RU2068555C1 - Device testing impurities in liquid - Google Patents

Abstract

FIELD: measurement technology. SUBSTANCE: invention is meant for inspection of condition of water objects and sources of their pollution during physical-chemical analysis of liquid media. Device testing impurities in liquid has case housing vessel with constant level with measurement chamber located in it provided with piston and hole in bottom for examined liquid and holes for reagents. Piston body houses additional pistons and mixer. Tubes resting against seals and connected with pipe-lines to vessel for reagents are installed in vertical sockets of chamber wall. Numbers of pistons, sockets, tubes, pipe-lines and vessels are related to quantity of used reagents. Conductive filaments are included into mix of all used drives. Device also has measurement pickup made in the form of illuminator with photodetector. EFFECT: simplified design, increased operational reliability. 6 cl, 1 dwg

Description

 The invention relates to physicochemical analysis of liquid media and can be used to monitor the state of water bodies and from sources of pollution.

 A device for controlling the quality of a liquid is known, comprising a housing, a measuring chamber made in the form of a cylinder block with pistons, measurement sensors and openings for the test liquid and reagents, a spool, a valve device, pipelines and tanks for reagents, a piston drive, a spool and a valve device, control and measurement unit. Pistons with rods interact with an inclined washer that acts as a programmer. Reagent tanks are connected via pipelines to the slots of the slide valve, which acts as a valve device for supplying the test fluid and reagents to the measuring chambers. The drive is made with an electric motor connected by a gear transmission with an inclined washer and is common to the mentioned movable elements of the device.

 The device provides for the sampling of a dosed sample, its processing with reagents, qualitative and quantitative analysis of a liquid sample, discharge of a sample with cleaning and washing of cylinder cavities.

 However, the device does not provide reagent dispensers, the valve device acting as a valve due to leaks in the spool does not provide high metering accuracy and, therefore, the accuracy of sample analysis.

 The purpose of the invention is to increase the accuracy of control of impurities in the test fluid by the control device and its reliability by solving the technical problem of increasing the accuracy of entering a given volume of reagents into the measuring chamber of the device and improving the reliability and accuracy of the components making up the device.

 The goal is achieved in that in a device for controlling impurities in a liquid containing a housing, a measuring chamber with a piston installed in its cavity, a measurement sensor and openings for the liquid and reagents to be studied, a spool, a valve device, pipelines and tanks for reagents, piston drives, a spool and a valve device, a control and measurement unit with a programmer, it is equipped with a constant-level vessel placed around the measuring chamber, the camera is equipped with installed with the possibility of changing its volume in lichestve corresponding to the number of containers for additional reagents pistons with individual drives and actuators of the pistons are provided with conductive yarns, connected to the programming device and a source of electrical current.

 For additional items can be installed in the longitudinal holes made in the piston body of the measuring chamber.

 It is possible to install them between the piston of the measuring chamber and its walls with the possibility of their mutual movement relative to each other and the walls of the chamber.

 In addition, the cross-sectional areas of the piston of the measuring chamber and additional pistons can be proportionally dependent on the overall proportionality coefficient from the volumes of doses of the controlled liquid and reagents, respectively.

 The gates of the valve device are made, for example, in the form of tubes installed in vertical sockets of the walls of the measuring chamber with the possibility of abutment by the ends in the seat seals.

 The mixer can be made in the form of a rod with a tip, also connected to an individual drive and installed in the longitudinal bore of the piston of the measuring chamber.

 The introduction of additional pistons with individual drives into the cavity of the measuring chamber made it possible to use them as dispensers when reagents are introduced into the chamber. Using an individual drive, a piston designed for dosed introduction of a specific reagent into the chamber increases the chamber volume by an amount equal to the input volume of the reagent. The dimensions of the pistons, more precisely the area of their cross sections and the length of the paths for their movement, are selected taking into account the dose sizes of the reagents required for the analysis of the test fluid, at a given metering accuracy, which increases the accuracy of control. It is clear that the possibility of accurate dosing of small doses allows you to reduce the dose of the investigated fluid introduced into the measuring chamber. This, in turn, allows to reduce the dimensions of the camera and the device as a whole. In addition, the possibility of issuing small doses of reagents increases the efficiency of the device. The number of additional pistons corresponds to the number of tanks for reagents, i.e. the number of different reagents used for analysis. But the number of pistons may be less than the number of reagents, since it is possible to introduce, for example, two reagents into the chamber using the same piston by successively increasing the chamber volume, if this does not impair the metering accuracy. It is possible that the number of pistons exceeds the number of reagents with a vernier dosing system.

 The indicated correspondence of the number of pistons to the number of reagents contributed to an increase in the quality of control.

 Additional pistons can be installed in the longitudinal guides (their longitudinal axes are parallel to the longitudinal axis of the chamber piston) made in the piston body of the measuring chamber. This ensures the operability of the piston assembly and gives it a vertical orientation in the device case, which created the conditions for reducing the dimensions of the measuring chamber, taking into account the location of the measurement sensor in its walls, the possibility of its functioning and the arrangement of the threads of all drives on one side of the chamber.

 However, the location of the additional pistons in the piston body of the chamber is not the only possible option. So, additional pistons can be located along the perimeter of the chamber piston between it and the chamber walls with the possibility of their mutual displacement relative to each other and the walls of the measuring chamber.

 Both piston arrangements are not critical to the shape of their cross sections.

 There may be other options for the location of additional pistons, for example, in the walls of the measuring chamber, but all options are within the scope of the rights of the claimed invention.

 It is important that these moving elements have the ability to change the volume of the measuring chamber when reagents of the prescribed dosage are introduced into it.

Аналогично для n-го реактива, где n 1, 2.If V _{kl is the} volume of the controlled fluid;
S _KZh the cross-sectional area of the piston of the chamber;
l _Qo piston stroke
then

Similarly for the nth reagent, where n 1, 2.

Возможен вариант, когда l_кж l_1p l_2p l_пр
В этом случае хода всех поршней одинаковы и объем дозы обусловлен только величиной площади поперечного сечения поршней.

A variant is possible when l _kzh l _1p l _2p l _pr
In this case, the strokes of all the pistons are the same and the dose volume is determined only by the value of the cross-sectional area of the pistons.

 The same piston strokes made it possible to reduce the number of control signal options generated by the control and measurement unit with the programmer: they can be the same in size and differ only in the moment of issue. This solution simplified the design of the unit, reduced the number of possible errors and, therefore, increased the accuracy and reliability of the device as a whole.

 The execution of the valves of the valve device in the form of tubes installed in the vertical sockets of the wall of the measuring chamber with an emphasis on the ends in the seat seals is easily feasible and has created a more reliable design. This is facilitated by the use of ring end seals and the emphasis in them by the ends of the tubes provided by its drive. A reliable seal eliminated the leakage of reagents into the measuring chamber, which, in turn, increased the accuracy of the control.

 The introduction of electrically conductive threads into the composition of the drives of the moving elements of the device, changing the length when electric current passes through them, connected electrically with the programmer and mechanically with means of transmitting movement to the moving elements, simplified the design of the drives and ensured almost trouble-free operation. The necessary accuracy of the piston stroke is achieved by setting adjustable stroke limiters.

 Introduction to the design of the device of the mixer provided the possibility of mixing the reagents in the sample and thereby accelerate the color development reaction occurring between the detected impurities and increase the accuracy of the analysis.

 Thus, the proposed combination of essential distinguishing features and each feature separately from this combination ensured the achievement of the goal of increasing the accuracy of controlling impurities in the fluid of the control device and increasing its reliability.

 The drawing shows a diagram of a device for controlling impurities in a liquid.

 The device comprises a housing 1, in the lower part of which a constant-level vessel 2 is made, a measuring chamber 3 with a piston 4 installed in its cavity, a measurement sensor, an opening in the bottom of the chamber for the test liquid, and holes 5 in the walls (one shown) for reagents, spool 6 , valve device, pipelines 7 (one shown), reagent containers 8 (one shown), piston drive 4, spool 6, valve device, additional pistons and agitator 9, control and measurement unit with programmer (not shown).

 The measurement sensor implements the photometric method of analysis and contains a illuminator 10 and a photodetector 11, for which windows are made in the lower part of the measuring chamber 3. The spool 6 is a shutter of the opening of the chamber 3 for the test fluid, essentially being its bottom, and is connected to the actuator. The valve device has several valves. Each of them is made in the form of a tube 12 installed in a vertical socket 13 of the wall of the measuring chamber 3. The tube 12 abuts against the seal 14 with one end, above which there is a reagent hole 5. At the other end, the tube 12 is connected to the drive. The internal cavity of the tube is connected with the atmosphere and a pipe 7 connected to the outlet of the reagent tank 8, made in the form of a vessel with constant pressure. The number of gates is equal to the number of pipelines 7 and the number of tanks 8 and is due to the analysis technique.

 Additional pistons 15 (one shown) are connected (each of them) to individual drives and are located in this particular embodiment in longitudinal guide holes made in the body of the piston 4. The number of pistons 15 corresponds to the number of reagents used, i.e. it may be somewhat larger or slightly less depending on the requirements for metering accuracy. With the same stroke of all pistons, their cross-sectional areas depend on the set dosing volumes of both the test fluid and the reagents. In this case, after a complete set of all reaction components, all pistons with end surfaces will be at the same level (flush), which facilitates mixing and cleaning of the chamber 3 after the analysis process. The mixer 9 consists of a rod with a tip. The rod is installed in the longitudinal bore of the piston 4 and is connected to the drive.

 The piston 4 of the measuring chamber 3, the additional pistons 15, the spool 6, the tube 12 of the valve device, the mixer 9 have individual drives. Each drive contains an electrically conductive metal thread 16 20 with a given length and temperature coefficient of elongation. One of the ends of each thread is isolated in isolation with the corresponding lever 21 25, and the other end is also isolated rigidly mounted on the housing 1. According to the control signals, the threads are connected to the control and measurement unit with a programmer (not shown). The levers have power elements made in the form of spiral springs 26 30. Each of the springs is fixed at one end on the housing 1, and at the point located on the other side from the axis of rotation of the lever relative to the mounting of the corresponding thread with the other end. As threads 16 20 for individual drives can be used, for example, nichrome wire. To prevent its rupture, elastic elements (not shown) are provided at the attachment point to the housing. To limit the movement of the pistons 4 and 15, limiters 31 and 32 are installed.

 The vessel 2 of a constant level has an overflow wall 33 mounted between the inlet and outlet openings 34 and 35, made in the bottom of the housing 1.

 The internal cavity of the measuring chamber 3 can be made of any shape. She corresponds to the shape of the piston 4. The shape of the additional pistons 15 can be any, it corresponds to the shape of their guide holes.

 In the tank 8 for reagents there is a tube 36 that regulates the working level. The pipelines 7 are installed with an inclination towards the chamber 3.

 The operation of the device for controlling impurities in the liquid. A controlled liquid enters the vessel 2 at a constant level of the housing 1 through the inlet 34 of the vessel and fills it to the level of the overflow wall 33. A constant level is established due to the excess fluid flowing through the wall 33, which goes further through the outlet 35.

 In the initial state, the threads 16 20 are de-energized and as a result, their length is reduced. The position of the levers 21, 22, 24 and 25 is such that the piston 4 of the measuring chamber 3, the additional pistons 15, the mixer 9 are in the highest position, and the springs 26, 27 and 30 are in a stretched state. The springs 29 are also in the extended state, and the tubes 12 are in the lower position, closing the reagent holes 5 and pressing the seals 14 of the sockets 13. The lever 23 is in the position in which the spool 6 opened the hole in the bottom of the chamber 3, and the spring 28 in the compressed state .

 Then, from the control and measurement unit with the programmer, an electrical signal is applied to the threads 16, 17 and 20, the threads are heated and lengthened, under the action of the springs 26, 27 and 30, the levers 21, 22 and 25 turn on their axes and the pistons 4 and 15, the mixer 9 goes down and clean the measuring chamber 3, its walls, the windows of the illuminator 10 and the photodetector 11. The cleaning mode can be carried out several times by moving the pistons 4, 15 and the mixer 9 to the upper and lower positions. After the end of the cleaning mode, when the pistons 4, 15 and the mixer 9 are in the lower position, a signal is taken from the thread 16 and the piston 4 rises up to the limiter 31, freeing up the inner space of the chamber 3. The measuring chamber 3 is filled with a portion of the test liquid. They send a signal to the thread 18. The thread lengthens, under the action of the spring 28, the lever 23 moves the spool 6 to overlap the holes for the test fluid, cutting off a predetermined portion due to the volume of the chamber 3 with the upper position of the piston 4 and the lower position of the pistons 15.

 They give a signal to the thread 19 of the drive of one of the tubes 12 of the valve device. The thread 19 is lengthened, the spring 29 is compressed, the lever 24 is rotated axially in the direction of the tube 12 moving upward, allowing access of the corresponding reagent from the tank 8 through the pipe 7 to the hole 5 in the wall of the chamber 3. The reagent will enter the chamber 3 after removing the signal from the thread 17 of one from the pistons 15, which at the same time rises up to the limiter 32, freeing up part of the space in the chamber 3. This part determines the dose of the reagent entering the chamber 3. The signal is taken in the thread 19 of the tube 12 drive of this reagent supply channel, the tube 12 lowers, closes the hole 5 and presses the seal 14. Similarly, other reagents are fed into the chamber by releasing part of the space in it with the corresponding pistons 15. The tubes 36 of the containers 8 maintain the working level of the reagents in them.

 To enable the stirrer 9 to work, the thread 20 of its drive is supplied with a periodic pulse signal, according to which with a pulse repetition rate, the thread is lengthened and shortened, and the stirrer 9 makes a reciprocating movement in the vertical direction. In accordance with the methodology for measuring impurities, the mixer 9 can be switched on in the intervals between the supply of reagents.

 After collecting the last reagent and mixing the prepared sample, a pause is maintained if necessary by the method, for example, to develop color or precipitate sediment, and photometry is performed by turning on the power to the illuminator 10 and receiving a signal from the photodetector 11.

 If necessary, intermediate photometric measurements can be carried out, for example, to determine the reference zero, to take into account the turbidity of the calibration, etc. After completing the measurements, the signal is removed from the thread 18 and the spool 6 opens a hole for the liquid of the chamber 3 under investigation and the device returns to its original state.

 A description of the characteristic features and the principle of operation of the inventive device, as well as the successful testing of a prototype created by the authors, confirmed the operability of the device and its technical advantages.

Claims (6)

 1. A device for controlling impurities in a liquid, comprising a housing, a measuring chamber with a piston in its cavity, a measurement sensor, openings for the liquid and reagents to be studied, a spool, a valve device, pipelines, reagent containers, piston, spool, and valve device drives, a unit control and measurement with a programmer, characterized in that the device is equipped with a constant-level vessel placed around the measuring chamber, and the camera is equipped with additional pistons with individual drives, setting GOVERNMENTAL to vary the chamber volume and in an amount corresponding to the number of tanks for the reagents, the drive pistons are provided with conductive yarns, connected to the control unit.  2. The device according to p. 1, characterized in that the piston of the measuring chamber is made with longitudinal holes, and additional pistons are installed in these longitudinal holes.  3. The device according to claim 1, characterized in that the additional pistons are installed between the piston of the measuring chamber and its walls with the possibility of mutual movement.  4. The device according to paragraphs. 1, 2, 3, characterized in that the cross-sectional areas of the piston of the measuring chamber and the additional pistons are proportional to the overall proportionality coefficient from the dose volumes of the controlled liquid and reagents, respectively.  5. The device according to claim 1, characterized in that the valve device is made with gates in the form of tubes installed in the vertical sockets of the walls of the measuring chamber with the possibility of abutment by the ends in the seat seals.  6. The device according to p. 1, characterized in that it is equipped with a stirrer installed in the longitudinal bore of the piston of the measuring chamber and made in the form of a rod connected to the actuator with a tip.