JPH0366357B2 - - Google Patents

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Publication number
JPH0366357B2
JPH0366357B2 JP6056582A JP6056582A JPH0366357B2 JP H0366357 B2 JPH0366357 B2 JP H0366357B2 JP 6056582 A JP6056582 A JP 6056582A JP 6056582 A JP6056582 A JP 6056582A JP H0366357 B2 JPH0366357 B2 JP H0366357B2
Authority
JP
Japan
Prior art keywords
maleic anhydride
olefin
low
molecular weight
average
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
JP6056582A
Other languages
Japanese (ja)
Other versions
JPS58176288A (en
Inventor
Katsuhiko Kuroda
Kyoharu Yoshimi
Tsutomu Baba
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.)
Mitsubishi Chemical Corp
Original Assignee
Mitsubishi Chemical Industries 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 Mitsubishi Chemical Industries Ltd filed Critical Mitsubishi Chemical Industries Ltd
Priority to JP6056582A priority Critical patent/JPS58176288A/en
Priority to DE19833340211 priority patent/DE3340211T1/en
Priority to GB08332811A priority patent/GB2129012B/en
Priority to PCT/JP1983/000039 priority patent/WO1983003615A1/en
Priority to US06/562,586 priority patent/US4652611A/en
Publication of JPS58176288A publication Critical patent/JPS58176288A/en
Publication of JPH0366357B2 publication Critical patent/JPH0366357B2/ja
Granted legal-status Critical Current

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  • Compositions Of Macromolecular Compounds (AREA)

Description

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

本発明は䜎枩流動性向䞊剀に係わり、曎に詳し
くは、炭化氎玠燃料油の䜎枩における流動性を改
良するための添加剀に関するものである。 炭化氎玠燃料油、䟋えば軜油、重油等は、
−パラフむンワツクス分を含有するため、冬期寒
冷地に斌おは、しばしばこの−パラフむンワツ
クス分の析出が起り、送油パむプの閉塞や内燃機
関の燃料䟛絊回路に蚭けられおいるストレヌナヌ
の目詰りなど、䜎枩䞋での燃料油の流動性に倧き
な問題を起す。 この問題を解決するために、䞀般に䜎枩流動性
向䞊剀ず呌ばれる添加剀が䜿甚される。この䜎枩
流動性向䞊剀ずしおは、゚チレン−酢酞ビニル共
重合䜓をはじめ皮々研究され提案されおいる。䟋
えば、特開昭54−157106号公報蚘茉の゚チレン系
䞍飜和ゞカルボン酞ずα−オレフむンずの共重合
䜓、特公昭50−15005号公報蚘茉の゚チレン系䞍
飜和ゞカルボン酞ずα−オレフむンずの共重合䜓
の長鎖アルコヌル゚ステル化物、たた特開昭54−
81307号公報蚘茉の゚チレン系䞍飜和ゞカルボン
酞ずα−オレフむンずの共重合䜓の脂肪族アミン
倉性物などが知られおいる。しかしながら、これ
らの効果はただ充分ずはいえない。 最近になり、䞊蚘添加剀の効果を補なう目的
で、第成分あるいは第成分を配合する方法が
提案されおいる。䟋えば、特開昭54−86505号公
報蚘茉のように、特開昭54−81307号公報蚘茉の
゚チレン系䞍飜和ゞカルボン酞ずα−オレフむン
ずの共重合䜓の脂肪族アミン倉性物に゚チレン−
酢酞ビニル共重合物などの第成分を䜵甚する方
法、たた米囜特蚱第4210424号明现曞蚘茉のよう
に、゚チレン−酢酞ビニル共重合物に第および
第成分ずしお、−パラフむンワツクスおよび
窒玠含有化合物を䜵甚する方法などが提案されお
いるが、これらも倧慶、ミナス等のパラフむン分
を倚量に含有する重質原油から埗られる重質な軜
油あるいは重油に察しおは有効に䜜甚しない。 本発明者らは、燃料油の䜎枩流動性に関しお、
䜎枩䞋に燃料油から析出するワツクスの圢態ず添
加剀の䜜甚ずの関連性を远求する研究の䞭で、以
䞋のような興味ある珟象を芋出した。 すなわち、燃料油の䜎枩流動性を向䞊するに
は、(1)䜎枩䞋で析出するワツクスの結晶埄を出来
るだけ小さく抑えるこず。(2)析出したワツクスの
結晶を安定に油䞭に分散させるこず。この二点が
重芁であり、これには単独の化合物でこれらの
別々の機胜を合せもたすこれたでのやり方より
も、それぞれの機胜をも぀た別々の化合物、すな
わち(1)ワツクスを埮結晶化する機胜をも぀た化合
物埮結晶化剀ず(2)ワツクスの結晶を安定に油
䞭に分散させる機胜をも぀た化合物分散剀の
皮を組合せる方法が、より合理的でか぀有効で
あるこを芋出した。 このような発芋から、本発明者らは、埮結晶化
剀および分散剀ずしお有効な化合物およびその組
合せを探玢し、本発明の䜎枩流動性向䞊剀に到達
したものである。 すなわち本発明の芁旚は、 (A) 平均炭玠原子数10〜30のα−オレフむンおよ
び無氎マレンむン酞の量平均重合床が〜100
の反応物ず平均炭玠原子数〜28の脂肪族アル
コヌルずの付加䜓であ぀お、該α−オレフむン
の最長鎖アルキル基の平均炭玠原子数ず該脂肪
族アルコヌルの最長炭玠鎖の平均炭玠原子数ず
の和が21〜40である付加䜓たたはその塩、 および (B) 量平均分子量300〜20000の䜎分子量ポリ゚チ
レンの無氎マレむン酞ずの反応生成物 よりなる䜎枩流動性向䞊剀にある。 以䞋本発明を詳现に説明する。 本発明の流動性向䞊剀の成分は平均炭玠原子
数10〜30のα−オレフむンず無氎マレむン酞ずの
反応物ず高玚アルコヌルずの付加䜓であり、α−
オレフむンず無氎マレむン酞ずの反応物ずしお
は、α−オレフむンず無氎マレむ酞ずのの
付加䜓の他量平均重合床100以䞋、奜たしくは45
以䞋の共重合䜓を包含する。量平均重合床が100
を越える堎合は、燃料油ぞの溶解性が劣るず同時
に䜎枩流動性の効果も劣り奜たしくない。 本発明においお成分の原料ずしお䜿甚するα
−オレフむンは平均炭玠原子数10〜30の炭化氎玠
のα䜍に二重結合を有するオレフむン系炭化氎玠
であり、このα−オレフむンは単品であ぀おも異
なる炭玠数を有するα−オレフむンの混合物であ
぀おもよい。 α−オレフむンず無氎マレむン酞ずの共重合反
応は垞法に埓い、ラゞカル開始剀の存圚䞋に、適
圓な溶媒、䟋えばベンれン、トル゚ン、キシレ
ン、メチルむ゜ブチルケトン、ゞオキサン等を甚
い、あるいは無溶媒で80〜180℃の枩床で行なわ
れる。 たた重合床に察応するα−オレフむンず無氎
マレむン酞ずの付加物に぀いおは、垞法に埓い、
α−オレフむンず無氎マレむン酞ずを無溶媒䞋に
160〜230℃に加熱するこずによ぀お埗るこずがで
きる。 反応終了埌、溶媒、未反応α−オレフむンおよ
び無氎マレむ酞を枛圧蒞留によ぀お陀去すれば目
的の化合物が埗られる。 α−オレフむンず無氎マレむン酞ずの反応にお
いお埗られる反応物のα−オレフむンず無氎マレ
むン酞ずの構成モル比は通垞〜の範
囲でありこれらはいずれも䜿甚できる。 α−オレフむンず無氎マレむン酞の反応物は次
いで個の氎酞基を有する脂肪族アルコヌルず反
応させる。このアルコヌルは平均炭玠原子数〜
28、奜たしくは〜21の盎鎖あるいは分岐鎖を有
するものが利甚できる。これらのアルコヌルは単
品であ぀おも、炭玠原子数の異なるアルコヌルの
混合物であ぀おもよいが、本発明においおはアル
コヌルの最長炭玠鎖の平均炭玠原子数ずα−オレ
フむンの最長鎖アルキル基重合埌は偎鎖ずなる
郚分の平均炭玠原子数ずの和が21〜40、奜たし
は24〜34の範囲ずなる必芁がある。この合蚈炭玠
数が21未満のずき、たた40をこえる堎合は、その
効果はほずんど期埅出来ない。 α−オレフむンず無氎マレむン酞ずの反応物
ず、アルコヌルずの反応は垞法に埓い、酞觊媒を
任意に䜿甚し、適圓な溶媒、䟋えばベンれン、ト
ル゚ン、キシレン、メチル゚チルケトン、ゞオキ
サン等の溶媒䞭、たたは溶媒なしで、60〜140℃
に加熱するこずによ぀お行なわれる。 アルコヌルの反応モル比は、α−オレフむンず
無氎マレむン酞の反応物䞭の酞無氎物基に察しお
〜倍モルが適圓である。反応生成物䞭には、
酞無氎物基モルに察しお平均アルコヌルが0.5
〜1.5モル付加したものが奜たしい。 反応終了埌酞觊媒を氎掗陀去しおから、溶媒お
よび未反応アルコヌル等を蒞留によ぀お陀去し、
目的のアルコヌル付加䜓以埌これを単に付加䜓
ずいう。が埗られる。 䞊蚘付加䜓の塩は垞法により埗られる。䟋え
ば、ベンれン、トル゚ン、キシレン等の溶媒䞭、
たたは溶媒なしで、氎酞化カリりム、氎酞化ナト
リりム、氎酞化アンモニりムなどの氎酞化物ずず
もに50〜140℃に加熱し、生成する氎を反応倖系
に陀去するこずにより䞊蚘付加䜓の塩が埗られ
る。 かくしお埗られる付加䜓およびその塩は以䞋に
述べるワツクスの埮結晶化剀ずずもに䜿甚され、
埮結晶化されたワツクスの分散剀ずしお機胜す
る。 ワツクスの埮結晶化剀成分ずしおは、量
平均分子量300〜20000の䜎分子量ポリ゚チレン無
氎マレむン酞ずの反応生成物が甚いられる。䜎分
子量ポリ゚チレンずしおは、゚チレンの䜎重合に
よ぀お埗られるα−オレフむンやポリ゚チレンワ
ツクス、あるいは高分子量ポリ゚チレンの補造時
に副生するグリヌスワツクスなどが䜿甚される。
䜎分子量ポリ゚チレンの量平均分子量が300未満
の堎合は、燃料油䞭に含たれるワツクスずの盞互
䜜甚が䞍十分なために埮結晶化の効果が劣り、た
た、量平均分子量が20000を越えるず燃料油ぞの
溶解性が劣るので奜たしくない。 䜎分子量ポリ゚チレンず無氎マレむン酞ずの反
応生成物は、垞法に埓぀お、䜎分子量ポリ゚チレ
ンず、これに察しお0.1〜40wtの無氎マレむン
酞ずを混合し、ラゞカル開始剀の存圚䞋たたは䞍
存圚䞋に加熱し、共重合反応たたはグラフト化反
応を行なわせるこずにより埗るこずができる。 成分に察する成分の䜿甚割合は0.1〜10重
量倍、奜たしくは0.5〜重量倍の範囲が適圓で
ある。 このようにしお埗られる成分および成分か
ら成る䜎枩流動性向䞊剀は、炭化氎玠燃料油に察
しお10〜10000ppm、奜たしくは100〜1000ppmæ·»
加するこずによ぀お䜎枩における流動性を著しく
改善するこずができる。 以䞊詳述したように本発明においおは、それぞ
れ単独では䜎枩流動性効果を発揮しない二成分を
䜵甚するこずにより、燃料油に察し優れた䜎枩流
動性効果を付䞎するこずができる。 以䞋実斜䟋により本発明を説明する。 なお、量平均重合床の枬定方法および䜎枩流動
性詊隓方法を瀺す。 (1) 量平均重合床Pwの枬定方法 ゲルパヌミ゚ヌシペンクロマトグラフG.P.
C法により、暙準ポリスチレンの怜量線を甚
いお、䞋匏より算出した。 PwΣNiPi2ΣNiPi ただし、Pw量平均重合床 Niなる分子の分子数 Piなる分子の重合床 なお、枬定には、東掋曹達工業(æ ª)補、高速液䜓
クロマトグラフHLC−802URを䜿甚し、以䞋の
条件で行な぀た。 溶媒THF カラム4000、3000、2000×東曹カラム 枩床40℃ 流速1.2mlmin (2) 䜎枩流動性詊隓方法 䜎枩流動性の評䟡は、JIS  2269「石油補
品流動詊隓方法」により流動点を枬定するか、
たたはIP 30976芏栌に準拠した自動過噚
目詰り点詊隓噚TAMEC−CEPP−AEI補造
販売元吉田科孊噚械(æ ª)を甚いCFPPコヌル
ド フむルタヌ プラツキング ポむント
Cold filter plugging pointを枬定するこず
によ぀お行な぀た。 すなわち、−34℃に保持した济䞭に、ステン
レス筒で倖被したガラス詊隓筒を浞し、 なかに詊料45mlを入れ冷华し、350メツシナ
孔埄44Όのステンレス補の網濟過噚を
先端に蚭けたガラス補ピペツトを詊料内に挿入
し、200mm氎柱の枛圧䞋で詊料をピペツト内に
吞匕、詊料20mlがピペツトの所定の目盛迄䞊昇
する時間が60秒に至る迄の油の枩床を以぀お
CFPP倀ずしお衚わす。このCFPP倀枩床
が䜎い皋、濟過噚の目詰りを起す枩床が䜎い。
即ち䜎枩流動性が良いこずを瀺す。 実斜䟋 〔A‐〕 α−オレフむンず無氎マレむン酞の反応
物の補造 衚−に蚘茉したα−オレフむン1.0モル、
無氎マレむン酞1.2モルおよびキシレン3.0モ
ル実隓No.ではキシレン6.0モルを䜿甚し、
実隓No.ではトル゚ン3.0モルを䜿甚した。
をフラスコに仕蟌み、窒玠ガスで充分眮換し
たのち枩床を100℃に調敎しお撹拌しながら
タヌシダリヌブチルパヌオクテヌト玔床75
6.920.02モルを加え時間反応さ
せた。次いで昇枩しおキシレンを留去し、曎
に枛圧においお未反応α−オレフむンおよび
無氎マレむン酞を陀き、α−オレフむン・無
氎マレむン酞共重合䜓を埗た。実隓No.〜
埗られた共重合䜓の量平均重合床はゲル
パヌミ゚ヌシペンクロマトグラフ法により求
め、たたα−オレフむンず無氎マレむン酞ず
の共重合モル比は元玠分析により求め、それ
ぞれ衚−に瀺した。 炭玠原子数18のα−オレフむン1.0モルず
無氎マレむン酞1.0モルずをフラスコに
仕蟌み、窒玠眮換を行な぀たのち、撹拌䞋
200℃に昇枩し、同枩床で時間反応させた。
次いで埐々に枛圧床を高めながら未反応のα
−オレフむンおよび無氎マレむン酞を留去
し、α−オレフむンず無氎マレむン酞付加物
270を埗た。α−オレフむンず無氎マレむ
ン酞ずの付加モル比は酞䟡の枬定により求め
た。結果は衚−に瀺す。 The present invention relates to a low temperature fluidity improver, and more particularly to an additive for improving the low temperature fluidity of hydrocarbon fuel oil. Hydrocarbon fuel oils, such as light oil, A heavy oil, etc.
- Because it contains paraffin wax, precipitation of n-paraffin wax often occurs in cold winter regions, resulting in blockage of oil pipes and strainers installed in the fuel supply circuit of internal combustion engines. This causes major problems with the fluidity of fuel oil at low temperatures, such as clogging. To solve this problem, additives commonly called cold flow improvers are used. Various types of low-temperature fluidity improvers have been studied and proposed, including ethylene-vinyl acetate copolymers. For example, the copolymer of ethylenically unsaturated dicarboxylic acid and α-olefin described in JP-A No. 54-157106, and the copolymer of ethylenically unsaturated dicarboxylic acid and α-olefin described in JP-A-50-15005. Long-chain alcohol esters of polymers, and JP-A-54-
Known are aliphatic amine-modified copolymers of ethylenically unsaturated dicarboxylic acids and α-olefins, described in JP 81307. However, these effects are still not sufficient. Recently, a method has been proposed in which a second or third component is added in order to compensate for the effects of the above-mentioned additives. For example, as described in JP-A No. 54-86505, ethylene-
A method in which a second component such as a vinyl acetate copolymer is used in combination, or as described in U.S. Pat. No. 4,210,424, n-paraffin wax and Methods have been proposed in which a nitrogen-containing compound is used in combination, but these methods do not work effectively on heavy light oil or heavy oil obtained from heavy crude oil containing large amounts of paraffin, such as Daqing and Minas. Regarding the low-temperature fluidity of fuel oil, the present inventors have
In our research into the relationship between the morphology of wax that precipitates from fuel oil at low temperatures and the effects of additives, we discovered the following interesting phenomenon. In other words, in order to improve the low-temperature fluidity of fuel oil, (1) the crystal size of wax that precipitates at low temperatures must be kept as small as possible; (2) To stably disperse the precipitated wax crystals in oil. These two points are important, and rather than the conventional method of combining these separate functions with a single compound, we need to create separate compounds with each function, namely (1) wax microcrystal. A more rational method is to combine two types of compounds: (2) a compound with the function of dispersing wax crystals stably in oil (microcrystallization agent) and (2) a compound with the function of stably dispersing wax crystals in oil. and found that it is effective. Based on these findings, the present inventors searched for compounds and combinations thereof that are effective as microcrystallization agents and dispersants, and arrived at the low-temperature fluidity improver of the present invention. That is, the gist of the present invention is that (A) the amount average degree of polymerization of the α-olefin having an average carbon number of 10 to 30 and maleic anhydride is 1 to 100;
and an aliphatic alcohol having an average carbon number of 6 to 28, the average number of carbon atoms of the longest chain alkyl group of the α-olefin and the average carbon atom of the longest carbon chain of the aliphatic alcohol. and (B) a reaction product of low molecular weight polyethylene with a weight average molecular weight of 300 to 20,000 and maleic anhydride. The present invention will be explained in detail below. Component A of the fluidity improver of the present invention is an adduct of an α-olefin having an average carbon number of 10 to 30 and maleic anhydride, and a higher alcohol.
As the reaction product of olefin and maleic anhydride, the other weight average degree of polymerization of the 1:1 adduct of α-olefin and maleic anhydride is 100 or less, preferably 45
Includes the following copolymers: Weight average degree of polymerization is 100
If it exceeds the above range, the solubility in fuel oil will be poor and the low-temperature fluidity effect will also be poor, which is not preferable. α used as a raw material for component A in the present invention
- Olefin is an olefinic hydrocarbon having a double bond at the α-position of a hydrocarbon having an average number of carbon atoms of 10 to 30, and even if this α-olefin is a single product, it is a mixture of α-olefins having different numbers of carbon atoms. It may be hot. The copolymerization reaction between α-olefin and maleic anhydride is carried out in the presence of a radical initiator using a suitable solvent such as benzene, toluene, xylene, methyl isobutyl ketone, dioxane, etc., or without solvent at 80°C. It is carried out at a temperature of ~180°C. Regarding the adduct of α-olefin and maleic anhydride corresponding to a degree of polymerization of 1, according to the conventional method,
α-olefin and maleic anhydride without solvent
It can be obtained by heating to 160-230°C. After the reaction is completed, the target compound is obtained by removing the solvent, unreacted α-olefin and maleic anhydride by distillation under reduced pressure. The constituent molar ratio of the reaction product α-olefin and maleic anhydride obtained in the reaction of α-olefin and maleic anhydride is usually in the range of 1:1 to 1:2, and any of these can be used. The reaction product of alpha-olefin and maleic anhydride is then reacted with an aliphatic alcohol having one hydroxyl group. This alcohol has an average number of carbon atoms of 6 to
28, preferably 7 to 21 linear or branched chains can be used. These alcohols may be used alone or as a mixture of alcohols having different numbers of carbon atoms, but in the present invention, the average number of carbon atoms in the longest carbon chain of the alcohol and the longest chain alkyl group (polymerized The sum of the average number of carbon atoms in the portions (which later become side chains) needs to be in the range of 21 to 40, preferably 24 to 34. When the total number of carbon atoms is less than 21 or more than 40, almost no effect can be expected. The reaction between the reaction product of α-olefin and maleic anhydride and the alcohol can be carried out according to a conventional method, optionally using an acid catalyst, in a suitable solvent such as benzene, toluene, xylene, methyl ethyl ketone, dioxane, etc. 60-140℃ without solvent
This is done by heating to. The reaction molar ratio of alcohol is suitably 1 to 2 times the molar ratio of the acid anhydride group in the reaction product of α-olefin and maleic anhydride. In the reaction product,
Average alcohol content is 0.5 per mole of acid anhydride group.
It is preferable to add up to 1.5 mol. After the reaction is completed, the acid catalyst is removed by washing with water, and the solvent and unreacted alcohol are removed by distillation.
The desired alcohol adduct (hereinafter simply referred to as adduct) is obtained. Salts of the above adducts can be obtained by conventional methods. For example, in a solvent such as benzene, toluene, xylene, etc.
Alternatively, the salt of the above adduct can be obtained by heating to 50 to 140°C with a hydroxide such as potassium hydroxide, sodium hydroxide, or ammonium hydroxide without a solvent and removing the generated water to the outside of the reaction system. . The adduct and its salt thus obtained are used with the wax microcrystallization agent described below,
Functions as a dispersant for microcrystalline wax. As the wax microcrystallization agent (component B), a reaction product of low molecular weight polyethylene with maleic anhydride having a weight average molecular weight of 300 to 20,000 is used. As the low molecular weight polyethylene, α-olefin or polyethylene wax obtained by low polymerization of ethylene, or grease wax produced as a by-product during the production of high molecular weight polyethylene, etc. are used.
If the weight average molecular weight of low molecular weight polyethylene is less than 300, the effect of microcrystallization will be poor due to insufficient interaction with the wax contained in fuel oil, and if the weight average molecular weight exceeds 20,000, the fuel It is not preferred because of its poor solubility in oil. The reaction product of low molecular weight polyethylene and maleic anhydride is prepared by mixing low molecular weight polyethylene with 0.1 to 40 wt% of maleic anhydride based on the conventional method, and then mixing the low molecular weight polyethylene with 0.1 to 40 wt% maleic anhydride in the presence or absence of a radical initiator. It can be obtained by heating in the presence of the compound to carry out a copolymerization reaction or a grafting reaction. The appropriate ratio of component B to component A is 0.1 to 10 times by weight, preferably 0.5 to 2 times by weight. The low-temperature fluidity improver composed of component A and component B obtained in this way can significantly improve fluidity at low temperatures by adding 10 to 10,000 ppm, preferably 100 to 1,000 ppm to hydrocarbon fuel oil. be able to. As described in detail above, in the present invention, by using together two components that do not exhibit a low-temperature fluidity effect on their own, it is possible to impart an excellent low-temperature fluidity effect to fuel oil. The present invention will be explained below with reference to Examples. The method for measuring the amount-average degree of polymerization and the method for testing low-temperature fluidity are shown below. (1) Measurement method of weight average degree of polymerization (Pw) Gel permeation chromatography (GP
Calculated by method C) using the standard polystyrene calibration curve and the following formula. Pw=ΣNiPi 2 /ΣNiPi Where, Pw: Weight average degree of polymerization Ni: Number of molecules of molecule i Pi: Degree of polymerization of molecule i For measurement, use a high performance liquid chromatograph HLC- manufactured by Toyo Soda Kogyo Co., Ltd. The test was conducted using 802UR under the following conditions. Solvent: THF Column: 4000, 3000, 2000 x 2 (Toso column) Temperature: 40°C Flow rate: 1.2ml/min (2) Low temperature fluidity test method Low temperature fluidity evaluation is based on JIS K 2269 "Petroleum product fluidity test" method” to measure the pour point, or
Alternatively, measure the CFPP cold filter plugging point using an automatic filter plugging point tester TAMEC-CEPP-AEI (manufacturer: Yoshida Scientific Instruments Co., Ltd.) that complies with IP 309/76 standards. I did this by doing this. That is, a glass test tube covered with a stainless steel cylinder was immersed in a bath kept at -34℃, 45ml of the sample was placed inside, cooled, and a 350 mesh (pore diameter 44ÎŒ) stainless steel mesh (filter) was inserted at the tip. Insert a glass pipette set into the sample into the sample, draw the sample into the pipette under reduced pressure of 200 mm of water, and measure the temperature of the oil until the time it takes for 20 ml of the sample to rise to the specified scale on the pipette for 60 seconds. Tsute
Expressed as CFPP value. This CFPP value (temperature)
The lower the temperature, the lower the temperature at which the filter becomes clogged.
That is, it shows good low-temperature fluidity. Example [A-] Production of a reaction product of α-olefin and maleic anhydride 1.0 mol of α-olefin listed in Table-1,
1.2 mol of maleic anhydride and 3.0 mol of xylene (6.0 mol of xylene was used in experiment No. 7,
In Experiment No. 8, 3.0 mol of toluene was used. )
After filling the flask with nitrogen gas, adjust the temperature to 100℃ and add tert-butyl peroctate (purity 75) while stirring.
%) 6.92g (0.02mol) was added and reacted for 6 hours. Next, the temperature was raised to distill off xylene, and unreacted α-olefin and maleic anhydride were removed under reduced pressure to obtain an α-olefin/maleic anhydride copolymer. (Experiment No. 1~
8) The weight average degree of polymerization of the obtained copolymer was determined by gel permeation chromatography, and the copolymerization molar ratio of α-olefin and maleic anhydride was determined by elemental analysis, and is shown in Table 1. Ta. 1.0 mol of α-olefin having 18 carbon atoms and 1.0 mol of maleic anhydride were placed in one flask, and after purging with nitrogen, the mixture was stirred.
The temperature was raised to 200°C, and the reaction was continued at the same temperature for 8 hours.
Then, while gradually increasing the degree of vacuum, unreacted α
- Olefin and maleic anhydride are distilled off to form an α-olefin and maleic anhydride adduct.
Obtained 270g. The addition molar ratio of α-olefin and maleic anhydride was determined by measuring the acid value. The results are shown in Table-1.

【衚】 合物であり、その他は単䞀の炭玠原子数を有す
るα−オレフむンである。
〔A‐〕 成分の補造 〔−〕で補造したα−オレフむンず無
氎マレむン酞ずの反応物実隓No.290.5
酞無氎物基1.0モルを含む量、炭玠原子
数13の合成アルコヌルダむダドヌル13商
暙、䞉菱化成工業(æ ª)補200.4およびキシ
レン122.3をフラスコに仕蟌み、撹拌
例100℃に昇枩し、同枩床で時間反応させ、
α−オレフむンず無氎マレむン酞ずの反応物
の半゚ステル化物486を埗た。埗られた付
加䜓の゚ステル化床は酞䟡の枬定により48
ず求められた。 たた、〔−〕の実隓No.で埗たα−オ
レフむン・無氎マレむン酞共重合䜓ず炭玠原
子数15のアルコヌルダむダドヌル15商
暙、䞉菱化成工業瀟補ずの付加䜓および
該付加䜓に含たれる氎酞基ず圓量の氎酞化カ
リりムをフラスコ䞭で撹拌䞋に135〜140℃に
加熱し、生成する氎を反応系倖に陀去し、濃
床調敎のため適量のキシレンを添加しお付加
䜓のカリりム塩を補造した。 同様の方法により衚−に瀺すアルコヌル
ずの付加䜓およびその塩を補造し、本発明の
䜎枩流動性向䞊剀の成分ずしお䜿甚した。
補造した成分を衚−に瀺す。[Table] Compounds, and the others are α-olefins having a single number of carbon atoms.
[A-] Production of component A Reactant of α-olefin produced in [A-] and maleic anhydride (Experiment No. 8) 290.5
(amount containing 1.0 mol of acid anhydride group), 200.4 g of synthetic alcohol having 13 carbon atoms (Diadol 13 (trademark), manufactured by Mitsubishi Chemical Industries, Ltd.) and 122.3 g of xylene were placed in one flask, and under stirring. Raise the temperature to 100℃ and react at the same temperature for 4 hours,
486 g of a half-esterified product of a reaction product of α-olefin and maleic anhydride was obtained. The degree of esterification of the obtained adduct was 48% as determined by acid value measurement.
was asked. In addition, an adduct of the α-olefin/maleic anhydride copolymer obtained in Experiment No. 5 of [A-] and an alcohol having 15 carbon atoms (Diadol 15 (trademark), manufactured by Mitsubishi Chemical Industries, Ltd.) and Potassium hydroxide in an amount equivalent to the hydroxyl group contained in the adduct is heated to 135 to 140°C with stirring in a flask, the water produced is removed from the reaction system, and an appropriate amount of xylene is added to adjust the concentration. The potassium salt of the adduct was prepared. Adducts with alcohols and salts thereof shown in Table 2 were produced in a similar manner and used as component A of the low temperature fluidity improver of the present invention.
The manufactured component A is shown in Table 3.

【衚】【table】

【衚】【table】

【衚】 〔B‐〕 成分の補造− 平均炭玠原子数玄48のα−オレフむン䞉
菱化成工業(æ ª)補、ダむダレン30商暙600
および無氎マレむン酞90.0をフラス
コに仕蟌み窒玠眮換埌、180℃の枩床条件で
撹拌䞋にゞヌタヌシダリヌブチルパヌオキサ
むド4.56を添加し、時間反応を行な぀
た。次いで、埐々に枛圧床を高めながら未反
応の無氎マレむン酞を留去し、α−オレフむ
ン・無氎マレむン酞共重合䜓690を埗た
−。埗られた共重合䜓の量平均重合床
は、ゲルパヌミ゚むシペンクロマトグラフむ
ヌにより、12.5ず求められた。 同様に、無氎マレむン酞の仕蟌量あるいは
α−オレフむンの皮類を倉曎しおα−オレフ
むン・無氎マレむン酞共重合䜓−およ
び−を補造した。結果は衚−に瀺
す。 ゞヌタヌシダリヌブチルパヌオキサむドを
添加しないで、220℃で時間反応を行な぀
たこず以倖は䞊蚘ず同様の方法でα−オレフ
むン・無氎マレむン酞付加䜓−および
−を補造した。結果は衚−に瀺す。[Table] [B-] Production of component B-1 α-olefin with an average number of carbon atoms of about 48 (manufactured by Mitsubishi Chemical Industries, Ltd., Dialene 30 (trademark)) 600
g and 90.0 g of maleic anhydride were placed in one flask, and after purging with nitrogen, 4.56 g of tertiary butyl peroxide was added under stirring at a temperature of 180° C., and the reaction was carried out for 4 hours. Next, unreacted maleic anhydride was distilled off while gradually increasing the degree of vacuum, to obtain 690 g of an α-olefin/maleic anhydride copolymer (B-1). The weight average degree of polymerization of the obtained copolymer was determined to be 12.5 by gel permeation chromatography. Similarly, α-olefin/maleic anhydride copolymers (B-2 and B-3) were produced by changing the amount of maleic anhydride charged or the type of α-olefin. The results are shown in Table-4. α-olefin/maleic anhydride adducts (B-4 and B-5) were produced in the same manner as above, except that the reaction was carried out at 220°C for 8 hours without adding di-tertiary butyl peroxide. did. The results are shown in Table-4.

【衚】 〔B‐〕 成分の補造− 数平均分子量数3500の䜎分子量ポリ゚チレ
ンポリ゚チレン補造時の副生グリヌスワツ
クス1000および無氎マレむン酞30を
フラスコに仕蟌み、窒玠眮換埌、160℃の
枩床条件で撹拌しながらゞヌタヌシダリヌブ
チルパヌオキサむド2.2を加え、時間反
応させた。次いで埐々に枛圧床を高めながら
未反応の無氎マレむン酞を留去し、量平均分
子量玄6400の䜎分子量ポリ゚チレン・無氎マ
レむン酞共重合䜓−1028.7を埗
た。 同様に、無氎マレむン酞の仕蟌み量あるい
は䜎分子量ポリ゚チレンの皮類を倉曎しお䜎
分子量ポリ゚チレン・無氎マレむン酞共重合
䜓−、−および−を補造し
た。結果は衚−に瀺す。[Table] [B-] Production of component B-2 1000 g of low molecular weight polyethylene with a number average molecular weight of 3500 (grease wax, a by-product during polyethylene production) and 30 g of maleic anhydride were mixed into 2
After charging the mixture into a flask and purging with nitrogen, 2.2 g of tertiary butyl peroxide was added while stirring at a temperature of 160° C., and the mixture was reacted for 4 hours. Then, unreacted maleic anhydride was distilled off while gradually increasing the degree of vacuum to obtain 1028.7 g of a low molecular weight polyethylene/maleic anhydride copolymer (B-6) having a weight average molecular weight of about 6400. Similarly, low molecular weight polyethylene/maleic anhydride copolymers (B-7, B-8 and B-9) were produced by changing the amount of maleic anhydride charged or the type of low molecular weight polyethylene. The results are shown in Table-5.

【衚】 〔C‐〕 䜎枩流動性詊隓− 垂販軜質軜油比重0.8356、硫黄分0.60、
流動点−7.5℃、匕火点72℃、動粘床
2.71cst50℃および重質経由比重
0.9012、硫黄分2.4、流動点22.5℃、匕火点
144℃、動粘床11.68cst50℃を重量比で
8020に配合した燃料油に先に補造した成分
A500ppmおよびたたは成分B500ppmを添
加し、䜎枩流動性を評䟡した。結果を衚−
に瀺す。[Table] [C-] Low temperature fluidity test-1 Commercially available light gas oil (specific gravity 0.8356, sulfur content 0.60,
Pour point -7.5℃, flash point 72℃, kinematic viscosity
2.71cst/50℃) and via heavy (specific gravity
0.9012, sulfur content 2.4, pour point +22.5℃, flash point
144℃, kinematic viscosity 11.68cst/50℃) by weight
80:20 blended fuel oil with previously manufactured ingredients
500 ppm of A and/or 500 ppm of component B were added to evaluate low temperature fluidity. Table 6 of the results
Shown below.

【衚】【table】

【衚】 〔C‐〕 䜎枩流動性詊隓− 流動点℃のミナス系重油に先に補造し
た成分および成分を添加しお流動点を枬
定した。結果は衚−に瀺す。[Table] [C-] Low-temperature fluidity test-2 Component A and component B prepared previously were added to Minas A heavy oil with a pour point of 5°C, and the pour point was measured. The results are shown in Table-7.

【衚】【table】

【衚】【table】

Claims (1)

【特蚱請求の範囲】  (A) 平均炭玠原子数10〜30のα−オレフむン
および無氎マレむン酞の量平均重合床が〜
100の反応物ず平均炭玠原子数〜28の脂肪族
アルコヌルずの付加䜓であ぀お、該α−オレフ
むンの最長鎖アルキル基の平均炭玠原子数ず該
脂肪族アルコヌルの最長炭玠鎖の平均炭玠原子
数ずの和が21〜40である付加䜓たたはその塩、 および (B) 量平均分子量300〜20000の䜎分子量ポリ゚チ
レンの無氎マレむン酞ずの反応生成物 よりなる䜎枩流動性向䞊剀。[Scope of Claims] 1 (A) α-olefin having an average number of carbon atoms of 10 to 30 and maleic anhydride having a quantity average degree of polymerization of 1 to 30;
100 reactant and an aliphatic alcohol having an average number of carbon atoms of 6 to 28, the average number of carbon atoms in the longest chain alkyl group of the α-olefin and the average carbon number of the longest carbon chain of the aliphatic alcohol. A low-temperature fluidity improver comprising: an adduct or a salt thereof having a sum of atomic numbers of 21 to 40; and (B) a reaction product of low molecular weight polyethylene with a weight average molecular weight of 300 to 20,000 and maleic anhydride.
JP6056582A 1982-04-12 1982-04-12 Low-temperature fluidity improver Granted JPS58176288A (en)

Priority Applications (5)

Application Number Priority Date Filing Date Title
JP6056582A JPS58176288A (en) 1982-04-12 1982-04-12 Low-temperature fluidity improver
DE19833340211 DE3340211T1 (en) 1982-04-12 1983-02-09 Low temperature fluidity improver
GB08332811A GB2129012B (en) 1982-04-12 1983-02-09 Agent for improving low temperature fluidity of fuel oil
PCT/JP1983/000039 WO1983003615A1 (en) 1982-04-12 1983-02-09 Agent for improving low temperature fluidity of fuel oil
US06/562,586 US4652611A (en) 1982-04-12 1983-02-09 Low-temperature fluidity improver

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP6056582A JPS58176288A (en) 1982-04-12 1982-04-12 Low-temperature fluidity improver

Publications (2)

Publication Number Publication Date
JPS58176288A JPS58176288A (en) 1983-10-15
JPH0366357B2 true JPH0366357B2 (en) 1991-10-17

Family

ID=13145909

Family Applications (1)

Application Number Title Priority Date Filing Date
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Country Status (1)

Country Link
JP (1) JPS58176288A (en)

Families Citing this family (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH0662964B2 (en) * 1986-10-31 1994-08-17 䜏友化孊工業株匏䌚瀟 Fuel oil composition

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