RU200182U1 - Float Liquid Level Gauge - Google Patents

Abstract

The proposal relates to instrumentation, namely to measuring the level of a liquid in a container. A float liquid level gauge includes a container, inserted vertically into the container, a pipe with a float inside, made with the possibility of longitudinal movement inside the pipe, a level indicator located above the container, made in the form of a vertical glasses with a viewing window with measuring strips and an upper float inside. The nozzle is made with a larger cross-section than the cross-sectional area of the pipe. The pipe is made of dielectric material. The float is made in the form of a piston with a soft magnetic material around the perimeter. The glass is connected from below with the top of the pipe by a hydraulic tube. The internal spaces of the pipe above the float, hydraulic tube and nozzle are filled with technical liquid up to the upper float. Outside the pipe to compensate for the level of technical fluid, a large float is installed with the possibility of longitudinal movement and magnets inside interacting with the soft magnetic material of the float inside the pipe. The proposed float level gauge is simple and reliable in manufacturing, setting up and operating, while allowing you to constantly monitor the liquid level in containers with great height, including in underground tanks. 1 wp f-ly, 1 dwg

Description

The proposal relates to control and measuring technology, namely to the measurement of the level of liquid in a container.

Known device for measuring the level of liquid (patent RU No. 2534423, IPC G01F 23/38, G01F 23/62, publ. 27.11.2014 Bull. No. 33), containing a sensing element immersed in a liquid, a magnetic system fixed in a hollow sleeve, which is connected to the sensing element with the ability to move when changing the position of the sensing element relative to the liquid level, and a Hall sensor connected to the measuring unit, and the bushing is made of spring steel or alloy; on its lateral surface there are annular rows of through slots, and between the mentioned rows of slots along the height of the sleeve, rows of solid flat rings are formed, while the length of the region of flat rings t along the height of the sleeve L is selected from the condition t≥0.3 L; the magnetic system is made in the form of two magnets located opposite each other in the area of solid flat rings, and the Hall sensor is placed in a cage of non-magnetic material, which is located between the two mentioned magnets.

The disadvantages of this device are the complexity and low reliability due to the presence of a large number of interconnected complex elements and devices that are very sensitive to changing external factors (temperature, humidity, etc.), as well as the need for an uninterrupted power supply, which is difficult to implement on remote objects.

Also known is a level gauge (patent RU No. 2050527, IPC G01F 23/30, publ. 20.12.1995 Bull. No. 35), containing a liquid in a vessel, a float, a magnetic field source, a visual device located on the outer wall of the vessel, and as a float a liquid with a lower density and other magnetic properties than the density and magnetic properties of the main liquid is used.

The disadvantages of this level gauge are the complexity of implementation in tanks with large overall dimensions (for example, in oil storage tanks, water towers, etc.), since a large volume of floating liquid with magnetic properties (which no one industrially produces) is required, and control will be required along the entire height of the tank, which can also be carried out in a pipe at objects with a large height (more than 5 m), and it is impossible to carry out control in underground tanks.

The closest is a septic tank (patent for PM RU No. 183169, IPC G01F 23/30, С02F 3/00, publ. 09/12/2018 Bull. No. 26), containing at least one section, and a pipe is vertically rigidly installed in the septic tank, in which the float is placed with the possibility of free movement in such a way that, with a properly functioning device, the float does not go beyond the upper end of the pipe, and in an emergency, it goes beyond the end of the pipe.

The disadvantage of this device is the indication only when the container is overfilled and a float with a height not less than the difference in levels in the container is required, which is technically difficult to implement in containers with a large height and with a large difference in liquid level.

The technical task of the proposed utility model is to create a simple and reliable design of a float level gauge that allows constant monitoring of the liquid level in containers with a large height, including underground containers.

The technical problem is solved by a float liquid level gauge, including a container, inserted vertically into the container, a pipe with a float inside, made with the possibility of longitudinal movement inside the pipe, a level indicator located above the container.

What is new is that the pipe is made of a dielectric material, the float is made in the form of a piston with a soft magnetic material around the perimeter, the indicator is made in the form of a vertical glass with a viewing window with measuring strips, and an upper float inside a larger cross-section than the cross-sectional area of the pipe, the bottom of the glass is communicated with the top of the pipe by a hydraulic pipe, and the inner spaces of the pipe above the float, the hydraulic pipe and the cavity up to the upper float are filled with technical fluid, while outside the pipe to compensate for the level of the technical fluid, a large float is installed with the possibility of longitudinal movement and magnets inside interacting with the magnetically soft float material inside the pipe.

It is also new that when the upper float fits snugly against the walls of the glass, the upper float is equipped with a bypass valve for releasing gas and excess technical liquid from the inner space of the glass under the upper float.

The drawing shows a diagram of the operation of a float level gauge.

A float liquid level gauge, includes a container 1, a pipe 2 inserted vertically into a container with a float 3 inside, made with the possibility of longitudinal movement inside a pipe 2, a level indicator located above the container 1, made in the form of a vertical glass 4 with a viewing window (not shown) having measuring strips (not shown), and the upper float 5 inside. The glass 4 is made of a larger cross-section D than the cross-sectional area d of pipe 2 to reduce the travel of the upper float 5 compared to the float 3 of pipe 2, which makes it more convenient to visualize the level in the tank 1, which has a greater depth (3 m or more) ... To exclude magnetic influences, pipe 2 is made of a dielectric material (polyethylene, polypropylene, glass, etc.). The float 3 is made in the form of a piston with a soft magnetic material around the perimeter (for example, metal foil, carbon steel walls, or the like). The glass 4 is connected from the bottom with the top of the pipe 3 by a hydraulic pipe 6 (a rubber pipe, a reinforced hose, or the like). The internal spaces 7, 8 and 9, respectively, of pipe 2 above the float 3, the hydraulic pipe 6 and the glass 4 to the upper float 5 are filled with a technical liquid (water, alcohol, antifreeze, antifreeze, etc.). Outside the pipe 2, to compensate for the level H of the technical fluid, a large float 10 is installed with the possibility of longitudinal movement and magnets (for example, in the form of plates, disks, or the like - are shown conditionally) on the inner surface 11 interacting with the soft magnetic material of the float 3 inside the pipe 2 ...

When used as technical fluids, hydrophilic fluids (alcohol, antifreeze, antifreeze, etc.) to exclude the enrichment of this fluid with moisture from the atmosphere with deterioration of properties (for example, an increase in the freezing point) or evaporation of an expensive fluid (for example, antifreeze, antifreeze, etc.) It is recommended to tightly fit the upper float 5 to the side walls of the glass 4. In this case, the upper float 4 is equipped with a bypass valve 12 to release gas and excess technical liquid from the inner space of cavity 9 under the upper float 4 during installation.

Structural elements, process connections and seals that do not affect the operability of the float level gauge are not shown in the drawing.

The float level gauge works as follows.

A pipe 2 with a float 3 inside and a large float 10 outside is inserted into a dry container 1 into the technological window (shown conditionally) from above, followed by sealing (flange, thread, etc.). To prevent the floats 3 and 10 from falling out, the pipe 1 is equipped from the bottom with internal 13 and external 14 stops. As magnets on the inner surface 11 of the large float 10, neodymium magnets, which are glued to the inner surface 11, have proven themselves well. The top of the pipe 1 is equipped with a hydraulic tube 6, with which it is connected to the bottom of the indicator glass 4. Flexible hydraulic tube 6 simplifies the tight connection of the pipe 1 and the nozzle 4, which can be placed in a convenient for observation, including a protected place, for example, in a vandal-proof cabinet (not shown). In this case, the use of a nozzle 4 of a larger cross-section D than the cross-sectional area d of pipe 2 allows the use of a more compact nozzle 4. For example, for an underground tank 12 m high when using a pipe with d = 10 mm and a length of 13 m (to reach the surface ) use a glass 4 with D = 32 mm and a height of 1.6 m, such a glass 4 is easily placed in a vandal-proof cabinet and is visually easily read through the viewing window by the operator. From above, process liquid is poured into the glass to fill it with the internal spaces 7, 8 and 9, respectively, pipe 2 above the float 3, hydraulic pipe 6 and glass 4 to the minimum mark (not shown) applied outside the viewing window of the glass 4. Into the glass 4 from above to the surface process liquid, an upper float 5 is installed, which is needed for better visualization of the technical liquid level and reduces the evaporation process of the technical liquid by several times. When using the level gauge in an unheated room or in the field, it is recommended to use a liquid with a low freezing point (antifreeze, antifreeze, alcohol, etc.) as a technical liquid in combination with a top float 5 with a check valve 12 tightly fitting to the side walls of the glass 4 When installing such an upper float 5, the air located on top of the process liquid, the excess of this liquid through the check valve 12 is vented from the inner space 9 of the glass 4 upwards. After installing the upper float 5 at the level of the minimum mark (marks, horizontal streaks of paint, etc.), the valve 12 closes and does not allow liquid and gas to penetrate into the space 9 of the glass. For greater protection against unauthorized overflows of liquid or gas, valve 12 can be additionally closed with a plug 15, and glass 4 is closed from above with a lid (shown conventionally). Then a known volume of liquid is poured into the container 1, pushing the float 3 and the large float 10 upward along with the growth of the liquid level 16. Since there is a column H of the process fluid above the float, its lifting force (Archimedes force) due to the small diameter d may not be enough for lifting, however, to level the column H of the process fluid there is a large float 10, which, rising with level 16, carries away using magnets on the inner surface 11 interacting with the soft magnetic material of the float 3 through the dielectric wall of the pipe 2, which does not shield the magnetic waves. In this case, the technical liquid is pushed out by the float 3 from the inner space 7 of the pipe 2 and through the inner space 8 of the hydraulic tube 6 into the inner space 9 of the glass 4, raising the level of the process fluid in it together with the upper float 5, the location of which is fixed by a mark on the viewing window. The container 1 is sequentially filled with the same volume of liquid, discretely raising the level 16 of the liquid in the container to the maximum. Together with the liquid level 16, the floats 3 and 10 rise, and under the action of the technical liquid, the upper float 5 also rises discretely, the position of which is fixed each time with a new mark on the viewing window, thereby calibrating the level readings in the glass 4 - the level indicator, the marks of which correspond to a certain level 16 of the liquid (and, as a consequence, the volume) in the container 1. Then the container 1 is put into operation. Periodically, the operator, at any time of the day or year, while walking around, monitors the level 16 of the liquid in the tank 1 by the location of the upper float 5 in the glass 4 relative to the marked marks. When the liquid is completely drained from the container 1, the position of the upper float 5 is verified relative to the minimum mark in the viewing window of the glass 4. If the upper float 5 is below the minimum level (during evaporation), then slightly add technical liquid, if it is higher (when moisture accumulates from the air) , then - pump out a little, after which the level gauge is again ready for accurate readings. This greatly simplifies the maintenance of the level gauge. Small overall dimensions of the glass 4 make its level readings by the upper float 5 easy to read by the operator. And the absence of mechanical and / or electrical connections between the floats 3, 10 and 5, which are in this case, respectively, in a closed container 1 and glass 4, ensures long-term and reliable operation.

The offered float level gauge is simple and reliable in manufacture, adjustment and operation, while it allows you to constantly monitor the liquid level in containers with a high height, including in underground containers.

Claims (2)

1. Float liquid level gauge, including a container, inserted vertically into the container, a pipe with a float inside, made with the possibility of longitudinal movement inside the pipe, a level indicator located above the container, characterized in that the pipe is made of a dielectric material, the float is made in the form of a piston with a soft magnetic material around the perimeter, the indicator is made in the form of a vertical glass with a viewing window having measuring strips and an upper float inside a larger cross-section than the cross-sectional area of the pipe, the bottom of the glass is communicated with the top of the pipe by a hydraulic pipe, and the inner spaces of the pipe are higher than the float, a hydraulic pipe and the cavities up to the upper float are filled with technical fluid, while outside the pipe to compensate for the level of the technical fluid, a large float is installed with the possibility of longitudinal movement and with magnets inside interacting with the soft magnetic material of the float inside the pipe. 2. The float liquid level gauge according to claim 1, characterized in that when the upper float is tightly attached to the walls of the glass, the upper float is equipped with a bypass valve to release gas and excess technical liquid from the inner space of the glass under the upper float.

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