RU178306U1 - LASER LIQUID LEVEL METER - Google Patents

Abstract

The claimed utility model relates to special devices that are used to determine the level of liquids. The device is a structure consisting of a tubular rod, with the lower end of the rod immersed in the fluid until it stops at the bottom of the tank, the upper end of the rod has a sliding flange connection with stuffing box seals, which is attached to the corresponding technological hole of the tank. It also consists of an electronic unit housing with a level measuring sensor located inside it on the basis of a laser range finder (hereinafter referred to as DIU) and a signal conversion unit (hereinafter referred to as BPS) mounted on the upper end of the rod, on the outside of the tank mounting flange. As the reflecting surface for the DIU operation, the upper side of a flat disk float (33 mm in diameter and 5 mm thick) freely floating in the liquid, located in the internal cavity of the UD rod, which is a thin-walled stainless steel pipe with an internal diameter of 37 mm, is used. The technical result of the claimed utility model is to simplify the design and improve the accuracy of the measurement. 1 ill.

Description

Level gauges are special devices that are used to determine the level of liquids, powders and others, materials or raw materials in certain tanks in which they are stored, or in a working environment.

Such devices in their development strive to ensure maximum ease of use and accuracy of measurements.

The utility model "Laser Liquid Level Gauge" refers to devices for detecting the level of liquids and may be industrially applicable.

A utility model is a structure consisting of three main parts:

1) a tubular rod (the lower end of the rod is immersed in the liquid until it stops in the bottom of the tank, the upper end of the rod has a sliding flange connection with stuffing box seals, which is attached to the corresponding technological hole of the tank);

2) the body of the electronic unit with a level measuring sensor located inside it on the basis of a laser rangefinder (1 in the drawing) (hereinafter - DIU) and a signal conversion unit (2 in the drawing) (hereinafter - BPS) installed on the upper end of the rod, from the outside tank mounting flange (3 in the drawing). To maintain the tightness of the tank, the laser beam (4 in the drawing) must pass into the tank through an optical media separator, which is a metal tube with a hermetically integrated quartz glass installed in the upper part of the rod, in front of the body of the electronic unit.

3) the upper side of a flat disk float (5 in the drawing) (33 mm in diameter and 5 mm thick) located in the inner cavity of the UD rod (6 in the drawing), which is a thin-walled pipe, is used as the reflecting surface for the DIU operation stainless steel with an inner diameter of 37 mm. The float, which serves as a diffuse reflector of laser radiation, is made of a polymer of low intrinsic density, which ensures the buoyancy of the float in any measured liquids and is not wetted by them, and has a diffuse reflectance of at least 90% in accordance with GOST 8.557, which ensures a wide range of measurements of the liquid level reflected radiation flux above the sensitivity threshold of the photodetector of the laser sensor. The float has a sufficient clearance (3-4 mm in diameter) relative to the inner diameter of the rod pipe, which provides free movement of the float inside the pipe, eliminating friction against its walls. The rod pipe is sealed from below by a cover having a small hole (5 mm in diameter) for the passage of fluid into the internal cavity. The second same hole for air outlet when the fluid moves inside the pipe is located in the pipe wall in its upper part, in front of the tube of the optical splitter. The inner cavity of the pipe is connected with the inner cavity of the reservoir as communicating vessels. When the reservoir is rapidly filled with liquid, the waves and level fluctuations that occur do not affect the float due to the throttling of the filling of the inner cavity of the pipe through the lower hole, and the level is also damped by the liquid column.

DIU is a laser range finder that measures the height of the liquid level in the inner cavity of the rod.

The prior art various technical solutions related to devices for determining the level of liquids

The well-known "Float liquid level gauge" containing a float made so that it is placed on the surface of the liquid and provided with vertical guides, as well as a vertically positioned ruler with a scale, characterized in that the collective and diffusing lenses are located on the float, the optical axes of which intersect and are located in the horizontal plane so that the ruler’s scale is located in the field of view of the lenses, while the output end of the first flexible fiber is connected to the scattering lens, to the collecting lens - the end face of the second flexible fiber, and the input end of the first fiber and the output end of the second fiber are connected respectively to the light source and video converter of a removable television camera connected to a television receiver (see patent for the invention No. 3228 of 05/12/1995).

The disadvantage of the considered analogue is its float design with mechanical work that excludes laser operation, as well as the need to use a video converter of a removable television camera.

Also known as a "stand-alone discrete electrochemical liquid level gauge", comprising a housing mounted vertically, liquid level alarm sensors arranged vertically in a row, characterized in that the housing is made of electrical insulation material, inside which there is an air chamber and a vertical channel for the working fluid, separated by a wall from the air chamber, gas-diffusion air cathodes were taken as alarm sensors mounted tightly in the wall separating the air chamber and the vertical channel, the housing is hermetically connected to the container for the working fluid located under it, into which a membrane of elastic material is mounted (see utility model patent No. 84113 of February 19, 2009).

The disadvantage of this analogue is the need to use gas diffusion air cathodes, which are mounted tightly in the wall separating the air chamber and the vertical channel.

As the closest analogue of the utility model, the technical solution was chosen - “Liquid level gauge”, containing a cylindrical body, the inner cavity of which is connected to the tank cavity through the channels made in its lower part, the float placed with the possibility of vertical movement in the cylindrical body, the upper surface of which is covered with a mirror layer , the radiation source and receiver associated with the internal cavity of the cylindrical body through an optical contactor, made in the form of a disk with windows, on the outside the surface of which is coated with a reflective layer, an angular reflector and a control unit of a sequence of operations electrically connected with a radiation source and receiver and with an optical contact rotation drive, characterized in that it further comprises a stepped hollow cylindrical nozzle having a support base for tight mounting on a rigid vertical neck the tank, the second corner reflector and the glass partition separating the steps of the hollow cylindrical nozzle, in the lower the diameter of which is fixed with the possibility of limited vertical movement of the pipe with a coaxially mounted cylindrical body of the level gauge, the annular gap between which at the lower ends is hermetically closed from contact with the measured liquid by a horizontal partition with a reflective layer on the inner surface, and in the step of a larger diameter of the hollow cylindrical nozzle an optical contactor is placed, in one of the windows of which the first and second corner reflectors are installed in the opposite direction, while the source and reception IR radiation and optical contactor drive are mounted on the support base of the hollow stepped cylindrical nozzle (see. utility model patent No. 56999 dated May 26, 2006).

The disadvantage of the considered closest analogue is the limited possibilities of its application in view of the need for additional electrical communication and an optical contactor. In addition, the design of the analogue leads to a significant increase in the cost of the final product due to the large number of constituent elements of the product.

The creation of the proposed utility model is based on the task of manufacturing such a device that will provide a level measurement method that is distinguished by great temporal and temperature stability due to the stability of the wavelength of the laser LED used in the phase laser range finder as an emitter.

The main technical result of the claimed utility model is to simplify the design and improve the accuracy of measurement, including due to the stability of the wavelength of the laser LED used in the phase laser rangefinder as an emitter.

The tasks are solved, and the technical results are achieved by the fact that since the laser range finder measures the distance from itself and at a distance, the following calculations are included in the level measurement software.

Before installation on the tank, in the vertical position of the level gauge, the installation constant is measured:

where N _l0 - laser rangefinder readings in the initial position, mm;

N _p - the thickness of the float, mm;

N _to - the thickness of the rod cover, mm

The obtained value of the constant H ₀ is entered into the level transmitter software.

Next, the level gauge is installed on the tank, with a bar all the way to the bottom, strictly upright.

With each further measurement, the level is calculated by the formula:

where h is the value of the calculated liquid level, mm;

N _l - laser rangefinder readings at each measurement of the liquid level, mm;

H ₀ - installation constant, mm.

Finally, the transmitter is calibrated adjustment in a small range docking constants H ₀ due to some pritaplivaniya float in the fluid at one point in comparison with readings exemplary level measuring means.

The measurement accuracy depends on the resolution of a laser rangefinder, the accuracy of measurement of thickness and the float rod cap, the precision of computing the constants N and ₀ can reach ± 0.3 ... 0.5 mm.

The essence of the claimed technical solution is illustrated by the scheme of the finished product.

In FIG. 1 shows a diagram of the finished product.

Today, the proposed utility model, due to its novelty and any forms (options) of manufacturing (including the appearance of the product), may become the most effective and popular tool for laser level measurement of liquids

The proposed technical solution will expand the arsenal of available level gauges.

Claims (1)

A laser liquid level gauge, consisting of a tubular rod, an electronic unit housing, characterized in that the unit has a level measuring sensor based on a laser rangefinder, a signal conversion unit is installed on the upper end of the rod having a sliding flange connection with stuffing box seals, with the outer side of the mounting flange to the tank, and the upper side of the flat disk float freely floating in the liquid, located o in the inner cavity of the rod, which is a thin-walled stainless steel pipe made of a polymer of low intrinsic density, which ensures the buoyancy of the float in any measured liquids and is not wetted by them, while the laser beam must pass into the tank through an optical media separator, which is a metal tube with hermetically integrated quartz glass.

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