PL224917B1 - Measuring unit of the flowmeter of the gravitationally flowing liquid, especially municipal sewage and industrial effluents - Google Patents

Description

Description of the invention

The subject of the invention is a measuring unit of a gravity flow meter, especially municipal sewage and industrial sewage, which is used in the measurement of the billing amount of sewage and in monitoring the sewage network, installed below the ground in sewage wells, at risk of flooding by groundwater.

There are known methods of measuring the flow rate in water and sewage management facilities. One of the solutions is measurement in open channels based on damming methods, in which the measurement of the liquid flow rate is made on the basis of measuring the current level of the flowing liquid, in a measuring element called the measuring trough, and then converting it into the amount of flow rate.

The measurement of the liquid level in the weir is usually done with an ultrasonic sensor by measuring the flight time of the ultrasonic beam between the sensor and the surface of the liquid whose level is to be measured. The Parshall, Venturi and UNIKLAR-77 measuring troughs used are designed to measure the volumetric flow rate in sewers, but are not suitable for measuring small amounts of flowing sewage and are not resistant to flooding of the trough by groundwater, which distorts the result measurement or causes the loss of measurability of the device making it unsuitable for billing metering.

For the measurement of small amounts of flowing sewage, overflows with rectangular or triangular cross-sections are known and used, which are used to measure the amount of treated sewage.

Due to the inability to self-clean the overflow, they are not suitable for municipal sewage. These devices are not suitable for billing measurements when installed in drains, because they are not tight and therefore groundwater or rainwater gets into the overflow and interferes with the measurement results.

There is known a sensor for measuring the volume and determining the density of a liquid flowing by gravity, according to DEP No. PL63318Y. This sensor has a tubing with two coils placed on the wire and measuring electrodes placed inside. The coils are positioned so that the lines of force of the electromagnetic field are perpendicular to the longitudinal axis of the conductor, while in a plane perpendicular to the axis, on the inner circumference of the conductor, four measuring electrodes are arranged in pairs parallel to each other, the ends of these measuring electrodes are led outside the tubular conductor . This sensor cannot be measured if the level of flowing wastewater is lower than 10% of the sensor diameter, because at this height there are the lowest measuring electrodes, which must be immersed in the measured medium in order to be measurable.

The aim of the invention is to develop a compact solution that will allow the billing application for the measurement of small amounts of flowing municipal or industrial wastewater, with a tightness sufficient to eliminate the phenomenon of groundwater infiltration into the measuring trough and with predisposition to put on a seal or padlock by users to protect against uncontrolled access to the processing element.

The solution according to the invention has a sealed body inside which, in the lower part, there is a wet space with a horizontally arranged liquid passage with a measuring overflow, ending on one side with an inlet conduit situated in the axis of its symmetry and, on the other side, ending with an outlet conduit situated in its symmetry axis, Whereas the upper part of the body ends with a cylinder where there is a dry space in which an ultrasonic measuring probe is placed above the measuring overflow, moreover, the outer wall of the body cylinder in the dry space has a cover with a gasket.

In the first version of the solution according to the invention, it has a liquid channel with a Palmel-Bowlus measuring overflow, a round inlet pipe and a round outlet pipe.

In the second variant of the solution according to the invention, it has a liquid channel with a measuring overflow in the form of a triangular measuring orifice, a round inlet pipe and a round outlet pipe.

In the third variant of the solution according to the invention, the sealed cover is closed from the outside with a key or a chain with a padlock.

In the fourth variant of the solution according to the invention, the outer body wall ends at the bottom with a foot for mounting at the bottom of the pit or on the foundation.

PL 224 917 B1

The measuring unit of the flow meter according to the invention enables the measurement of the wastewater flow from very low flow values close to zero, which until now was impossible to achieve with the currently used flow meters measuring by gravity flowing municipal or industrial wastewater. Due to the hermetic structure, the measurement is free of errors and deviations from the measured values caused by the infiltration of water into the measuring unit. The tight construction of the body protects against unwanted access to the level probe, which prevents influencing the measurement result.

Thanks to the invention, the main elements, such as: a liquid channel with a measuring overflow, an inlet pipe, a liquid outlet pipe, and the dry space in the barrel of the body in which the ultrasonic measuring probe is placed, constitute a monolithic tight body, which allows the metrological properties obtained during calibration at the manufacturer to be maintained, which do not change during transport, assembly and operation under normal conditions of use. Equipping the body in the lower middle part with a foot creates favorable conditions for the leveling of the measuring trough and for the correct positioning of the inlet pipe and the liquid discharge pipe during installation. A preferred embodiment is that the liquid inlet conduit, the Palmer-Bowlus measurement overflow and the liquid outlet conduit are arranged on a vertical and a horizontal axis of symmetry with respect to each other.

In the solution according to the invention, the sealed cover in the barrel of the body allows servicing and maintenance of the dry and wet space of the measuring assembly, moreover, the provision of a lockable cover eliminates the influence of bystanders who may affect the operation and indications of the measuring device, without the knowledge of the party transmitting and receiving sewage . In addition, the tight closure of the body cylinder prevents water from flooding of the measuring well into the measuring trough during flooding of the measuring well, and therefore does not interfere with the measurement result of the amount of sewage flowing through the device under the level probe.

Retrofitting the device with wireless transmission elements and a sump flooding sensor, usually with a random, uncontrolled inflow, allows for quick transmission of alarm information to the services of securing the movement of the measuring device or environmental protection.

The invention, in an exemplary embodiment, is shown in the drawing, in which fig. 1 shows the measuring assembly in a front view, fig. 2 - the measuring assembly in a top view with the cover in place, fig. 3 - the measuring assembly in a top view with the cover removed, fig. 4 - measurement assembly in a side view from the lead-in, fig. 5 - measurement assembly in cross-section at location AA shown in fig. 3, fig. 6 - measurement assembly in cross-section at location BB shown in fig. 3, fig. 7 - block diagram of a system for measuring the volume of wastewater flow with the use of a measuring unit.

The measuring unit has a monolithic body in which there are: an inlet conduit 1, a dry space in the form of a vertical cylinder 2, a liquid channel with a measuring overflow 3, for example a Palmer-Bowlus, an outlet conduit 4, an ultrasonic measuring probe 5, an ultrasonic measuring probe support 6, a cover 7, gasket 17, chain 8 blocking the possibility of removing the cover, clamp 9 for fastening the chain, padlock 10 connecting the chain, base 11 of the body.

The body at one end is provided with a round inlet conduit 1, and at the other end with a round outlet conduit 4 located in the extension of the axial line of the inlet conduit 1. Between these conduits 1 and 4, in the central part of the body, there is a liquid channel with a measuring overflow 3 Palmer-Bowlus visible from the inside of the vertical cylinder 2 after removing the cover 7, blocked against removal with a chain 8, fastened to the clamp 9 and protected against disconnection with a padlock 10. The body in the middle part from the bottom ends with a foot 11 to mount the measuring assembly in a horizontal position on the bottom manholes or on the foundation. In the upper part of the body in the form of a cylinder 2, an ultrasonic measuring probe 5 is mounted, mounted on the support 6. Moreover, a sealed passage 18 is provided in the wall of the cylinder 2 for the supply of electric power and data cables.

The outlet conduit 4 is situated in the vertical axis of symmetry with respect to the inlet conduit 1, while the horizontal and vertical symmetry axis of the liquid channel with the measuring overflow 3 is located in the vertical and horizontal axis of symmetry of conduits 1 and 4.

The system for measuring the volume of liquid flow with the use of a measuring unit, additionally includes: an intelligent counter 12, a non-volatile electromechanical counter 13, a power control module

PL 224 917 B1

14, a GSM module for wireless data transmission to the server 15 and a power backup module 16.

An important element of the flow measuring device for the achievable measurement accuracy with a measuring overflow, for example a Palmer-Bowlus, is the ultrasonic probe used. Its task is to precisely determine the height of the surface of the flowing liquid. The offered parameters of the available ultrasonic probes show that a reasonable limit of the achievable accuracy of measuring the height of the flowing liquid column is ± 1 mm. If other factors of the hole error are to be ignored, the characteristics of the measurement error, understood as the limit error, depending on the flow value, for example for a Palmer-Bowlus trough with a diameter of DN 160, are presented in the table below:

Flow Measurement error during wet calibration Limit measurement error [m ³ / hour] [%] [%] from 0.3 to 0.5 +/- 10% +/- 20% greater than 0.5 to 1.0 +/- 5% +/- 10% greater than 1.0 to 3.0 +/- 3% +/- 5% greater than 3.0 to 30.0 +/- 2% +/- 3%

The above assessment of the accuracy of measurements is acceptable because untreated sewage is a flowing liquid that is particularly difficult to measure, especially in the form of a measuring overflow. The device according to the invention significantly reduces or removes such error-generating factors as: assembly defects, diameter jumps, inhomogeneous pipe walls, insufficient inflow sections, undercutting, floating elements or foam in the path between the ultrasonic probe and the surface of the flowing liquid, especially when the measuring well was installed in wetlands where water infiltration may have occurred through the bottom and walls of the well, or in the floodplain where water inflows through the manhole may have occurred.

The assessment of the accuracy of the measurement of the Palmer-Bowlus measuring orifice with a diameter of DN 160 shows that for correctly measured flow values, the beginning of the scale is at least 1 m / h. The flow below this minimum should be classified as still measurable. The flow without a detailed understanding of the measurement accuracy is very important for billing. The flowmeter with a measuring unit measures from values close to 0 m / h in order to naturally prevent - non-invasive influence on the measurement result. This is understood as the state, i.e. the flow of liquid below which the device does not measure, i.e. does not count on the flow index, even though the liquid is flowing. The expectation of the settling parties has been met, which means that the measuring device measures and counts even a very small amount of flowing liquid.

Measurement range resulting in the device according to the invention, for example, for transfer mediocre ₃ which Palmer-Bowlus DN 160 ranged from a minimum of 0.3 m / h. to the maximum, it is about 30 m ³ / h.

The area of application of the measuring unit includes: measurements of the flow of social and technological sewage and water in industrial plants, measurements of the flow of raw and treated sewage at the inlet and outlet of sewage treatment plants, measurements of the flow of rainwater from squares, roads and highways, measurements of the leachate flow from landfills and landfills .

With such a wide application area of the solutions according to the invention, in order to maintain the declared qualitative and quantitative parameters of measurements of the measured media, in order to avoid possible disturbances caused by the occurrence of significant sewage contamination, the following alternatives can be used: sewage pretreatment, a grate limiting the possibility of larger contaminants entering the measuring section, a sedimentation tank or separator or additional sump.

The solution according to the invention finds application in the measurement of small, hitherto unmeasurable amounts of flowing sewage in sewage networks and can be installed in sewage wells below ground level.

PL 224 917 B1

List of markings

1.- liquid supply line

2nd - vertical cylinder

3. - Palmer-Bowlus transfer

4. - liquid drainage pipe

5. - liquid level sensor

6. - sensor support for measuring the liquid level

7. - sensor cover

8.- chain blocking the cover

9.- chain clamp

10.- a padlock connecting the chain

11. - the base of the body

12. - intelligent abacus

13. - electromechanical index

14. - power control module

15. - remote data transfer

16. - power backup module

17. - gasket

18. - culvert

Claims (5)

Patent claims 1.Measuring unit of a flowmeter of a gravity-flowing liquid, especially municipal sewage and industrial sewage, comprising an inlet conduit, a liquid channel with a measuring overflow, an outlet conduit and an ultrasonic liquid level probe, characterized in that it has a sealed body inside which in the lower part there is a wet space with a horizontally located flow channel with a measuring overflow (3), on one side ending with an inlet conduit (1) along the symmetry axis of the conduit and on the other side ending with an outlet conduit (4) along the symmetry axis of the conduit, while in the upper part of the body there is dry space in which the ultrasonic measuring probe (5) is placed above the measuring overflow, moreover, the outer wall of the body in the dry space is equipped with a cover (7) with a gasket (17). 2. A flowmeter measuring unit according to claim 1, The method of claim 1, characterized in that it has a liquid channel with a Palmer-Bowlus measuring overflow (3) and a round inlet conduit (1) and a circular outlet conduit (4). 3. A flowmeter measuring unit according to claim 1, A method according to claim 1, characterized in that it has a liquid channel with a measuring overflow (3) in the form of a triangular measuring orifice and a round inlet pipe (1) and a round outlet pipe (4). 4. A flowmeter measuring unit according to claim 1. The method of claim 1, characterized in that the sealed cover (7) is closed from the outside with a key (12) or a chain with a padlock. 5. A flowmeter measuring unit according to claim 1. The method according to claim 1, characterized in that the outer body wall terminates at the bottom with a foot (11) for mounting on the bottom of the pit or on a foundation.