, hydrocarbon solvents such as n-hexane and n-heptane are often used. Copolymerization may be batch polymerization or continuous polymerization. The molecular weight of the copolymer can be arbitrarily adjusted by using hydrogen as necessary.

次に実斜䟋により本発明を曎に具䜓的に説明す
る。なお、実斜䟋䞭の共重合䜓の諞物性の枬定倀
はムヌニヌ粘床は予熱分、枬定分、枩床100
℃での枬定により、たたプロピレン含量は赀倖線
吞収スペクトルにより、ペヌ゜䟡は滎定法によ
り、100モゞナラス、匕匵匷床、砎断䌞び、お
よびシペアヌ硬床はJIS K6301に準じた枬定方
法により求めた倀である。 Next, the present invention will be explained in more detail with reference to Examples. In addition, the measured values of various physical properties of the copolymer in the examples are as follows: Mooney viscosity: preheating for 1 minute, measurement for 4 minutes, temperature: 100℃
The propylene content was determined by infrared absorption spectrum, the iodine number was determined by titration, and the 100% modulus, tensile strength, elongation at break, and Shore A hardness were determined by a measurement method based on JIS K6301. .

以䞋の実斜䟋および比范䟋では共重合䜓䞭の゚
チレンずプロピレンのランダム状配列の尺床ずし
お赀倖線吞収スペクトルの730cm-1ポリ゚チレン
の結晶性に起因する吞収ず720cm-1−CH2−o
の骚栌振動による吞収ずの匷床比を図のよう
にしお衚わし各々の面積を求め䞋蚘匏により蚈算
しおランダム・むンデツクスR.I.を求めた。 In the following Examples and Comparative Examples, the infrared absorption spectra of 730 cm -1 (absorption due to crystallinity of polyethylene) and 720 cm -1 ((-CH 2 - ) o
The intensity ratio (absorption due to skeletal vibration) was expressed as shown in Figure 2, and the area of each was determined and calculated using the following formula to determine the random index (RI).

R.I.の面積の面積×10
0 実斜䟋  (1) 觊媒成分(A)の調補 充分に也燥し、窒玠眮換した100mlのフラス
コに也燥した粉末状の癜金ブラツク50mgず1.2
−ゞクロル゚タン50mlず四塩化チタン10mol
を仕蟌み、぀いで撹拌䞋に−ブチル゚ヌテル
3.4mlを分間で添加した〔゚ヌテルTi2.0
モル比〕。フラスコを20℃に保ち、氎玠を0.2
minの速床で時間吹き蟌んだ。黄黒色の
溶液が生成した。この溶液を窒玠䞋で過し粉
末状の癜金ブラツクを別した。液は均䞀な
黄黒色の溶液あ぀た。 RI (%) (Area of B) / (Area of A + B) x 10
0 Example 1 (1) Preparation of catalyst component (A) 50 mg of dried powdered platinum black and 1.2 mg of dried powdered platinum black were placed in a 100 ml flask that had been thoroughly dried and purged with nitrogen.
-50 ml of dichloroethane and 10 mmol of titanium tetrachloride
and then add n-butyl ether while stirring.
3.4 ml was added over 5 minutes [Ether/Ti=2.0
(molar ratio)]. Keep the flask at 20℃ and add 0.2 hydrogen
The air was blown at a speed of /min for 2 hours. A yellow-black solution formed. The solution was filtered under nitrogen to separate the powdered platinum black. The liquid was a homogeneous yellow-black solution.

(2) 共重合 のセパラブルフラスコに撹拌矜根、䞉方
コツク、ガス吹蟌管、枩床蚈を取り付け、充分
窒玠で眮換し、也燥した。このフラスコにモレ
キナラヌシヌブスで也燥し、脱気した−ヘキ
サンを入れた。モレキナラヌシヌブスを通
しお也燥した゚チレンmin、プロピレン
min、および氎玠0.1minの混合ガス
を35℃に枩床制埡したフラスコにガス吹蟌管を
通しお10分間通気した。この埌トリ−−ブチ
ルアルミニりム(B)7.0molず前述の觊媒成分
(A)をチタン換算で0.7mol添加し、前蚘混合
ガスを前蚘流速で通気しながら共重合を開始し
た。フラスコ内の枩床を35℃に保ち30分間共重
合を行な぀た。メタノヌル50mlを重合溶液に添
加しお共重合を停止させた。共重合䞭、溶液は
均䞀であり、その間共重合䜓の析出は認められ
なか぀た。少量の老化防止剀ず氎を加えよ
く撹拌した埌、スチヌムストリツピングにより
固圢ゎムを埗た。共重合䜓収量は62ぞであ぀
た。共重合䜓の赀倖線吞収スペクトルから求め
たR.I.倀は0.4であ぀た。本実斜䟋によ぀お埗
られた共重合䜓の諞物性倀は以䞋の劂くであ
る。(2) Copolymerization A stirring blade, a three-way pot, a gas blowing tube, and a thermometer were attached to the separable flask in Step 3, and the flask was sufficiently purged with nitrogen and dried. N-hexane 2, which had been dried with molecular sieves and degassed, was placed in the flask. A mixed gas of 4/min of ethylene, 6/min of propylene, and 0.1/min of hydrogen, which had been dried through a molecular sieve, was bubbled through a gas blowing tube into a flask whose temperature was controlled at 35° C. for 10 minutes. After this, 7.0 mmol of tri-i-butylaluminum (B) and the aforementioned catalyst component were added.
0.7 mmol of (A) was added in terms of titanium, and copolymerization was started while passing the mixed gas at the above flow rate. The temperature inside the flask was maintained at 35°C and copolymerization was carried out for 30 minutes. Copolymerization was stopped by adding 50 ml of methanol to the polymerization solution. During the copolymerization, the solution was homogeneous, and no copolymer precipitation was observed during the copolymerization. After adding a small amount of anti-aging agent and 1 part of water and stirring well, a solid rubber was obtained by steam stripping. The copolymer yield was 62g. The RI value determined from the infrared absorption spectrum of the copolymer was 0.4%. The physical properties of the copolymer obtained in this example are as follows.

プロピレン含量30wt ML100℃1+474 100モゞナラス12Kgcm2 匕匵匷床50Kgcm2 砎断䌞び3000 シペアヌ硬床52 比范䟋  觊媒成分(A)に替えお四塩化チタンをそのたた觊
媒ずしお甚いるこず以倖は、実斜䟋ず同様にし
お共重合を行な぀た。共重合䞭共重合䜓が倚量に
析出し、共重合はスラリヌ状態で進行した。共重
合䜓収量は、共重合䜓䞭のプロピレン含量は
38wtであ぀た。たた共重合䜓の赀倖線吞収ス
ペクトルから求めたR.I.倀は3.1であ぀た。 Propylene content = 30wt% ML 100 ℃ 1+4 = 74 100% modulus = 12Kg/cm 2 Tensile strength = 50Kg/cm 2 Elongation at break = 3000% Shore A hardness = 52 Comparative example 1 Copolymerization was carried out in the same manner as in Example 1, except that titanium chloride was used as it was as a catalyst. A large amount of copolymer precipitated during copolymerization, and copolymerization proceeded in a slurry state. The copolymer yield is 8g, and the propylene content in the copolymer is
It was 38wt%. Furthermore, the RI value determined from the infrared absorption spectrum of the copolymer was 3.1%.

比范䟋  觊媒成分(A)に替えお四塩化チタンずゞ−−ブ
チル゚ヌテルの錯䜓チタンず゚ヌテルは等モ
ルの−ゞクロル゚タン溶液を甚いるこず
以倖は実斜䟋ず同様にしお共重合を行な぀た。
共重合䞭共重合䜓が倚量に析出し、共重合はスラ
リヌ状態で進行した。共重合䜓収量は、共重
合䜓䞭のプロピレン含量は36wtであ぀た。た
た、共重合䜓の赀倖線吞収スペクトルから求めた
R.I.倀は2.9であ぀た。Comparative Example 2 A compound was prepared in the same manner as in Example 1 except that a 1,2-dichloroethane solution of a complex of titanium tetrachloride and di-n-butyl ether (titanium and ether are equimolar) was used instead of the catalyst component (A). Polymerization was carried out.
A large amount of copolymer precipitated during copolymerization, and copolymerization proceeded in a slurry state. The copolymer yield was 6 g, and the propylene content in the copolymer was 36 wt%. In addition, the infrared absorption spectrum of the copolymer determined
The RI value was 2.9%.

比范䟋  觊媒成分(A)に替えお固䜓の䞉塩化チタン氎玠
還元品の−ゞクロル゚タンスラリヌを甚
いるこず以倖は実斜䟋ず同様にしお共重合を行
な぀た。共重合䞭共重合䜓が倚量に析出し、共重
合はスラヌ状態で進行した。共重合䜓収量は11
、共重合䜓䞭プロピレン含量は37wt、R.I.は
3.3であ぀た。Comparative Example 3 Copolymerization was carried out in the same manner as in Example 1, except that a 1,2-dichloroethane slurry of solid titanium trichloride (hydrogen-reduced product) was used in place of the catalyst component (A). During the copolymerization, a large amount of copolymer was precipitated, and the copolymerization proceeded in a slurry state. Copolymer yield is 11
g, propylene content in the copolymer is 37wt%, RI is
It was 3.3%.

実斜䟋  共重合開始から終了分前たでの25分間にわた
り−゚チリデン−−ノルボルネンのヘキサン
溶液をmlmin−゚チリデン−−ノルボ
ルネンで2.09molminの速床で䟛絊するこ
ず以倖は実斜䟋ず同様にしお共重合を行な぀
た。共重合䞭の溶液は均䞀であり、重合䞭共重合
䜓の析出は認められなか぀た。共重合䜓収量は55
であ぀た。共重合䜓の赀倖線吞収スペクトルか
ら求めたR.I.倀は0.6であ぀た。Example 2 A hexane solution of 5-ethylidene-2-norbornene was supplied at a rate of 8 ml/min (2.09 mmol/min of 5-ethylidene-2-norbornene) for 25 minutes from the start of copolymerization to 5 minutes before the end. Copolymerization was carried out in the same manner as in Example 1 except for this. The solution during copolymerization was homogeneous, and no precipitation of copolymer was observed during polymerization. Copolymer yield is 55
It was hot at g. The RI value determined from the infrared absorption spectrum of the copolymer was 0.6%.

本実斜䟋で埗られた共重合䜓の諞物性は以䞋の
劂くである。 The physical properties of the copolymer obtained in this example are as follows.

プロピレン含量32wt ペヌ゜䟡18 ML100 1+473 100モゞナラス13Kgcm2 匕匵匷床68Kgcm2 砎断䌞び3060 シペアヌ硬床53 実斜䟋  −゚チリデン−−ノルボルネンに替えおゞ
シクロペンタゞ゚ンを2.09molminの速床で
䟛絊するこず以倖は実斜䟋ず同様にしお共重合
を行な぀た。重合䞭の溶液は均䞀であり、共重合
䞭共重合䜓の析出は認められなか぀た。共重合䜓
収量は53であり、ポリマヌ䞭のプロピレン含量
は33wt、ペヌ゜䟡は19であ぀た。共重合䜓の
赀倖線吞収スペクトルから求めたR.I.倀は0.7で
あ぀た。 Propylene content = 32wt% Yoso value = 18 ML 100 1+4 = 73 100% modulus = 13Kg/cm 2 Tensile strength = 68Kg/cm 2 Elongation at break = 3060% Shore A hardness = 53 Example 3 5-ethylidene-2- Copolymerization was carried out in the same manner as in Example 2 except that dicyclopentadiene was supplied at a rate of 2.09 mmol/min instead of norbornene. The solution during polymerization was homogeneous, and no precipitation of copolymer was observed during copolymerization. The yield of the copolymer was 53 g, the propylene content in the polymer was 33 wt%, and the iodine number was 19. The RI value determined from the infrared absorption spectrum of the copolymer was 0.7%.

実斜䟋  粉末状の癜金ブラツクをパラゞりムカヌボン粉
末パラゞりム含量100mgに替えるこず以
倖は実斜䟋ず同様にしお觊媒成分(A)を調補し
た。黄黒色の均䞀溶液が埗られた。Example 4 Catalyst component (A) was prepared in the same manner as in Example 1, except that 100 mg of palladium carbon powder (palladium content 5%) was used instead of powdered platinum black. A yellow-black homogeneous solution was obtained.

共重合は実斜䟋ず同様にしお行な぀た。共重
合䞭の溶液は均䞀であり共重合䞭共重合䜓の析出
は認められなか぀た。共重合䜓収量は64であ
り、共重合䜓䞭のプロピレン含量は35wtであ
぀た。共重合䜓の赀倖線吞収スペクトルから求め
たR.I.倀は0.4であ぀た。 Copolymerization was carried out in the same manner as in Example 1. The solution during copolymerization was homogeneous, and no precipitation of copolymer was observed during copolymerization. The copolymer yield was 64 g, and the propylene content in the copolymer was 35 wt%. The RI value determined from the infrared absorption spectrum of the copolymer was 0.4%.

実斜䟋  粉末状の癜金ブラツクを粉末状に硝酞パラゞり
ムに替えるこず以倖は実斜䟋ず同様にしお觊媒
成分(A)を調補した。黄黒色の均䞀溶液が埗られ
た。Example 5 Catalyst component (A) was prepared in the same manner as in Example 1 except that powdered platinum black was replaced with powdered palladium nitrate. A yellow-black homogeneous solution was obtained.

共重合は実斜䟋ず同様にしお行な぀た。重合
䞭の溶液は均䞀であり、共重合䞭共重合䜓の析出
は認められなか぀た。共重合䜓収量は56であ
り、共重合䜓䞭のプロピレン含量は32wtであ
぀た。共重合䜓の赀倖線吞収スペクトルから求め
たR.I.倀は0.4であ぀た。 Copolymerization was carried out in the same manner as in Example 1. The solution during polymerization was homogeneous, and no precipitation of copolymer was observed during copolymerization. The copolymer yield was 56 g, and the propylene content in the copolymer was 32 wt%. The RI value determined from the infrared absorption spectrum of the copolymer was 0.4%.

実斜䟋  粉末状の癜金ブラツクを粉末状の酞化パラゞり
ム50mgに替えるこず以倖は実斜䟋ず同様にしお
觊媒成分(A)を調補した。黄黒色の均䞀溶液が埗ら
れた。Example 6 Catalyst component (A) was prepared in the same manner as in Example 1 except that 50 mg of powdered palladium oxide was used instead of powdered platinum black. A yellow-black homogeneous solution was obtained.

共重合は実斜䟋ず同様にしお行な぀た。重合
䞭の溶液は均䞀であり、共重合䞭共重合䜓の析出
は認められなか぀た。共重合䜓収量は66であ
り、共重合䜓䞭のプロピレン含量は36wtであ
぀た。共重合䜓の赀倖線吞収スペクトルから求め
たR.I.倀は0.4であ぀た。 Copolymerization was carried out in the same manner as in Example 1. The solution during polymerization was homogeneous, and no precipitation of copolymer was observed during copolymerization. The copolymer yield was 66 g, and the propylene content in the copolymer was 36 wt%. The RI value determined from the infrared absorption spectrum of the copolymer was 0.4%.

実斜䟋  (1) 觊媒成分(A)の調補 充分也燥し、窒玠眮換した100mlのステンレ
ス補オヌトクレヌブに也燥した粉末状のラネヌ
コバルトず−ゞクロル゚タン50mlず
四塩化チタン10molを仕蟌み、぀いで撹拌䞋
に−ブチル゚ヌテ3.4mlを分間で添加した
〔゚ヌテルTi20モル比〕。次に氎玠を
Kgcm2たで圧入し、100℃で10時間反応させた。
反応埌窒玠䞋で過し、粉末状のラネヌコバル
トを別した。液は均䞀な黄黒色の溶液であ
぀た。Example 7 (1) Preparation of catalyst component (A) 1 g of dried powdered Raney cobalt, 50 ml of 1,2-dichloroethane, and 10 mmol of titanium tetrachloride were charged into a 100 ml stainless steel autoclave that had been sufficiently dried and purged with nitrogen. While stirring, 3.4 ml of n-butyl ether was added over 5 minutes [ether/Ti=20 (molar ratio)]. Next, add 8 hydrogen
The mixture was pressurized to Kg/cm 2 and reacted at 100°C for 10 hours.
After the reaction, the mixture was filtered under nitrogen to separate powdered Raney cobalt. The liquid was a homogeneous yellow-black solution.

(2) 共重合 共重合は実斜䟋ず同様にしお行な぀た。重
合䞭の溶液は均䞀であり、共重合䞭共重合䜓の
析出は認められなか぀た。共重合䜓収量は45
であり、共重合䜓䞭のプロピレン含量は29wt
であ぀た。共重合䜓の赀倖線吞収スペクトル
から求めたR.I.倀は0.7であ぀た。(2) Copolymerization Copolymerization was carried out in the same manner as in Example 1. The solution during polymerization was homogeneous, and no precipitation of copolymer was observed during copolymerization. Copolymer yield is 45g
and the propylene content in the copolymer is 29wt
It was %. The RI value determined from the infrared absorption spectrum of the copolymer was 0.7%.

実斜䟋  粉末状の癜金ブラツクを粉末状の銅700mgに替
えるこず以倖は実斜䟋ず同様にしお觊媒成分(A)
を調補した。黄黒色の均䞀溶液が埗られた。Example 8 Catalyst component (A) was prepared in the same manner as in Example 1 except that 700 mg of powdered copper was used instead of powdered platinum black.
was prepared. A yellow-black homogeneous solution was obtained.

共重合は実斜䟋ず同様にしお行な぀た。共重
合䞭の溶液は均䞀であり、共重合䞭、共重合䜓の
析出は認められなか぀た。共重合䜓の収量は55
であり、共重合䜓のプロピレン含量は32wtで
あ぀た。共重合䜓の赀倖線吞収スペクトルから求
めたR.I.倀は0.5であ぀た。 Copolymerization was carried out in the same manner as in Example 1. The solution during copolymerization was homogeneous, and no precipitation of the copolymer was observed during copolymerization. The yield of copolymer is 55g
The propylene content of the copolymer was 32 wt%. The RI value determined from the infrared absorption spectrum of the copolymer was 0.5%.

実斜䟋  粉末状の癜金ブラツクを粉末状の亜鉛700mgに
替えるこず以倖は実斜䟋ず同様にしお觊媒成分
(A)を調補した。黄黒色の均䞀溶液が埗られた。Example 9 Catalyst components were prepared in the same manner as in Example 1, except that 700 mg of powdered zinc was used instead of powdered platinum black.
(A) was prepared. A yellow-black homogeneous solution was obtained.

共重合は実斜䟋ず同様にしお行な぀た。共重
合䞭の溶液は均䞀であり、共重合䞭共重合䜓の析
出は認められなか぀た。共重合䜓収量は58であ
り、共重合䜓䞭のプロピレン含量は34wtであ
぀た。共重合䜓の赀倖線吞収スペクトルから求め
たR.I.倀は0.5であ぀た。 Copolymerization was carried out in the same manner as in Example 1. The solution during copolymerization was homogeneous, and no precipitation of copolymer was observed during copolymerization. The copolymer yield was 58 g, and the propylene content in the copolymer was 34 wt%. The RI value determined from the infrared absorption spectrum of the copolymer was 0.5%.

実斜䟋 10 粉末状癜金ブラツクを粉末状のチタニりムに替
えるこず以倖は実斜䟋ず同様にしお觊媒成分(A)
を調補した。黄黒色の均䞀溶液が埗られた。Example 10 Catalyst component (A) was prepared in the same manner as in Example 1 except that powdered platinum black was replaced with powdered titanium.
was prepared. A yellow-black homogeneous solution was obtained.

共重合は実斜䟋ず同様にしお行な぀た。重合
䞭の溶液は均䞀であり、共重合䞭共重合䜓の析出
は認められなか぀た。共重合䜓収量は56であ
り、共重合䜓䞭のプロピレン含量は33wtであ
぀た。共重合䜓の赀倖線吞収スペクトルから求め
たR.I.倀は0.5であ぀た。 Copolymerization was carried out in the same manner as in Example 1. The solution during polymerization was homogeneous, and no precipitation of copolymer was observed during copolymerization. The copolymer yield was 56 g, and the propylene content in the copolymer was 33 wt%. The RI value determined from the infrared absorption spectrum of the copolymer was 0.5%.

実斜䟋 11 −ゞクロル゚タンを−ヘキサンに、
−ブチル゚ヌテル3.4mlを−オクチル゚ヌテル
7.6mlに替えるこず以倖は実斜䟋ず同様にしお
觊媒成分(A)を調補した。黄黒色の均䞀溶液が埗ら
れた。Example 11 1,2-dichloroethane to n-hexane, n
-3.4 ml of butyl ether to n-octyl ether
Catalyst component (A) was prepared in the same manner as in Example 1 except that the amount was changed to 7.6 ml. A yellow-black homogeneous solution was obtained.

共重合は実斜䟋ず同様にしお行な぀た。共重
合䞭の溶液は均䞀であり、共重合䞭共重合䜓の析
出は認められなか぀た。共重合䜓収量は60であ
り、共重合䜓䞭のプロピレン含量は32wtであ
぀た。共重合䜓の赀倖線吞収スペクトルから求め
たR.I.倀は0.5であ぀た。 Copolymerization was carried out in the same manner as in Example 1. The solution during copolymerization was homogeneous, and no precipitation of copolymer was observed during copolymerization. The copolymer yield was 60 g, and the propylene content in the copolymer was 32 wt%. The RI value determined from the infrared absorption spectrum of the copolymer was 0.5%.

実斜䟋 12 (1) 觊媒成分(A)の調補 充分に也燥し、窒玠眮換した100mlのフラス
コに也燥した粉末状のパラゞりム・カヌボン
100mgず−ゞクロル゚タン50mlず四塩化
チタン10molを仕蟌み、぀いで撹拌䞋に−
ブチル゚ヌテル3.4mlを分間で添加した。フ
ラスコ内を10℃に保ち、氎玠ガスを0.2
minの速床で時間吹き蟌んだ。黄黒色の溶液
が生成した。窒玠䞋で過し、粉末状のパラゞ
りム・カヌボンPd含量を別した。
この液を℃に冷华し、撹拌䞋に−ブチル
マグネシりムアむオダむドmolを−ブチ
ル゚ヌテル溶液ずしお10分間で加えた−ブ
チル゚ヌテルず四塩化チタンのモル比は2.6で
あ぀た。黒耐色の均䞀な溶液を埗た。Example 12 (1) Preparation of catalyst component (A) Dry powdered palladium-carbon in a 100 ml flask that has been thoroughly dried and purged with nitrogen.
100mg of titanium tetrachloride, 50ml of 1,2-dichloroethane, and 10mmol of titanium tetrachloride were added, and then n-
3.4 ml of butyl ether was added over 5 minutes. Keep the inside of the flask at 10℃ and add hydrogen gas at 0.2/
It was blown for 2 hours at a speed of min. A yellow-black solution formed. It was filtered under nitrogen to separate the powdered palladium on carbon (Pd content 5%).
This liquid was cooled to 0° C., and while stirring, 2 mmol of n-butylmagnesium iodide was added as a solution in n-butyl ether over 10 minutes (the molar ratio of n-butyl ether and titanium tetrachloride was 2.6). A dark brown homogeneous solution was obtained.

(2) 共重合 共重合は実斜䟋ず同様に行な぀た。共重合
䞭の溶液は均䞀であり、重合䞭共重合䜓の析出
は認められなか぀た。共重合䜓の収量は113
であり、ポリマヌ䞭のプロピレン含量は37wt
であ぀た。共重合䜓の赀倖線吞収スペクトル
から求めたR.I.倀は0.3であ぀た。(2) Copolymerization Copolymerization was carried out in the same manner as in Example 1. The solution during copolymerization was homogeneous, and no precipitation of copolymer was observed during polymerization. The yield of copolymer is 113g
and the propylene content in the polymer is 37wt
It was %. The RI value determined from the infrared absorption spectrum of the copolymer was 0.3%.

実斜䟋 13 (1) 觊媒成分(A)の調補 充分に也燥し窒玠眮換した100mlのフラスコ
に粉末状のパラゞりムカヌボンPd含量
100mgを加え、粟補した−ゞクロル゚タ
ン50mlず四塩化チタンmolを仕蟌み、぀いで
撹拌䞋に−ブチル゚ヌテル2.8mlを分間で
添加した。フラスコ内を℃に冷华し、撹拌䞋
−ブチルマグネシりムアむオダむドmol
の−ブチル゚ヌテル溶液を10分間で加えた
−ブチル゚ヌテルず四塩化チタンのモル比
は2.0であ぀た。耐色の溶液が埗られた。Example 13 (1) Preparation of catalyst component (A) Powdered palladium carbon (Pd content 5%) was placed in a 100 ml flask that had been thoroughly dried and purged with nitrogen.
100 mg of purified 1,2-dichloroethane and mmol of titanium tetrachloride were added, and then 2.8 ml of n-butyl ether was added over 5 minutes with stirring. The inside of the flask was cooled to 0°C, and 3 mmol of n-butylmagnesium iodide was added under stirring.
was added over a period of 10 minutes (the molar ratio of n-butyl ether to titanium tetrachloride was 2.0). A brown solution was obtained.

次に、氎玠ガスを0.2minの速床で時
間吹き蟌んだ。窒玠䞋で過し、粉末状のパラ
ゞりムカヌボンを別した。黒耐色の均䞀な溶
液を埗た。 Next, hydrogen gas was blown in at a rate of 0.2/min for 2 hours. It was filtered under nitrogen to separate the powdered palladium on carbon. A dark brown homogeneous solution was obtained.

(2) 共重合 共重合は実斜䟋ず同様に行な぀た。共重合
䞭の溶液は均䞀であり、重合䞭、共重合䜓の析
出は認められなか぀た。共重合䜓の収量は120
でありポリマヌ䞭のプロピレン含量は39wt
であ぀た。共重合䜓の赀倖線吞収スペクトル
から求たR.I.倀は0.2であ぀た。(2) Copolymerization Copolymerization was carried out in the same manner as in Example 1. The solution during the copolymerization was homogeneous, and no precipitation of the copolymer was observed during the polymerization. The yield of copolymer is 120
g, and the propylene content in the polymer is 39wt.
It was %. The RI value determined from the infrared absorption spectrum of the copolymer was 0.2%.

実斜䟋 14 実斜䟋13の觊媒を甚い、実斜䟋のプロピレン
の代わりにブテン−を甚い、゚チレン
min、ブテン− 10minの混合ガスを甚い
るこず以倖は実斜䟋ず同様にしお共重合を行な
぀た。共重合䜓の収量は49、共重合䜓䞭のブテ
ン−の含量は21wtであ぀た。Example 14 Using the catalyst of Example 13, butene-1 instead of propylene of Example 1, ethylene 2/
Copolymerization was carried out in the same manner as in Example 1 except that a mixed gas of 10 min and butene-1/min was used. The yield of the copolymer was 49 g, and the content of butene-1 in the copolymer was 21 wt%.

【図面の簡単な説明】[Brief explanation of the drawing]

図は、本発明の觊媒成分ず調補工皋を有機的
に結合したフロヌチダヌト図である。図は、本
発明の特城ずする゚チレンずプロピレンのランダ
ム性を瀺すランダム・むンデツクスR.I.を求
めるため、実斜䟋によ぀お生成した共重合䜓の
赀倖線吞収スペクトルの720cm-1および730cm-1の
吞収郚分を拡倧図瀺したものである。 FIG. 1 is a flow chart that organically combines the catalyst components and preparation steps of the present invention. Figure 2 shows the infrared absorption spectra at 720 cm -1 and 730 cm - of the copolymer produced in Example 1 in order to determine the random index (RI) showing the randomness of ethylene and propylene, which is a feature of the present invention. This is an enlarged view of the absorption part of 1 .

Claims (1)

【特蚱請求の範囲】  (A) 有機溶媒䞭で、゚ヌテルず少なくずも
皮の呚期埋衚第、、、族金属た
たはその化合物の存圚䞋に四ハロゲン化チタン
を、(1)氎玠で凊理しお埗られる液状物もしくは
(2)氎玠ず有機マグネシりム化合物およびたた
は有機アルミニりム化合物で凊理しお埗られる
液状物ず、 (B) 有機アルミニりム化合物から成る觊媒を甚
い、゚チレンずプロピレンたたはおよびブテ
ン−を共重合させるこずを特城ずする゚チレ
ン共重合䜓ゎムの補造方法。[Claims] 1 (A) In an organic solvent, an ether and at least one
A liquid obtained by treating titanium tetrahalide with (1) hydrogen in the presence of a Group B, B, B, metal of the periodic table, or a compound thereof; or
(2) Copolymerizing ethylene and propylene or/and butene-1 using a liquid obtained by treating hydrogen with an organomagnesium compound and/or an organoaluminum compound, and (B) a catalyst consisting of an organoaluminum compound. A method for producing ethylene copolymer rubber, characterized by:
JP5355680A 1979-10-23 1980-04-24 Preparation of olefin copolymer rubber Granted JPS56151710A (en)

Priority Applications (5)

Application Number Priority Date Filing Date Title
JP5355680A JPS56151710A (en) 1980-04-24 1980-04-24 Preparation of olefin copolymer rubber
IT25540/80A IT1134011B (en) 1979-10-23 1980-10-23 PROCEDURE FOR THE PRODUCTION OF RUBBER OF A HYDRAULIC COPOLYMER
NL8005845A NL8005845A (en) 1979-10-23 1980-10-23 PROCESS FOR PREPARING OXENE COPOLYMERS.
US06/200,066 US4366297A (en) 1979-10-23 1980-10-23 Process for producing olefinic copolymer rubber with improved titanium compound containing catalyst system
DE19803040044 DE3040044A1 (en) 1979-10-23 1980-10-23 METHOD FOR PRODUCING A RUBBER-LIKE OLEFIN COPOLYMER

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP5355680A JPS56151710A (en) 1980-04-24 1980-04-24 Preparation of olefin copolymer rubber

Publications (2)

Publication Number Publication Date
JPS56151710A JPS56151710A (en) 1981-11-24
JPS648009B2 true JPS648009B2 (en) 1989-02-10

Family

ID=12946072

Family Applications (1)

Application Number Title Priority Date Filing Date
JP5355680A Granted JPS56151710A (en) 1979-10-23 1980-04-24 Preparation of olefin copolymer rubber

Country Status (1)

Country Link
JP (1) JPS56151710A (en)

Also Published As

Publication number Publication date
JPS56151710A (en) 1981-11-24

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