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JPH044335B2 - - Google Patents
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JPH044335B2 - - Google Patents

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Publication number
JPH044335B2
JPH044335B2 JP7528383A JP7528383A JPH044335B2 JP H044335 B2 JPH044335 B2 JP H044335B2 JP 7528383 A JP7528383 A JP 7528383A JP 7528383 A JP7528383 A JP 7528383A JP H044335 B2 JPH044335 B2 JP H044335B2
Authority
JP
Japan
Prior art keywords
rubber
styrene
weight
butadiene copolymer
bond content
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
JP7528383A
Other languages
Japanese (ja)
Other versions
JPS59199733A (en
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
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Priority to JP7528383A priority Critical patent/JPS59199733A/en
Publication of JPS59199733A publication Critical patent/JPS59199733A/en
Publication of JPH044335B2 publication Critical patent/JPH044335B2/ja
Granted legal-status Critical Current

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  • Compositions Of Macromolecular Compounds (AREA)
  • Addition Polymer Or Copolymer, Post-Treatments, Or Chemical Modifications (AREA)

Description

【発明の詳现な説明】[Detailed description of the invention]

本発明は改善された反ぱ぀匟性率を有するゎム
組成物に関するものである。詳しくは分子鎖䞭に
特定のベンゟプノン類又はチオベンゟプノン
類を導入したスチレン−ブタゞ゚ン共重合ゎムを
ゎム成分ずしお含有するタむダトレツド甚ゎム組
成物に関するものである。 最近、自動車の䜎燃費指向ず安党性の䞡芳点よ
り、特にタむダの転動抵抗の䜎枛ず湿最路面での
すぐれた制動性すなわちり゚ツトスキツド抵抗の
向䞊が匷く芁望されおいる。 䞀般にこれらのタむダの特性はトレツドゎム材
料の動的粘匟性特性ず察応させお考えられ、互に
盞反する特性であるこずが知られおいる〔䟋えば
Transaction of I.R.I.第40巻第239頁〜256
頁1964幎を参照〕。 タむダの転動抵抗を䜎枛するにはトレツドゎム
材料の反぀ば匟性率が高いこずが必芁であり、車
の走行状態を考慮するず、この反ぱ぀匟性率は50
℃から70℃付近たでの枩床で評䟡する必芁があ
る。䞀方、車の安党性の点で重芁な性胜である湿
最路面での制動性胜の向䞊にはブリテむツシナ・
ポヌタブル・スキツドテスタヌで枬定されるり゚
ツトスキツド抵抗が倧きいこずが必芁であり、ト
レツドゎム材料ずしおはタむダに制動をかけお路
面をすべらせた堎合に生ずる摩擊抵抗ずしおの゚
ネルギヌ損倱が倧きいこずが必芁である。 埓来、これら぀の盞反する特性を満足させる
ために、原料ゎムずしおは、乳化重合スチレン−
ブタゞ゚ン共重合ゎム、高シス−ポリブタゞ゚ン
ゎム、䜎シス−ポリブタゞ゚ンゎム、有機リチり
ム化合物觊媒を甚いお埗られるスチレン−ブタゞ
゚ンゎム、倩然ゎム、高シス−む゜プレンゎム等
が単独で、あるいは組合せお甚いられおきたが、
十分満足の行くものではなか぀た。 すなわち、高反ぱ぀匟性を埗ようずするず、䜎
シス−ポリブタゞ゚ンゎムや倩然ゎム等のり゚ツ
トスキツド抵抗性が劣るゎムの配合割合を増加さ
せるか、カヌボンブラツク等の充おん剀を枛量す
るか、硫黄等の加硫剀を増量させるかしなければ
ならなか぀た。しかしながら、このような方法で
はり゚ツトスキツド抵抗が䜎䞋したり、機械的性
質が䜎䞋したりするずいう欠点があ぀た。逆に、
高り゚ツトスキツド抵抗を埗ようずするず、結合
スチレン量が比范的倚い䟋えば結合スチレン含
有量30重量以䞊のスチレン−ブタゞ゚ン共重
合ゎムや−結合含有量が比范的高い䟋え
ば−結合含有量60以䞊のポリブタゞ゚
ンゎム等のり゚ツトスキツド抵抗性に優れたゎム
の配合割合を増加させるか、カヌボンブラツク等
の充おん剀やプロセスオむルを増加させるかしな
ければならなか぀た。このような方法では、反ぱ
぀匟性が䜎䞋するずいう欠点があ぀た。 したが぀お、機械的性質が実甚䞊差し支えない
範囲でか぀、り゚ツトスキツド抵抗ず反ぱ぀匟性
ずが実甚䞊蚱容される範囲で最も調和するよう原
料ゎムの組成が決められおいるのが実情であ぀
た。このため、埓来のゎムを組合せおり゚ツトス
キツド抵抗ず反ぱ぀匟性ずの調和を図るこずは限
界に達したず考えられおいた。 本発明者等は前蚘欠点を解決すべく鋭意研究の
結果、驚くべきこずに、分子鎖に特定のベンゟフ
゚ノン類又はチオベンゟプノン類が導入された
スチレン−ブタゞ゚ン共重合ゎムをゎム成分ずし
お含むゎム組成物は該化合物が導入されおいない
同䞀のスチレン−ブタゞ゚ン共重合ゎムを甚いた
組成物ず比范しおり゚ツトスキツド抵抗を䜎䞋さ
せるこずなく反ぱ぀匟性を著しく向䞊させ、なお
か぀高反ぱ぀匟性の特城を生かし、必芁ならばカ
ヌボンブラツク等の充おん剀の増量によ぀お耐摩
耗性等の機械的性質を改善し぀぀、反ぱ぀匟性ず
り゚ツトスキツド抵抗性ずの調和を図れるこずを
芋出し、本発明に到぀たものである。 即ち、本発明は機械的特性およびり゚ツトスキ
ツド抵抗を損うこずなく、転動抵抗を䜎枛したタ
むダトレツド甚ゎム組成物の提䟛を目的ずするも
のでありスチレン−ブタゞ゚ン共重合ゎム分子鎖
に少なくずも個のアミノ基、アルキルアミノ基
あるいはゞアルキルアミノ基を有するベンゟプ
ノン類又はチオベンゟプノン類を該ゎム分子鎖
モル圓り少なくずも0.1モルを導入した結果ス
チレン含有量が〜20重量で、ブタゞ゚ン郚分
の−結合含有量が50を超え、80以䞋
で、ムヌニヌ粘床ML1+4100℃が20〜150の
スチレン−ブタゞ゚ン共重合ゎム20〜95重
量ず倩然ゎムおよびたたはシス−−結
合含有量が少なくずも90のポリむ゜プレンゎム
60〜重量および−結合含有量が
20以䞋でムヌニヌ粘床ML1+4100℃が20
〜100のポリブタゞ゚ンゎム50〜重量
をゎム成分ずしお含んで成るタむダトレツド甚ゎ
ム組成物を䜿甚するこずによ぀お達せられる。 本発明のタむダ甚ゎム組成物を甚いるず前述し
たタむダ性胜ずしお重芁な転動抵抗ず湿最路面で
の制動性、すなわちり゚ツトスキツド抵抗ずが高
い氎準で調和した優れたタむダが埗られるが、り
゚ツトスキツド抵抗倀は特に芁求されず、高反ぱ
぀匟性率が芁求されるタむダの補造にも本発明の
組成物を䜿甚するこずができる。 本発明で䜿甚する分子鎖に該ベンゟプノン類
又はチオベンゟプノン類を導入した高−
結合含有量のスチレン−ブタゞ゚ン共重合ゎムは
溶液重合においお通垞䜿甚されるアルカリ金属基
材觊媒を甚いお重合した分子鎖の末端にアルカリ
金属が結合しおいるスチレン−ブタゞ゚ン共重合
ゎムあるいは、該觊媒を甚いお埗た該ゎムに埌反
応でアルカリ金属を付加させたものず該ベンゟフ
゚ノン類又はチオベンゟプノン類ずを反応させ
お埗られるスチレン−ブタゞ゚ン共重合ゎム分子
鎖の末端あるいは末端及びこれ以倖の分子鎖䞭に
該化合物が炭玠−炭玠結合で、䞀般匏
 The present invention relates to rubber compositions having improved rebound modulus. More specifically, the present invention relates to a rubber composition for tire treads containing as a rubber component a styrene-butadiene copolymer rubber in which specific benzophenones or thiobenzophenones have been introduced into the molecular chain. Recently, from the viewpoints of both fuel efficiency and safety of automobiles, there has been a strong demand for a reduction in the rolling resistance of tires and an improvement in braking performance on wet road surfaces, that is, improvement in wet skid resistance. Generally, these tire properties are considered to correspond to the dynamic viscoelastic properties of the tread rubber material, and it is known that these properties are contradictory to each other [e.g.
Transaction of IRI, Volume 40, Pages 239-256
1964]. To reduce the rolling resistance of a tire, the tread rubber material must have a high anti-flange modulus, and considering the driving conditions of the car, this anti-flange modulus is 50.
It is necessary to evaluate at temperatures from ℃ to around 70℃. On the other hand, British technology is used to improve braking performance on wet roads, which is an important performance in terms of vehicle safety.
It is necessary that the wet skid resistance measured by a portable skid tester is high, and the tread rubber material must have a high energy loss as frictional resistance that occurs when the tire is braked and slides on the road surface. . Conventionally, in order to satisfy these two contradictory properties, emulsion polymerized styrene has been used as raw rubber.
Butadiene copolymer rubber, high cis polybutadiene rubber, low cis polybutadiene rubber, styrene-butadiene rubber obtained using an organolithium compound catalyst, natural rubber, high cis isoprene rubber, etc. are used alone or in combination. However,
It wasn't completely satisfying. In other words, in order to obtain high rebound elasticity, one must increase the blending ratio of rubber with poor wet skid resistance such as low cis-polybutadiene rubber or natural rubber, reduce the amount of filler such as carbon black, or increase the amount of filler such as sulfur. I had to increase the amount of vulcanizing agent. However, this method has disadvantages in that wet skid resistance and mechanical properties are reduced. vice versa,
In order to obtain high wet skid resistance, styrene-butadiene copolymer rubber with a relatively large amount of bound styrene (e.g., 30% by weight or more of bound styrene) or a styrene-butadiene copolymer rubber with a relatively high content of 1,2-bonds (e.g., 1, 2-It was necessary to increase the blending ratio of rubber with excellent wet skid resistance such as polybutadiene rubber (with a bond content of 60% or more), or to increase the amount of filler such as carbon black or process oil. This method has the disadvantage that the rebound elasticity is reduced. Therefore, the actual situation is that the composition of the raw rubber is determined so that the mechanical properties are within a practically acceptable range and the wet skid resistance and rebound elasticity are in the most harmonious range within a practically acceptable range. . For this reason, it was thought that the ability to achieve a balance between wet skid resistance and rebound elasticity by combining conventional rubbers had been reached. As a result of intensive research to solve the above-mentioned drawbacks, the present inventors surprisingly found that a rubber containing as a rubber component a styrene-butadiene copolymer rubber into which specific benzophenones or thiobenzophenones have been introduced into the molecular chain. Compared to a composition using the same styrene-butadiene copolymer rubber in which the compound is not introduced, the composition significantly improves the rebound resilience without reducing wet skid resistance, and has the characteristics of high rebound resilience. We have discovered that it is possible to achieve a balance between rebound elasticity and wet skid resistance while improving mechanical properties such as abrasion resistance by increasing the amount of filler such as carbon black if necessary, and have arrived at the present invention. It is something. That is, the object of the present invention is to provide a rubber composition for tire treads that has reduced rolling resistance without impairing mechanical properties and wet skid resistance. As a result of introducing at least 0.1 mole of benzophenones or thiobenzophenones having an amino group, alkylamino group or dialkylamino group per mole of the rubber molecule chain, the styrene content is 3 to 20% by weight, and 1 of the butadiene moiety is , 2- 20-95% by weight of styrene-butadiene copolymer rubber () with a bond content of more than 50% and less than 80% and a Mooney viscosity (ML 1+4 , 100°C) of 20-150, natural rubber and / or polyisoprene rubber () with a cis-1,4-bond content of at least 90% and a 1,2-bond content of 60 to 5% by weight
Mooney viscosity (ML 1+4 , 100℃) of 20% or less
~100 polybutadiene rubber ()50~0% by weight
This can be achieved by using a rubber composition for tire tread comprising as a rubber component. When the rubber composition for tires of the present invention is used, it is possible to obtain an excellent tire that has a high level of balance between rolling resistance, which is important for tire performance, and braking performance on wet road surfaces, that is, wet skid resistance. is not particularly required, and the composition of the present invention can also be used for manufacturing tires that require a high rebound modulus. The high 1,2-
The styrene-butadiene copolymer rubber with a bond content is a styrene-butadiene copolymer rubber in which an alkali metal is bonded to the end of the molecular chain, or a styrene-butadiene copolymer rubber polymerized using an alkali metal-based catalyst commonly used in solution polymerization. Terminals or terminals of styrene-butadiene copolymer rubber molecular chains obtained by reacting the rubber obtained by adding an alkali metal in a post-reaction with the benzophenones or thiobenzophenones, and other than this. The compound has a carbon-carbon bond in the molecular chain, and has the general formula

【匏】匏䞭R1及びR2は氎玠 又は前蚘眮換基を、は又はを、及びは
敎数をそれぞれ衚わすで瀺される原子団ずしお
導入されたスチレン−ブタゞ゚ン共重合ゎムであ
る。特に望たしいものは分子鎖の末端に該化合物
が導入されたスチレン−ブタゞ゚ン共重合ゎムで
ある。 本発明で䜿甚される該ベンゟプノン類及びチ
オベンゟプノン類は䟋えば4′−ビスゞメ
チルアミノ−ベンゟプノン4′−ビス
ゞ゚チルアミノ−ベンゟプノン4′−ビ
スゞブチルアミノ−ベンゟプノン
4′−ゞアミノベンゟプノン−ゞメチルアミ
ノベンゟプノン等及びこれらの察応のチオベン
ゟプノンが䟋瀺される䞀方あるいは䞡方のベン
れン環に少なくずも぀のアミノ基アルキルア
ミノ基あるいはゞアルキルアミノ基を有するベン
ゟプノン及びチオベンゟプノンである。 ベンゟプノン類及びチオベンゟプノン類は
䞀般匏Styrene-butadiene copolymer rubber introduced as an atomic group represented by [Formula] (wherein R 1 and R 2 represent hydrogen or the above-mentioned substituent, M represents O or S, and m and n represent integers, respectively) It is. Particularly desirable is a styrene-butadiene copolymer rubber in which the compound is introduced at the end of the molecular chain. The benzophenones and thiobenzophenones used in the present invention are, for example, 4,4'-bis(dimethylamino)-benzophenone, 4,4'-bis(diethylamino)-benzophenone, 4,4'-bis(dibutyl amino)-benzophenone, 4,
Examples include 4'-diaminobenzophenone, 4-dimethylaminobenzophenone, etc., and their corresponding thiobenzophenones, which have at least one amino group, alkylamino group or dialkylamino group on one or both benzene rings benzophenone and thiobenzophenone. Benzophenones and thiobenzophenones have the general formula

【匏】匏䞭R1R2は 氎玠、又はアミノ基アルキルアミノ基ゞアル
キルアミノ基から遞択される眮換基を、は又
はを、及びはずの合蚈が〜10ずなる
敎数をそれぞれ衚わすで衚わされる化合物であ
る。 該ベンゟプノン類及びチオベンゟプノン類
を分子鎖䞭に導入したスチレン−ブタゞ゚ン共重
合ゎムは䟋えば、アルカリ金属基材觊媒を甚いお
スチレン−ブタゞ゚ン共重合ゎムを重合し、重合
反応を完了させた該ゎム溶液䞭に該チオベン
ゟプノン類を添加する方法スチレン−ブタゞ
゚ン共重合ゎムの溶液䞭で該ゎムにアルカリ金属
を付加させた埌該チオベンゟプノン類を添
加する方法等が䟋瀺できる。 重合反応および付加反応に䜿甚されるアルカリ
金属基材觊媒は通垞の溶液重合で䜿甚されるリチ
りムナトリりムルビゞりムセシりムの各金
属元玠たたはこれらの炭化氎玠化合物あるいは極
性化合物ずの錯䜓䟋えば−ブチルリチりム
−ナフチルリチりムカリりム−テトラヒドロ
フラン錯䜓カリりム−ゞ゚トキシ゚タン錯䜓
等である。 スチレン−ブタゞ゚ン共重合ゎム䞭に導入され
る該チオベンゟプノン類は平均しおゎム分
子鎖モル圓り0.1モル以䞊である。0.1モル未満
では反ぱ぀匟性の向䞊は埗られない。奜たしくは
0.3モル以䞊、さらに奜たしくは0.5モル以䞊、特
に奜たしくは0.7モル以䞊であるが、モル以䞊
になるずゎム匟性が倱われるので奜たしくない。
該ベンゟプノン類又はチオベンゟプノン類を
重合䜓鎖䞭に導入した結合スチレン含有量〜20
重量、ブタゞ゚ン郚分の−結合含有量が
50を超え、80以䞋のスチレン−ブタゞ゚ン共
重合ゎムは、本ゎム組成物䞭のゎム成分䞭
少なくずも20重量以䞊含たれるこずが必芁であ
る。20重量未満では、反発匟性向䞊効果が少な
く、本発明の目的は達成されない。又95重量を
超えるず耐摩耗性が䜎䞋するので奜たしくない。
倩然ゎムおよびたたはシス−−結合含有
量が少なくずも90のポリむ゜プレンゎム
をゎム成分䞭60〜重量および−結合含
有量が20以䞋のポリブタゞ゚ンゎムを50
〜重量含有させるこずにより、匷床特性や耐
摩耗性を損うこずなく反発匟性率55℃ずり゚
ツトスキツド抵抗性の調和のより優れたゎム組成
物ずするこずができる。即ち、倩然ゎムおよび
たたはシス−結合含有量が少なくずも90
のポリむ゜プレンゎムのぞのブレン
ドは、反発匟性率を䜎䞋させるこずなく、匷床特
性を向䞊させうる。しかし、それが60重量を超
えるずり゚ツトスキツド抵抗の䜎䞋が倧ずなるの
で奜たしくない。 䞀方、−結合含有量が20以䞋のポリブ
タゞ゚ンゎムを必芁に応じず
ず混合するこずにより、耐摩耗性を向䞊させるこ
ずができるが、50重量を超えるず匷床特性およ
びり゚ツトスキツド抵抗の䜎䞋が倧きくなるので
奜たしくない。したが぀お、タむダトレツド材料
ずしお重芁な特性である匷床特性耐摩耗性お
よびり゚ツトスキツド抵抗をある䞀定のレベル以
䞊に保ち、か぀反発匟性率を向䞊させるために
は、本発明のゎム組成が最も奜たしいこずを芋出
した。 本発明で䜿甚するゎム成分のすべお、あるいは
䞀郚を油展ゎムずしお䜿甚するこずができる。 本発明のゎム組成物は目的甚途に応じおゎム
工業で汎甚される各皮配合剀−䟋えば硫黄ステ
アリン酞亜鉛華各皮加硫促進剀チアゟヌル
系チりラム系スルプンアミド系など、
HAFISAF等の皮々のグレヌドのカヌボンブラ
ツクシリカ炭酞カルシりム等の補匷剀充お
ん剀プロセス油等から適宜遞択するこずができ
るが−ずロヌルバンバリヌ等の混合機を甚いお
混緎混合されおゎム配合物ずされ、成圢加硫工
皋を経お目的ずするタむダが補造される。 本発明のゎム組成物は、高い氎準で反ぱ぀匟性
率ずり゚ツトスキツド抵抗ずを調和させるこずが
できるから、特に安党性燃料消費性の改善され
た自動車タむダトレツド甚ゎム材料に適しおいる
が、自転車タむダ甚にも䜿甚するこずができる。 以䞋、実斜䟋により本発明を具䜓的に説明す
る。 補造䟋 (1) 以䞋の実斜䟋で䜿甚する該ベンゟプノン類
を導入したスチレン−ブタゞ゚ン共重合ゎム
以䞋SBRず略蚘するこずがあるの調補方法
を瀺す。内容積のステンレス補重合反応噚
を掗浄也燥し、也燥窒玠で眮換したのち、
−ブタゞ゚ン185〜160、スチレン15〜
40、−ヘキサン600、ゞスチレングリコ
ヌルゞメチル゚ヌテルゞグラむム1.2及び
1.6mmolの氎準、−ブチルリチりム1.2ml
1.55mol−ヘキサン溶液を添加し、
内容物を攪拌しながら、45℃で、30分〜60分重
合反応させた。重合転換率玄80に達したずこ
ろで、−ビスゞ゚チルアミノベンゟ
プノンを重合觊媒量の1.5倍mol加え、分
間攪拌したのち、重合反応噚䞭の重合䜓溶液
を、−ゞ−−ブチル−−クレゟヌル
BHT1.5重量のメタノヌル溶液䞭に取り
出し、生成重合䜓を凝固した。これを60℃で24
時間枛圧也燥し、埗られたゎムのムヌニヌ粘床
を枬定した。〔SBR(2)(4)〕。又同様にしお該
ベンゟプノンを察応のチオプノンに倉えた
SBRも調補した〔SBR2′4′〕。たた、重
合反応終了埌、4′ビスゞ゚チルアミノ
チオベンゟプノンを添加せずに重合䜓溶
液をBHT含量メタノヌル䞭に取り出し、生成
重合䜓を凝固したのち、前蚘ず同様にしお也燥
ゎム重合䜓を埗た〔SBR(1)(3)〕。 (2) (1)ず同様にしおゞグラむムを1.2mmolを甚い
お、−ブタゞ゚ンずスチレンを共重合さ
せた。重合終了埌、BHT含有メタノヌル溶液
䞭に重合反応噚䞭の重合䜓溶液を泚ぎ、生成
SBRを凝固させた。分離したクラムをベンれ
ンに溶解し、前蚘ず同じ操䜜でSBRを凝固さ
せた。この操䜜を回繰返しおSBR䞭の觊媒
残枣を取り陀いた。(1)ず同じ条件で也燥を行な
い、粟補也燥SBRを埗た。 このSBR100を也燥ベンれン1000に溶解
した溶液に−ブチルリチりム3.5mmolおよび
テトラメチル゚チレンゞアミン3.5mmolを添加
し、70℃で時間反応させた。 次いで(1)で䜿甚したベンゟプノン化合物を
2.7mmol添加し分間反応させた埌、䞊蚘ず同
様にしお凝固也燥させた〔SBR(5)〕。 以䞊の方法で調補したスチレン−ブタゞ゚ン共
重合ゎムのスチレン含有量、ブタゞ゚ン郚分の
−結合含量、ムヌニヌ粘床、及び4′−
ビスゞ゚チルアミノベンゟプノン導入量を
第衚に瀺す。スチレン含有量、ブタゞ゚ン郚分
の−結合含有量は垞法の赀倖分光法によ぀
お枬定した。4′−ビスゞ゚チルアミノ
チオベンゟプノン導入量は13C−NMRを甚
いお求めた。[Formula] (In the formula, R 1 and R 2 are hydrogen or a substituent selected from an amino group, an alkylamino group, and a dialkylamino group, M is O or S, and m and n are the sum of m and n. (each represents an integer from 1 to 10). The styrene-butadiene copolymer rubber into which the benzophenones and thiobenzophenones have been introduced into the molecular chain is obtained by, for example, polymerizing the styrene-butadiene copolymer rubber using an alkali metal-based catalyst and completing the polymerization reaction. Examples include a method in which the (thio)benzophenones are added to a rubber solution, and a method in which an alkali metal is added to the rubber in a solution of styrene-butadiene copolymer rubber and then the (thio)benzophenones are added. The alkali metal-based catalysts used in polymerization and addition reactions are metal elements such as lithium, sodium, rubidium, and cesium used in ordinary solution polymerization, or their complexes with hydrocarbon compounds or polar compounds (e.g., n- butyl lithium,
2-naphthyllithium, potassium-tetrahydrofuran complex, potassium-diethoxyethane complex, etc.). The (thio)benzophenone introduced into the styrene-butadiene copolymer rubber is on average 0.1 mole or more per mole of rubber molecular chain. If the amount is less than 0.1 mol, no improvement in rebound elasticity can be obtained. Preferably
The amount is 0.3 mol or more, more preferably 0.5 mol or more, particularly preferably 0.7 mol or more, but if it is 5 mol or more, rubber elasticity is lost, which is not preferable.
The bound styrene content in which the benzophenone or thiobenzophenone is introduced into the polymer chain is 3 to 20.
Weight%, 1,2-bond content of butadiene moiety is
The styrene-butadiene copolymer rubber () exceeding 50% and not exceeding 80% must be contained in an amount of at least 20% by weight or more in the rubber component of the rubber composition. If it is less than 20% by weight, the effect of improving impact resilience will be small and the object of the present invention will not be achieved. Moreover, if it exceeds 95% by weight, wear resistance decreases, which is not preferable.
Natural rubber and/or polyisoprene rubber () with a cis-1,4-bond content of at least 90%
50% polybutadiene rubber () with a rubber component of 60 to 5% by weight and a 1,2-bond content of 20% or less
By containing up to 0% by weight, a rubber composition with better balance between rebound modulus (55° C.) and wet skid resistance can be obtained without impairing strength properties or abrasion resistance. i.e. natural rubber and/or
or has a cis-1,4-bond content of at least 90%
Blending of polyisoprene rubber () into () can improve strength properties without reducing impact modulus. However, if it exceeds 60% by weight, the wet skid resistance will drop significantly, which is not preferable. On the other hand, use polybutadiene rubber () with a 1,2-bond content of 20% or less as necessary () and ().
Although abrasion resistance can be improved by mixing with 50% by weight, it is not preferable because the strength properties and wet skid resistance will decrease significantly. Therefore, in order to maintain the strength properties, abrasion resistance, and wet skid resistance, which are important properties for a tire tread material, at a certain level or higher, and to improve the rebound modulus, the rubber composition of the present invention is most preferable. I discovered that. All or part of the rubber components used in the present invention can be used as oil-extended rubber. The rubber composition of the present invention can be prepared using various compounding agents commonly used in the rubber industry, such as sulfur, stearic acid, zinc white, various vulcanization accelerators (thiazole type, thiuram type, sulfenamide type, etc.), depending on the purpose and use.
Various grades of carbon black such as HAF and ISAF, reinforcing agents such as silica and calcium carbonate, fillers, process oils, etc. can be selected as appropriate, and are kneaded and mixed using a mixer such as a roll or Banbury mixer. The rubber compound is made into a rubber compound, and the target tire is manufactured through a molding and vulcanization process. Since the rubber composition of the present invention is able to balance recoil modulus and wet skid resistance at a high level, it is particularly suitable as a rubber material for automobile tire treads with improved safety and fuel consumption. It can also be used for tires. Hereinafter, the present invention will be specifically explained with reference to Examples. Production Example (1) A method for preparing styrene-butadiene copolymer rubber (hereinafter sometimes abbreviated as SBR) into which the benzophenones are introduced will be described to be used in the following examples. After cleaning and drying a stainless steel polymerization reactor with an internal volume of 2, and purging it with dry nitrogen,
1,3-butadiene 185~160g, styrene 15~
40g, n-hexane 600g, distyrene glycol dimethyl ether (diglyme) 1.2 and
1.6 mmol level, n-butyllithium 1.2 ml
(1.55 mol/, n-hexane solution) was added,
While stirring the contents, a polymerization reaction was carried out at 45° C. for 30 to 60 minutes. When the polymerization conversion rate reached approximately 80%, 1.5 mol of 4,4-bis(diethylamino)benzophenone was added to the polymerization catalyst amount, and after stirring for 5 minutes, the polymer solution in the polymerization reactor was converted into 2,6- The resulting polymer was taken out into a methanol solution containing 1.5% by weight of di-t-butyl-P-cresol (BHT), and the resulting polymer was coagulated. This at 60℃ for 24
The rubber was dried under reduced pressure for a period of time, and the Mooney viscosity of the obtained rubber was measured. [SBR(2), (4)]. In the same manner, the benzophenone was changed to the corresponding thiophenone.
SBR was also prepared [SBR (2'), (4')]. In addition, after the completion of the polymerization reaction, 4,4′bis(diethylamino)
The polymer solution was taken out into BHT-containing methanol without adding (thio)benzophenone, the resulting polymer was coagulated, and then dried rubber polymers were obtained in the same manner as above [SBR (1), (3)] . (2) In the same manner as in (1), 1,3-butadiene and styrene were copolymerized using 1.2 mmol of diglyme. After polymerization is complete, pour the polymer solution in the polymerization reactor into a methanol solution containing BHT to generate
Solidified SBR. The separated crumb was dissolved in benzene, and SBR was coagulated by the same operation as above. This operation was repeated three times to remove the catalyst residue in the SBR. Drying was performed under the same conditions as in (1) to obtain purified and dried SBR. 3.5 mmol of n-butyllithium and 3.5 mmol of tetramethylethylenediamine were added to a solution of 100 g of this SBR dissolved in 1000 g of dry benzene, and the mixture was reacted at 70° C. for 1 hour. Next, the benzophenone compound used in (1) was
After adding 2.7 mmol and reacting for 5 minutes, it was coagulated and dried in the same manner as above [SBR(5)]. The styrene content, 1,2-bond content of the butadiene moiety, Mooney viscosity, and 4,4'- of the styrene-butadiene copolymer rubber prepared by the above method.
Table 1 shows the amount of bis(diethylamino)benzophenone introduced. The styrene content and the 1,2-bond content of the butadiene moiety were measured by conventional infrared spectroscopy. 4,4'-bis(diethylamino)
The amount of (thio)benzophenone introduced was determined using 13 C-NMR.

【衚】【table】

【衚】 実斜䟋 ゎム詊料をタむダトレツド甚基瀎配合ずしお第
衚に瀺す配合凊方の各皮配合剀ず容量250mlの
ブラベンダヌタむプミキサヌ䞭で混緎混合しお各
ゎム配合組成物を埗た。硫黄および加硫促進剀
は、各ゎム配合組成物を加硫しお最適状態ずなる
量を䜿甚した。これらのゎム配合組成物を160℃
×15〜30分、プレス加硫しお詊隓片を䜜成した。[Table] Examples Rubber samples were kneaded and mixed with various compounding ingredients shown in Table 2 as a basic compound for tire tread in a Brabender type mixer having a capacity of 250 ml to obtain various rubber compound compositions. Sulfur and vulcanization accelerator were used in amounts that would achieve the optimum state when vulcanizing each rubber compound composition. These rubber compound compositions were heated to 160°C.
A test piece was prepared by press vulcanization for 15 to 30 minutes.

【衚】 それぞれのゎム配合組成物の加硫ゎムに぀い
お、匷床特性をJIS−−6301に埓぀お、たた反
発匟性率はダンロツプトリプ゜メヌタヌを甚い
お、枩床55℃にお枬定した。り゚ツトスキツド抵
抗はポヌタヌブルスキツドテスタヌ英囜スタン
レヌ瀟補を甚いお23℃で、ASTM−E303−74
の路面3M瀟補屋倖甚タむプ黒のセヌフテ
むヌりオヌクで枬定し、 各ゎム配合加硫物のり゚ツトスキツド抵抗倀−SBR
配合加硫物のり゚ツトスキツド抵抗倀 ×100 で蚈算しお指数衚瀺した。 ピコ摩耗指数は、ASTM−−2228に埓぀お、
グツドリツチ匏ピコ摩耗詊隓機を甚いお枬定し、 −SBR−1502の配合加硫物のピコ摩耗量各ゎム配
合加硫物のピコ摩耗量 ×100 で蚈算しお衚瀺した。以䞊の結果を第衚に瀺
す。[Table] Regarding the vulcanized rubber of each rubber compound composition, the strength characteristics were measured according to JIS-K-6301, and the rebound modulus was measured at a temperature of 55° C. using a Danlop lipometer. Wet skid resistance was measured using a portable skid tester (manufactured by Stanley, UK) at 23°C, according to ASTM-E303-74.
Wet skid resistance value of each rubber compound vulcanizate / E-SBR
The wet skid resistance of the blended vulcanizate was calculated by multiplying by 100 and expressed as an index. Pico wear index is according to ASTM-D-2228,
It was measured using a Gutdoritsu type pico abrasion tester, and was calculated and displayed as: Pico abrasion amount of E-SBR-1502 compound vulcanizate/Pico abrasion amount of each rubber compound vulcanizate x 100. The above results are shown in Table 3.

【衚】【table】

【衚】 第衚の結果から、比范䟋実隓番号〜に察
応した本発明䟋の反応匟性率が、いづれもり゚ツ
トスキツド抵抗や、ピコ摩耗性を損うこずなく、
〜ポむントの向䞊効果が認められる。さらに
SBR(2)ず倩然ゎム及びCis−BRずの組合せを適
切にするこずによ぀お、実隓番号のごずく、ピ
コ摩耗性および匕匵匷さを損うこずなく、反発匟
性率ずり゚ツドスキツド抵抗の調和の良いゎム組
成物が埗られるこずが瀺しおある。 実斜䟋  SBR(5)ずSBR(6)にカヌボンブラツク配合量を
50PHRから55PHRに増量した堎合の効果を第衚に
瀺した。 䞀般にカヌボンブラツクを増量するず耐摩耗性
は改善されるが、反ぱ぀匟性は䜎䞋する。しかし
ながら本発明では反ぱ぀匟性は䜎䞋は埓来のゎム
組成物よりも小さい。 即ち、比范䟋の実隓番号ず6′の比范、本発明
䟋の実隓番号11ず11′匐比范より、本発明䟋にお
ける反ぱ぀匟性の䜎䞋が小さいこずが分る。 埓぀お、本発明においおはカヌボンブラツクの
増量による耐摩耗性の改善も期埅できる。[Table] From the results in Table 3, it can be seen that the reaction modulus of the present invention examples corresponding to Comparative Example Experiment Nos. 2 to 4 did not impair wet skid resistance or pico abrasion resistance.
An improvement effect of 3 to 4 points was observed. moreover
By appropriately combining SBR(2) with natural rubber and Cis-BR, as shown in Experiment No. 8, the impact modulus and wet skid resistance were balanced without impairing pico abrasion resistance and tensile strength. It has been shown that a rubber composition with good properties can be obtained. Example 2 Addition of carbon black to SBR(5) and SBR(6)
Table 4 shows the effects of increasing the dose from 50 PHR to 55 PHR . Generally, increasing the amount of carbon black improves abrasion resistance, but reduces rebound resilience. However, in the present invention, the reduction in rebound elasticity is smaller than in conventional rubber compositions. That is, a comparison between Experiment No. 6 and 6' of the comparative example and a comparison of Experiment No. 11 and 11' of the invention example shows that the decrease in recoil elasticity in the example of the invention is small. Therefore, in the present invention, it is expected that the wear resistance will be improved by increasing the amount of carbon black.

【衚】【table】

【衚】【table】

Claims (1)

【特蚱請求の範囲】[Claims]  スチレン−ブタゞ゚ン共重合ゎム分子鎖に、
少なくずも個のアミノ基、アルキルアミノ基あ
るいはゞアルキルアミノ基を有するベンゟプノ
ン類又はチオベンゟプノン類を、該ゎム分子鎖
モル圓り少なくずも0.1モルを導入した結合ス
チレン含有量が〜20重量で、ブタゞ゚ン郚分
の−結合含有量が50を超え、80以䞋
で、ムヌニヌ粘床ML1+4100℃が20〜150の
スチレン−ブタゞ゚ン共重合ゎム20〜95重
量ず、倩然ゎムおよびたたはシス−−
結合含有量が少なくずも90のポリむ゜プレンゎ
ム60〜重量および−結合含有量
が20以䞋で、ムヌニヌ粘床ML1+4100℃
が20〜100のポリブタゞ゚ンゎム50〜重
量をゎム成分ずしお含んで成るこずを特城ずす
るタむダトレツド甚ゎム組成物。1 In the styrene-butadiene copolymer rubber molecular chain,
At least 0.1 mole of benzophenones or thiobenzophenones having at least one amino group, alkylamino group, or dialkylamino group is introduced per mole of the rubber molecule chain, and the bound styrene content is 3 to 20% by weight. , styrene-butadiene copolymer rubber (20-95% by weight) with a 1,2-bond content of more than 50% but less than 80% in the butadiene moiety and a Mooney viscosity (ML 1+4 , 100℃) of 20-150 % and natural rubber and/or cis-1,4-
Polyisoprene rubber () with a bond content of at least 90% from 60 to 5% by weight and a 1,2-bond content of not more than 20%, Mooney viscosity (ML 1+4 , 100 °C)
1. A rubber composition for a tire tread, comprising 50 to 0% by weight of polybutadiene rubber () having a polybutadiene rubber of 20 to 100 as a rubber component.
JP7528383A 1983-04-28 1983-04-28 Rubber composition for tire tread Granted JPS59199733A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP7528383A JPS59199733A (en) 1983-04-28 1983-04-28 Rubber composition for tire tread

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP7528383A JPS59199733A (en) 1983-04-28 1983-04-28 Rubber composition for tire tread

Publications (2)

Publication Number Publication Date
JPS59199733A JPS59199733A (en) 1984-11-12
JPH044335B2 true JPH044335B2 (en) 1992-01-28

Family

ID=13571740

Family Applications (1)

Application Number Title Priority Date Filing Date
JP7528383A Granted JPS59199733A (en) 1983-04-28 1983-04-28 Rubber composition for tire tread

Country Status (1)

Country Link
JP (1) JPS59199733A (en)

Also Published As

Publication number Publication date
JPS59199733A (en) 1984-11-12

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