RU5648U1 - DENSITY SENSOR FOR LIQUID MEDIA - Google Patents

Abstract

1. Density sensor for liquid media, containing a protective hollow body, inside of which is a movable float connected to a rod connected to a sensing head fixed in the housing and formed by a movable ferromagnetic core and inductive elements, one of the terminals of the windings of which are outputs of information signals, and elements for counteracting the buoyancy force of the float, characterized in that an additional rod is inserted into it, coaxial with the rod of the float and rigidly connected to the ferromagnetic heart com, the elements of counteracting the buoyancy force of the float are made in the form of elastic plates located on both sides of the inductive elements, and calibration weights and elements for adjusting the position of the ferromagnetic core relative to the inductive elements are installed at the ends of the additional rod, and a thrust element made with providing the possibility of transmitting force on the end of the lower calibration weight of the additional rod. 2. The sensor according to claim 1, characterized in that the protective hollow body is made in the form of a body of revolution, for example, of a cylindrical shape, through holes are made in the side walls and in the lower base of the body to provide for the flow of a liquid medium, and the safety valves are located inside and outside the float clamps made in the form of elastic plate elements of curved shape. 3. The sensor according to claim 1, characterized in that it contains a heat-sensitive element, the output of which is the output of an additional information signal of the density meter. The sensor according to claim 1,

Description

DENSITY SENSOR FOR LIQUID MEDIA

The utility model relates to measuring equipment, namely to float density meters, and can be used in the petrochemical, food and other industries for precision measurements of the density of liquid media taking into account their temperature.

A device for measuring the density of low-medium media 1 is known, comprising a flow-through body, a float equipped with a vertically mounted non-magnetic rod, a differential induction sensor, a block cable system, and a differential induction sensor coil is fixed at the upper end of the non-magnetic rod, and its core is suspended from the block cable system on sensor coil.

The disadvantages of this device are the design complexity and low reliability, since the presence of a cable system dramatically reduces operational performance.

Another known device 2 comprises a housing, inside of which a float is located, rigidly connected through a common rod with a sensitive electromagnetic head, elements of counteracting the buoyancy force of the float, made in the form of springs and membranes.

This design also has a drawback, because it lacks the technical means for calibrating the device to achieve high measurement accuracy.

The closest in technical essence to the proposed technical solution is a known density sensor 3 containing a float associated with an elastic counter element and a remote displacement transducer of the float connected to the registration unit, the densitometer made in the form of a measuring probe consisting of a protective housing with through holes for free access of the studied fluid, guide rods fixed inside the housing parallel to its axis, while the float is made in the form of a flat cylinder and is installed inside the housing with the possibility of free axial movement along the guide rods, and the bulk density of the float is selected 1.5 to 2 times higher than the average value of the bulk density of the investigated fluid.

One of the disadvantages of such a sensor is its limited scope, since the implementation of the float in the form of a continuous cylinder with a density 1.5–2 times higher than the density of the liquid under study limits the range of measurement of the density value.

Another disadvantage of the known technical solution is the lack of measurement accuracy that does not allow for effective calibration, which is caused by the design of the float, rigidly connected through a common rod with a ferromagnetic element.

The noted drawbacks are eliminated in the proposed density sensor for liquid media containing a protective hollow body, inside of which there is a movable float connected to a rod connected to a sensing head fixed in the body and formed by a movable ferromagnetic core and inductive elements, one of the terminals of the windings of which are outputs density meter information signals, and elements

counteracting the buoyancy force of the float by the fact that an additional rod is inserted into it, coaxial with the stem of the float and rigidly connected to the ferromagnetic core, the elements of counteracting the buoyancy force of the float are made in the form of elastic plates located on both sides of the inductive elements, and calibration ends are installed loads and elements for adjusting the position of the ferromagnetic core relative to inductive elements, with a stop element located in the upper part of the float rod ying to enable the transmission of impacts to the lower end of the calibration weight of additional stock.

In this case, the protective hollow body is made in the form of a body of revolution, for example, of a cylindrical shape, through holes are made in the side walls and in the lower base of the body to provide a flow of liquid medium, and inside the body there are safety locks made in the form of elastic plate elements above and below the float curved shape.

In addition, the device contains a heat-sensitive element, the output of which is the output of an additional information signal and a support node formed by an annular element, a horizontal plate and a fastening element, made, for example, in the form of a fixing screw located in a threaded hole made in the wall of the ring element, the inner diameter of which is greater than the outer diameter of the housing by the value of the technological gap, and the support node is placed on the outer side surface of the housing with the possibility of its movement in the direction of the longitudinal axis of the housing.

FIG. 1 shows a sectional view of the construction of a density sensor;

- the sensitive head of the density sensor is shown in section;

FIG. Figure 3 shows a view of the sensitive head along arrow A in the direction of the vertical axis of the sensor.

The density sensor (Fig. 1) contains a protective hollow housing 1, inside of which there is a movable float 2 with a known volume and mass, connected to the rod 3. Inside the housing 1 is mounted a sensitive head 4 formed by a movable ferromagnetic core 5 and inductive elements 6, one of conclusions of windings of which are outputs of information signals. The ferromagnetic core 5 is located inside the inductive elements 6. The sensitive head 4 is a symmetrical thermostable system.

The design also has an additional rod 7, coaxial with the rod of the float 3 and rigidly connected with the ferromagnetic core 5, the elements of counteraction push it force of the float, made in the form of elastic plates 8 located on both sides of the inductive elements 6 and fixed inside the housing 1.

At the ends of the additional rod 7, calibration weights 9 and adjustment elements 10 are installed, made, for example, in the form of nuts and designed to set the desired position of the ferromagnetic core 5 relative to the inductive elements 6.

In the upper part of the rod 3 of the float 2 there is a stop element 11, made with the possibility of transmitting force on the end of the lower calibration weight 9, mounted on an additional rod 7.

the base 12 of the housing 1 has through holes 13 for providing a flow of liquid medium, and inside the housing, safety clamps are arranged above and below the float, made in the form of curved elastic plate elements 14.15, as well as a retainer spring 16.

The design also contains a heat-sensitive element 17, the output of which is the output of an additional information signal. The heat-sensitive element 17 is located near the bottom zone of the housing. The presence of the temperature-sensitive element 17 is due to the need for subsequent temperature compensation of the measured values of the density of liquid media and bringing them to normal conditions.

The design also provides a support unit formed by an annular element 18, a horizontal plate 19 and a fastening element 20, made, for example, in the form of a fixing screw located in a threaded hole made in the wall of the annular element 18, the inner diameter of which is larger than the outer diameter of the housing by the amount of technological clearance. The support node is placed on the outer side surface of the housing 1 with the possibility of its movement in the direction of the longitudinal axis of the housing.

In the upper part of the case there are elements 21 of the electronic converter circuit and cable bundle 22 for connecting to an external unit for analysis and processing of information signals (not shown in the drawings).

In addition, in the drawings (Figs. 1-3), fasteners 23, 24 are shown for securing and fixing the corresponding structural members in the housing.

The design of the housing 1 provides protection for the movable system (hollow float 2 with the rod 3 and the sensitive head 4, consisting of elements 5 to 10) from external mechanical influences.

When storing or transporting the sensor, the float 2 is centered by the latches 14, 15 and the spring 16 along the axis of the housing 1, thereby eliminating the possibility of the beating of the float 2 against the walls of the housing 1 and impacts on the rod 7 of the sensitive head, which increases the operational reliability of the design.

Since during operation intensive external influences are possible (changes in temperature and humidity, shock loads, shaking, etc.), as well as due to the fact that certain elements can undergo aging, the ferromagnetic core 5 in the sensitive head 4 can change its initial position relative to inductive elements 6, which will lead to an increase in measurement error.

Therefore, after prolonged use, storage or transportation, the density meter should be calibrated before measuring the density of liquid media.

The presence of two separate rods 3 and 7, calibration weights 9, clamps 14 and 15, as well as the complete symmetry of the sensitive head 4 allow preliminary calibration of the density meter sensor without immersing it in the reference liquid.

The principle of calibration is based on monitoring the response of the sensitive head of the densitometer to the reference load, the calibration load 9.

Calibration is carried out at two points of the linear functional characteristics of the density meter (not shown).

For this, two control positions of the ferromagnetic core 5 relative to the inductive elements 6 are used with the float 2 fixed.

In the first position, the sensor is installed vertically, with the location of the sensitive head at the bottom.

In the second position, the density meter sensor is mounted vertically with the sensitive head located at the top.

In the first position, the value of the information signal level

density psti is determined only by the weight of the calibration weight 9,

tilted up and corresponds to a certain buoyant force acting on the float 2, lowered into a liquid medium with

density Psti: where Vn, Mn are the volume and mass of the float, respectively;

MK is the gross weight of the calibration weight suspended on the elastic plates 8.

In the second position, the value of the information signal level

density pst2 is determined only by the weight of the calibration weight S located at the bottom and corresponds to the moment of float 2 floating up in a liquid medium with density Pst2:

Thus, the values of information signals in two positions of the sensor psti and pst2 are determined by the constructive

sensor parameters: Vn, MP, MK, which are constants.

Vn X psti - MP 2 MK,

VnXpst2 - MP 0.

The mass MK of the calibration weight 9 is selected so that the points Psti and pst2 overlap about half

estimated range of measurements.

The constants set in this way underlie the calibration or correction of the linear functional characteristics of the sensor at two points.

The density sensor for liquid media works as follows.

The principle of operation of the density sensor is based on measuring the buoyancy force acting on the movable float 2, completely immersed in the investigated liquid medium.

When the sensor is immersed in liquid, the buoyancy force moves the float 2 in the vertical direction, while the thrust element 11 located at the end of the rod 3 is in contact with the lower calibration weight 9 and transfers force to the additional rod 7, which moves the ferromagnetic core 5 into the field of inductive elements 6 The movement occurs until the moment of balancing the buoyancy force and the elastic reaction forces created by the plates 8. Since the inductive elements are included in the measuring electrical circuit (for example In the form of a bridge - not shown) across the terminals of the inductive element formed electrical information signals, the value of

which corresponds to the density value Rzh.sr. test liquid

Wednesday.

At the same time, the thermosensitive element 17 forms an additional information signal about the temperature tx.cp. investigated liquid medium, which is further used in the block of analysis and processing of information signals (in the drawings

shown) to bring the obtained density values to normal conditions.

The reference assembly, consisting of elements 18.19 and 20, is designed to use the sensor together with a buffer tank (not shown in the drawings), into which a sample of the test fluid is taken. In this case, the horizontal support plate 19 is supported along the perimeter on the upper edge of the tank, the sensor is strictly vertical, and the required depth of immersion of the sensor in the buffer tank is provided by moving the sensor housing in the ring element 18 with subsequent fixation of the immersion depth using the fastening element 20.

In operation, the proposed density sensor for liquid media provides two methods of measurement:

-measurement of the density and temperature of the liquid with partial immersion of the sensor, in which only the part of the sensor in which the float 2 is located is immersed in the test liquid;

-measurement of the density and temperature of the liquid with complete immersion of the sensor, when the sampling process cannot ensure the accuracy and identity of the measurement conditions, or the sampling process is difficult, while the sensor readings do not depend on the depth of immersion. The immersion depth of the sensor can reach more than 18m.

The proposed density sensor is used to measure the density of liquid media in both laboratory and field conditions in the density measurement range of 650-1070 kg / m, in the temperature range from -50 ° C to + 50 ° C with a measurement accuracy of at least ± 0.1 %

The design of the sensor is small-sized, portable.

Sources of information:

1. Author's certificate. USSR No. 935744, M. Cl. 6 G01N 9/18, 1980

2. US patent No. 4400978, NKI 75-453, M. Cl. G01N 9/20, 1981

3. RF patent No. 2038577, M.cl.6 G01N 9/12, 1992 - prototype.

Claims (4)

1. Density sensor for liquid media, containing a protective hollow body, inside of which is a movable float connected to a rod connected to a sensing head fixed in the housing and formed by a movable ferromagnetic core and inductive elements, one of the terminals of the windings of which are outputs of information signals, and elements for counteracting the buoyancy force of the float, characterized in that an additional rod is inserted into it, coaxial with the rod of the float and rigidly connected to the ferromagnetic heart com, the elements of counteracting the buoyancy force of the float are made in the form of elastic plates located on both sides of the inductive elements, and calibration weights and elements for adjusting the position of the ferromagnetic core relative to the inductive elements are installed at the ends of the additional rod, and a thrust element made with providing the possibility of transmitting force on the end face of the lower calibration load of the additional rod.  2. The sensor according to claim 1, characterized in that the protective hollow body is made in the form of a body of revolution, for example, of a cylindrical shape, through holes in the side walls and in the lower base of the body are made to provide a flow of liquid medium, and inside the body above and below the float safety latches are located, made in the form of elastic plate elements of curved shape.  3. The sensor according to claim 1, characterized in that it contains a heat-sensitive element, the output of which is the output of an additional information signal of the density meter. 4. The sensor according to claim 1, characterized in that it contains a support node formed by an annular element, a horizontal plate and a fastening element, made, for example, in the form of a fixing screw located in a hole with a thread made in the wall of the annular element, the inner diameter which is larger than the outer diameter of the housing by the value of the technological gap, and the support node is placed on the outer side surface of the housing with the possibility of its movement in the direction of the longitudinal axis of the housing.