Determination of Intrinsic Viscosity of Polyester Products

1 Scope

This standard applies to the determination of the intrinsic viscosity of prepolymers, polyester chips and melts. The measurement range is: 0.020-1.500dL/g

1 Scope

This standard applies to the determination of the intrinsic viscosity of prepolymers, polyester chips and melts. The measurement range is: 0.020-1.500dL/g

2 Method Overview

The sample was dissolved in a mixture of phenol and 1,2-dichlorobenzene. The flow time t was measured by an Ubbelohde viscometer. The flow time of the mixture of phenol and 1,2-dichlorobenzene was measured by an Ubbelohde viscometer. , to determine the relative viscosity of the sample η relative = t / t0. The relationship between relative viscosity and intrinsic viscosity can be expressed by the Billmeyer equation:

η characteristic=1/4×(ηrelative-1)/C+3/4×(lnηrelative)/C

Where: C-sample solution concentration, g/100mL;

η characteristics - sample intrinsic viscosity, dL/g;

η-relative-sample relative viscosity.

3 Instruments

3.1 Viscometer: The temperature can be controlled to 25.00 ± 0.05 °C.

3.2 Ubbelohde viscometer, plus a viscometer frame that matches it.

3.3 Thermometer: 0-50°C, 0.1 degree.

3.4 Magnetic heating stirrer.

3.5 Pipette: 25 mL.

3.6 metal filter: 200 mesh.

3.7 stoppered flask: 50 mL.

3.8 Teflon stirrer.

3.9 Glass funnel: 5 cm in diameter.

3.10 Beaker: 5000 mL.

4 Reagents and materials

4.1 Water: Meets the requirements for tertiary water specified in GB 6682-92.

4.2 Phenol.

4.3 1,2-Dichlorobenzene.

4.4 Ethanol.

4.5 Hydrochloric acid solution: (1+1).

4.6 Acetone.

5 test steps

5.1 Preparation of phenol-1,2-dichlorobenzene solution

5.1.1 mixed phenol / 1,2-dichlorobenzene: 510mL 1,2-dichlorobenzene was added to a bottle containing 1kg of phenol (3:2 by weight mixing), the density of the solution was 1.151 ±0.001g/cm3 (25 °C).

5.1.2 Heat the mixture in an oven. The oven temperature is 60°C. During the heating process, it should be shaken continuously until it is evenly mixed.

5.1.3 Pour the solution through the filter into the brown reservoir bottle.

5.2 Determination of blank

5.2.1 set the viscosity bath water temperature 25.00 ± 0.05 °C.

5.2.2 Add approximately 17 mL of phenol/1,2-dichlorobenzene solution (5.1) to the viscometer between the two marked lines.

5.2.3 Put the viscometer in the water bath of the viscometer and keep it at a constant temperature for 15-20 minutes. Determine the flow time of phenol/1,2-dichlorobenzene. Measure five times. The deviation should not exceed 0.1 second.

5.2.4 Take the average of five tests as the flow time of each freshly prepared phenol/1,2-dichlorobenzene solution. The flow time of the to measure should be between 80-120 seconds. Too high and too low are not allowed.

5.3 Preparation of Samples

5.3.1 The moisture content of the polyester should be less than 0.5%. Wet slices should be cleaned with acetone and the residual acetone should be sliced ​​and dried in an oven at 80 °C for 15-20 minutes. The residual moisture is so small that it does not have a significant effect on the relative viscosity value.

5.3.2 If the polyester has a high degree of crystallinity, its crystal structure must be destroyed. The method is to load the slices into a suitable grinder to crush the slices (pressure is about 150 bar).

5.4 Test

5.4.1 Finely weighed 125-145mg sample to a value of 0.0001g and put it into a 50-mL Erlenmeyer flask. Add 25 mL (weight 28.75--28.80 g) of phenol/1,2-dichlorobenzene solution (5.1.1 ), put a magnetic stir bar, and cap it.

5.4.2 Place the flask on a magnetic stirrer and heat, stir and dissolve the sample at 90-100°C.

5.4.3 After the sample is dissolved, cool the sample.

5.4.4 The sample solution is filtered through a 200 mesh metal filter and added to the viscometer.

5.4.5 The viscometer shall be immersed in a water bath of the viscometer for a period of 20 minutes. Through three measurements, the flow time of the sample solution shall be determined. The difference shall not exceed 0.2 second.

5.4.6 Calculate the average t of the three measurements.

5.5 Calculation

5.5.1 Determination of Relative Viscosity

          η relative = t (average flow time of sample solution, second) / t0 (average flow time of phenol/1,2-dichlorobenzene solution, second)

5.5.2 Correlation Factor F

          The relevant factor F read out from the attached table.

5.5.3 Calculation of Intrinsic Viscosity

         With the relevant factor F, divided by the weight of the sample, the value is the intrinsic viscosity.

         η characteristic = F/W

         Among them: η characteristics - sample intrinsic viscosity, dL/g;

         F-related factor, mg·dL/g;

         W-sample weight, mg.

5.5.4 The difference between two parallel determinations of the same sample is not greater than 0.008 dL/g, and the arithmetic average is taken as the measurement result. The result is rounded off to the third decimal place.

5.6 Viscometer Cleaning

5.6.1 After the operation is complete, pour the solution from the viscometer into the waste bottle.

5.6.2 Place the viscometer to be cleaned in a beaker.

5.6.3 Add an appropriate amount of ethanol to the viscometer and wash it several times with a suction earball. Thoroughly pour off the residue.

5.6.4 soak in hydrochloric acid solution for one day.

5.6.5 Clean the viscometer with water, rinse with ethanol, and dry it upside down on the shelf.

5.6.6 The viscometer is cleaned with chromic acid lotion when it is used for the first time or when there are many impurities.

 Description

When the normal polyester chips are melted or no oil, the heating temperature cannot be too high and cannot exceed 100°C. This step takes about 15 minutes.

When the dry section before spinning is dissolved, the heating temperature can be increased to 130-140°C.

7 Precautions

Phenol, 1,2-dichlorobenzene and acetone are toxic. Avoid inhalation and contact with the skin. Wear rubber gloves and goggles when preparing and using these chemicals. All operations including waste treatment should be completed in a fume hood. . The waste liquid is poured into the waste barrel and processed regularly.

Glass Capillary Viscometers (Viscometer accessories)

The principle of capillary viscometer

A viscometer based on Hagen Poisson's (Hagen-Poisculli) rule is obtained by measuring the flow rate of fluid flowing through the capillary, the pressure difference between the capillary outlet and the inlet, and then according to Hagen Poisson's law.

Capillary viscometer

A viscometer based on Hagen Poisson's (Hagen-Poisculli) rule is obtained by measuring the flow rate of fluid flowing through the capillary, the pressure difference between the capillary outlet and the inlet, and then according to Hagen Poisson's law.

Hagen - bershaw leaf formula:

ETA = (n R^4Pt) /8VL

Among them:

V--t time flows through the capillary volume

R-- capillary radius

P-- capillary pressure difference at the end of two

L-- capillary length

As long as the volume, time and pressure added to the liquid are obtained, the viscosity of the liquid can be reversed.

There are three main types of capillary viscometer: round - piston, glass tube and pass viscometer. The circular hole - piston viscometer allows for greater pressure, so it can be used to determine the viscosity of the polymer.

The pore type viscometer is also called the short tube type, and the small pore type can be used for rough measurement and viscosity comparison of Newtonian fluid. Glass tube type viscosity and wide application, can be divided into gravity type and pressure type. The gravity type is generally used to measure the Newton fluid, and the pressure type can be used to measure the non Newton fluid. There are many kinds of glass capillary viscometer, most of which are named by the designer's name abroad. The methods of their construction and use are all the same.

Using Ubbelohde viscometer one-point method to determine the intrinsic viscosity

Material: a triangular flask

Two 10ml pipettes

Ubbelohde viscometer (capillary 0.5mm)

A water bath (temperature control accuracy of ± 0.1 ℃)

A stopwatch

Rubber hose two sections

A syringe

Wash the ear ball one

The company is located in:

step:

1, the system solution: Take a certain amount of polymer, add 10mm solvent, make it completely dissolved, if necessary, heated.

2, constant temperature: installed device, stable temperature up and down changes 0.1 ℃.

3, plus the solution balance 5min: up and down into the capillary tube three times.

4, determination: measured three sets of data, so that the deviation but 0.2s.

5, Determination of solvent flow time.

data processing:

ηr = t / t0 (t is the solution flow time, t0 solvent time)

ηsp = ηr-1

[η] = [2 (ηsp-ηr)] / C (C is the concentration unit g / ml)

[η] = (ηSP / C) c = 0 = (ln ηr / C) c = 0 [η] = KMα

Remove the pipette has been pre-heated solution 10ml, into the viscometer, the same method, the installation of viscometer, the determination of the solution outflow time t. Then followed by adding 2.00,3.00,5.00,10.00 ml of distilled water.

Kent Yuan (Mr.) Hangzhou Zhongwang Technology Co., LTD. Skype: kenyuan9023   Wechat/WhatsApp:+86 15068109723E lei@zonwon.com  W www.zonwontech.com

Introduction and influencing factors of kinematic viscosity determination of petroleum products

Scope of application

The petroleum product movement tester is designed and manufactured according to the national standard GB/T265. It is used to measure the kinematic viscosity of liquid petroleum products. LCD screen Chinese display, man-machine dialogue interface, preset temperature, test time and other parameters menu prompt input, appearance design is beautiful, is the introduction of new instruments.

Viscosity is one of the main indexes of petroleum products, and viscosity is one of the important factors that affect the biodegradability of base oils. Many domestic lubricants are classified and classified according to their kinematic viscosity of 40oC and 100oC. In practical application, viscosity is an important index to evaluate the flow performance of lubricating oil. It is important for quality identification of petroleum products and their application. Viscosity is large, oil film thickness is large, lubrication performance is good, but the viscosity is too large, will increase the friction resistance, waste of resources.

Kinematic viscosity is the ratio of the dynamic viscosity of a liquid to its density at the same temperature. It represents a measure of the friction of a liquid when it flows under gravity. Kinematic viscosity measurement is the determination of the time at which a certain volume of liquid passes through a calibrated glass capillary viscometer at a constant temperature. The product of the capillary constant and flow time, i.e., the kinematic viscosity of the liquid at this temperature.

Functional characteristics

1. ring type fluorescent lamp illumination, fluoroscopy is good. Easily observed.

2. heater and guide tube and bath parts are made of stainless steel, durable and durable.

3. Automatically calculate the capillary constant and the average product of the test time. The temperature control precision is high and the accuracy is good.

4, computer temperature control, timing, constant temperature, water bath and other parts. Constant temperature bath is small cylinder, round cylinder, double layer, uniform temperature distribution in the bath, the temperature control effect is good.

5. Chinese LCD screen display, man-machine interface, the preset temperature, test time and other parameters, menu input, actuator adopts advanced SSR, its features of no contact, no spark, no action noise, vibration resistance, long life.

Technical parameter:

1, weight: 25kg

2, constant temperature accuracy: + 0.1

3, the number of cards installed capillary: 3 branches

4 ,heater power: 1000W

5, environmental temperature: room temperature to 35 degrees

6, temperature control settings: room temperature to 100 degrees set at any time

7, work power supply: 220V + 10% 50Hz

The main factors influencing the determination of kinematic viscosity:

First, the measurement of the factors:

1. Stopwatch: The stopwatch is used to determine the time the sample flows through the viscometer. If the stopwatch is not precise enough, it may cause a test error. Therefore, for the use of the stopwatch, be sure to regularly test.

2. viscometer coefficient: capillary viscometer must be calibrated on a regular basis, otherwise it will cause a greater error.

Second, the experimental operation of the factors

1, the viscosity of the process of measuring the flow of oil through the viscometer

The flow time of the specimen must be within the specified range. GB / T265 provides that the flow time to> 200S. Mainly in order to ensure that the oil flow in the viscometer for the laminar flow. If the oil flow rate is too fast beyond the specified range, will become turbulent, with turbulence can not use the cassace equation to calculate the viscosity of oil. In addition, the flow rate is too fast, the reading error will increase accordingly. If the oil flow rate is too slow, within a specified time is not easy to maintain constant temperature

2, the viscosity of the test process bath temperature accuracy

Determination of kinematic viscosity to be strictly in accordance with the provisions of constant temperature test, which is the determination of oil moving viscosity of one of the important conditions. In GB / T265, the temperature control accuracy of the thermostatic bath must be ± 1oC, while in the ASTMD445 bath temperature control accuracy of ± 0.5oC. Because the viscosity of the oil sample decreases with increasing temperature and increases with the temperature drop, it must be strictly in accordance with the specified constant temperature, the slight temperature deviation will make the viscosity measurement results have a greater error.

Third, the viscosity of the other factors in the determination process

Test oil samples containing impurities, moisture and capillary viscometer is not washed, will also affect the sample in the capillary viscometer in the normal flow, the results are high. The solvent used for the washing in the viscometer is not dry and the sample is diluted so that the result is low.

When measuring the viscosity of the oil, the sample in the viscometer can not have air bubbles. If the oil bubbles will affect the oil volume, while entering the capillary will form a gas plug, so that the flow resistance of oil increased, the determination of high results.

Kent Yuan (Mr.) Hangzhou Zhongwang Technology Co., LTD.

P  /Wahtsapp: +86 15068109723  E lei@zonwon.com

Application of Hangzhou Zhongwang's Viscometer in Polymer, Plastics, Rubber and Other Fields

Application of Hangzhou Zhongwang's Viscometer in Polymer, Plastics, Rubber and Other Fields

Polymer material characterization is an important field of polymer science. From the initial aggregation, laboratory analysis, prediction of processability, and then to predict end-use performance, and the impact of material degradation on the environment, polymer characterization is an important way for us to understand or predict material properties throughout the life cycle process.

Hangzhou Zhongwang Technology CO.,LTD of Ubbelohde viscosity automatic measurement equipment can quickly measure the kinematic viscosity, dynamic viscosity, Concentrated viscosity, intrinsic viscosity, relative viscosity, polymer molecular weight, rheological properties and other information. The software integrates almost all of the viscous calculation formulas, and the experimenter does not need to do it manually.

Application of polymer recycling:

Recycling may cause changes in polymer properties. For example, shearing and heating can cause degradation; the addition will weaken the material properties. Therefore, the quality control of recycled materials is of great importance to the target application of these materials. The automatic viscosity measurement system of Hangzhou Zhongwang Technology Co.,ltd can measure the intrinsic viscosity and viscosity average molecular weight of the recovered polymer.

Kent Yuan (Mr.) Hangzhou Zhongwang Technology Co., LTD.

P  /Wahtsapp: +86 15068109723  E lei@zonwon.com