RU8802U1 - STABILIZATION CAMERA - Google Patents

Abstract

1. A stabilization chamber for a flowmeter with a converter and a controller, comprising a thermally insulated housing in which a sensor and a temperature transducer of the measured medium are connected to the controller, and a sensor and a temperature transducer in the chamber, characterized in that it contains sources of overpressure and heat, a pressure sensor and pressure and temperature regulators, the camera body is sealed, and the flow transducer is made in the form of a measuring standard or special constricting devices and pressure transducers and the pressure difference, the pressure and temperature sensors inside the chamber are connected via controllers with appropriate sources associated with the chamber, and the pressure transducers and the pressure difference are connected with kontrollerom.2. The camera according to claim 1, characterized in that the pressure and temperature sensors inside the camera are connected to the corresponding sources through the controller. The chamber according to claims 1 and 2, characterized in that the heating source is made in the form of an electric heater. The chamber according to claims 1 and 2, characterized in that the heating source is made in the form of a battery of solar or thermoelectric elements. The chamber according to claim 1, characterized in that the heating source is made in the form of a bimetallic element, part of which is located inside the chamber, and the other part is located along the pipeline of the measured medium, having a temperature above the temperature maintained inside the chamber.

Description

Stabilization chamber

The invention relates to the field of measuring equipment and can be used to measure the flow rate of liquids, vapors and gases by the method of variable differential pressure with narrowing devices, as well as to measure the differential pressure, excess, absolute and barometric pressure.

Known devices for measuring flow, comprising a flow sensor, a converter, performing the square root extraction from the pressure drop when measuring the flow by the variable pressure differential method and pressure and temperature sensors of the medium to be measured are included in the feedback circuit of the differential pressure flow meter through transformer type compensated transducers. In the steady state, the device is fully compensated for errors when measuring the temperature and pressure of the medium being measured in the entire measured range 11.

A disadvantage of the known device is the lack of accounting for additional measurement error associated with changes in pressure and ambient temperature.

Of the known devices, the closest is the stabilization chamber for the meter (flow meter) with a mechanical type converter and a controller, containing a sealed and thermally insulated housing in which the sensor and the ambient temperature transducer 21 are located.

The temperature sensor of the flowing gas and the sensor of the temperature of the environment generate corrective signals arriving at the controller, which measures the amount (flow rate) of gas used. Thus, this device compensates for additional errors from changes in ambient temperature.

The disadvantage of this device is the lack of accounting for additional errors from changes in environmental pressure and the use of compensation for additional errors from changes in temperature for mechanical type converters.

The problem to which the invention is directed, is to increase the accuracy of flow measurement by the method of variable differential pressure with constrictive devices, as well as the measurement of differential pressure, gauge, absolute and barometric pressure.

kp G01F15 / 04

The technical result is ensured by the fact that the chamber is stationary for a flowmeter with a converter and a controller, comprising a thermally insulated housing, in which a sensor and a temperature transducer of the measured medium are located, connected to the controller, and a sensor and a temperature transducer in the chamber contain a source of overpressure and heat and a pressure sensor, the housing the chamber is sealed, and the flow transducer is made in the form of pressure and differential pressure transducers, moreover, pressure and temperature sensors The circuitry inside the chamber is connected to corresponding sources connected to the chamber, and the pressure and differential pressure transducer are connected to the controller.

In the particular case, the technical result is ensured by the fact that the heating source is made in the form of an electric heater.

In another particular case, the technical result is ensured by the fact that the heating source is made in the form of a battery of solar or thermoelectric elements.

In the third particular case, the technical result is ensured by the fact that the heating is made in the form of a bimetallic element, part of which gas is placed inside the chamber, and the other part is located along the measured medium pipe, which has a temperature higher than the temperature maintained inside the chamber.

On (| 02G.1, a block diagram of the stabilization camera is shown.

Figure 2 shows a diagram of a stabilization chamber1ш51НЫ) - с я: © a temperature gauge made in the form of a bimetallic element. The stabilization chamber contains heat-insulated from the external environment and a sealed housing 1 (Fig. 1), in which a flow transducer is arranged, made in the form of a pressure transducer 2, temperature 3 and differential pressure 4, connected to the pipeline 5 of the medium to be measured through the respective pressure sensors and selected measuring standard or special narrowing device 6. These converters are connected to the controller 7. The stabilization chamber also contains a source of overpressure 8 and heat 9 (which can can be found both inside the chamber and outside) and the corresponding pressure sensors 10 and temperature 11 inside the chamber, which are connected to the corresponding sources through regulators 12 and 13.

controller 7 can execute. In this case, sensors 10 and 11 | They are connected to pressure and heat sources through the corresponding inputs and outputs of the controller.

The heating source 9 can be made in the form of an electric heater or in the form of batteries of solar or thermoelectric elements. In addition, the heating source can be made in the form of a bimetallic element 14 (Fig. 2), part of which 15 is located inside the chamber and combined with a shutter 16 that overlaps the throttle hole 17 and simultaneously regulates the pressure and temperature inside the chamber.

The stabilization camera works as follows.

The measured flow rate of the medium, the leakage through the pipeline 5, is carried out using a measuring diaphragm connected through a differential pressure transducer 4 to the controller 7. Compensation of temperature and pressure changes of the measured medium is carried out using the corresponding sensors connected through the transducers 2 and 3 to the controller 7.

When the pressure and ambient temperature change, they will not lead to the appearance of an additional measurement error, since the pressure and temperature in the chamber are stabilized by regulators 12 and 13 or by controller 7 if they perform the functions of these regulators. Moreover, the absolute values of the tabulating pressures and temperatures do not play a role; it is important that they remain constant during the operation of the devices.

In the case of a heat source 9 in the form of an electric heater, it is placed inside the chamber and connected to the electric power circuit of the controller 7.

In the case of the heat source 9 in the form of solar or thermoelectric batteries, the latter are placed on the lid of the camera and connected to the converter located inside the camera.

The implementation of the heat source 9 in the form of a bimetallic element is provided if it is possible to use the heat of the medium flowing through the pipeline. The indicated possibility arises with insignificant and slow changes in the temperature of the medium being measured. In this case, the shutter 16, switching the throttle hole 17, is part of the bimetallic element 15 located inside the chamber, and at the same time regulates the pressure inside the chamber.

The stabilization of pressure and temperature inside the chamber eliminates additional error when measuring pressure and ambient temperature within the limits determined by the accuracy of the corresponding sensors (10. and 1G) and the passport values of the sensitivity functions of the differential pressure, pressure and temperature transducers.

Sources of information

1. The author's certificate of the USSR L523293, class S01P 15/04, 1976

2. Great Britain Application J 204955, class A01P 15/04, 1988

Claims (5)

1. A stabilization chamber for a flowmeter with a converter and a controller, comprising a thermally insulated housing in which a sensor and a temperature transducer of the measured medium are connected to the controller, and a sensor and a temperature transducer in the chamber, characterized in that it contains sources of overpressure and heat, a pressure sensor and pressure and temperature regulators, the camera body is sealed, and the flow transducer is made in the form of a measuring standard or special constricting devices and pressure transducers and the pressure difference, the pressure and temperature sensors inside the chamber are connected via controllers with appropriate sources associated with the chamber, and the pressure transducers and the pressure difference are connected with the controller.  2. The chamber according to claim 1, characterized in that the pressure and temperature sensors inside the chamber are connected to respective sources through a controller.  3. The chamber according to claims 1 and 2, characterized in that the heating source is made in the form of an electric heater.  4. The camera according to claims 1 and 2, characterized in that the heating source is made in the form of a battery of solar or thermoelectric elements. 5. The chamber according to claim 1, characterized in that the heating source is made in the form of a bimetallic element, part of which is located inside the chamber, and the other part is located along the pipeline of the measured medium having a temperature above the temperature maintained inside the chamber.