NO20093598A1 - Optical particle templates - Google Patents

Abstract

BACKGROUND OF THE INVENTION The present invention relates to a measurement unit for monitoring particles in a fluid stream, the unit comprising a sleeve which is adapted to be mounted in a pipe wall with a first end in contact with the fluid stream, the first end of which includes a window, wherein the sleeve comprises a a camera placed inside the sleeve, where the camera is aimed at a selected volume through the window and which is connected to an electronic sampling and analysis device for analyzing the sampling images for detecting particles in the above volume. The unit of measurement also includes at least one light source located inside the sleeve and which is adapted to illuminate, illuminate, the selected volume.

Description

DEVICE FOR MONITORING PARTICLES

The present invention relates to a measuring unit for monitoring particles in a fluid flow, in which the particles can be made of solid or liquid materials dispersed in a fluid flow.

In fluid flows, the existence of particles can give rise to problems relating to wear and damage to equipment present in the flow, such as pumps, and also the presence of a certain amount of liquid droplets in the flow can be an indication that e.g. an upstream separator or a sand filter needs adjustment or improvement. Environmental concerns also place restrictions on the content of such things as injection water that is pumped into underwater oil wells where the injection water is separated from oil and there is a need for detection and classification of oil droplets in the stream. Another application for particle monitoring is in gas compressors where the longevity of the compressor can be reduced if a large number of solid particles are present in the stream, while small liquid droplets of the same size do not have the same effect.

A known way of measuring the presence of particles in a stream has been the use of passive acoustic sensors, but they do not provide information about the shape or size of the particles. Nor can they distinguish between solids and liquid particles to any great extent. A better system is discussed in US7162057 where a camera is used to obtain images of the particles in the flow and analyze these images to be able to investigate the nature of the particles. For some types of fluids and particles, the solution in US7162057 has the disadvantage of low contrast. It is therefore a purpose of the present invention to monitor the particle content in a fluid stream by taking pictures of the stream content where the pictures have an improved contrast. This is achieved by using the measuring unit mentioned above and is preferably based on the methods discussed in US7162057, although similar methods can also be used, and characterized as stated in the independent claim.

The present invention therefore provides a solution where the imaged volume of the fluid flow is illuminated at an angle from the same side of the tube as the camera, which preferably provides so-called dark field images of the flow volume. At least two light sources are preferably placed symmetrically around the camera. A measuring unit is therefore obtained which is capable of measuring small oil droplets and solid particle concentrations separately.

In addition to the improved contrast, the device of the present invention provides an improvement when used in pipes or pipelines in underwater or borehole situations as the device requires only one hole in the pipe.

The present invention will be described below with reference to the accompanying drawings which illustrate the present invention as examples.

Figure 1 schematically illustrates the device installed in a pipe.

Figure 2 illustrates the measuring unit according to the preferred embodiment of

present invention.

Figure 3 illustrates the measurements obtained by the device for monitoring of

particle sizes.

Figure 4 illustrates an aid for cleaning the window of the unit.

As indicated by figure 1, the unit 1 can be placed in a standard opening in the pipe wall 3 and is provided with a window 2. The window material can be of any type suitable for the light used in the measurements, but it is preferably made from sapphire or similar to be able to resist the erosion from the particles in the current as well as wear from processes that clean the window. The sleeve of the measuring unit 1 can be of any suitable metal compatible with the pipe material and expected current content. A typical application as an oil and particulate sensor is in 6" pipe containing injection water to be pumped into oil wells underwater.

The functional parts of the measuring unit are illustrated in figure 2. The measuring unit 1 comprises a window 2 and a camera 6 with a lens adapted to obtain images of a defined volume in the flow outside the window. The volume is defined by the focus of the lens or objective 5, both focusing at a selected distance and the depth of field of the lens at the selected distance and aperture. The camera 6 is preferably a digital camera which is capable of taking test images at a sufficiently high frequency. According to the preferred embodiment of the present invention, the camera and the lens form a microscope camera, and the illumination provides a dark field light.

The illustration shows the preferred embodiment with one window covering both the light sources and the camera, but it is possible to split the window having window parts over the light sources and the camera. The window or window parts may also have optical properties that act as lenses, e.g. to direct the light from the light sources.

The illustrated measuring unit 1 also includes two light sources 4a, 4b which are placed on both sides of the camera 6, and which therefore illuminate the selected volume at an angle in relation to the camera's optical axis. The light sources can provide continuous illumination or flashes synchronized with the sampling in the camera 6. The number of light sources can vary depending on the situation and the application, e.g. of the required light intensity and lens aperture. The light source or sources 4a,4b can be made up of sections around the camera of different sizes depending on the required effect and light intensity, but larger sections up to 180° will be advantageous both for side lighting and contrast. The light sources can be placed close to the window, or the light can be transmitted through a light guide towards the desired position. A single light source that surrounds the camera can of course also be used, or a tube-shaped light guide that distributes the light in a 360 degree section from one or more light sources.

The measuring unit also includes an electronic unit 7 for storing and/or processing the sampled information, for providing power supply and which possibly also has connectors 8 for communication with e.g. other instruments or control systems on land, or a power supply.

In use, the measuring unit will take a number of pictures, and the number of droplets and/or solid particles will be counted. The sampling may be at a constant that monitors the number of particles in each image and observes an increase, or the sampling is performed until a predetermined number of images or a predetermined number of particles are counted, and the sampling information is analyzed.

For use as a sensor to monitor the amount of oil droplets and/or solids in a stream, the shape of the particles can be observed using the microscope camera and dark field illumination, and analyzed. In this analysis, observed uneven shapes indicate solids, while round shapes indicate small liquid droplets, which is useful when used for monitoring e.g. a stream of water used for injection into a reservoir. This shape analysis is based on the solution described in the above-mentioned US patent and will not be discussed in detail here.

When water is injected into a reservoir, the well injection can be damaged by excess small oil droplets or solids content. (Dissolved hydrocarbons do not affect the injection to the well to any great extent). Injection damage from excess content of small oil droplets is often reversible (by injecting with clean water over time), while damage from solids can be irreversible, requiring an expensive well intervention to remedy. The permissible ppm limits for solids are normally lower than the permissible limits for small oil droplets. For water injection, it is therefore important to be able to determine the concentration of small oil droplets and solids separately and independently of each other.

The device can also be used with a wet gas compressor, in order to be able to measure the amount of small liquid droplets entering the compressor. At the same time, the device can be used to obtain the size distribution of the small droplets. A gas compressor can tolerate several percent of liquid content at the intake which ensures that the small droplets are small.

The measuring unit according to the present invention can also be used to characterize the flow conditions by finding the size and mass distribution of the small droplets in the flow. Figure 3 illustrates a measurement result where the distribution of the number of particles with sizes in (micrometers) and weight in (micrograms) is shown, which can be used when monitoring the content of the injection water to be pumped into a well, e.g. by making it possible to adjust or stop the separator that separates oil from water.

As the measuring unit will be used in environments containing oil, solid particles, etc., it may accumulate on the window after a period of use. The measuring unit can be cleaned by removing it from the tube, but e.g. in underwater installations this can become complicated and expensive. Procedures for cleaning the window on the spot can therefore be used. Figure 4 shows a possible cleaning procedure where the window is flushed with high-pressure methanol. The methanol is provided with a tool 9 connected to a flushing nozzle and solenoid valve 10, and which is placed immediately downstream from the window 2 so as not to disturb the flow 11 during normal use, and can be installed through the same opening in the pipe or a separate opening in close by.

The flushing can be activated manually or can be carried out automatically if deposits are detected on the window. This detection can be performed by detecting e.g. loss of contrast, constant dark areas in the images, etc.

Alternative cleaning methods can be based on optical cleaning agents, e.g. by using a high power laser aimed at the window either from the inside or outside of the sleeve, or by vibrating the window at ultrasonic frequencies with a transformer connected to the window.

Claims (10)

1. Measuring unit for monitoring particles in a fluid flow, characterized in that the unit comprises a sleeve which is adapted to be mounted in a pipe wall with a first end which is in contact with the fluid flow, where the first end includes a window, where the sleeve comprises a camera placed inside the sleeve, where the camera is aimed at a selected volume through the window and which is connected to an electronic unit for sampling and analysis aid for analyzing the sampling images for recording particles in the above-mentioned volume, where the measuring unit also comprises at least one light source placed inside the sleeve and which is adjusted to illuminate the selected volume. 2. Measuring unit according to claim 1, characterized in that it includes at least two light sources aimed at the selected volume. 3. Measuring unit according to claim 2, characterized in that the light sources are placed symmetrically around the camera. 4. Measuring unit according to claim 2, characterized in that the light sources are adapted to provide dark field illumination in the selected volume. 5. Measuring unit according to claim 1, characterized in that the analysis aid is adapted to recognize and count the number of particles in each image, where the measuring unit is adapted to take pictures until a predetermined number of particles has been detected. 6. Measuring unit according to claim 1, characterized in that the analysis aid is adapted to recognize predetermined particle properties, and therefore categorize the detected particles, e.g. such as small liquid droplets or sand particles from their measured shapes or sizes. 7. Measuring unit according to claim 1, characterized in that the camera consists of a microscope with an image sensor. 8. Measuring unit according to claim 1, characterized in that it also comprises a flushing unit placed outside the sleeve and which is adapted to flush a fluid, e.g. methanol, at higher pressure towards the window for purification. 9. Measuring unit according to claim 1, characterized in that it comprises an acoustic transformer to insonify the window in order to remove contamination from there in this way. 10. Measuring unit according to claim 1, characterized in that it comprises an optical power laser device for cleaning the window from the inside of the device.