CHLUMICRYL® AMA Monómero / Metacrilato de alilo CAS 96-05-9

(1 valoración de cliente)

AMA Monomer Allyl metacrilato CAS 96-05-9 es un monómero UV para recubrimientos, tintas, adhesivos y formulaciones de impresión 3D curables con UV. Los beneficios clave incluyen Hazen 20 Pueity, % ≥ 99,5 de contenido de agua y % ≤ 0,1 VA de acidez (como ácido metacrílico).

Descripción

AMA Monómero/metacrilato de alilo CAS 96-05-9

Artículo Especificación
Nº CAS 96-05-9
Color(Pt-Co),Hazen 20
Peidad,% ≥ 99.5
Contenido de agua,% ≤ 0.1
VAcidez (como ácido metacrílico),% ≤ 0.03

 

El metacrilato de alilo es un importante agente de reticulación que proporciona una reticulación eficaz de grupos bifuncionales en la segunda etapa con buena resistencia farmacéutica, resistencia al impacto, adhesión, dureza y baja contracción. Se utiliza en materiales dentales, pinturas industriales, intermedios de silicona, agentes antideslumbrantes, polímeros ópticos, elastómeros y algunos sistemas poliméricos de vinilo y acrilato.

Otro nombre:

Ageflex AMA;

Allylester kyseliny metakrylove;

2-metacrilato de alilo;

metacrilato de alilo;

Visómero AMA;

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LCXMARK494X CLETOXILADO (4) BISFENOL A DIACRILATE

Politiol/Polimercaptano
CHLUMICRYL®DMES Monómero Sulfuro de bis(2-mercaptoetilo) 3570-55-6
CHLUMICRYL® Monómero DMPT TIOCURA DMPT 131538-00-6
CHLUMICRYL® Monómero PETMP 7575-23-7
CHLUMICRYL® PM839 Monómero Polioxi(metil-1,2-etanodiilo) 72244-98-5
Monómero monofuncional
CHLUMICRYL® Monómero HEMA Metacrilato de 2-hidroxietilo 868-77-9
CHLUMICRYL® HPMA Monómero Metacrilato de 2-hidroxipropilo 27813-02-1
CHLUMICRYL® Monómero de THFA Acrilato de tetrahidrofurfurilo 2399-48-6
CHLUMICRYL® HDCPA Monómero Acrilato de diciclopentenilo hidrogenado 79637-74-4
CHLUMICRYL® DCPMA Monómero Metacrilato de dihidrodiciclopentadienilo 30798-39-1
CHLUMICRYL® DCPA Monómero Acrilato de dihidrodiciclopentadienilo 12542-30-2
CHLUMICRYL® DCPEMA Monómero Metacrilato de diciclopenteniloxietil 68586-19-6
CHLUMICRYL® DCPEOA Monómero Acrilato de diciclopenteniloxietil 65983-31-5
CHLUMICRYL® NP-4EA Monómero (4) nonilfenol etoxilado 50974-47-5
LA Monómero Acrilato de laurilo/acrilato de dodecilo 2156-97-0
CHLUMICRYL® Monómero THFMA Metacrilato de tetrahidrofurfurilo 2455-24-5
CHLUMICRYL® Monómero de PHEA 2-FENOXIETILACRILATE 48145-04-6
CHLUMICRYL® LMA Monómero Metacrilato de laurilo 142-90-5
CHLUMICRYL® IDA Monómero Acrilato de isodecilo 1330-61-6
CHLUMICRYL® IBOMA Monómero Metacrilato de sobornilo 7534-94-3
CHLUMICRYL® Monómero IBOA Acrilato de sobornilo 5888-33-5
CHLUMICRYL® EOEOEA Monómero Acrilato de 2-(2-etoxietoxi)etilo 7328-17-8
Monómero multifuncional
CHLUMICRYL® Monómero DPHA 29570-58-9
CHLUMICRYL® DI-TMPTA Monómero DI(TRIMETILOLPROPANO) TETRAACRILATE 94108-97-1
Monómero de acrilamida
CHLUMICRYL® ACMO Monómero 4-acriloilmorfolina 5117-12-4
Monómero difuncional
CHLUMICRYL® PEGDMA Monómero Dimetacrilato de poli(etilenglicol) 25852-47-5
CHLUMICRYL® TPGDA Monómero Diacrilato de tripropilenglicol 42978-66-5
CHLUMICRYL® Monómero TEGDMA Dimetacrilato de trietilenglicol 109-16-0
CHLUMICRYL® PO2-NPGDA Monómero Diacrilato de propoxilato de neopentilenglicol 84170-74-1
CHLUMICRYL® PEGDA Monómero Diacrilato de polietilenglicol 26570-48-9
CHLUMICRYL® PDDA Monómero Diacrilato de dietilenglicol ftalato
CHLUMICRYL® NPGDA Monómero Diacrilato de neopentilglicol 2223-82-7
CHLUMICRYL® HDDA Monómero Diacrilato de hexametileno 13048-33-4
CHLUMICRYL® EO4-BPADA Monómero 64401-02-1
CHLUMICRYL® EO10-BPADA Monómero ETOXILADO (10) BISFENOL A DIACRILATE 64401-02-1
CHLUMICRYL® EGDMA Monómero Etilenglicol dimetacrilato 97-90-5
CHLUMICRYL® DPGDA Monómero Dienoato de dipropilenglicol 57472-68-1
CHLUMICRYL® Monómero Bis-GMA Bisfenol A Glicidil Metacrilato 1565-94-2
Monómero trifuncional
CHLUMICRYL® TMPTMA Monómero Trimetilolpropano trimetacrilato 3290-92-4
CHLUMICRYL® Monómero TMPTA Triacrilato de trimetilolpropano 15625-89-5
CHLUMICRYL® Monómero PETA 3524-68-3
CHLUMICRYL® GPTA (G3POTA) Monómero TRIACRILATO DE GLICERILO PROPOXY 52408-84-1
CHLUMICRYL® EO3-TMPTA Monómero Etriacrilato de trimetilolpropano etoxilado 28961-43-5
Monómero fotorresistente
CHLUMICRYL® IPAMA Monómero Metacrilato de 2-isopropil-2-adamantilo 297156-50-4
CHLUMICRYL® Monómero ECPMA 1-Metacrilato de etilciclopentilo 266308-58-1
CHLUMICRYL® Monómero ADAMA 1-Metacrilato de adamantilo 16887-36-8
Monómero de metacrilato
CHLUMICRYL® TBAEMA Monómero Metacrilato de 2-(terc-butilamino)etilo 3775-90-4
CHLUMICRYL® NBMA Monómero Metacrilato de n-butilo 97-88-1
CHLUMICRYL® MEMA Monómero Metacrilato de 2-metoxietilo 6976-93-8
CHLUMICRYL® i-BMA Monómero Metacrilato de sobutilo 97-86-9
CHLUMICRYL® EHMA Monómero 2-Metacrilato de etilhexilo 688-84-6
CHLUMICRYL® EGDMP Monómero Etilenglicol Bis(3-mercaptopropionato) 22504-50-3
CHLUMICRYL® EEMA Monómero 2-metilprop-2-enoato de 2-etoxietilo 2370-63-0
CHLUMICRYL® DMAEMA Monómero N, metacrilato de M-dimetilaminoetilo 2867-47-2
CHLUMICRYL® DEAM Monómero Metacrilato de dietilaminoetilo 105-16-8
CHLUMICRYL® Monómero CHMA Metacrilato de ciclohexilo 101-43-9
CHLUMICRYL® BZMA Monómero Metacrilato de bencilo 2495-37-6
CHLUMICRYL® BDDMP Monómero Di(3-mercaptopropionato) de 1,4-butanodiol 92140-97-1
CHLUMICRYL® BDDMA Monómero 1,4-butanodioldimetacrilato 2082-81-7
CHLUMICRYL® AMA Monómero Metacrilato de alilo 96-05-9
CHLUMICRYL® Monómero AAEM Metacrilato de acetilacetoxietilo 21282-97-3
Monómero de acrilatos
CHLUMICRYL® IBA Monómero Acrilato de sobutilo 106-63-8
CHLUMICRYL® EMA Monómero Emetacrilato de etilo 97-63-2
CHLUMICRYL® DMAEA Monómero Acrilato de dimetilaminoetilo 2439-35-2
CHLUMICRYL® DEAEA Monómero 2-(dietilamino)etilo prop-2-enoato 2426-54-2
CHLUMICRYL® CHA Monómero prop-2-enoato de ciclohexilo 3066-71-5
CHLUMICRYL® BZA Monómero prop-2-enoato de bencilo 2495-35-4
Otro monómero
CHLUMICRYL® MCPMA Monómero Metacrilato de 1-metilciclopentilo 178889-45-7
CHLUMICRYL® TMPMP Monómero Trimetilolpropano Tris(3-mercaptopropionato) 33007-83-9
CHLUMICRYL® Monómero CTFA Acrilato formal de trimetilopropano cíclico 66492-51-1
CHLUMICRYL® HPHPDA Monómero 30145-51-8
CHLUMICRYL® Monómero MPEG 26915-72-0

 

Factors affecting the glass transition temperature Tg, melting temperature Tm, and viscous flow temperature Tf of polymers

The glass transition temperature (Tg), melt temperature (Tm) (crystalline polymers), and viscous flow temperature (Tf) (non-crystalline polymers) of polymers are important temperature parameters, with Tg determining the service temperature of the polymer and Tm and Tf determining the processing temperature of the polymer. Although there are many factors that affect the Tg, Tm and Tf values of polymers, but in general two, one is the influence of the structure and properties of oligomers, and the other is the influence of other factors. First, the impact of polymer chain structure. Any chain structure factors that increase the chain rigidity can make Tg, Tm and Tf values increase, any chain flexibility to increase the chain structure factors can make Tg, Tm and Tf values decrease. When rigid groups such as phenyl group, biphenyl group and conjugated double bond are introduced to the main chain, the rigidity of the chain will increase, and Tg, Tm and Tf will all increase; when ether bond and isolated double bond are introduced to the main chain, the chain will become flexible, and Tg, Tm and Tf will all decrease; when the side chain is a rigid group, the flexibility of the chain will decrease as the volume of the side group increases, and Tg, Tm and Tf will all increase; when the side chain is a flexible group or a flexible chain, the The larger the side chain, the better the flexibility, the better the flexibility of the whole molecular chain, Tg, Tm and Tf are reduced. Second, intermolecular forces. For polar polymers, there is strong interaction between polar groups on the molecular chain, and the intermolecular force is strong, and the values of Tg, Tm and Tf are larger than the corresponding values of non-polar polymers; and the values of Tg, Tm and Tf increase with the increase of intermolecular force. Third, molecular weight. Since Tm is related to crystallization, in general, molecular weight has little effect on Tm, and both Tg and Tf increase with the increase of molecular weight. For Tg, this trend is more obvious when the molecular weight is low, while the change of Tg is extremely slow when the molecular weight increases to a certain degree. The effect of molecular weight on Tf is much more significant than that on Tg. This is because the effect of molecular weight on Tg is attributed to the chain end effect, which can only show its effect when the chain end content in the system is relatively high, i.e., the molecular weight is relatively low; after the molecular weight is high to a certain extent and the weight of the chain end is small to almost negligible, its effect on Tg will not be obvious. The movement of the whole chain is achieved by the coordinated movement of all chain segments. The larger the molecular weight is, the more chain segments are needed to achieve the whole chain motion, and the more frictional force needs to be overcome during the motion, and the Tf will rise. Therefore, the Tf value is strongly dependent on the molecular weight. The following are the effects of external factors on the Tg, Tm and Tf values of polymers. Fourth, small molecule soluble additives. Polymer molding process, sometimes to add plasticizers or other soluble additives in the ingredients. For polymers, these small molecules are equivalent to diluents, they will make the polymer Tg, Tm and Tf lower. V. External forces. Unidirectional external force has a driving effect on the chain segments, so increasing the external force can make Tg and Tf lower. And the extension of the external force is also conducive to the movement of molecules in the direction of the external force, which can also reduce Tf. The increase in pressure reduces the free volume and increases Tg and Tf. The effect of external force on Tm is as follows: when the polymer is crystallized under the action of tensile force, the crystallization ability is increased, which improves the crystallinity and also raises the melting point of crystallization, i.e., Tm is increased; crystallization under pressure can increase the thickness of the wafer, thus increasing the perfection of the crystal, which also makes Tm increase. VI. Test rate. This is in terms of the magnitude of the test value obtained from the temperature test aspect. Since the motion of polymer chains is a relaxation process and is time dependent, there is a relationship between the Tg test value and the experimental time scale: increasing the rate of temperature increase or the frequency of dynamic experiments will increase Tg. The same is true for Tf, while the opposite is true for Tm. When testing the Tm value, if the temperature is increased slowly, the imperfect grains can be melted first and then recrystallized into more perfect and stable crystals at a slightly higher temperature. The last measured “melting point” is the temperature at which all the more perfect crystals melt, and is higher than the value measured at a rapid temperature rise.

1 valoración en CHLUMICRYL® AMA Monómero / Metacrilato de alilo CAS 96-05-9

  1. Alexander Lee

    From start to finish, the entire shopping experience was seamless. The product arrived well-packaged and in pristine condition. A definite five-star!

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