SU735970A1 - Device for determining liquid-liquid interfacial surface tension - Google Patents

Description

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The invention relates to a technique for the physicochemical analysis of liquids, in particular to the determination of the surface tension of liquids. A known device for determining the surface tension at the liquid-liquid interface by droplet volume, comprising a table with a stand, a bracket in which a syringe with a capillary is fixed and a micrometric head moving along the rack with a spring-loaded electric actuator, a thermostat, a removable glass tube that is worn on capillary l.

However, such a device has a single speed of shaping the caps attached to the rack by a spring-loaded actuator due to small distortions creates subtle shaking of the device, sufficient for premature detachment of the droplets from the capillary, which consequently reduces the accuracy of measurements.

In order to fill the syringe and release the air bubble, you need to turn the syringe upside down by the capillary, which requires

almost complete disassembly of the device, and then assembly, which takes a lot of time.

Due to unsuccessful constructive placement of the thermostatic unit, degraded visibility through three glass tubes (thermostat, vessel and tube) and three layers of liquid, it is difficult to set the depth of the capillary in the working fluid and determine the moment of the dropping of the drop.

The most technical solutions to the invention are a device for determining the surface tension at the liquid-liquid interface with drops, containing a table with a stand, a bracket, in which a syringe with a capillary is attached to; # 1 micrometer head, an electric motor with a gearbox mounted on the thermostat's lid and connected to the micrometer screw by a 2J coupling.

Claims (1)

However, the spring-loaded drive is crushed on the rods by the screwed-in 3, 7 with the crotric screw, warped by the cores and causes the entire system of the device to be shaken, which reduces the measurement accuracy. The inaccuracy of centering the axis of the syringe and the axis of the micrometer and the face beating of the bushing of the syringe rod is the most important for the eye relative reciprocating movement of the syringe rod. To insert an air bubble on the syringe, it is necessary to disconnect and remove the actuator, remove the device from the thermostat, remove the bracket with the syringe and the micrometer head, and then reassemble the device with the microscopic axis of the micrometric screw with the axis, which takes a lot of time. Setting the capillary to a constant immersion depth in the liquid is hampered by the fact that the bracket does not move the burner MO in the rack, since it is connected to the actuator located on the thermostat. As a result, the time spent for disassembling and assembling the device violation of the thermostatic measurement mode, after which we need to establish the required temperature, in the known device only one speed of formation of liquid droplets, while the static value of surface tension is ONE & Measurement result obtained at two droplet formation rates. The purpose of the invention is to increase the reproducibility and accuracy of determining the surface tension at the liquid-liquid interface by ensuring optimal conditions for forming the droplet. For this purpose, the device is equipped with a lifting device, a removable holder with replaceable split sleeves, and a drive shutdown mechanism in a ball inserted between the micrometer screw and the syringe stem retainer. With an atom, the lifting device includes a handle with a spring-loaded roller for smoothly raising and lowering the measuring mechanism and a handle rigidly fixing it on the stand. In addition, the drive disconnect mechanism includes an axis, a bushing, a screw, a spring, and an adjusting screw for precisely setting the actuator to its original position. position when turned on. The axis is rigidly connected 0 with a lifting device, the sleeve - with the drive reducer. The actuator, when turned on, is connected to the micrometer screw by means of a gear transmission, so that the gear is fixed on the micrometer screw and, when screwed in, is mixed down running in along the wide gear on the gearbox axis. At the same time there are no nikak. X warps, seizures, shocks, shaking. The installation of a ball with a diameter of 5 mm into the recess made on the needle of the syringe allows it to smoothly, uniformly transfer the translational motion from the rotating micrometric screw to the syringe rod. The removable holder is quickly and easily detached from the lifting device along with a syringe and a micrometer head. This allows for quick refilling of the syringe and release of an air bubble. Then; the holder is set to its original position. The lifting device of the device using the handwheel faucet allows you to smoothly raise and lower the rack of the device, to set the device precisely to a constant depth of the capillary in the liquid and to fix it rigidly on the rack, Keszachatelno. the time spent on preparing the device for operation and recharging almost does not violate the thermal balance in the thermostat. . The device has two speeds of formation of droplets, which is achieved by simply switching the gear lever. When preparing the device for operation, the drive is easily retracted to the side and is precisely set to its original position, ensuring correct gear engagement. The rate of formation of droplets can be changed not only by a two-speed gearbox, but also by syringes of various sections. This operation is also performed very easily, quickly and precisely with the help of interchangeable split sleeves. Curved glass capillary, I have -. conical slice, ground to the conical tip of the syringe. FIG. Shows the proposed Ribor, a general view; FIG. 2 is a sectional view of Ag-A of FIG. 1: FIG. 3 - section bb figs, 1.. The drive includes a DSD2-P1 1 motor connected to Ishtern 2 with a 5 gear 3 having a speed selector handle 4 in two positions. A wide gear 5 is mounted on the axis of the reducer 3, which transmits rotation through gear B on the micrometer screw 7. on m. There are an adjustment wig 8 and a screw 9, the axis 10 of the drive disconnection mechanism is fixed on the lifting device 11, which has a screw needle 12 for zak; the holder 13 is inserted; from the bottom, a syringe 1 is inserted into the removable holder e shI ets with a bandage 15 through a pair of split sleeves 16, a glass capillary tube 17 at the end of the syringe, - Between the micrometric screw 7 and a sub spindle (1 ball 14, a ball 18 is inserted, and between the binder and the syringe body 14 is 19. Drive turning off, it rotates about the axis 1O and the sleeve 2O, for Replaced to the drive, the Lifting device is provided with a handle 21 for fixing, a handle 22 with a roller 23 that rests on the springs 24 through the bracket 25, the whole mechanism of the device is movably mounted on a stand 26 fixed on the table 27, the table 27 has screws 28 for installing 5i sec the level using the level sensor 29 integrated into it, the device's electric drive is turned on and off by the AO toggle switch. The drive disconnect mechanism turns off the drive by unscrewing screw 9 by spring 31 (see, fig 3), DSD2-P1 motor gearbox has 2 rev / min two speed gearbox and EET gear ratio of 1: 5 and 1:10. Thus, the micrometer screw has a rotation of 0.2 rpm and 0, 4 rpm, which is O, O1 and O, O2 mm / min of translational motion. During operation, the device is installed in an air thermostat with transparent walls (not shown in the drawings). The device is prepared for operation, not removed from the thermostat. Having loosened the fixation knob 21, by rotating the knob 22, the entire mechanism of the device is lifted (see, Fig. 2), the instrument's table 27 is set in Level 28 using the level of pa 29. Select the desired syringe 14, apply it to the extreme upper 70 position corresponding to the diameter of the syringe, a replaceable-split sleeve 16 with a side down, inserted into the opening of the holder 13 from the bottom and a syringe fixed with a vent 15. Turn off the drive, unscrewing 3-4 turns of the screw 9 (see, Fig, 3). At the same time, the gearbox 3 with the electric motor 1 and the sleeve 20 fixed to it, expanding the spring 31 rotates about the axis 10, disconnecting the gear 5 on the axis of the reducer from the gear 6, mounted on the micrometer screw. The drive is turned on by turning the screw 9 up to the stop in the adjusting screw 8, the setting of the gears 5 and 6, which ensures accurate, I.X engagement. While maintaining the removable dorogel 13, the screw-ish 12 is unscrewed 4-5 turns, slightly podpuchuvu up, pulled aside and remove the dorzhltrl along with the syringe and micrometric head. Immerse the capillary cap 17, worn on the syringe, into the liquid under study (carosin) and screw in the micrometric screw 7, fill the syringe 14, then, turning the syringe upwards with the capillary, squeeze the air bubble by screwing in the micrometric screw. Between the stem bushing and the crown of the syringe body, prunsina 19 is inserted, which, pushing out the plunger, presses its bolster through the ball 18 to the end of the micrometer screw. A glass vessel with another liquid to be tested (aqueous surfactant solution) is placed on the device's table. Having released the fixing knob 21, the knob 22 lowers the measuring mechanism by the capillary into the vessel to the chosen immersion depth and fix it on the stand with a handle 21, Screw in until it stops pint 9 include drive. The thermostat door is closed and in a few minutes the temperature in the thermostat is set to the desired value. The device is ready for operation. The plug is switched on in the electrical circuit, the toggle switch and the measurement is started. When the rotor of the engine rotates, the kerino medulla is displaced from the syringe of the thalagmometer and formed on the tip of the capillary in the form of drops. The number of divisions of the limb of the micrometer is measured with the neighboring tear drops from the keeller, the magnitude of the interfacial tension on the two-fluid interface (kerosene - water-surfactant solution) is determined by the formula: cr V4-v (, V where (5 - interfacial tension, dyn / c K is the constant of the device; V is the volume of the droplet being formed in the divided scale of the density of both 1.; liquids; To determine the constant of the device K, the phase tension at the boundary of distilled water — cryoscopic benzene is measured The proposed device and the determination of the surface tension on the verge The liquid-liquid has a high accuracy and stability of determination, the time for preparing the device for operation is significantly reduced; when performing measurements it does not require any adjustments to the device and tool, it significantly increases labor productivity. The device is simple in design, compact and convenient in operation. It can be used in chemical industries to control the interfacial tension process between the carbon and aqueous media, inventive claim 1 liquid-liquid bone through the droplet volume, containing an actuator, a measuring mechanism including a syringe for the test liquid, a capillary and a micrometer head, characterized in that with a pinch of increasing reproducibility and accuracy of determination by ensuring optimal conditions for the formation of a droplet , it is equipped with a lifting device, a removable holder with interchangeable split sleeves, unplugging the motor & n () the drive and a ball inserted between the micrometer screw and the shaft ritsa. 2, The device according to claim 1, wherein the lifting device includes a handle with a spring-loaded roller for smoothly raising and lowering the measuring mechanism and a handle rigidly fixing it on the rack, 3. Apparatus according to PP, 1 and 2 , characterized by and and with - Since the mechanism for disabling the drive contains an axis, a sleeve, a spring screw and a control screw. Sources of information taken in the audience during examination 1, USSR Author's Certificate No. 338828, cl. Q01V113 / O2, 1971, 2, The use of surfactants and other chemical reagents in the oil industry. Proceedings of BashNIPInefgy, Issue 1U,. M ,, 1970, s, 86-89,