RU2708714C1 - Method for determination of density of solid bodies and device for its implementation - Google Patents

Abstract

FIELD: measurement technology.

SUBSTANCE: method for determination of density of solid bodies and device for its implementation relate to the field of instrument making. Device for implementation of proposed method includes transparent cylindrical vertical vessel with graduated in volume units and arranged in it is liquid, bedplate, wherein vessel is divided by rigid horizontal, freely permeable for liquid partition to two cavities of equal volume, lower of which is filled with liquid in volume equal to half of capacity of vessel, and is equipped with two rigidly fixed with vessel, outer horizontal cylindrical pins, axis of which passes through the center of gravity of the vessel, as well as geometrically identical tight plugs with retainers of the vertical position of the vessel, wherein pins are arranged with possibility of rotation on vertical stands of bedplate, equipped with control level of its horizontal position and height-adjustable feet. Fluid may be colored or opaque. Bedplate can be mounted on scales.

EFFECT: determining density of solid bodies of regular and irregular shape, simplifying calculations and measuring operations, enabling measurement of density of samples having both negative and positive buoyancy in a liquid.

4 cl, 3 dwg

Description

The method for determining the density of solids and a device for its implementation relate to the field of instrumentation, metrology and can be used in the metallurgical, mining, woodworking, food industries for the organization of a metering system, storage, dispensing of substances, where an accurate measurement of density is essential.

The density of a substance is the value equal to the ratio of body mass m and its volume V:

Density measurement comes down to measuring body mass and volume. Mass refers to the number of physical quantities whose values can be determined by direct measurements using weighing. On the contrary, body volume is determined by indirect measurements. In the case of samples of the correct geometric shape, the volume is found from the measurement of linear dimensions. When determining the density of the substance of samples of irregular shape (or samples of substance) it is impossible to calculate the volume of the sample through linear dimensions.

Known methods for measuring the density of solids of irregular shape, based on the principle of hydrostatic weighing, areometric methods, mechanical methods. (Kivilis S.S. Density meters. - M.: Energy, 1980).

The disadvantages of the known methods are: a significant number of necessary sequential operations, the need to attract highly qualified staff, the difficulty of implementation in the field.

Known closest to the proposed pycnometric method for determining density. The pycnometric method for measuring density is as follows.

A pycnometer (a glass vessel, the volume of which is known with great accuracy), is filled with distilled water (up to the mark) and weighed. The mass of the pycnometer with water M ₀ is

where ρ ₀ is the density of water;

V _p and m _p - volume and mass of the vessel. Then weighed the test sample. Its mass m is equal to

where ρ is the desired density of the sample;

V is the volume of the sample.

Then the weighed sample is immersed in a pycnometer with water.

Then the excess water is removed so that its level again coincides with the mark on the pycnometer vessel.

Then determine the mass M of the pycnometer with water and a sample

Then, subtracting (4) from (2) and adding (3), the mass of displaced water is determined and, having determined the volume V from this, we obtain the expression for the desired density

(https://works.doklad.ru/view/V3AHngEk73s.html) - prototype.

The disadvantages of the prototype are: the need to perform a significant number of operations and calculations; the complexity of the method outside the laboratory; the impossibility of using the method to determine the density of samples having a density lower than the density of distilled water (or other liquid poured into the pycnometer vessel), since a sample having positive buoyancy displaces a smaller liquid volume when immersed than its own volume.

The technical result of the proposed method is the creation of a new method for determining the density of solids of regular and irregular shape, which reduces the number of necessary operations, simplifies calculations, provides the ability to measure the density of samples with both negative and positive buoyancy in a liquid poured into a vessel of a measuring device, and also simplification of measuring operations with ensuring their performance not only in laboratory but also in the field by personnel who do not have special training.

The technical result is achieved in that a method for determining the density of solids, including determining the mass of a sample or sample of a substance by weighing, filling a vessel with liquid, placing a sample or sample of a substance in a vessel, determining the volume of a sample or sample of a substance by measuring the volume of liquid displaced by a sample or sample of a substance, vessel divided by a horizontal septum freely permeable to liquid into two cavities of equal volume, fill the vessel with liquid in the volume of half its capacity, place the sample and whether the sample of the substance in the dry upper cavity of the vessel, hermetically close the neck of the vessel, rotate the vessel 180 ° in a vertical plane and determine the volume of liquid displaced by the sample or the sample of the substance in the upper cavity of the vessel after rotation by fixing the liquid level in this cavity according to the graduated scale.

The invention has the following differences from the prototype:

- the vessel is separated by a horizontal septum freely permeable to liquid into two cavities of equal volume;

- fill the vessel with liquid in the volume of half its capacity;

- place a sample or sample of the substance in the dry upper cavity of the vessel;

- tightly close the neck of the vessel;

- turn the vessel 180 ° in a vertical plane;

- determine the volume of liquid displaced by the sample or a sample of the substance in the upper cavity of the vessel after rotation by fixing the liquid level in this cavity according to the indications of a graduated scale.

These differences minimize the number of measurement operations and simplify calculations, since the desired volume V of a sample or sample of substance is obtained by turning the vessel with a tightly closed neck 180 °, by visually recording the readings on the scale of the device that determines the volume of liquid V displaced by the sample or sample of the substance . This allows you to determine the density ρ of a sample or sample of a substance of known mass m according to one known formula

ρ = m / V.

It does not matter what buoyancy, positive or negative, a sample or a sample of a substance in a liquid in a vessel has.

The implementation of the method is carried out without additional measuring tools, the method is simple to implement, does not require laboratory conditions and the participation of qualified specialists.

A comparative analysis of the claimed invention and the prototype reveals the distinctive features of the proposed method in comparison with the closest analogue, which allows us to conclude that the proposed technical solution meets the criterion of "novelty."

In the patent information fund that we reviewed, no technical solutions with the indicated differences were found, as well as technical solutions with the specified set of distinctive features.

The proposed technical solution is applicable and will be used in the metallurgical, mining, woodworking, food industries in the organization of a metering system, storage, dispensing of substances, where the exact measurement of density is essential.

Known devices for determining the density of a sample or sample of a substance. These are hydrostatic and areometric scales, rocker, spring and electromagnetic densitometers, with which they measure the volume of liquid displaced by a solid sample or a sample of a substance, and therefore the volume of a sample or sample of a substance immersed in a liquid. Knowing the mass of the sample or sample of the substance and their volumes, analytically determine the desired density of the test substance. (Kivilis S.S. Density meters. - M.: Energy, 1980).

A common disadvantage of the known devices is the need for a significant number of measurements, the implementation of which in practice is possible only in laboratory conditions, as well as the difficulty of determining the volume of samples or samples of substances whose density is lower than the density used in the device fluid. Such samples are impossible or difficult to completely immerse in the liquid used only due to their gravity.

The closest devices for the implementation of the proposed method are liquid meters, usually made in the form of a transparent cylindrical container, graduated in units of volume or length, with a liquid in which, after weighing on the balance with the necessary accuracy, place the studied solid samples or a sample of the substance. The volume of the test sample or sample of the substance is found by the volume of the displaced fluid inside the vessel. (Kivilis S.S. Density meters. - M.: Energy, 1980. S. 155-156) - prototype.

The disadvantage of the prototype is the difficulty of determining the volume of a sample or sample of a substance with positive buoyancy. Their full immersion in liquid is possible only with the use of a pusher, or with the help of an additional load attached to the samples. This greatly complicates the operation of the device and reduces the accuracy of determining the magnitude of the volume of liquid displaced by the sample, and even more so the breakdown of the substance. In the latter case, a sample of a substance with positive buoyancy must be placed in a net package. Studies of samples with positive buoyancy can only be carried out in laboratory conditions with the assistance of trained personnel.

The result of the claimed technical solution for the implementation of the proposed method is the creation of a new universal device that provides the ability to measure volumes of solids or samples of substances with both negative and positive buoyancy in the liquid used without the use of additional devices designed to ensure their complete immersion in the liquid, as well as simplification of the process of making the necessary measurements and achieving the possibility of working in the field (outside the laboratory) conditions with the involvement of non-qualified personnel.

The technical result is achieved by the fact that the device for implementing the proposed method includes a transparent cylindrical vertical vessel with a vertical graduation in units of volume and the liquid placed in it, a bed, while the vessel is divided by a rigid horizontal wall freely permeable to liquid into two cavities of equal volume, the lower of which filled with liquid in a volume equal to half the capacity of the vessel, and is equipped with two external horizontal cylindrical fingers rigidly attached to the vessel, the axis of which passes through the center of gravity of the vessel, as well as geometrically identical sealed plugs with clamps for the vertical position of the vessel, while the fingers are rotatably mounted on the vertical stands of the bed, equipped with a level of control of its horizontal position and height-adjustable legs. The fluid placed in the vessel may be tinted or opaque. The bed can be mounted on the scales.

The invention has the following differences from the prototype:

- the vessel is divided by a rigid horizontal partition, which is freely permeable to liquid, into two cavities of equal volume;

- the lower cavity of the vessel is filled with liquid in a volume equal to half the capacity of the vessel;

- the vessel is equipped with two external horizontal cylindrical fingers rigidly attached to the vessel, the axis of which passes through the center of gravity of the vessel;

- the vessel is equipped with geometrically identical sealed plugs with clamps for the vertical position of the vessel;

- the fingers are rotatably placed on the uprights of the bed, equipped with a level of control of its horizontal position and legs adjustable in height;

- the liquid placed in the vessel may be tinted or opaque;

- The bed can be mounted on the scales.

A comparative analysis of the claimed invention and the prototype reveals the presence of distinctive features of the claimed device in comparison with the closest analogue, which allows us to conclude that the proposed technical solution meets the criterion of "novelty."

In the patent information fund that we reviewed, no technical solutions with the indicated differences were found, as well as technical solutions with the specified set of distinctive features.

The proposed technical solution is applicable and will be used in the metallurgical, mining, woodworking, food industries in the organization of a metering system, storage, dispensing of substances, where the exact measurement of density is essential.

The design of the device is illustrated by the following materials:

FIG. 1 is a diagram of a device before conducting research;

FIG. 2 - the same during the period of research with a sample with negative buoyancy;

FIG. 3 - the same during the period of research with a sample with positive buoyancy;

A device for implementing the method includes a transparent cylindrical vertical vessel 1 with a liquid 2 and a test sample 3, divided into two equal in volume cavities by a rigid partition 4 with a hole 5. The vessel 1 is equipped with two sealed geometrically identical plugs 6 with clamps 7, a vertical ruler 8 and rigidly fastened to the vessel 1 by two outer cylindrical fingers 9, the axis of which passes through the center of gravity of the vessel 1. The fingers 9 lie on the rotation supports 10 of the vertical posts 11 of the frame 12, equipped with a horizontal level 13 and height-adjustable legs 14.

A device for implementing the method for determining the density of solids works as follows.

By installing the device on a horizontal surface, achieve a horizontal position in the space of its frame 12 using a standard horizontal level 13 and height-adjustable legs 14.

Liquid 2 is poured into a vessel 1, vertically fixed by a lower retainer 7, with, for example, a threaded upper sealed stopper 6 removed, in an amount equal to half the capacity of the vessel 1. A test sample 3 (or a sample of the substance) is placed on a rigid partition 4 and the vessel 1 is sealed with a stopper 6, FIG. 1.

Then turn the vessel 1 in a vertical plane through 180 ° on the cylindrical fingers 9 located on the bearings 10 of the vertical uprights 11 and fix the vertical position of the vessel 1 using the latch 7 turned upside down tube 6.

Upon completion of the rotation of the vessel 1, the liquid 2 through the hole 5 in the rigid partition 4 flows into that cavity of the vessel 1, where the test sample (or sample of substance) is placed, FIG. 2.

In this position, FIG. 2, in the upper cavity of the vessel 1 is the volume of liquid displaced by the sample 3 (or breakdown of the substance) from the opposite cavity of the vessel, and, obviously, equal to the volume of the sample (or sample of the substance). The value of this volume is determined visually by the reading of the scale of the vertical ruler 8, graduated in units of volume.

The density of the substance ρ of a pre-weighed sample 3 with mass m is determined by the formula ρ = m / V, where V is the reading of the scale of line 8.

At the end of the research process of the sample (or sample of substance), the device, turning the vessel 1 through 180 °, is returned to its original position, remove the plug 7, remove the sample and proceed to the next study.

In FIG. 1, 2 shows the sequence of operation of the device for determining the density of the substance of sample 3 with negative buoyancy. Therefore, in FIG. 2, the sample lies at the bottom of the lower cavity of the vessel 1.

In the case of determining the density of samples with positive buoyancy, sample 3 in FIG. 3 will float in the fluid volume of the lower cavity of the vessel 1, or rather, it will be pressed by the buoyancy force to the lower plane of the rigid partition 4.

In the study of samples of matter, a rigid partition 4 is made with one or more holes to ensure free flow of liquid 2 from one cavity of the vessel 1 into its opposite cavity. The diameter of the holes in the partition 4 should be less than the smallest of the particles that make up the sample of the substance.

The condition for the axis of the fingers 9 to pass through the center of gravity of the vessel 1 must be satisfied to ensure the reliable operation of the latches 7. The lower airtight plug 6, FIG. 1 is removable for periodic cleaning of the vessel 1.

The fluid used in the device may be opaque or tinted in order to more accurately visually fix its level in relation to the risks of graduation of the ruler 8. The fluid must be replaced if it is contaminated with particles that have separated from the sample or sample of the substance during the study period.

The frame 12 of the device can be installed on the scales, which will allow you to measure the mass of the samples or samples of the substance simultaneously with the determination of their volume.

The determination of the capacity of the vessel 1 with the installed partition 4 for each individual device of the proposed design is carried out before the start of its first operation using the measured capacity. The dimensions of the device depend on the size of the test sample (or sample of the substance).

The device is simple to manufacture and convenient to operate, provides the ability to study samples or samples of substances in both laboratory and field conditions.

Claims (4)

1. The method of determining the density of solids, including determining the mass of a sample or sample of a substance, filling a vessel with liquid, placing a sample or sample of a substance in a vessel, determining the volume of a sample or sample of a substance by measuring the volume of liquid displaced by a sample or sample of a substance, characterized in that the vessel they are divided freely by a liquid-permeable horizontal partition into two cavities of equal volume, a vessel is filled with liquid in the volume of half its capacity, a sample or sample of the substance is placed in a dry top th cavity of the vessel, hermetically close the neck of the vessel, turn the vessel 180 ° in a vertical plane and determine the volume of liquid displaced by the sample or sample of the substance in the upper cavity of the vessel after rotation by fixing the liquid level in this cavity according to the readings of a graduated scale. 2. A device for determining the density of solids, including a transparent cylindrical vertical vessel with a vertical graduation in units of volume and a liquid placed in it, a bed, characterized in that the vessel is divided by a rigid horizontal, freely permeable to liquid partition into two cavities of equal volume, the lower of which is filled with liquid in a volume equal to half the capacity of the vessel, and is equipped with two cylindrical fingers rigidly attached to the vessel, the axis of which passes through the center of gravity of the vessel, and e geometrically identical plugs with clamps for the vertical position of the vessel, while the fingers are rotatably mounted on the vertical racks of the bed, equipped with a level of control of its horizontal position and height-adjustable legs. 3. The device according to p. 2, characterized in that the liquid in its vessel may be tinted or opaque. 4. The device according to p. 2, characterized in that the bed can be mounted on the scales.

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