RU44845U1 - DISPENSER FOR LIQUID REAGENTS - Google Patents

Abstract

The utility model relates to the field of chemical technology, namely to devices for dispensing liquid reagents, and can be used, for example, in water treatment systems, in the chemical and petrochemical industry, as well as in oil production and transportation. The dispenser for liquid reagents contains a vessel for liquid reagent, means for introducing a liquid reagent and withdrawing a replacement medium, a device for calibrating the flow of liquid reagent, a device for selecting a dynamic pressure, made with the possibility of rotation and includes two pipelines, one of which is located inside the other. At one end, the pipelines are connected to a head located in the main pipeline in the form of a body of revolution, in which there are mutually perpendicular channels communicating with the pipelines, one of the channels being aligned with the axis of rotation of the device for selecting the dynamic pressure and perpendicular to the axis of the main pipeline. In addition, the dispenser for liquid reagents is equipped with a device for determining the level of liquid reagent, which contains a float. The density value of the float lies in the interval between the density value of the replacement medium and the density value of the reagent. The proposed dispenser for liquid reagents can improve the reliability of the design and ease of use, as well as to ensure the accuracy of dispensing liquid reagent.

Description

The utility model relates to the field of chemical technology, namely to devices for dispensing liquid reagents, and can be used, for example, in water treatment systems, in the chemical and petrochemical industry, as well as in oil production and transportation.

A known dispenser for liquid reagents, in which the dosed reagent passes through a liquid reagent flow sensor, a diaphragm valve, a nozzle and a differential pressure regulator cavity, an inlet channel, a subvalve cavity, a nozzle, a subvalve cavity and an output channel of a liquid reagent flow controller, is mixed with pressure water in ejector and enters the purified water line (see the description of the patent of the Russian Federation No. 2022319, IPC G 05 D 11/02, publ. 30.10.1994). In addition to slowly adjusting the concentration of the liquid reagent in the purified water line through the input input of the liquid reagent flow regulator, a quick response to the change in the flow of the liquid reagent is carried out using a differential pressure regulator by maintaining the difference in fluid pressure in the cavities and the flow rate regulator of the liquid reagent constant. The disadvantages of the described design of the dispenser include its structural complexity. As a result, the dispenser has a high cost.

The closest adopted for the prototype is a dispenser for liquid reagents (see the description of the certificate for PM No. 22714, IPC G 05 D 11/03, E 21 B 37/06, announced April 26, 2001, publ. April 20, 2002).

The dispenser for liquid reagents contains a container for a liquid reagent, a device for the selection of dynamic pressure located in the main stream. Moreover, the device for the selection of dynamic pressure includes two pipelines located in different positions relative to the direction of the main flow and is made with the possibility of rotation relative to the main flow. The container is equipped with means for introducing a liquid reagent and withdrawing a replacement medium. Additionally, the dispenser can

contain a device for calibrating the flow of liquid reagent located between the container for liquid reagent and one of the pipelines of the device for the selection of dynamic pressure.

The disadvantage of this dispenser is that in this design, the rotation of the device for the selection of dynamic pressure relative to the direction of the main flow leads to a change in the position of both pipelines. At the same time, the pipeline through which the liquid reagent must enter the main stream is in the zone of intense turbulence of the latter, which negatively affects the uniformity of the outflow of the liquid reagent into the main stream and, as a result, the accuracy of dispensing the liquid reagent. For the same reason, the angle of rotation of the device for the selection of dynamic pressure relative to the direction of the main flow is limited by an angle of / 4 radians (45 degrees), which requires high precision positioning of the node for the selection of dynamic pressure in the specified interval and complicates the operation of the dispenser.

SUBSTANCE: proposed is a dispenser for liquid reagents, comprising a vessel for a liquid reagent, means for introducing a liquid reagent and withdrawing a replacement medium, a device for calibrating the flow of a liquid reagent, a device for selecting a dynamic pressure, made with the possibility of rotation and including two pipelines, one of which is located inside the other moreover, at one end the pipelines are connected to a head located in the main pipeline in the form of a body of revolution in which there are mutually perpendicular channels communicating with the pipe odes, wherein one of the channels is disposed coaxially to the rotation axis of the apparatus and selecting the dynamic pressure perpendicular to the axis of the main pipeline. In addition, the dispenser for liquid reagents is equipped with a device for determining the level of liquid reagent, which contains a float. The density value of the float lies in the interval between the density value of the replacement medium and the density value of the reagent.

The proposed dispenser for liquid reagents can improve the reliability of the design and ease of use, as well as to ensure the accuracy of dispensing liquid reagent.

The essence of the claimed utility model is illustrated by the following drawings:

Figure 1 is a schematic illustration of a dispenser for liquid reagents;

Figure 2 - device for the selection of dynamic pressure;

Figure 3 - device for determining the level of liquid reagent.

The dispenser for liquid reagents contains a vessel for liquid reagent 1, equipped with means for introducing a liquid reagent 2, made in the form of an open container and communicating with the vessel 1 by means of a valve 3. A valve 4 for venting air and a valve 5 for displacing the replacement medium are also connected to the vessel 1 . The vessel 1 is connected to a device for the selection of dynamic pressure 6, consisting of pipelines 7 and 8 and connected to them by a head in the form of a body of revolution 9, which can be made, for example, in the form of a spherical head and which is located in the main pipe 10, intended for passage trunk flow. A device for the selection of dynamic pressure 6 is made with the possibility of rotation relative to the axis of the main pipeline. The pipe 8 is placed inside the pipe 7. In the head in the form of a body of revolution 9 there are channels 11 and 12, respectively connected with pipelines 7 and 8. Channel 12 is made perpendicular to the axis of the main pipeline and coaxially with the axis of rotation of the device for selecting the dynamic pressure 6, and channel 11 is perpendicular channel 12. The vessel 1 and the device for the selection of dynamic pressure 6 are communicated by means of taps 13 and 14, as well as a device for calibrating the flow rate of the liquid reagent 15, made, for example, in the form of a jet. A device for determining the level of liquid reagent 16 is connected to the vessel 1 by means of taps 17 and 18. In the device for determining the level of liquid reagent 16 there is a float 19, and on the outer surface there is a scale that allows controlling the flow of liquid reagent.

The dispenser for liquid reagents works as follows. The vessel 1 is filled with a liquid reagent using means 2. For this, the valves 3 and 4 are opened, as a result of which the liquid reagent enters the vessel 1, and the air from the vessel 1 enters the atmosphere. Cranes 17 and 18 are also opened, as a result of which the liquid reagent fills the device for determining the level of liquid reagent 16 as the vessel 1 is filled. Moreover, if the density of the float 19

less than the density of the liquid reagent, the float 19 rises to the upper part of the device 16. After filling the vessel 1, the taps 3 and 4 close and open the taps 13 and 14. The medium from the main stream through the channel 11 located in the direction of the main stream, pipeline 7 and valve 14 enters the vessel 1 and replaces the liquid reagent, as a result of which the latter flows out of the vessel 1, a device for calibrating the flow of liquid reagent 15, made, for example, in the form of a nozzle, through a valve 13, a pipe 8 and a channel 12 located in the head in the form of a body in ascheniya 9, into the main pipeline 10. Also, replacement fluid through the valve 17 enters the device for determining the level of reagent liquid 16 and displaces the liquid reagent is located in this device. In the device for determining the level of liquid reagent 16 there is a float 19. The density value of the float lies in the interval between the density value of the replacement medium and the density value of the reagent. Due to this, the float 19 is located at the interface between the liquid reagent and the replacement medium, thus showing the level of the liquid reagent. According to the law of communicating vessels, the height of the column of liquid reagent in the device 16 can be used to judge the volume of liquid reagent in the vessel 1. The presence of a device for calibrating the flow rate of the liquid reagent 15 provides the required flow rate of the liquid reagent. Since the pressure drop in the channels 11 and 12 varies depending on the speed of the main stream, the flow rate of the liquid reagent changes in accordance with the change in the flow rate of the medium in the main stream. Thus, the proportion between the flow rate of the liquid reagent and the flow rate of the medium in the main flow is automatically maintained in a wide range of flow rates of the medium in the main flow.

Turning the device for the selection of dynamic pressure 6, you can change the position of the channel 11 relative to the axis of the main pipeline, and therefore; coefficient of proportionality between the flow rate of the medium in the main stream and the flow rate of the liquid reagent. This makes it possible to smoothly control the flow rate of the liquid reagent and the proportion of dosing. The location of the channel 12, through which the liquid reagent enters the main stream, is perpendicular to this stream and does not change when the device is rotated to

selection of dynamic pressure 6. Due to this, the channel 12 does not fall into the zone of intense turbulence, which increases the accuracy of dosing.

When the vessel 1 is filled with a substitute medium, the pipelines 7 and 8 of the dynamic pressure sampling device 6 are disconnected from the vessel 1 using the taps 13 and 14, the valve 4 is opened to allow air to enter the vessel 1, and the replacement medium is taken out of the vessel 1 with the help of a valve 5. After that, the dispenser is ready for subsequent filling with a new portion of the liquid reagent.

Liquid dispenser can be used in industry. The manufacture of a dispenser of the described construction is possible by known and common methods on equipment traditionally used in mechanical engineering.

Thus, the proposed dispenser for liquid reagents makes it possible to ensure high metering accuracy with a changing flow rate of the medium in the main flow, and the presence of a device for determining the level of liquid reagent makes the dispenser more convenient to use.

Claims (4)

1. The dispenser for liquid reagents, containing a vessel for reagent, means for introducing a reagent and withdrawing a replacement medium, a device for calibrating the flow of reagent, a device for selecting a dynamic pressure, made with the possibility of rotation and includes two pipelines, characterized in that one piping is placed inside the other, with one end of the pipelines connected to a head located in the main pipeline in the form of a body of revolution, in which there are mutually perpendicular channels communicating with the pipelines, when Volume one of the channels is located coaxial to the axis of rotation of the device for the selection of dynamic pressure and is perpendicular to the axis of the main pipeline. 2. The dispenser for liquid reagents according to claim 1, characterized in that it further comprises a device for determining the level of the reagent located in the vessel. 3. The dispenser for liquid reagents according to claim 2, characterized in that the device for determining the level of the reagent contains a float. 4. Dispenser for liquid reagents according to claims 2 and 3, characterized in that the density value of the float lies in the interval between the density value of the replacement medium and the density value of the reagent.