NO325399B1 - Acoustic multiphase painters - Google Patents

Abstract

Method and device (10) for improving ultrasonic measurements for a multiphase current. This is achieved by using various means to increase the rigidity of the device (10).

Description

Introduction

The present invention relates to a device for determining the characteristics of a multiphase flow in a pipe where the flow is led through a constriction in the device used to generate eddies that can be detected and interpreted using sensor device(s) that are acoustically connected to the multiphase flow.

More specifically, the invention describes construction details of the device which enable the device to provide improved measurement results compared to other devices for multiphase measurement.

Background for the invention

There are different measurement principles to determine the characteristics of the phases that make up a multiphase current.

The present invention uses known measurement principles based on ultrasound to characterize a multiphase current. The main focus is ways to improve the measurements.

US-5083452 describes a method for recording and interpreting multiphase current using acoustic sensors. The main focus is the measurement principle itself, and not ways to improve the measurement results.

NO-316342 describes a method that uses the same measuring principle, but with a main focus on influencing the flow by adjusting pressure and flow rate by regulating means to create stable and controlled measuring conditions.

There are also other examples in the prior art, where different focuses have been used to achieve improved measurement results. There are publications that range from design aspects to the narrowing itself to signal processing.

The present invention differs from prior art in that it focuses on dimensional aspects that affect the rigidity of the main body of the device where the measurement is to take place.

Much effort, research and testing have shown that the device according to the invention will give better and more stable measurement results.

Summary of the invention

An object of the present invention is to provide a method for determining the characteristics of a multiphase flow in a pipe, where the flow is directed through a constriction in the device used to generate vortices which can be detected and interpreted by means of one or more sensor devices which is acoustically coupled to the multiphase current.

The invention is characterized in that the main part of the wall section of the device is reinforced, in order to increase the rigidity of the device, either by making the wall section of the device thicker than connected pipes to transport the multiphase current upstream and downstream of the device, or by other stiffening means arranged externally in relation to the facility.

The invention also includes a system and method for using the device described above.

Other characteristic features and advantages of the present invention will become clear in light of the patent claims and the following detailed description of exemplary embodiments thereof.

Detailed description of the invention

The features and advantages of the present invention will be better understood with the help of the following description, the claims and associated drawings where: Figure 1 illustrates a cross-section of a detail of the device installed in a pipeline, and

figure 2 shows an example of further details of the device.

As mentioned, the device 10 is used to determine the characteristics of the multiphase flow in a pipeline, where the flow is directed through a constriction 20 in the device 10 used to generate eddies that can be detected and interpreted by means of sensor device(s) 30 which are acoustically connected to the polyphase current.

The main features of the invention are that the main part of the wall section 40 of the device 10 is reinforced, in order to increase the rigidity of the device 10, either by making the wall section 40 of the device 10 thicker than the connected pipelines 100 that transport the multiphase current upstream 110 and downstream 120 of the device 10, or by other stiffening means 50 arranged externally in relation to the device 10.

There are several aspects that will affect the measurement results when using the ultrasonic principle to determine the characteristics of a multiphase flow.

One aspect is construction details of the device 10 where the measurements take place. The shape of the constriction is important and will affect the generation of vortices which in turn generate signals that can be picked up by sensors, preferably ultrasonic transducers. In the last ten years, a lot of research has been done to optimize the shape of the constriction to improve the signal generation of the vortices.

Another aspect is the signal processing where the interpretation of the signals takes place, for example how the signals are processed to derive various characteristics of the current. This aspect is very complex and requires fast processing of the signals to perform continuous measurements and characterization of the properties.

The present invention focuses on the first mentioned aspect.

The applicant has put a lot of effort and research into various construction details of the device 10 in order to achieve better measurement results than existing measurement devices that use the ultrasonic measurement principle. This includes different narrowing designs and different designs for the device itself 10.

It was found that better measurement results can be achieved by creating a stable environment for the multiphase current where the measurements take place.

Experiments and real scale tests have shown that the wall thickness of the device 10 is an important parameter for obtaining accurate signals to be interpreted by the signal processing means. The wall thickness contributes to the rigidity of the device 10.

There are several ways to increase the rigidity of device 10.

A preferred way is to make a wall section 40 of the device 10 thicker than connected pipelines 100 that transport multiphase current upstream 110 and downstream 120 relative to the device 10.

Another way is to use external mounting means 50 by connecting another hollow body with a larger cross-section than the device 10, which makes the device 10 double-walled with an annular space 60 between the walls 40, 50. This body can be a tube or a hollow body with the same cross-sectional shape as that external to the device 10, that is, the device 10 does not necessarily have to have the same circular cross-section, but the upper and/or lower part of the device can, for example, be flattened in the region where the ultrasound sensors are located.

Another way of increasing the rigidity is to use bars between the flanges 55 which may or may not be part of the device 10 itself.

If the device 10 is produced with bilges, rods can be adapted and fixed between them. The number of rods used can affect the rigidity of the device 10.

If the device 10 is not equipped with flanges 55, rods will be able to provide connecting means to attach the device 10 between flanges on the pipelines 100.

As mentioned above, a preferred embodiment is to make the wall section 40 of the device 10 thicker than the connected pipelines 100. If the device 10 does not have flanges, it is further preferred to secure the device 10 to the pipelines 100 by inserting bolts through the holes in the flanges of the pipelines 100 and tighten them together using threads in the device 10.

A further preferred design of the device 10 is to make a device where the constriction 20 of the device 10 is made in one piece with the same material.

In another design, the constriction 20 and the device 10 are made up of two separate parts, and where the constriction 20 has a pipeline section 25 which extends broadly through the device, thereby contributing to the wall thickness of the device 10.

In order to determine the flow characteristics of a multiphase flow, including flow velocity, both the ultrasonic sensor 30 and pressure sensors 35, 38 must be used.

The pressure sensors 35, 38 must be placed upstream and downstream of the constriction 20.

The localization of the ultrasound sensor 30 is essential to be able to achieve an optimal acoustic coupling to the generated vortices.

In a preferred embodiment, one or more recesses 35 are made in the constriction section 20 of the device 10 to hold the ultrasonic sensor(s) 30. This will both help to protect the ultrasonic sensors 30, and improve the acoustic coupling to generated vortices. Ultrasonic sensor(s) can either be glued to the recess 35 or preferably fixed by means of screws.

In one embodiment, holes 45 are drilled in the surface 48 of the device 10 to attach the ultrasonic sensor 30 and/or measurement instrumentation.

The surface of the device 10 can also be protected with a cover layer to thereby make the device more robust against external wear and tear.

The present invention also includes a system for determining the characteristics of a multiphase flow in a pipeline comprising the device 10 described above, one or more ultrasonic sensors 30 connected to the multiphase flow, means 35, 38 for measuring the pressure differences upstream 110 and downstream 120 of the constriction 20, the signal receptions and processing means connected to the ultrasonic sensors 30, and signal interpreting means for deriving the characteristics of the multiphase flow.

The invention is further described by a method for determining the characteristics of the multiphase flow in a pipeline, where the flow is directed through a constriction 20 in the device 10 described above to generate eddies that can be detected and interpreted by means of ultrasonic sensor(s) 30 which are acoustically connected to the multiphase current, and where the method comprises interpreting the acoustic signals generated in the multiphase current by: - using one or more acoustic sensors to receive signals in the frequency range 0-2000kHz; - applying signal processing means to produce interpretable signals in the frequency range; - to apply multivariate data analysis to the data to derive the characteristics of the multiphase flow.

While the foregoing specification of the invention has been described with respect to a specific preferred embodiment, and details have been set forth for purposes of illustration, it will be apparent to one skilled in the art that the invention may be varied and that certain other details described herein may vary considerably. without deviating from the main principles of the invention.

Claims (10)

1. Device (10) used to determine the characteristics of a multiphase flow in a pipeline, where the flow is directed through a constriction (20) in the device (10), used to generate vortices that can be detected and interpreted using an ultrasonic sensor ( is) (30) which is acoustically connected to the multiphase flow, characterized in that the main part of the wall section (40) of the device (10) is reinforced, in order to be able to increase the rigidity of the device (10), either by making the wall thickness (40) of the device (10) thicker than the connected pipelines (100) which transport the multiphase current upstream (110) and downstream (120) in relation to the device (10), or by other stiffening means (50) arranged externally in relation to the device (10). 2. Device (10) according to claim 1, characterized in that the constriction (20) and the device (10) are made in one piece of the same material. 3. Device (10) according to claim 1, characterized in that the external stiffening means (50) are made by connecting a hollow part with a larger cross-section, which makes the device (10) double-walled with an annular space (60) between the walls (40, 50). 4. Device (10) according to claim 1, characterized in that the external stiffening means (50) are made by using rods between the flanges (55) which may or may not be part of the device (10). 5. Device (10) according to claim 1, characterized in that the constriction (20) and the device (10) are made from two separate parts, and where the constriction (20) has a pipeline section (25) which extends broadly through the device (10), thereby contributing to the wall thickness of the device (10). 6. Device (10) according to claims 1 and 2, characterized in that there are one or more recesses (35) in the narrowing section (20) of the device (10) to hold the ultrasonic sensor(s) (30), thereby improving the acoustic coupling of the sensors (30) to generate vortices. 7. Device (10) according to claims 1 and 2, characterized in that holes (45) are drilled in the surface (48) of the device (10) to attach ultrasonic sensors (30) and/or measuring instrumentation. 8. Device (10) according to claim 1, characterized in that the surface of the device is protected with a cover layer which makes the device more robust against external wear and tear. 9. System used to determine the characteristics of a multiphase flow in a pipeline, characterized in that the system comprises a device (10) according to claims 1-8, one or more ultrasonic sensors (30) connected to the multiphase flow, means (35, 38) for measuring the pressure difference upstream (110) and downstream (120) in relation to the constriction (20), the signal receiving means connected to the ultrasonic sensors (30) and signal interpreting means to derive the characteristics of the multiphase flow. 10. Method for determining the properties of multiphase flow in a pipeline, where the flow is led through a constriction (20) in the device (10) according to claims 1-8 in order to generate eddies that can be detected and interpreted using ultrasonic sensors ( 30) which is acoustically connected to the multiphase current, and where the method includes interpreting the acoustic signals generated in the multiphase current, characterized in that the method includes the steps: - using one or more acoustic sensors to receive signals in the frequency range 0-2000kHz; - applying signal processing means to produce interpretable signals in the frequency domain; - to apply multivariate data analysis to the data to derive the characteristics of the multiphase flow.