RU73867U1 - MAGNETIC LIQUID TREATMENT DEVICE - Google Patents

Abstract

The invention relates to techniques for magnetic processing of liquids and can be used in oil production for magnetic processing of oil production wells.

The objective of the proposed technical solution is to provide effective magnetic processing of high-flow liquids by dividing the flow into equal parts without the use of a settling apparatus, for example, on any part of the pipeline.

A device for magnetic fluid treatment, including a supply pipe, a fluid flow divider into parts, electromagnets installed in parallel, is characterized in that the fluid flow dividers into equal parts are placed before and after the electromagnets installed in parallel.

The liquid flow divider into equal parts is made in the form of a mixer and connecting pipes.

The mixer, installed in front of the electromagnets, has a pipe for supplying liquid from below, and pipes for drainage are at the top; and the mixer installed after the electromagnets has nozzles for supplying liquid to it from below, and a nozzle for drainage is at the top.

The connecting pipes are connected to the mixer symmetrically with respect to the nozzle for supplying or discharging a fluid stream located in the center of the mixer.

Connecting pipes have the same diameter, length and the same bends.

The placement of the fluid flow dividers before and after the parallel lines of the magnetic fluid treatment allows you to maintain equal hydraulic resistance in all parallel lines, which ensures equal fluid flow in them and the most effective treatment of the fluid with a magnetic field in any section of the pipeline, regardless of the presence of a settling apparatus with a gas cap.

2 of FIG.

Description

The invention relates to techniques for magnetic processing of liquids and can be used in oil production for magnetic processing of oil production wells.

A device is known by A.S. N 865852, С02F 1/48, publ. 09/23/81. The device is a diamagnetic material-mounted housing in the pipeline and an electromagnet in the form of a winding on the housing, a power and control unit. The processed fluid flows through the housing and is exposed to an alternating magnetic field of low frequency. A disadvantage of the known device is the decrease in the effectiveness of the magnetic field on a liquid with an increase in the diameter of the device casing in order to process a large flow rate liquid.

The closest analogue is the device according to the patent of the Russian Federation N 2095119, B01D 17/06, publ. 11/10/97. The device contains parallel mounted electromagnets for magnetic field treatment of high-flow liquids. In this case, the fluid flow is distributed in parallel lines using a gas-liquid mixture flow divider in the presence of a gas pad; the fluid flow divider is connected to the gas space of the settling apparatus located after the device for treating the liquid with a magnetic field. The disadvantage of this device is the inability to divide into equal parts of the fluid flow without a gas cushion provided by the prototype with a settling apparatus; this leads to unsatisfactory processing of a large flow rate liquid in parallel with installed electromagnets. In practice, magnetic treatment of the fluid transported, for example, by pipeline, in any of its sections, i.e. without the use of a settling apparatus.

The objective of the proposed technical solution is to provide effective magnetic processing of high-flow liquids by dividing the flow into equal parts without the use of a settling apparatus, for example, on any part of the pipeline.

The problem is solved in that the device for magnetic processing of liquid, including the supply pipe, the divider of the fluid flow into parts, installed electromagnets in parallel, characterized in that the flow dividers

liquids are placed in equal parts before and after parallel mounted electromagnets.

The liquid flow divider into equal parts is made in the form of a mixer and connecting pipes.

The mixer, installed in front of the electromagnets, has a pipe for supplying liquid from below, and pipes for drainage are at the top; and the mixer installed after the electromagnets has nozzles for supplying liquid to it from below, and a nozzle for drainage is at the top.

The connecting pipes are connected to the mixer symmetrically with respect to the nozzle for supplying or discharging a fluid stream located in the center of the mixer.

Connecting pipes have the same diameter, length and the same bends.

The placement of the fluid flow dividers before and after the parallel lines of the magnetic fluid treatment allows you to maintain equal hydraulic resistance in all parallel lines, which ensures equal fluid flow in them and the most effective treatment of the fluid with a magnetic field in any section of the pipeline, regardless of the presence of a settling apparatus with a gas cap.

The liquid flow divider can be made in the form of a mixer (mixing chamber) with taps / inlets according to the number of parallel electromagnets. The connecting pipes connecting the mixer to the electromagnets installed in parallel have the same diameter, length and the same bends to ensure equal hydraulic resistance.

The mixers placed before and after the electromagnets have nozzles for supplying liquid from below, and for drainage from above. This prevents the accumulation of gas phase in the mixers.

The nozzles for the connecting pipes are placed on the mixer symmetrically with respect to the nozzle for the total fluid flow, which provides the same conditions for the flow of the flow in the mixer from the nozzle of the general flow through the nozzles for the connecting pipes and vice versa.

The scheme of the proposed device is shown in figure 1 and figure 2 in two projections.

The device consists of a pipeline 1, electromagnets 2 (with power and control units), liquid flow dividers, each consisting of a mixer 3 and connecting pipes 4.

The device operates as follows. A liquid is pumped through pipeline 1, which must be processed in a magnetic field. The magnetic field is created inside the electromagnets 2, which have an optimal size; each individually, the fluid throughput is several times smaller than the throughput of pipeline 1. In this case, it is necessary to connect several electromagnets 2 in parallel with a total throughput equal to the throughput of pipeline 1. Effective operation of the parallel-connected electromagnets is ensured only if they are uniformly loaded, which is ensured divider fluid flow into equal parts by the number of electromagnets 2.

The placement of the fluid flow divider before and after the electromagnets installed in parallel creates equal hydraulic resistance to the flow on each line of the electromagnet and as a result ensures equal fluid flow in parallel lines.

The flow divider consists of a mixer 3 and connecting pipes 4. The nozzles for the connecting pipes on the mixer are placed symmetrically with respect to the nozzle for the total flow, which provides the same conditions for the flow in the mixer from the common flow nozzle through the nozzles for the connecting pipes and vice versa. In this case, the connecting pipes have the same length, diameter and the same bends to ensure equal hydraulic resistance.

The proposed device allows, in necessary cases, to subject magnetic flows of liquids with high flow rates, while using in parallel connected the most effective and optimal in size electromagnets.

Thus, by dividing the fluid flow into equal parts, the problem is solved and a technical result is achieved for the efficient processing of large fluid flow rates in any section of the pipeline with minimal cost.

Claims (3)

1. A device for magnetic fluid treatment, including a supply pipe, a fluid flow divider into parts, electromagnets installed in parallel, characterized in that the fluid flow divider into equal parts is made in the form of a mixer and connecting pipes, while the mixer installed in front of the electromagnets has a nozzle for supplying liquid from below, and branch pipes for drainage - at the top; the device further comprises a mixer installed after the electromagnets, which has nozzles for supplying liquid to it from below, and a nozzle for drainage is at the top. 2. The device according to claim 1, characterized in that the connecting pipes are connected to the mixer symmetrically with respect to the nozzle for supplying or discharging a fluid stream located in the center of the mixer. 3. The device according to claim 2, characterized in that the connecting pipes have the same diameter, length and the same bends.