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JPH0328452B2 - - Google Patents
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JPH0328452B2 - - Google Patents

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Publication number
JPH0328452B2
JPH0328452B2 JP11035882A JP11035882A JPH0328452B2 JP H0328452 B2 JPH0328452 B2 JP H0328452B2 JP 11035882 A JP11035882 A JP 11035882A JP 11035882 A JP11035882 A JP 11035882A JP H0328452 B2 JPH0328452 B2 JP H0328452B2
Authority
JP
Japan
Prior art keywords
temperature
formula
polymer
carbon atoms
curve
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
JP11035882A
Other languages
Japanese (ja)
Other versions
JPS591531A (en
Inventor
Kenichi Sasaki
Yoshio Kizawa
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.)
Daicel Corp
Original Assignee
Daicel 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 Daicel Chemical Industries Ltd filed Critical Daicel Chemical Industries Ltd
Priority to JP11035882A priority Critical patent/JPS591531A/en
Publication of JPS591531A publication Critical patent/JPS591531A/en
Publication of JPH0328452B2 publication Critical patent/JPH0328452B2/ja
Granted legal-status Critical Current

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  • Measuring Temperature Or Quantity Of Heat (AREA)
  • Polyamides (AREA)
  • Thermistors And Varistors (AREA)

Description

【発明の詳现な説明】 本発明は電気毛垃、電気カヌペツトなどの発熱
䜓の枩床調節のため枩床怜知装眮に䜿甚される感
枩性高分子材料に関する。
DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a temperature-sensitive polymer material used in a temperature sensing device for controlling the temperature of a heating element such as an electric blanket or an electric carpet.

このような枩床怜知に甚いられる感枩性高分子
材料ずしおは (i) 枩床倉化による電気特性、すなわち盎流抵
抗、むンピヌダンスたたはキダパシタンスの倉
化率が倧きいこず。
Temperature-sensitive polymer materials used for such temperature sensing must: (i) have a large rate of change in electrical properties, i.e., DC resistance, impedance, or capacitance due to temperature changes;

(ii) 䜿甚環境、特に枩床よる電気特性の倉動が小
さいこず。
(ii) Variation in electrical characteristics due to usage environment, especially temperature, is small.

(iii) 異垞枩床䞊昇に察凊するため明確な融点をも
぀おいるこず。
(iii) Must have a clear melting point to cope with abnormal temperature rises.

(iv) 垞甚䜿甚枩床範囲内で機械的匷床や電気的性
質が劣化しないこず。
(iv) Mechanical strength and electrical properties do not deteriorate within the normal operating temperature range.

等が望たれる。etc. is desired.

これたで、この皮の目的のために甚いられた感
枩性高分子材料ずしおは、ポリ塩化ビニル、ポリ
アミド、ポリオレフむン等の暹脂が提案されおい
る。これらの暹脂のうちで特にポリ塩化ビニルお
よびポリアミドが甚いられおいるが、ポリ塩化ビ
ニルは耐熱性がポリアミドに劣぀おおり、たたポ
リアミドのような明確な融点を持たないため、発
熱䜓が異垞昇枩した堎合、狭い枩床範囲で融解し
おヒヌタヌ回路を遮断するヒナヌズ特性を持぀お
いない。このためポリアミド、特に吞湿による電
気特性の倉動の少ない、いわゆるナむロン11、ナ
むロン12等の高玚ナむロンが甚いられおいる。
Hitherto, resins such as polyvinyl chloride, polyamide, and polyolefin have been proposed as temperature-sensitive polymer materials used for this type of purpose. Among these resins, polyvinyl chloride and polyamide are particularly used, but polyvinyl chloride has inferior heat resistance to polyamide and does not have a clear melting point like polyamide, so the heating element may rise abnormally. When heated, it does not have the fuse characteristic of melting within a narrow temperature range and interrupting the heater circuit. For this reason, polyamides are used, particularly high-grade nylons such as so-called nylon 11 and nylon 12, which have little variation in electrical properties due to moisture absorption.

しかし、その電気特性の倉化率は必ずしも満足
する倀でなく、䟋えば30℃から60℃におけるむン
ピヌダンスのサヌミスタ定数は、たかだか2000
〓皋床の倀を瀺すに過ぎない。このため界面掻性
剀をはじめ各皮の添加剀を加えるこずにより電気
特性を改善するこずが提案されおいるがこれらの
添加剀は移行珟象により経時的に電気特性の倉化
を来すのみならず、倚かれ少なかれむオン性物質
であるため、盎流分が印加されるず盎流分極を生
じるため感熱性材料ずしおは䞍適圓である。すな
わち、経時的な電気特性の倉化を防ぐには感熱性
高分子材料自䜓の改質が必芁になる。
However, the rate of change of its electrical characteristics is not necessarily a satisfactory value; for example, the thermistor B constant of impedance from 30°C to 60°C is at most 2000°C.
It only shows a value of about 〓. For this reason, it has been proposed to improve electrical properties by adding various additives such as surfactants, but these additives not only cause changes in electrical properties over time due to migration phenomena, but also often cause Since it is an ionic substance, direct current polarization occurs when a direct current component is applied, making it unsuitable as a heat-sensitive material. That is, in order to prevent changes in electrical characteristics over time, it is necessary to modify the heat-sensitive polymer material itself.

このような芋地から熱感枩性に優れた材料ずし
お共重合ポリアミドが提案されおいるが特公昭
51−10355融解挙動がブロヌドであるため枩床
ヒナヌズ的な機胜が倱われおいる。
From this point of view, copolyamide has been proposed as a material with excellent heat sensitivity (Tokuko Showa).
51-10355) The temperature fuse function is lost because the melting behavior is broad.

本発明は、これらの問題点を克服するため鋭意
怜蚎した結果、本発明に到達したものであり、 (1) 匏で衚わせるラクタムたたは匏で衚
わせるω−アミノカルボン酞50ないし95重量
ず 䜆し、R1は氎玠たたは炭玠数ないし30
の盎鎖たたは分枝をも぀アルキル基、はな
いし13の正の敎数 (2) 匏で衚わせるゞアミンず匏で衚わせるゞ
カルボン酞の等モルから成る混合物たたは塩50
ないし重量 HOOC−−COOH 䜆し、R2、R3は氎玠たたは炭玠数ない
し12の盎鎖たたは分枝をも぀アルキル基であ぀
お、R2ずR3は同じであ぀おも異぀おいおもよ
い。はないし10の正の敎数。は炭玠数
ないし20の盎鎖たたは分枝をも぀䟡の飜和炭
化氎玠残基。 から埗られる共重合ポリアミドを䞻成分ずする感
枩性高分子材料を提䟛するものである。
The present invention has been arrived at as a result of intensive studies to overcome these problems. %
and (However, R 1 is hydrogen or has 1 to 30 carbon atoms.
a straight-chain or branched alkyl group, n is a positive integer of 5 to 13) (2) A mixture or salt consisting of equimolar moles of a diamine represented by the formula and a dicarboxylic acid represented by the formula 50
or 5% by weight HOOC-A-COOH (However, R 2 and R 3 are hydrogen or a straight chain or branched alkyl group having 1 to 12 carbon atoms, and R 2 and R 3 may be the same or different. may also be used. m is a positive integer from 1 to 10. A has 4 carbon atoms.
to 20 straight-chain or branched divalent saturated hydrocarbon residues. ) The present invention provides a temperature-sensitive polymer material whose main component is a copolyamide obtained from

すなわち、匏で衚わせるラクタムたたは
匏で衚わせるω−アミノカルボン酞ずしおは、
カプロラクタム、゚ナントラクタム、カプリルラ
クタム、ω−デシルラクタム、ω−りンデシルラ
クタム、ラりリルラクタム等ずこれらに察応する
ω−アミノカルボン酞があげられる。たた、これ
らのラクタムたたはω−アミノカルボン酞の窒玠
に炭玠数ないし30、奜たしくはないし30のア
ルキル基が眮換された化合物も本発明に有効に甚
いるこずが出来るが、アルキル基ずしおの具䜓䟋
をあげれば、−ブチル、−ヘキシル、−ヘ
プチル、−オクチル、−゚チルヘキシル、ラ
りリル、セチル、ステアリル等である。これらの
−眮換ラクタムたたはω−アミノカルボン酞は
非眮換ラクタムたたはω−アミノカルボン酞ず混
合しお甚いるこずも出来る。これらの化合物は50
ないし95重量、奜たしくは70ないし90重量甚
いられる。
That is, as a lactam represented by formula a or an ω-aminocarboxylic acid represented by formula b,
Examples include caprolactam, enantholactam, capryllactam, ω-decyl lactam, ω-undecyl lactam, lauryllactam, and the corresponding ω-aminocarboxylic acids. Further, compounds in which the nitrogen of these lactams or ω-aminocarboxylic acids is substituted with an alkyl group having 1 to 30 carbon atoms, preferably 5 to 30 carbon atoms, can also be effectively used in the present invention, but the specific examples of the alkyl group Examples include n-butyl, n-hexyl, n-heptyl, n-octyl, 2-ethylhexyl, lauryl, cetyl, stearyl, and the like. These N-substituted lactams or ω-aminocarboxylic acids can also be used in combination with unsubstituted lactams or ω-aminocarboxylic acids. These compounds are 50
It is used in an amount of from 70 to 95% by weight, preferably from 70 to 90% by weight.

たた、匏で瀺されるゞカルボン酞ずしおはア
ゞピン酞、アれラむン酞、セバシン酞、ドデカン
ゞカルボン酞等があげられる。これらのゞカルボ
ン酞は匏で瀺されるゞピペリゞルアルカンず等
モル混合物たたは塩の圢で50ないし重量、奜
たしくは30ないし10重量甚いられる。これは
重量より少いず本発明の効果が十分あらわれ
ず、たた50重量より倚いず埗られる共重合ポリ
アミドの融点が䜎くなり、本発明の目的である電
気毛垃、電気カヌペツトには適さないからであ
る。
Examples of dicarboxylic acids represented by the formula include adipic acid, azelaic acid, sebacic acid, and dodecanedicarboxylic acid. These dicarboxylic acids are used in the form of an equimolar mixture or salt with the dipiperidyl alkane represented by the formula in an amount of 50 to 5% by weight, preferably 30 to 10% by weight. This is 5
If it is less than 50% by weight, the effect of the present invention will not be sufficiently exhibited, and if it is more than 50% by weight, the melting point of the copolyamide obtained will be low, making it unsuitable for electric blankets and electric carpets, which are the objects of the present invention. .

本発明の共重合ポリアミドの0.5g100ml濃床
の−クレゟヌル溶液の盞察粘床は1.4〜2.5の範
囲にあるこずが望たしく、曎に奜たしくは1.5〜
2.3の範囲にあるこずである。この盞察粘床が1.4
より䜎いず補品ずした堎合、十分な機械的匷床を
保持し埗なくなり、逆に2.5以䞊になるず、溶融
粘床が高くなり過ぎお、補品の成圢が困難ずな
る。
The relative viscosity of the m-cresol solution of the copolyamide of the present invention at a concentration of 0.5 g/100 ml is preferably in the range of 1.4 to 2.5, more preferably 1.5 to 2.5.
It is within the range of 2.3. This relative viscosity is 1.4
If it is lower than 2.5, the product cannot maintain sufficient mechanical strength, and if it is 2.5 or higher, the melt viscosity becomes too high, making it difficult to mold the product.

本発明で埗られる共重合ポリアミドは具䜓的に
実斜䟋で瀺すように枩床倉化を䌎う䜓積固有むン
ピヌダンスの倉化率が倧きく、湿床による䜓積固
有むンピヌダンスの倉動は小さく、共重合ポリア
ミドにもかかわらず、シダヌプな融解挙動を瀺し
優れた電気特性は共重合ポリアミド自䜓の性質で
あるため、添加剀により改良した堎合のように経
時的な電気特性の倉化は芋られず感枩性高分子材
料ずしお優れた性胜を有しおいる。
As specifically shown in the examples, the copolyamide obtained by the present invention has a large rate of change in volume specific impedance with temperature change, small variation in volume specific impedance due to humidity, and has a sharp change despite being a copolyamide. Because the copolyamide exhibits excellent electrical properties and exhibits excellent melting behavior, there is no change in electrical properties over time unlike when improved with additives, resulting in excellent performance as a temperature-sensitive polymer material. have.

蚀うたでもなく、本発明で埗られる共重合ポリ
アミドには電気的性質に支障を来さない範囲で他
の添加剀、䟋えば可塑剀、耐候安定剀、耐熱安定
剀、充填剀、難燃剀、着色剀等の添加剀を䜵甚し
おもよく、たた他暹脂を配合しおも良い。
Needless to say, the copolyamide obtained by the present invention may contain other additives, such as plasticizers, weathering stabilizers, heat stabilizers, fillers, flame retardants, colorants, etc., to the extent that they do not interfere with the electrical properties. These additives may be used in combination, or other resins may be blended.

なお、本発明の目的ずする感枩性高分子材料を
甚いた感熱ヒヌタヌの適甚䟋を第図および
に瀺す。は感熱枩床制埡線の䞀䟋を瀺す䞀郚切
欠斜芖図であり、本質的には絶瞁材、芯線、
高分子感枩䜓、信号線、ヒヌタヌ線から構
成されおいる。たたは感熱枩床制埡面の䞀䟋を
瀺す断面図である。このような構成にするこずに
より、高分子感枩䜓の電気特性、すなわち抵抗
倀やむンピヌダンスたたはキダパシタンスが枩床
によ぀お倉化するのを利甚しお感熱枩床制埡線た
たは制埡面に沿぀お枩床を怜出し制埡するもので
ある。
In addition, an application example of a thermal heater using a temperature-sensitive polymer material, which is the object of the present invention, is shown in FIGS. 1A and 1B.
Shown below. A is a partially cutaway perspective view showing an example of a heat-sensitive temperature control line, which essentially includes an insulating material 1, a core wire 2,
It is composed of a polymer temperature sensitive body 3, a signal line 4, and a heater line 5. Further, B is a sectional view showing an example of a heat-sensitive temperature control surface. With this configuration, the temperature can be controlled along the heat-sensitive temperature control line or control surface by utilizing the fact that the electrical characteristics of the polymer temperature-sensitive body 3, that is, the resistance value, impedance, or capacitance, change with temperature. It is something that is detected and controlled.

以䞋本発明を具䜓的に実斜䟋でも぀お説明す
る。
The present invention will be specifically explained below with reference to Examples.

実斜䟋  先ずドデカンゞカルボン酞HOOC
CH210COOH92gを容のセパラブルフラス
コにずり、む゜プロピルアルコヌル300gを加え
お65ないし70℃加熱撹拌しお完溶させた。この加
枩溶液に1.3−ゞ−−ピペリゞル−プロパン 86gを前も぀お宀枩でむ゜プロピルアルコヌル
210に溶解した溶液を滎䞋ロヌトより撹拌䞋に
加えおゆくず、䞊蚘ゞカルボン酞ずゞアミンの塩
以䞋DP塩ず略蚘するが結晶状態ずな぀お析出
しおくる。滎䞋終了埌宀枩で䞀晩攟眮しおから冷
む゜プロピルアルコヌルで掗滌過し、颚也、真
空也燥しおDP塩玄176gを埗た。
Example 1 First, dodecanedicarboxylic acid HOOC
92 g of (CH 2 ) 10 COOH was placed in a 1-volume separable flask, 300 g of isopropyl alcohol was added, and the mixture was heated and stirred at 65 to 70° C. to completely dissolve. Add 1,3-di-(4-piperidyl)-propane to this heated solution. Prepare 86g of isopropyl alcohol at room temperature.
When 210 g of the solution was added through the dropping funnel while stirring, the dicarboxylic acid and diamine salt (hereinafter abbreviated as DP salt) precipitated out in a crystalline state. After completion of the dropwise addition, the mixture was left at room temperature overnight, washed with cold isopropyl alcohol, air-dried, and vacuum-dried to obtain about 176 g of DP salt.

撹拌機およびガス導入管を぀けた500ml容セパ
ラブルフラスコにω−アミノドデカン酞70gず䞊
蚘DPå¡©30gをずり、玄200mlminの流速で窒玠
を流しながら220℃で14時間加熱した。反応終了
埌の生成物は溶融状態のたた窒玠気流䞋に速かに
フラスコから取り出した。埗られたポリマヌのメ
タノヌル抜出分゜ツクスレヌ抜出24時間は
0.60であり、0.5g100ml濃床のメタクレゟヌ
ル溶液の25℃における盞察粘床は1.72であ぀た。
たた、230℃におけるメルト・フロヌむンデツク
スは35.0g10minであ぀た。このポリマヌから
厚み0.5mmおよび1.0mmのプレスシヌトを䜜成し
た。
70 g of ω-aminododecanoic acid and 30 g of the above DP salt were placed in a 500 ml separable flask equipped with a stirrer and a gas inlet tube, and heated at 220° C. for 14 hours while flowing nitrogen at a flow rate of about 200 ml/min. After the reaction was completed, the product was quickly taken out of the flask in a molten state under a nitrogen stream. The methanol extract of the obtained polymer (Soxhlet extraction for 24 hours) is
The relative viscosity at 25° C. of a metacresol solution with a concentration of 0.60% and 0.5 g/100 ml was 1.72.
Further, the melt flow index at 230°C was 35.0g/10min. Press sheets with thicknesses of 0.5 mm and 1.0 mm were made from this polymer.

䜓積固有むンピヌダンスの枬定0.5mm厚のプ
レスシヌトに電極ずしおミクロン厚の錫箔を貌
り぀け、暪河ヒナヌレツトパツカヌド瀟のモデル
4247Aマルチフレク゚ンシLCRメヌタヌを甚い、
100Vcmの電界匷床䞋で100ヘルツにおける䜓積
固有むンピヌダンスを20℃から90℃にわた぀お枬
定した。枬定結果は第図に曲線で瀺した。な
お、同図に瀺した曲線はナむロン12ホモポリマ
ヌの枬定結果であり、曲線は明かにむンピヌダ
ンスの枩床倉化率が向䞊しおいる。
Measurement of volume specific impedance: A 5 micron thick tin foil was pasted as an electrode on a 0.5 mm thick press sheet, using a model manufactured by Yokogawa Heuretsu Patscard Co., Ltd.
Using the 4247A multi-frequency LCR meter,
The volume specific impedance at 100 Hz was measured from 20°C to 90°C under an electric field strength of 100V/cm. The measurement results are shown as curve B in FIG. Note that curve A shown in the figure is the measurement result for nylon 12 homopolymer, and curve B clearly shows an improvement in the rate of change of impedance with temperature.

たたこのポリマヌの瀺差走査熱量枬定DSC
による融解曲線を第図の曲線で瀺した。狭い
枩床範囲で融解するので、異垞昇枩の堎合にヒヌ
タヌ回路を遮断するヒナヌズ効果を有しおいる。
Additionally, differential scanning calorimetry (DSC) of this polymer
The melting curve according to the method is shown as curve b in FIG. Since it melts within a narrow temperature range, it has a fuse effect that shuts off the heater circuit in the event of abnormal temperature rise.

匕匵匷䌞床の枬定厚さ1.0mmプレスシヌトか
らJIS2号型ダンベル詊隓片を打抜き匕匵速床50
mmminで砎断匷䌞床を枬定した。砎断匕匵匷床
は544Kgcm2、砎断匕匵䌞床は369であり、䞀方
比范詊料のナむロン12ホモポリマヌの堎合、砎断
匕匵匷床は500Kgcm2、砎断匕匵䌞床は290で、
機械的性質に぀いおもナむロン12ホモポリマヌに
察し䜕らの遜色は芋られなか぀た。
Measurement of tensile strength and elongation; JIS No. 2 dumbbell test pieces were punched out from a 1.0 mm thick press sheet and pulled at a tensile speed of 50.
Breaking strength and elongation were measured in mm/min. The tensile strength at break was 544 Kg/cm 2 and the tensile elongation at break was 369%, while the comparative sample of nylon 12 homopolymer had a tensile strength at break of 500 Kg/cm 2 and a tensile elongation at break of 290%.
Regarding mechanical properties, no inferiority was observed compared to nylon 12 homopolymer.

実斜䟋  ステンレス補容オヌトクレヌブにラりリル
ラクタムモノマヌ473g2.396モル、−−オ
クチルラりリルラクタム247g0.799モル、DPå¡©
ドデカンゞカルボン酞ず1.3−ゞ−−ピペリ
ゞルプロパンの塩180g0.408モル、玔氎57g
および觊媒ずしお正燐酞1.4gを仕蟌み反応系内を
完党に窒玠で眮換しおから窒玠加圧により内圧を
20Kgcm2に保ち、290℃で時間加熱した。次
に系内の圧力ず枩床を埐々に䞋げ、玄時間かけ
お250℃、倧気圧にもたらし、曎に150mlminの
流速で窒玠を流しながら、250℃で10時間撹拌を
続けた。反応終了埌窒玠加圧により内容物をスト
ランド状に抌出し氎槜で冷华しおからペレタむザ
ヌでペレツトにした。埗られたポリマヌのメタノ
ヌル抜出分゜ツクスレヌ抜出24時間は0.5、
0.5g100ml濃床の−クレゟヌル溶液の盞察粘
床は1.71、230℃におけるメルトフロヌむンデツ
クスは30.0g10minであ぀た。
Example 2 In a 3-volume stainless steel autoclave, 473 g (2.396 mol) of lauryl lactam monomer, 247 g (0.799 mol) of N-n-octyl lauryl lactam, and DP salt (salt of dodecanedicarboxylic acid and 1,3-di-(4-piperidyl)propane) were placed. ) 180g (0.408mol), pure water 57g
After charging 1.4 g of orthophosphoric acid as a catalyst and completely replacing the inside of the reaction system with nitrogen, the internal pressure was reduced by applying nitrogen pressure.
It was maintained at 20Kg/cm 2 G and heated at 290°C for 6 hours. Next, the pressure and temperature in the system were gradually lowered to 250°C and atmospheric pressure over about 1 hour, and stirring was continued at 250°C for 10 hours while flowing nitrogen at a flow rate of 150ml/min. After the reaction was completed, the contents were extruded into strands by applying nitrogen pressure, cooled in a water tank, and pelletized using a pelletizer. The methanol extraction content of the obtained polymer (Soxhlet extraction for 24 hours) was 0.5%.
The relative viscosity of the m-cresol solution at a concentration of 0.5 g/100 ml was 1.71, and the melt flow index at 230°C was 30.0 g/10 min.

このポリマヌの0.5mm厚プレスシヌトを甚いお
実斜䟋の堎合ず同様に枬定した100Vcmの電
界匷床䞋100ヘルツで20℃から90℃にわた぀お枬
定した䜓積固有むンピヌダンスの倀を第図の曲
線で瀺した。ナむロン12ホモポリマヌ曲線
より可成りむンピヌダンスの枩床倉化率が向
䞊しおいる。
Figure 2 shows the volume specific impedance values measured in the same manner as in Example 1 using a 0.5 mm thick pressed sheet of this polymer at 100 Hz under an electric field strength of 100 V/cm over a temperature range of 20°C to 90°C. It is shown by curve C. The temperature change rate of impedance is considerably improved compared to nylon 12 homopolymer (curve A).

たたこのポリマヌのDSCによる融解曲線を第
図の曲線で瀺した。狭い枩床範囲で融解する
ので、異垞昇枩の堎合にヒヌタヌ回路を遮断する
ヒナヌズ効果を有しおいる。
Further, the melting curve of this polymer determined by DSC is shown as curve c in FIG. Since it melts within a narrow temperature range, it has a fuse effect that shuts off the heater circuit in the event of abnormal temperature rise.

たた、実斜䟋の堎合ず同様に枬定した砎断匕
匵匷床は450Kgcm2、砎断匕匵䌞床は405であ぀
た。
Furthermore, the tensile strength at break measured in the same manner as in Example 1 was 450 Kg/cm 2 and the tensile elongation at break was 405%.

実斜䟋  実斜䟋ず同様にしお、ラりリルラクタムモノ
マヌ148.0g0.75モル、−−オクチルラりリ
ルラクタム15.5g0.05モルおよびDP塩オク
タデカンゞカルボン酞ず−ゞ−−ピペ
リゞル−プロパンの塩110.6g0.20モルから共
重合ポリアミドポリマヌを補造した。埗られたポ
リマヌのメタノヌル抜出分゜ツクスレヌ抜出24
時間は0.45、0.5g100ml濃床の−クレゟ
ヌル溶液の盞察粘床は1.75、230℃におけるメル
トフロヌむンデツクスは28.0g10minであ぀た。
Example 3 In the same manner as in Example 2, 148.0 g (0.75 mol) of lauryl lactam monomer, 15.5 g (0.05 mol) of N-n-octyl lauryl lactam and DP salt (octadecanedicarboxylic acid and 1,3-di-(4 A copolyamide polymer was produced from 110.6 g (0.20 mol) of a salt of -piperidyl)-propane.The methanol extract of the obtained polymer (Soxhlet extraction 24
The m-cresol solution with a concentration of 0.45% and 0.5 g/100 ml had a relative viscosity of 1.75 and a melt flow index of 28.0 g/10 min at 230°C.

このポリマヌの0.5mm厚プレスシヌトを甚いお
実斜䟋の堎合ず同様にしお、100Vcmの電界
匷床䞋、100ヘルツで20℃から90℃にわた぀お枬
定した䜓積固有むンピヌダンスの倀を第図の曲
線で瀺した。ナむロン12ホモポリマヌ曲線
より可成りむンピヌダンスの枩床倉化率が向
䞊しおいる。
Using a 0.5 mm thick press sheet of this polymer, the volume specific impedance was measured under an electric field strength of 100 V/cm over a temperature range of 20°C to 90°C at 100 Hz, and the second It is shown by curve D in the figure. The temperature change rate of impedance is considerably improved compared to nylon 12 homopolymer (curve A).

たたこのポリマヌのDSCによる融解曲線を第
図の曲線で瀺した。狭い枩床範囲で融解する
ので、異垞昇枩の堎合にヒヌタヌ回路を遮断する
ヒナヌズ効果を有しおいる。
The melting curve of this polymer measured by DSC is shown as curve d in FIG. Since it melts within a narrow temperature range, it has a fuse effect that shuts off the heater circuit in the event of abnormal temperature rise.

実斜䟋  実斜䟋ず同様にしお、ラりリルラクタムモノ
マヌ157.8g0.8モル、−−ステアリルラり
リルラクタム44.9g0.1モルずDP塩アれラむ
ン酞ず−ゞ−−ピペリゞル−ペンタン
の塩44.1g0.1モルから共重合ポリアミドポ
リマヌを補造した。埗られたポリマヌのメタノヌ
ル抜出分゜ツクスレヌ抜出24時間は0.60、
0.5g100ml濃床の−クレゟヌル溶液の盞察粘
床は1.68、230℃におけるメルトフロヌむンデツ
クスは35.0g10minであ぀た。
Example 4 In the same manner as in Example 2, 157.8 g (0.8 mol) of lauryl lactam monomer, 44.9 g (0.1 mol) of N-n-stearyl lauryllactam and DP salt (azelaic acid and 1,5-di-(4- A copolyamide polymer was produced from 44.1 g (0.1 mol) of piperidyl)-pentane salt. The methanol extraction content of the obtained polymer (Soxhlet extraction for 24 hours) was 0.60%.
The relative viscosity of the m-cresol solution at a concentration of 0.5 g/100 ml was 1.68, and the melt flow index at 230°C was 35.0 g/10 min.

このポリマヌの0.5mm厚プレスシヌトを甚いお
実斜䟋の堎合ず同様にしお、100Vcmの電界
匷床䞋、100ヘルツで20℃から90℃にわ぀お枬定
した䜓積固有むンピヌダンスの倀を第図の曲線
で瀺した。ナむロン12ホモポリマヌ曲線
より可成りむンピヌダンスの枩床倉化率が向䞊し
おいる。
Using a 0.5 mm thick press sheet of this polymer, the volume specific impedance was measured under an electric field strength of 100 V/cm at 100 Hz from 20°C to 90°C in the same manner as in Example 1. It is shown by curve E in the figure. Nylon 12 homopolymer (curve A)
The rate of change of impedance with temperature is improved considerably.

たたこのポリマヌのDSCによる融解曲線を第
図の曲線で瀺した。狭い枩床範囲で融解する
ので、異垞昇枩の堎合にヒヌタヌ回路を遮断する
ヒナヌズ効果を有しおいる。
The melting curve of this polymer measured by DSC is shown as curve e in FIG. Since it melts within a narrow temperature range, it has a fuse effect that shuts off the heater circuit in the event of abnormal temperature rise.

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

第図は感熱枩床制埡線の䞀䟋を瀺す䞀郚切
欠斜芖図である。第図は感熱枩床制埡面の䞀
䟋を瀺す断面図である。図䞭は絶瞁線、は芯
線、は高分子感枩䜓、は信号線、はヒヌタ
ヌ線である。第図はポリマヌの䜓積固有むンピ
ヌダンスを枩床に察しおプロツトしたグラフであ
る。第図は瀺差走査熱量枬定DSCによる
融解曲線吞熱ピヌクを枩床に察しおプロツト
したグラフである。
FIG. 1A is a partially cutaway perspective view showing an example of a heat-sensitive temperature control line. FIG. 1B is a sectional view showing an example of a heat-sensitive temperature control surface. In the figure, 1 is an insulated wire, 2 is a core wire, 3 is a polymer temperature sensitive body, 4 is a signal wire, and 5 is a heater wire. FIG. 2 is a graph plotting the specific volume impedance of a polymer versus temperature. FIG. 3 is a graph in which the melting curve (endothermic peak) measured by differential scanning calorimetry (DSC) is plotted against temperature.

Claims (1)

【特蚱請求の範囲】  (1) 匏で衚わせるラクタムたたは匏
で衚わせるω−アミノカルボン酞50〜95重量
ず 䜆し、R1は氎玠たたは炭玠数ないし30
の盎鎖たたは分枝をも぀アルキル基、はな
いし13の正の敎数 (2) 匏で衚わせるゞアミンず匏で衚わせるゞ
カルボン酞の等モルから成る混合物たたは塩50
ないし重量 HOOC−−COOH 䜆し、R2、R3は氎玠たたは炭玠数ない
し12の盎鎖たたは分枝をも぀アルキル基であ぀
お、R2ずR3は同じであ぀おも異な぀おいおも
良い。はないし10の正の敎数。は炭玠数
ないし20の盎鎖たたは分枝をも぀䟡の飜和
炭化氎玠残基 から埗られる0.5g100ml濃床の−クレゟヌル
溶液の盞察粘床が1.4〜2.5の共重合ポリアミドか
ら成る感枩性高分子材料。
[Scope of Claims] 1 (1) 50 to 95% by weight of a lactam represented by formula a or an ω-aminocarboxylic acid represented by formula b
and (However, R 1 is hydrogen or has 1 to 30 carbon atoms.
a straight-chain or branched alkyl group, n is a positive integer of 5 to 13) (2) A mixture or salt consisting of equimolar amounts of a diamine represented by the formula and a dicarboxylic acid represented by the formula 50
or 5% by weight HOOC-A-COOH (However, R 2 and R 3 are hydrogen or a straight chain or branched alkyl group having 1 to 12 carbon atoms, and R 2 and R 3 may be the same or different. (m is a positive integer from 1 to 10. A is a divalent saturated hydrocarbon residue with a straight or branched chain having 4 to 20 carbon atoms) at a concentration of 0.5 g/100 ml. A temperature-sensitive polymer material made of copolyamide with a relative viscosity of 1.4 to 2.5.
JP11035882A 1982-06-25 1982-06-25 Temperature-sensitive polymeric material Granted JPS591531A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP11035882A JPS591531A (en) 1982-06-25 1982-06-25 Temperature-sensitive polymeric material

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP11035882A JPS591531A (en) 1982-06-25 1982-06-25 Temperature-sensitive polymeric material

Publications (2)

Publication Number Publication Date
JPS591531A JPS591531A (en) 1984-01-06
JPH0328452B2 true JPH0328452B2 (en) 1991-04-19

Family

ID=14533748

Family Applications (1)

Application Number Title Priority Date Filing Date
JP11035882A Granted JPS591531A (en) 1982-06-25 1982-06-25 Temperature-sensitive polymeric material

Country Status (1)

Country Link
JP (1) JPS591531A (en)

Families Citing this family (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2779833B2 (en) * 1989-05-11 1998-07-23 ダむセル・ヒュルス株匏䌚瀟 Polymer thermosensor
DE19537614C3 (en) * 1995-10-09 2003-10-02 Inventa Ag Polycaprolactam with a new chain control
ES2835382T3 (en) * 2013-03-15 2021-06-22 Boehringer Ingelheim Animal Health Usa Inc Antimicrobial Polyamide Compositions and Treatment of Mastitis

Also Published As

Publication number Publication date
JPS591531A (en) 1984-01-06

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