p.P(3,5,6,7,8);
p.A(425,0,0,'Sustainability',n,n,n,n,n,0);
p.A(426,0,425,'Biobased content',n,n,'0','100','%',1,438,'Up to 40%','0','39',440,'Form 40% to 60%','40','59',441,'Above 60%','60','99',442,'100%','100','100');
p.A(427,0,425,'Biodegradable',n,n,'0','100','%',0,443,'Yes',n,n,444,'No',n,n);
p.A(428,0,425,'Recycled content',n,n,'0','100','%',1,445,'Up to 40%','0','39',447,'Form 40% to 60%','40','59',448,'Above 60%','60','99',449,'100%','100','100');
p.A(328,3,0,'Dimensional stability',n,n,n,n,n,0);
p.A(331,3,328,'Coefficient of linear thermal expansion',n,'Under the effects of increasing temperature, any material will expand. This can lead to significant changes in dimension, generate warpage or  internal stress particularly if the part is mounted on a material having a very different expansion coefficient.','0','25','10E-5 /°C',1,146,'Very Low',n,'2',147,'Low','2','4',148,'Medium','4','8',149,'High','8','15',150,'Very High','15',n);
p.A(330,3,328,'H2O absorption 24 hours',n,'Some polymers have a natural tendency to absorb water. This leads to changes in dimensions, and in mechanical and electrical performance. This represents the % of water absorbed after immersion during 24 hours at 23°C.','0','10','%',1,26,'Very Low',n,'0.05',27,'Low','0.05','0.1',28,'Medium','0.1','0.6',29,'High','0.6','1',30,'Very High','1',n);
p.A(329,3,328,'Shrinkage',n,'Mould shrinkage is the difference between the dimensions of the mould and of the moulded part produced. Low values are preferred when the part has tight dimensional tolerances.','0','6','%',1,36,'Very Low',n,'0.5',37,'Low','0.5','1',38,'Medium','1','2',39,'High','2','4',40,'Very High','4',n);
p.A(322,3,0,'Electrical performances',n,n,n,n,n,0);
p.A(324,3,322,'Arc resistance',n,'When an electric current travels across an insulator’s surface, this surface is damaged over time and then becomes conductive. Arc resistance is a measure of the time required to make an insulating surface conductive under a high voltage, low current arc. Values are reported in seconds.','0','400','sec',1,186,'Very Low',n,'10',187,'Low','10','100',188,'Medium','100','200',189,'High','200','300',190,'Very High','300',n);
p.A(326,3,322,'Dielectric constant',n,'Dielectric constant is also called permittivity. A dielectric constant of 2 means an insulator will absorb twice more electrical charge than a vacuum.','2','9',n,1,166,'Very Low',n,'2',167,'Low','2','4',168,'Medium','4','6',169,'High','6','8',170,'Very High','8',n);
p.A(325,3,322,'Dielectric rigidity',n,'Dielectric strength reflects the electric strength of insulating materials at power frequencies, or the measure of dielectric breakdown resistance of a material under an applied voltage. The values are generally reported in kV by mm of thickness.','7','105','kV/mm',1,176,'Very Low',n,'10',177,'Low','10','20',178,'Medium','20','40',179,'High','40','80',180,'Very High','80',n);
p.A(327,3,322,'Dissipation factor',n,'Dissipation factor is the percentage of electrical energy absorbed and lost when current is applied to an insulating material. Most of the absorbed energy is dissipated as heat.','1','2200','10E-4',1,226,'Very Low',n,'5',227,'Low','5','10',228,'Medium','10','50',229,'High','50','500',230,'Very high','500',n);
p.A(323,3,322,'Volume resistivity',n,'Volume resistivity is the electrical resistance when an electric potential is applied between opposite faces of a unit cube. Below 10^5 Ohm.cm the material is considered as conductive, Above 10^9 Ohm.cm the material is considered as an electrical insulator.','-1','18','10E15 Ohm.cm',1,156,'Very Low',n,'2',157,'Low','2','5',158,'Medium','5','9',159,'High','9','14',160,'Very High','14',n);
p.A(338,3,0,'Fire performances',n,n,n,n,n,0);
p.A(332,3,338,'Fire resistance (LOI)',n,'The purpose of the oxygen index test is to measure the relative flammability of materials by burning them in a controlled atmosphere consisting of a mixture of oxygen and nitrogen. The oxygen index represents the minimum level of oxygen in the atmosphere that can sustain flame on a thermoplastic material. The higher the values, the higher the non-flammability.','17','96','%',1,191,'Very Low',n,'20',192,'Low','20','40',193,'Medium','40','60',194,'High','60','80',195,'Very High','80',n);
p.A(339,3,338,'Flammability UL94',n,'UL-94 test (according to the American National UL-94) is widely used for determining a specimen\'s relative flammability,  its ability to extinguish the flame after ignition, and evaluate dripping. HB = Slow burning V2=extinction within 30 seconds + Dripping. V1= extinction within 30 seconds, No Dripping, V0= extinction within 10 seconds, No Dripping.',n,n,n,0,406,'HB',n,n,408,'V2',n,n,409,'V1',n,n,410,'V0',n,n);
p.A(301,3,0,'Mechanical properties',n,n,n,n,n,0);
p.A(309,3,301,'Elongation at break',n,'% Elongation that a polymer can endure before breaking during tensile stress.','1','990','%',1,101,'Very Low',n,'3',102,'Low','3','10',103,'Medium','10','30',104,'High','30','90',105,'Very High','90',n);
p.A(306,3,301,'Elongation at yield',n,'Materials which exhibit a ductile behaviour have a yield point beyond which the deformation is not reversible. Elongation at Yield is the limit of use of a ductile polymer.','1','250','%',1,216,'Very Low',n,'1',217,'Low','1','3',218,'Medium','3','8',219,'High','8','12',220,'Very High','12',n);
p.A(307,3,301,'Flexibility ','Flexural Modulus','Flexibility is proportional to the flexural modulus (Flexural Stress/Strain). The lower the flexural modulus, the higher the flexibility.','0','37','GPa',1,206,'Very High',n,'1',207,'High','1','2.5',208,'Medium','2.5','5',209,'Low','5','10',210,'Very Low','10',n);
p.A(312,3,301,'Hardness Rockwell M',n,'Rockwell M hardness is a standadized test which consists of measuring the depth of penetration of a polished steel ball pressed at the surface of a polymer under controlled conditions. The higher the value, the harder the material. For thermoplastics this test is used for hard materials.','1','125',n,1,56,'Very Low',n,'50',57,'Low','50','70',58,'Medium','70','90',59,'High','90','115',60,'Very High','115',n);
p.A(311,3,301,'Hardness Shore D',n,'Shore D hardness is a standardized test consisting in measuring the depth of penetration of a specific indentor. The higher the value, the higher the hardness. This test is used when the material is too soft to be measured by a Rockwell test. For very soft materials such as Rubber, TPE, the Shore A test is recommended.','15','100',n,1,46,'Very Low',n,'25',47,'Low','25','50',48,'Medium','50','70',49,'High','70','85',50,'Very High','85',n);
p.A(308,3,301,'Stiffness','Flexural Modulus','Stiffness is proportional to the flexural modulus (Flexural Stress/Strain). The higher the flexural modulus, the higher the stiffness.','0','37','GPa',1,121,'Very Low',n,'1',122,'Low','1','2.5',123,'Medium','2.5','5',124,'High','5','10',125,'Very High','10',n);
p.A(303,3,301,'Strength at break (tensile)',n,'Maximum stress that a polymer can endure just before breaking during a tensile test.','0','280','MPa',1,71,'Very Low',n,'10',72,'Low','10','40',73,'Medium','40','80',74,'High','80','140',75,'Very High','140',n);
p.A(305,3,301,'Strength at yield (tensile)',n,'Materials which exhibit ductile behaviour have a yield point after which deformation is not reversible. Stress at Yield is the maximum force that a ductile polymer can endure without reaching an irreversible deformation.','3','240','MPa',1,76,'Very Low',n,'10',77,'Low','10','40',78,'Medium','40','80',79,'High','80','140',80,'Very High','140',n);
p.A(310,3,301,'Toughness','Notched Izod impact at room temperature','There are numerous impact tests available. We have selected Notched Izod Impact test performed at room temperature (23°C) presenting the energy to be applied to a notched standardized sample to break it.','5','1065','J/m',1,16,'Very Low',n,'30',17,'Low','30','100',18,'Medium','100','200',19,'High','200','500',20,'Very High','500',n);
p.A(334,3,301,'Toughness at low T','Notched Izod impact at low temperature','There are numerous impact tests available. We have decided to use Notched Izod Impact test performed at low temperature representing the energy to be applied to a notched standardized specimen to break it.','15','550','J/m',1);
p.A(302,3,301,'Young modulus',n,'Young Modulus is defined as (tensile stress/strain). It represents the ability of a material to resist tensile deformation.','0','37','GPa',1,116,'Very Low',n,'1',117,'Low','1','2.5',118,'Medium','2.5','5',119,'High','5','10',120,'Very High','10',n);
p.A(335,3,0,'Optical properties',n,n,n,n,n,0);
p.A(343,3,335,'Gloss',n,'Gloss is a measure of surface quality. Materials that have a high gloss are very smooth and highly reflective.','0','200','%',1,426,'Low',n,'69.99',427,'Medium','70','89.99',428,'High','90','130',429,'Very High','130.01',n);
p.A(337,3,335,'Haze',n,'Percentage of incident light scattered more than 2.5°. Haze is caused by impurities, crystallinity... The lower the values, the higher the transparency/clarity.','0','100','%',1,423,'Low',n,'0.99',424,'Medium','1','2',425,'High','2.01',n);
p.A(336,3,335,'Transparency','% visible light transmission','Percentage of incident light transmitted through a standardized sample. The higher the value, the higher the transparency.','70','95','%',1,420,'Medium',n,'85',421,'High','85.01','90',422,'Very High','90.01',n);
p.A(313,3,0,'Physical properties',n,n,n,n,n,0);
p.A(314,3,313,'Density',n,n,'1','2','g/cm<sup>3</sup>',1);
p.A(315,3,313,'Glass transition temperature',n,'Temperature point where a polymer experiences a significant change in properties. The polymer structure turns "rubbery" upon heating and "glassy" upon cooling. Amorphous polymers cannot be used above this temperature. Semi-crystalline polymers generally become brittle below this temperature.','-110','340','°C',1);
p.A(340,3,0,'Radiation resistance',n,n,n,n,n,0);
p.A(341,3,340,'Gamma radiation resistance',n,n,n,n,n,0,430,'Poor',n,n,411,'Fair',n,n,412,'Good',n,n,413,'Excellent',n,n);
p.A(342,3,340,'UV light resistance',n,n,n,n,n,0,431,'Poor',n,n,414,'Fair',n,n,415,'Good',n,n,416,'Excellent',n,n);
p.A(316,3,0,'Service temperature',n,n,n,n,n,0);
p.A(321,3,316,'Ductile/fragile temperature',n,'Temperature below which the polymer becomes brittle.','-250','20','°C',1);
p.A(319,3,316,'HDT @0.46 Mpa (67 psi)',n,'HDT is a relative measure of a material’s ability to perform for a short time at elevated temperatures while supporting a load (0.46 MPa). The test measures the effect of temperature on stiffness: a standard test specimen is given a defined surface stress and the temperature is raised at a uniform rate.','30','323','°C',1);
p.A(320,3,316,'HDT @1.8 Mpa (261 psi)',n,'HDT is a relative measure of a material’s ability to perform for a short time at elevated temperatures while supporting a load (1.8 MPa). The test measures the effect of temperature on stiffness: a standard test specimen is given a defined surface stress and the temperature is raised at a uniform rate.','23','360','°C',1);
p.A(317,3,316,'Max continuous Service temperature',n,n,'34','360','°C',1);
p.A(318,3,316,'Min continuous service temperature',n,n,'-250','20','°C',1);
p.A(344,3,0,'Sterilization resistance (Repeated)',n,'Ability of a material to endure repeated sterilization cycles (chemical, steam, gamma radiation…) without damage. This is particularly useful in applications such as medical, dentistry, Pets\' cages, industrial food equipments…',n,n,n,0,432,'Poor',n,n,417,'Fair',n,n,418,'Good',n,n,419,'Excellent',n,n);
p.A(333,3,0,'Thermal insulation','Thermal conductivity','The thermal insulating capacity of plastics is rated by measuring the thermal conductivity.The values are reported in W/m.K. The lower the value, the better the thermal insulation.','0','1','W/m.K',1,136,'Very High',n,'0.1',137,'High','0.1','0.2',138,'Medium','0.2','0.3',139,'Low','0.3','0.6',140,'Very Low','0.6',n);
p.A(415,4,0,'Chemical resistance',n,n,n,n,n,0);
p.A(419,4,415,'Chlorinated solvents resistance',n,n,n,n,n,0,386,'Very Low',n,n,387,'Low',n,n,388,'Medium',n,n,389,'High',n,n,390,'Very High',n,n);
p.A(417,4,415,'Hydrolysis resistance',n,n,n,n,n,0,376,'Very Low',n,n,377,'Low',n,n,378,'Medium',n,n,379,'High',n,n,380,'Very High',n,n);
p.A(418,4,415,'Ketones resistance',n,n,n,n,n,0,381,'Very Low',n,n,382,'Low',n,n,383,'Medium',n,n,384,'High',n,n,385,'Very High',n,n);
p.A(416,4,415,'Oil resistance',n,n,n,n,n,0,371,'Very Low',n,n,372,'Low',n,n,373,'Medium',n,n,374,'High',n,n,375,'Very High',n,n);
p.A(423,4,0,'Density',n,n,'1','2',n,1);
p.A(422,4,0,'Dielectric behaviour',n,n,n,n,n,0,401,'Very Low',n,n,402,'Low',n,n,403,'Medium',n,n,404,'High',n,n,405,'Very High',n,n);
p.A(420,4,0,'Flame resistance',n,n,n,n,n,0,391,'Very Low',n,n,392,'Low',n,n,393,'Medium',n,n,394,'High',n,n,395,'Very High',n,n);
p.A(421,4,0,'Gaz impermeability',n,n,n,n,n,0,396,'Very Low',n,n,397,'Low',n,n,398,'Medium',n,n,399,'High',n,n,400,'Very High',n,n);
p.A(401,4,0,'Mechanical properties',n,n,n,n,n,0);
p.A(404,4,401,'Abrasion resistance',n,n,n,n,n,0,341,'Very Low',n,n,342,'Low',n,n,343,'Medium',n,n,344,'High',n,n,345,'Very High',n,n);
p.A(407,4,401,'Compression set',n,'Compression set is the permanent deformation of a material after removal of the compressive stress.',n,n,n,0,346,'Very Low',n,n,347,'Low',n,n,348,'Medium',n,n,349,'High',n,n,350,'Very High',n,n);
p.A(424,4,401,'Elongation at break (tensile)',n,'% Elongation that a polymer can endure before breaking during tensile stress.','5','950','%',1,433,'Very Low',n,'10',434,'Low','10','200',435,'Medium','200','400',436,'High','400','600',437,'Very High','600',n);
p.A(408,4,401,'Flexural fatigue resistance',n,n,n,n,n,0,351,'Very Low',n,n,352,'Low',n,n,353,'Medium',n,n,354,'High',n,n,355,'Very High',n,n);
p.A(405,4,401,'Hardness Shore A',n,'Shore A hardness is a standardized test consisting in measuring the depth of penetration of a specific indentor. The higher the value, the higher the hardness. This test is recommended for  very soft materials such as Rubber and TPE.','10','99',n,1,6,'Very Low',n,'25',7,'Low','25','50',8,'Medium','50','70',9,'High','70','85',10,'Very High','85',n);
p.A(406,4,401,'Hardness Shore D',n,'Shore D hardness is a standardized test consisting in measuring the depth of penetration of a specific indentor. The higher the value, the higher the hardness. This test is used when the material is too soft to be measured by a Rockwell test. ','1','82',n,1,236,'Very Low',n,'25',237,'Low','25','50',238,'Medium','50','70',239,'High','70','85',240,'Very High','85',n);
p.A(409,4,401,'Rebound resilience',n,n,n,n,n,0,356,'Very Low',n,n,357,'Low',n,n,358,'Medium',n,n,359,'High',n,n,360,'Very High',n,n);
p.A(402,4,401,'Strength at break (tensile)',n,'Maximum stress that a polymer can endure just before breaking during a tensile test.','2','150','MPa',1,86,'Very Low',n,'10',87,'Low','10','40',88,'Medium','40','80',89,'High','80','140',90,'Very High','140',n);
p.A(403,4,401,'Tear resistance',n,n,n,n,' ',0,336,'Very Low',n,n,337,'Low',n,n,338,'Medium',n,n,339,'High',n,n,340,'Very High',n,n);
p.A(414,4,0,'Ozone resistance',n,n,n,n,n,0,366,'Very Low',n,n,367,'Low',n,n,368,'Medium',n,n,369,'High',n,n,370,'Very High',n,n);
p.A(410,4,0,'Thermal',n,n,n,n,n,0);
p.A(411,4,410,'Max continuous service temperature',n,n,'50','140','°C',1);
p.A(412,4,410,'Min continuous service temperature',n,n,'-60','-20','°C',1);
p.A(413,4,0,'Weatherability',n,n,n,n,n,0,361,'Very Low',n,n,362,'Low',n,n,363,'Medium',n,n,364,'High',n,n,365,'Very High',n,n);
p.C(-1,0,0,'Chemical properties',n,n,n,n,n);
p.C(-711,0,-1,'Acetone @ 100%, 20°C',n,n,n,n,n);
p.C(-405,0,-1,'Ammonium hydroxide @ 10%, 20°C',n,n,n,n,n);
p.C(-406,0,-1,'Ammonium hydroxide @ 30%, 20°C',n,n,n,n,n);
p.C(-407,0,-1,'Ammonium hydroxide @ diluted, 20°C',n,n,n,n,n);
p.C(-408,0,-1,'Ammonium hydroxide @ diluted, 60°C',n,n,n,n,n);
p.C(-625,0,-1,'Aromatic hydrocarbons @ 20°C',n,n,n,n,n);
p.C(-626,0,-1,'Aromatic hydrocarbons @ hot conditions',n,n,n,n,n);
p.C(-629,0,-1,'Benzene @ 100%, 20°C',n,n,n,n,n);
p.C(-460,0,-1,'Butylacetate @ 100%, 20°C',n,n,n,n,n);
p.C(-461,0,-1,'Butylacetate @ 100%, 60°C',n,n,n,n,n);
p.C(-570,0,-1,'Chlorinated solvents @ 20°C',n,n,n,n,n);
p.C(-576,0,-1,'Chloroform @ 20°C',n,n,n,n,n);
p.C(-104,0,-1,'Concentrated acids @ 20°C',n,n,n,n,n);
p.C(-105,0,-1,'Concentrated acids @ hot conditions',n,n,n,n,n);
p.C(-474,0,-1,'Dioctylphtalate @ 100%, 100°C',n,n,n,n,n);
p.C(-475,0,-1,'Dioctylphtalate @ 100%, 20°C',n,n,n,n,n);
p.C(-476,0,-1,'Dioctylphtalate @ 100%, 60°C',n,n,n,n,n);
p.C(-319,0,-1,'Ethanol @ 96%, 20°C',n,n,n,n,n);
p.C(-322,0,-1,'Ethyleneglycol (Ethane diol) @ 100%, 100°C',n,n,n,n,n);
p.C(-323,0,-1,'Ethyleneglycol (Ethane diol) @ 100%, 20°C',n,n,n,n,n);
p.C(-324,0,-1,'Ethyleneglycol (Ethane diol) @ 100%, 50°C',n,n,n,n,n);
p.C(-657,0,-1,'Gasoline',n,n,n,n,n);
p.C(-878,0,-1,'Glycerol @ 100%, 20°C',n,n,n,n,n);
p.C(-737,0,-1,'Grease @ 20°C',n,n,n,n,n);
p.C(-1022,0,-1,'Hydrogen peroxide @ 3%, 20°C',n,n,n,n,n);
p.C(-1024,0,-1,'Hydrogen peroxide @ 30%, 60°C',n,n,n,n,n);
p.C(-672,0,-1,'Kerosene @ 20°C',n,n,n,n,n);
p.C(-338,0,-1,'Methanol @ 100%, 20°C',n,n,n,n,n);
p.C(-729,0,-1,'Methylethyl ketone @ 100%, 20°C',n,n,n,n,n);
p.C(-749,0,-1,'Mineral oil @ 20°C',n,n,n,n,n);
p.C(-1083,0,-1,'Phenol @ 20°C',n,n,n,n,n);
p.C(-963,0,-1,'Silicone oil @ 20°C',n,n,n,n,n);
p.C(-966,0,-1,'Soap @ 20°C',n,n,n,n,n);
p.C(-967,0,-1,'Soap @ 60°C',n,n,n,n,n);
p.C(-437,0,-1,'Sodium hydroxide @ <40%, 20°C',n,n,n,n,n);
p.C(-438,0,-1,'Sodium hydroxide @ <40%, 60°C',n,n,n,n,n);
p.C(-439,0,-1,'Sodium hydroxide @ 10%, 20°C',n,n,n,n,n);
p.C(-440,0,-1,'Sodium hydroxide @ 10%, 60°C',n,n,n,n,n);
p.C(-441,0,-1,'Sodium hydroxide @ 10%, 90°C',n,n,n,n,n);
p.C(-1062,0,-1,'Sodium hypochlorite @ 10%, 50°C',n,n,n,n,n);
p.C(-1068,0,-1,'Sodium hypochlorite @ 20%, 20°C',n,n,n,n,n);
p.C(-238,0,-1,'Strong acids @ 20°C',n,n,n,n,n);
p.C(-239,0,-1,'Strong acids @ concentrated, 20°C',n,n,n,n,n);
p.C(-697,0,-1,'Toluene @ 20°C',n,n,n,n,n);
p.C(-698,0,-1,'Toluene @ 60°C',n,n,n,n,n);
p.C(-706,0,-1,'Xylene @ 20°C',n,n,n,n,n);
u.A('°F','°C','{0}*1.8+32','({0}-32)/1.8');
u.A('10E-5 /°F','10E-5 /°C','{0}/1.8','{0}*1.8');
u.A('lb/in^3','g/cm^3','{0}*0.03612729','{0}/0.03612729');
u.A('ksi','GPa','{0}*145.0377','{0}/145.0377');
u.A('ft-lb/in','J/m','{0}*0.0187341','{0}/0.0187341');
u.A('kV/in','kV/mm','{0}*25.4','{0}/25.4');
u.A('psi','MPa','{0}*145.0377','{0}/145.0377');
u.A('BTU-in/hr-ft2-°F','W/m.K','{0}*6.94','{0}/6.94');