DE102022000719A1 - Device for determining and/or monitoring a parameter of a fluid - Google Patents

Abstract

The invention relates to a device (1) for determining and/or monitoring at least one parameter of a fluid. A tube (2) carrying the fluid has a constriction section (20) with a reduced cross-sectional area. At least one of two temperature sensors (31, 32) can be heated. A first temperature sensor (31) is in thermal interaction with fluid which flows through the constriction section (20). A second temperature sensor (32) is in thermal interaction with fluid flowing into the throat section (20) or flowing out of the throat section (20). An evaluation device determines and/or monitors the parameter based on a difference between measurement data from the temperature sensors (31, 32) and/or based on a heating power supplied to the at least one temperature sensor (31, 32).

Description

The present invention relates to a device for determining and/or monitoring at least one parameter of a fluid. The fluid is, for example, a liquid, a gas or a gas mixture.

It is known in the prior art to determine or monitor the flow of a flowing liquid calorimetrically. This exploits the fact that the liquid cools a heated temperature sensor. Two variants are available for the measurement: the temperature sensor is kept at a constant temperature and the necessary heating output is evaluated or the heating output is kept constant and the temperature readings are evaluated. An alternative measurement method consists in measuring the differential pressure in the fluid, which results from an orifice in the pipe that carries the fluid.

In order to control combustion processes in a burner device (e.g. as part of a heating system), it is necessary to measure the amount of combustible fuel (e.g. propane, butane, diesel or petrol) and the amount of combustion air supplied as precisely as possible record in order to obtain a residue-free and effective combustion. For example, the measurement or monitoring of the gas flow allows an increase in the accuracy of the gas metering, for which z. B. a proportional valve is used. As a result, the gas-air mixture to be burned can be controlled more precisely, which has a direct effect on the exhaust gas values.

The object on which the invention is based is to propose a device for determining or monitoring a parameter of a flowing fluid, which is particularly suitable for gases or gas mixtures.

The invention solves the problem with a device for determining and/or monitoring at least one parameter of a fluid, with a tube, two temperature sensors and an evaluation device, with the tube guiding the fluid, with the tube having a constriction section with a reduced cross-sectional area, with at least one of the two temperature sensors can be heated, with a first temperature sensor being in thermal interaction with fluid which flows through the constriction section, with a second temperature sensor being in thermal interaction with fluid which is flowing into the constriction section or which is flowing out of the constriction section, and with the evaluation device the parameter is determined and/or monitored based on a difference between measurement data from the temperature sensors and/or based on a heating power supplied to the at least one temperature sensor.

Two measurement principles are combined in the device according to the invention. A calorimetric measurement takes place in connection with a constriction. The constriction causes a higher flow rate of the fluid, which leads to an increased temperature. By using temperature sensors and not pressure sensors, there is a cost advantage.

One embodiment provides that the parameter is the flow rate of the fluid. Alternatively or additionally, the parameter is an amount of energy required for combustion of the fluid.

According to one configuration, the second temperature sensor is in thermal interaction with fluid which flows into the constriction section. In this embodiment, a temperature sensor interacts with the fluid that flows into the constriction section and is therefore at a higher temperature. The other temperature sensor interacts with the fluid in the constriction.

One configuration includes that the two temperature sensors can be heated.

The aforementioned embodiment is followed by an embodiment in which the evaluation device determines and/or monitors the parameter using data on heating power that is required to heat the two temperature sensors to specified temperature values. In this embodiment, therefore, both temperature sensors are heated. Based on the measured temperature values, the heating power is regulated in order to keep the temperature sensors at a specified temperature value.

According to one embodiment, the evaluation device determines and/or monitors the parameter based on a difference between the data on the heating power. In this embodiment, the difference between the heating powers that are required to keep the temperature sensors at constant temperature values is evaluated.

In an alternative embodiment, only one of the two temperature sensors is heated. The measured values of the non-heated temperature sensor are fed to the evaluation device.

One embodiment provides that the constriction portion is a portion with a having the smallest cross-sectional area within the constriction section, and that the first temperature sensor is in thermal interaction with fluid which flows through the section.

One configuration includes that the device only has the two temperature sensors. In particular, there are no pressure sensors.

One embodiment provides that two temperature sensors are fitted outside the tube. In this embodiment, the temperature is measured from the outside. Therefore, there are no sealing requirements in particular, as they arise with a sensor located in the pipe.

One configuration includes that thermal insulation is provided, and that the thermal insulation thermally insulates at least the fluid between the two temperature sensors. The insulation blocks thermal interaction with the environment, thereby improving measurement quality.

One embodiment provides that the fluid is a gas or a gas mixture.

One embodiment includes that a burner device is arranged downstream of the device. Based on the measurement or monitoring of the parameter, z. B. the flow rate, the burner is controlled.

• 1 eine schematische Darstellung der Vorrichtung und
• 2 eine schematische Darstellung zur Verwendung der Vorrichtung.

In particular, there are a number of possibilities for designing and developing the device according to the invention. For this purpose, reference is made to the following description of exemplary embodiments in connection with the drawing. Show it:

• 1 a schematic representation of the device and
• 2 a schematic representation of the use of the device.

The 1 shows schematically the structure of a device for determining and/or monitoring a parameter of a flowing fluid. The fluid is, for example, a combustible gas such as propane or butane or a gas mixture. The parameter is, for example, the flow, the mass flow or a measure of the amount of energy that the fluid has. Depending on the application or design, the device serves to determine or monitor the parameter. It is either determined a current value or it is determined whether the current value - z. B. beyond a tolerance value - differs from a predetermined target value, so whether it remains essentially constant or changes.

In the figure, the fluid flows through the pipe 2 from left to right as an example, which is indicated by the arrows. The tube 2 has a section 20 which is embodied symmetrically here and has a constriction, ie a reduced cross-sectional area. The partial area 21 with the smallest cross-sectional area is located in the middle of the constriction section 20. The fluid is accelerated into the constriction and the temperature increases as a result of the Joule-Thomson effect.

Two temperature sensors 31, 32 are arranged along the pipe 2, which are referred to purely by way of example as the first temperature sensor 31 and the second temperature sensor 32, respectively. The two temperature sensors 31, 32 are located outside of the tube 2, so that no sealing problems can arise. The pipe 2 is surrounded by thermal insulation 5, which is intended to prevent thermal interactions between the fluid in the pipe 2 and the environment. It is thus prevented in particular that the fluid and the temperature sensors 31, 32 are cooled down or possibly heated up by the ambient air.

The two temperature sensors 31, 32 are located at two different locations along the flow direction of the pipe 2: The first temperature sensor 31 is located in front of the constriction section 20. The second temperature sensor 32 is located in the constriction section 20 and here in particular in the partial area 21 with the smallest Cross sectional area. The two temperature sensors 31, 32 are thus arranged asymmetrically along the tube 2.

In the embodiment shown, each temperature sensor 31, 32 is assigned a heating device 310, 320 in order to heat the respective temperature sensor 31, 32. The arrangement shown allows different measurement modes to be used. The evaluation device 4 , which receives measured values from the temperature sensors 31 , 32 or operating data from the heating devices 310 , 320 , is present for the measurements and monitoring. Corresponding data connections are available for this, which are not shown here for the sake of clarity.

In one variant, both temperature sensors 31, 32 record the temperature of the fluid and the measured temperature values are processed by the evaluation device 4. The processing consists z. B. in a difference formation.

In a further variant, both temperature sensors 31, 32 are heated and it is based on their measured values are regulated to a respectively specified temperature value. A constant temperature of the temperature sensor 31, 32 is thus brought about. The required heating power allows the parameter to be measured or monitored.

The 2 shows a purely schematic application of the device 1. The device 1 is located between a gas source 99 and a burner device 100. The gas source 99 makes available, for example, a mixture of propane and butane. The burner device 100 is, for example, part of a heating system for heating room air, service water or heating fluid. Based on the determined values of the parameter or the determination of whether changes have occurred, the device 1 acts on the gas source 99 by z. B. the amount of gas z. B. is increased or decreased. Alternatively, the device 1 acts on a - not shown here - air conveying device, which conveys the combustion air required for the combustion to the burner device 100 in order to z. B. to compensate for changes in the flow rate of the gas mixture.

Reference List

1

contraption

2

Pipe

4

evaluation device

5

thermal insulation

20

constriction section

21

subarea

31

temperature sensor

32

temperature sensor

99

gas source

100

burner device

310

heating device

320

heating device

Claims (10)

Device (1) for determining and/or monitoring at least one parameter of a fluid, with a tube (2), two temperature sensors (31, 32) and an evaluation device (4), the tube (2) carrying the fluid, wherein the tube (2) has a constriction section (20) with a reduced cross-sectional area, wherein at least one of the two temperature sensors (31, 32) can be heated, wherein a first temperature sensor (31) is in thermal interaction with fluid which flows through the constriction section (20), wherein a second temperature sensor (32) is in thermal interaction with fluid flowing into the throat section (20) or flowing out of the throat section (20), and wherein the evaluation device (4) determines and/or monitors the parameter based on a difference between measurement data from the temperature sensors (31, 32) and/or based on a heating power supplied to the at least one temperature sensor (31, 32). Device (1) after claim 1 , wherein the second temperature sensor (32) is in thermal interaction with fluid flowing into the constriction section (20). Device (1) after claim 1 or 2 , wherein the two temperature sensors (31, 32) can be heated. Device (1) after claim 3 , wherein the evaluation device (4) determines and/or monitors the parameter on the basis of data on the heating power required to heat the two temperature sensors (31, 32) to predetermined temperature values. Device (1) after claim 4 , wherein the evaluation device (4) determines and/or monitors the parameter on the basis of a difference between the data on the heating power. Device (1) according to one of Claims 1 until 5 , wherein the constriction section (20) has a partial area (21) with a smallest cross-sectional area within the constriction section (20), and wherein the first temperature sensor (31) is in thermal interaction with fluid which flows through the partial section (21). Device (1) according to one of Claims 1 until 6 , wherein two temperature sensors (31, 32) outside the tube (2) are mounted. Device (1) according to one of Claims 1 until 7 , wherein thermal insulation (5) is provided, and wherein the thermal insulation (5) thermally insulates at least the fluid between the two temperature sensors (31, 32). Device (1) according to one of Claims 1 until 8th , where the fluid is a gas or a gas mixture. Device (1) according to one of Claims 1 until 9 , wherein the device (1) is arranged downstream of a burner device (100).

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