SU347581A1 - MASS TURBINE FLOW METER SENSOR - Google Patents

Description

The invention relates to the field of instrumentation, in particular to turbine meters for measuring the mass flow of gas and liquid.

The known turbine flowmeters do not allow instruments of this type to measure the flow of gaseous substances, since the density of the gas varies not only from a change in temperature, but from the static pressure in the pipeline.

The proposed sensor, in order to increase sensitivity and speed, expanding the field of application, including providing measurement of mass flow of gases, is equipped with a pressure corrector made in the form of a gas-filled bellows, the movable bottom of which is kinematically connected with a restriction device, and stationary with a housing the sensor, and the thermocorrector is made in the form of a fluid-filled bellows, the movable bottom of which is kinematically connected with the impeller shaft, and the fixed one with the sensor body; In addition, the thermocorrector is provided with an additional bellows installed inside the main and connected at one end with its movable bottom, and the other with the sensor body, the pressure corrector is equipped with an additional bellows attached to the fixed bottom of the main cannon located inside the latter.

FIG. 1 shows schematically the proposed sensor with an axial impeller; in fig. 2 - the proposed sensor with a tangential impeller.

The sensor includes a housing; a straightening device 2 rigidly connected to the body; an impeller 3 rotating on bearings 4 mounted on shaft 5; Strainer 6, rigidly connected to the hull.

The shaft 5 is rigidly connected at one end to a movable bottom of the bellows 7, the internal cavity of which is filled with liquid.

The impeller 5 is located inside the restriction device 8, one of the ends of which

rigidly connected to the movable bottom of another bellows I filled with gas, or connected through the tube 10 with the atmosphere. The impeller speed is fixed by the converter //, the signal from which is transmitted to

secondary device.

Inside the bellows 7 a second bellows 12 can be installed, which will minimize the volume of fluid in the first bellows and thus increase the speed and sensitivity of the device. An additional snlfon 13 can also be installed inside the bellows 9, which adjusts the free space of the sylun 9 with a screw 14.

measures, gas) the impeller rotates inside the restriction device 8, in the zone corresponding to the defined value of the gas density: temperature and static pressure in the pipeline. The speed of the impeller in this case is proportional to the mass flow rate of this substance.

When changing (for example, increasing) the temperature of the measured substance (i.e., reducing its density) in the bellows 7, the liquid will tend to change its volume, as a result of which the moving bottom of this bellows will move. In connection with this, the impeller together with the axis will move towards the larger diameter of the restriction device 8 and the impeller rotational speed will decrease in proportion to the decrease in gas density as the temperature rises.

When the static pressure in the pipeline changes, for example, when it rises, the bellows 9 is salt, which will cause its moving bottom to move, which pulls the constriction device 8 behind. At the same time, the impeller will be located in the zone of smaller diameter of the constriction device and will rotate faster, which will correspond to higher mass flow rate due to higher gas density.

Selection of the appropriate type and volume of fluid in the bellows 7 provides small dimensions and the possibility of using the device for measuring the flow rate of virtually any gases at various pressures, their aggressive and other properties.

Installing an additional bellows 13 inside the bellows 9 allows the device to be easily and reliably tuned to different measuring ranges and types of measured gases.

Fie1S7 12

Similar to a thermocorrector and a pressure corrector can be provided with a mass flow sensor with a tangential impeller (see Fig. 2). The role of the restriction device here is performed by the iris diaphragm S associated with the pressure-sensitive element (bellows 9) through the rack 15.

Subject invention

Claims (3)

1. A mass turbine flowmeter sensor comprising a housing, an impeller, a constriction device, a thermocorrector, and a signal pickup unit, characterized in that, in order to expand the field of application, the sensor is equipped with a pressure corrector made in the form of a bellows filled with gas, the movable bottom of which is kinematically It is fitted with a narrowing device, and a fixed one with a sensor body, and the thermal corrector is made in a fluid-filled bellows. the movable bottom of which is kinematically connected with the impeller shaft, and the fixed bottom with the sensor housing. 2. The mass flow sensor according to claim 1, characterized in that, in order to increase sensitivity and speed, the thermocorrector is provided with an additional bellows installed inside the main and connected at one end to its movable bottom and the other to the sensor body. 3. The mass flow sensor according to claim 1, characterized in that, in order to adjust the instrument to different measurement ranges, the pressure corrector is provided with an additional bellows, cantilever attached to the fixed bottom of the main body and located inside the latter. Sul .l