SU1089416A1 - Automatic metering pump - Google Patents

Abstract

1. AUTOMATIC LIQUID DISPENSER containing an evaporator, a sampling chamber installed at the inlet to the evaporator and provided with a channel for supplying the analyzed liquid, a hollow needle with a plugged end and a side opening installed (with the possibility of reciprocating movement in the gland seals, a metering chamber connected to the end of the cannula, opposite the plugged end, a piston with an axial channel, a chamber for outputting the analyzed liquid, connected to the dosing chamber and supplied with valve and limiting stop, a device for adjusting the internal volume of the dosing chamber, a pneumatic actuator for moving the cannula and a dosing chamber, which is equipped with two calibrated springs, an additional cannula with a side opening and a plugged end, which is installed in the gland seal placed in the chamber to discharge the analyzed liquid, and the other end of the needle is installed the axial channel of the piston, the pneumatic actuator is made in the form of pneumatic cylinders, the rods of which are rigidly connected to the piston by means of a transverse bar, the device for adjusting the internal volume i of the dosing chamber is made in the form of additional stops placed (L with the possibility of moving on the outer walls of the dosing chamber, and the transverse bar equipped with grippers installed with the possibility of interaction with additional stops, and calibrated springs are installed respectively between the transverse n Anka and the chamber for 00. output of the analyzed fluid and co between the transverse plate and additional stops. 2. A dispenser according to claim 1, in accordance with the fact that, in order to reduce overall dimensions, the pneumatic cylinders of the pneumatic actuator are fixed on the flange rigidly connected to the sampling chamber. 3. The dispenser according to claim 2, which means that the pneumatic cylinders of the pneumatic actuator are installed symmetrically and parallel to the axis of the dosing chamber.

Description

The invention relates to analytical instrumentation, in particular, to means of automatically dosing samples of liquid substances introduced from a stream into a composition analyzer, such as a gas chromatograph, and can be used in liquid chromatography, analytical chemistry, and for preparing solutions of a given concentration in medicine and biology. . An automatic liquid metering device is known that contains a sampling chamber unit, through a gland seal which passes a tube with a plugged end and radial openings associated with a metering device, a piston that includes a housing, and a main pneumatic actuator for the fluid outlet and an evaporator l. However, in the dispenser, the working fluid volume of the dose is determined by the position of the piston of the metering device relative to its body, and during sampling the liquid product is often degassed by creating a dilution in the dispenser volume. The closest in technical essence and the achieved result to the proposed is an automatic liquid dispenser containing an evaporator, a sampling chamber installed at the entrance to the evaporator and provided with a channel for supplying the analyzed liquid, a cannula with a muffled end and a side opening that can be returned -accessible movement in the packing seals placed in the sampling chamber, the metering chamber connected to the end of the cannula, opposite to the damped an end that enters the evaporator, a piston, has a central channel and is installed in the dispensing chamber, a chamber for outputting the analyzed liquid connected to the dispensing chamber from the side opposite to its connection with the cannula, and b equipped with a stop valve for interrupting the flow of the analyzed liquid and a stop limiting its movement in the direction opposite to the evaporator, a device for adjusting the internal volume of the dosing chamber and a pneumatic drive for moving the hollow needle and the dosing chamber C 2J. A disadvantage of the known device is the relatively low reliability of its operation due to the complexity of the design, primarily due to the presence of three pneumatic actuators with their control systems before moving the piston, the dosing chamber and the cannula and controlling the closing and opening of the shut-off valve, respectively. The purpose of the invention is to increase the reliability of the dispenser. This goal is achieved by the fact that an automatic liquid metering device containing an evaporator, a sampling chamber installed at the inlet to the evaporator and provided with a channel for supplying the analyzed liquid, a hollow needle with a closed end and a side opening installed with the possibility of reciprocating movement in the packing seals, a metering chamber connected to the end of a cannula opposite to its closed end, a piston with an axial channel installed in the metering chamber, a chamber for outputting an analysis liquid connected to the dosing chamber and equipped with a shut-off valve and borders on the elbow stop, a device for adjusting the internal volume of the dosing chamber, a pneumatic actuator for moving the cannula and the dosing chamber, is equipped with two calibrated springs, an additional cannula with a side opening and a dead valve the end face, which is located in the gland seal placed in the chamber for outputting the analyzed fluid, and the other end of the needle is mounted in the axial channel of the piston, the pneumatic actuator is made in the de pneumatic cylinders, the rods of which by means of a cross bar are rigidly connected to the piston. The device for adjusting the internal volume of the dosing chamber is made in the form of additional stops mounted for movement on the outer walls of the dosing chamber, with a tfc cross section of the sl-abgen grips cooperating with these stops, and calibrated springs are installed respectively between the transverse strip and the chamber for outputting the analyzed liquid and between the transverse galley and additional stops. In addition, pneumatic cylinders of the pneumatic actuator are fixed on the flange rigidly connected with the sampling chamber, and are installed symmetrically and parallel to the axis of the dispensing chamber. At the same time, the pneumatic cylinder rods serve as guides when the dosing chamber and the piston move together, as well as the nortbix needles and stuffing box seals in which they are installed, 4to additionally increases the reliability of the dosing unit. FIG. 1 shows the dispenser, the time of sampling; in FIG. 2, the same, dose cut-off; in fig. 3 the same, the moment of injection of the sample into the gas chromatograph evaporator. The dispenser contains an evaporator 1, which serves to evaporate the dispensed liquid, which is supplied through a channel 2, made in the part of the evaporator 1, which serves as a sampling chamber. Evaporating the liquid enters the chromatographic column (not shown) with a flow of carrier gas, which enters the evaporator 1 through channel 3. The dosing volume 4 for the dosing liquid is formed during the movement of the piston 5 relative to the dosing chamber 6, ending with a hollow needle 7 with a side opening 8 at the end through which the liquid to be metered enters the dispensed volume 4. The piston 5 in the upper part ends with a hollow needle 9 with a side opening 10 at the end. In the hollow needles 7 and 9, the ends located near the side holes 8 and 10 are plugged. Above the upper part of the needle 9 there is a chamber 11 for discharging the analyzed liquid, having a can 12, intended for the flow of lysed liquid through the dispenser. The chamber 11 is able to move upward along the needle 9 under the action of the spring 13 to the limiting stop 15. The dispenser is moved by means of pneumatic cylinders 16, working together. The rods 17 of the pneumatic cylinders 16 are connected by a transverse bar 18 with a piston 5 and two grippers 19. The claws 19 cling upwardly attach additional stops 20, made in the form of nuts, screwed onto the thread of the external walls of the dosing chamber 6 and have the ability to move along The housing of the dosing chamber 6. Between the lugs 20 and the transverse bar .18 there is a spring 21 ,, designed to create an effort in which the piston 5 moves and the sample is introduced into the evaporator after the needle 7 is moved to the lower position. The dispenser works as follows. At the time preceding the sampling (Fig. 1), the flow of liquid sample continuously flows through channel 2. through the hole 8 of the needle 7 into the volume 4, through the channel in the piston 5 into the needle 9 and through the hole 10 enters the outlet into the channel 12 and further in the drainage. At the time of the OT6qpa test, the rods 17 of the pneumatic cylinders 16 move from the extreme upper position downward, dragging the transverse bar 18 against which the springs 13 and 21 abut. The needle 9 also moves downwards and the opening 10 is blocked by an stuffing box 14, thus locking the flow outlet the analyzed liquid from the dispenser to the drainage (Fig. 2). When downwardly moving the rods 17, the needle 7 enters the evaporator 1, and the housing of the dosing chamber 6 in the lower position abuts against the housing of the sampling chamber of the evaporator 1 and stops (Fig. 2). Upon further movement of the rod 17 to the lowest position, the spring 21 is compressed and downward movement of the piston 5, which pushes. the analyzed liquid from the volume 4 of the dosing chamber 6 to the volume of the evaporator 1 (Fig. 3). When moving upwards from the extreme lower position of the rods 17, the force of the actuators 16 and the spring 21 moves up the piston 5, transferring the dispenser from the bottom of the polo shown in FIG. 3 to the position shown in FIG. 2. Upon further upward movement of the rods 17, the needle 7 emerges from the evaporator. P position when the side hole 8 of the needle rises opposite channel 2. At this point, the camera 1 1 leaves the anapizable liquid and abuts the rest stop 15, and the end of the needle 9 with the hole 10 out of the stuffing box 14, which allows the fluid to flow freely through the dispenser and flush it from the remnants of the previous dose. Thus, the dispenser comes to its original position and is prepared for dispensing and entering the sample after the sample. It should be noted that all phases of the operation of the dispenser are carried out when the rods 17 are moved from the extreme position (fig. 1) to the extreme, bottom (fig. 3) and back. At the same time, in the intermediate position (Figo 2), the flow of the analyzed liquid and the cut-off of the dose are interrupted automatically by the action of the spring 13. The role of the check valve in the proposed design dose 1

(Rig. 1 66 of the torus performs the end of the needle 9 with the side opening 10 and the gland seal 14. This not only increases the reliability of the dispenser, but also reduces its dead volume. The upper part of the evaporator I, which functions as a sampling chamber, is equipped with cooling, preventing the seal from overheating, in which the needle 7 is installed. By simplifying the design of the proposed dispenser, the reliability of its operation has been significantly increased, and the number of continuous operation cycles (MTBF) is 5 times higher than the corresponding th component of the dispenser of the prototype. 15 L

(Reg. 2

fig.Z

Claims (3)

1. .AUTOMATIC LIQUID DISPENSER containing an evaporator, a sampling chamber installed at the inlet of the evaporator and provided with a channel for supplying the analyzed liquid, a hollow needle with a plugged end face and a side hole installed with * the possibility of reciprocating movement in stuffing box seals, a metering chamber connected to the end of the hollow needle opposite the muffled end, a piston with an axial channel, a chamber for outputting the analyzed fluid, connected to a metering chamber and equipped with a locking valve pan and restrictive emphasis, a device for regulating the internal volume of the metering chamber, a pneumatic actuator for moving the hollow needle and the metering chamber, is distinguished by the fact that, in order to increase the reliability of operation by reducing the number of autonomous drive organs, it is equipped with two calibrated springs, an additional hollow needle with a side hole and a plugged end face, which is installed in the stuffing box packing, located in the chamber for the output of the analyzed fluid, and the other end of the needle • is installed in the axial chamber the piston, the pneumatic actuator is made in the form of pneumatic cylinders, the rods of which are rigidly connected to the piston by means of a transverse bar, the device for regulating the internal volume of the metering chamber is made in the form of additional stops placed to move on the external walls of the metering chamber, and the transverse bar is equipped with grippers installed with the possibility of interaction with additional stops, and calibrated springs are installed respectively between the transverse bar and the camera for water and analyzed liquid between the crossbar and additional -uporami. 2. Dispenser according to π. 1, characterized in that, in order to reduce the size, the pneumatic pneumatic actuator cylinders are mounted on a flange rigidly connected to the sampling chamber. 3. The dispenser according to claim 2, with the fact that the pneumatic pneumatic actuator cylinders are installed symmetrically and parallel to the axis of the metering chamber.