RU2777152C1 - Device for water purification in places of environmental disasters - Google Patents

Abstract

FIELD: water treatment.

SUBSTANCE: invention relates to water purification devices. A device for water purification is described, containing a housing with inlet and outlet pipes, a spiral-shaped flow channel of circular cross-section, the terminal part of which is withdrawn into the outlet pipe, while an external slot for removing impurities is made along the outer generatrix of the flow channel, connected along the entire length with an external channel for removing impurities, an internal one is made along the inner generatrix of the flow channel for removing impurities, connected along the entire length with an internal channel for removing impurities, while the outer slot has a narrowing shape in cross-section, the width of the outer slot at the flow channel is greater than the width of this slot at the outer channel of impurity removal.

EFFECT: comprehensive cleaning of the liquid from both less dense contaminants and denser ones.

1 cl, 4 dwg

Description

The field of technology.

The claimed technical solution relates to devices for separating liquids (emulsions) by density due to centrifugal force, namely, to devices for purifying water from both denser and less dense liquids and particles. The technical solution can be used to purify water in places of environmental disasters.

prior art.

A device for cleaning liquids is known (patent RU2404839, IPC B01D17/038, 2010), containing a housing with inlet and outlet pipes, and a spiral flow channel having a constant value of the circular cross-sectional area. The end part of the channel is led into the outlet branch pipe. Along the outer generatrix of the flow channel, there is a slot for removing impurities, connected along the entire length with the channel for removing impurities.

Particles of impurities move in the fluid flow in the flow channel of the known device. Under the action of centrifugal forces, particles of impurities fall on the wall of the flow channel near the gap for removing impurities, are reflected from it and move towards the center of the channel and towards the opposite wall. Then, reflected from this wall or under the action of centrifugal forces, the particles again move to the wall of the flow channel near the slot. A disadvantage of the known device is the shape of the slot for removal of impurities, which occupies a relatively small part of the channel surface. The disadvantage mentioned above leads to the fact that in order to achieve a high degree of purification, it is necessary to increase the length of the flow channel. This leads to an increase in material consumption and dimensions of the device.

The length of the flow channel is reduced in the liquid purification device (patent RU116781, IPC B01D17/038, 2012), which is a development of the technical solution according to the above patent RU2404839. In this device, grooves are additionally made on the wall of the flow channel along its entire length, one end of each of which goes into the slot at an obtuse angle to the direction of flow near the slot.

However, the disadvantage of said execution of the grooves at an angle to the direction of flow is the formation of flow turbulence on these grooves. This leads to the fact that the specific cleaning efficiency per unit length of the flow channel is not high enough.

The above devices relate to the separation from liquids of denser (heavy) fractions.

A device for separating the less dense part of a liquid mixture is known from patent RU161442 (IPC B01D17/038, 2012). This device includes a housing with an inlet and a first outlet connected by a spiral first channel. A slot is made along the outer generatrix of this channel, connecting it with a spiral-shaped second channel, ending with a second outlet pipe. At half of the outer turn, the first channel is made tapering in cross-sectional area in the direction of fluid movement, and the second channel begins in the area where the first channel narrows.

Despite the fact that the device according to patent RU161442 separates the less dense part from the liquid flow, it is designed to clean the less dense part from dense impurities, including solid particles. To do this, the first channel is made tapering. When using this device to clean the liquid from less dense parts that make up a small part of the total liquid, the tapering design of the first channel will undesirably force a large part of the liquid into the second channel.

Disclosure of invention

The technical problem to be solved by the claimed technical solution is the complex purification of the liquid from both less dense contaminants and more dense ones.

The technical result provided by the claimed technical solution is the solution of the problem.

An additional technical result is a reduction in the length of the flow channel while maintaining a high degree of purification.

The essence of the technical solution lies in the fact that the device for water purification contains a housing with inlet and outlet nozzles, a spiral flow channel of circular cross section, the end part of which is led into the outlet nozzle. Along the outer generatrix of the flow channel, an external slot for removal of impurities is made, connected along the entire length with the external channel for removal of impurities. It differs in that along the internal generatrix of the flow channel, an internal slot for removal of impurities is made, connected along the entire length with the internal channel for removal of impurities. The outer slot has a tapering shape in cross section. The width of the outer slot at the flow channel is greater than the width of this slot at the outer channel for removing impurities.

The above entity is a set of essential features of the claimed technical solution, ensuring the achievement of the claimed technical result.

In a particular case, the outer slot has a trapezoid shape in cross section.

The authors of the technical solution made a prototype, the tests of which confirmed the achievement of the technical result. Brief description of the drawings.

In FIG. 1 shows a view of the inventive device for water purification in places of environmental disasters in a section along the axis of the output channel, in Fig. 2 is a sectional view of the device A-A of FIG. 1 in FIG. Fig. 3 is a view of the outer and inner channels (view B of Fig. 2 is enlarged), in Fig. 4 is a view of the outer slot in the section G-D of FIG. 2.

Options for the implementation of the technical solution.

The water purification device in places of environmental disasters contains a housing (1) with inlet (2) and outlet (4) nozzles (Fig. 1, 2). Inside the housing, a spiral flow channel (3) is made with a constant value of the circular cross-sectional area, connecting the inlet (2) and outlet (4) branch pipes. The flow channel (3) is led into the outlet pipe (4) tangentially.

To remove the separated impurities of a higher density compared to the density of the bulk of the liquid (water) along the outer generatrix of the flow channel (3) of the device, the most distant from the axis of the spiral, an external slot (5) is made, connected to the external channel for removing impurities (6), through which separated impurities with a higher density are output to the first receiver (not shown) (Fig. 3). The outer slot (5) has a tapering cross-sectional shape, in particular a trapezoid shape (FIG. 4). The smaller base of the trapezoid communicates the outer slot with the outer channel for removing impurities (6). The larger base of the trapezium communicates this gap with the flow channel (3). The smallest size of the outer gap (5) is determined by the maximum size of solid particles of impurities that the water treatment device must be able to remove. Preferably, the size of the outer slot (5) on the side of the outer channel for removing impurities is 1 mm, and on the side of the flow channel - 5 mm. It is expedient to place the beginning of the outer channel at a quarter of the first turn of the flow channel (3).

The end of the external channel (6) for removing impurities is connected to the first receiver through a control device (7) configured to change the cross-sectional area of the external channel (6) at its installation site. The control device (7) allows you to change the flow rate of the separated liquid and mechanical particles from the external channel (6) for removing impurities into the first receiver, which regulates the degree and quality of cleaning.

To remove the separated impurities of lower density compared to the density of the bulk of the liquid (water) along the inner generatrix of the flow channel (3) of the device, the least spaced from the axis of the spiral, an internal slot (8) is made, connected to the internal channel for removing impurities (9), through which separated impurities with a lower density are output to the second receiver (not shown) (Fig. 3). The inner slot (8) can have a tapering shape in cross section, as well as the outer slot (5), while the shell has a smaller width on the side of the inner slot. The size of the inner slot (8) can be 1 mm. The size of the inner slot and the size of the inner channel (9) is determined by the volume of liquid contamination with light components, which mainly include fuels and lubricants (POL). It is expedient to place the beginning of the internal channel in the area of the beginning of the curvature of the flow channel (3), for example, with an indent of 1-2 cm from this beginning.

The end of the internal channel (9) for removal of impurities is connected to the second receiver through a control device (not shown) configured to change the cross-sectional area of the internal channel (9) at its installation site. The specified control device allows you to change the flow rate of the separated liquid from the internal channel (9) removal of impurities in the second receiver, which regulates the degree and quality of cleaning.

The water purification device works as follows.

Polluted water (generally - polluted liquid) is supplied under pressure to the inlet pipe (2), and then enters the spiral flow channel (3). Since the flow channel (3) has a curvilinear shape, centrifugal forces act on the liquid and impurity particles suspended in it. Under the influence of these forces, the density distribution of liquid particles and impurities occurs in the cross section of the channel (3).

In this case, particles of liquid impurities having a density less than the density of the main water flow (for example, fuel and lubricants) are displaced to the inner side of the spiral flow channel (3). Such particles of impurities, having reached the wall of the channel (3) from the inner side of the spiral, and continuing their movement along the channel (3), through the inner slot (8) enter the inner channel (9) for removing impurities. Moving along the inner channel (9), these light fractions are discharged to the second receiver through the appropriate control device. By changing the cross-sectional area at the installation site of the control device, a change in the throughput of the internal channel (9) is achieved, which leads to a change in the amount of low-density liquid discharged from the cleaning device, and, consequently, to a change in the degree of purification.

Particles of mechanical impurities and liquid impurities, having a density greater than the density of the main flow, are pressed against the outer side of the spiral flow channel (3). Such particles of impurities, having reached the wall of the channel (3) from the outer side of the spiral, and continuing their movement along the channel (3), through the outer slot (5) enter the outer channel (6) for removing impurities. The execution of the outer slot (5) is trapezoidal, with a wide base communicating with the flow channel, allows you to capture into the slot a larger number of impurity particles that have reached this slot, compared with analogues described in patents RU2404839 and RU116781. In this case, there is no flow turbulence near this gap, as in the device according to patent RU116781. The entrance area to the outer slot (5) from the side of the flow channel (3) is larger than the same area in the device according to patent RU2404839 and the area of the slot and grooves in the device according to patent RU116781. If particles of impurities, moving towards the slot (5), hit its walls, then they "rebound" towards the external channel (6) for removing impurities, and not towards the flow channel. This explains the increase in the specific efficiency per unit length of the claimed device in terms of separating the denser components of the original liquid compared to analogues RU2404839 and RU116781. Thus, it becomes possible to reduce the length of the flow channel, reducing the material consumption and the size of the device.

Making the width of the outer slot (5) near the outer channel (6) for the removal of impurities of a smaller size is aimed at reducing the probability of the return of particles trapped in this channel into the flow channel (3).

Moving along the outer channel (6), the impurity particles are removed to the first receiver through the control device (7). By changing the cross-sectional area at the installation site of the control device (7), a change in the throughput of the external channel (6) is achieved, which leads to a change in the amount of impurity particles discharged from the cleaning device, and, consequently, to a change in the degree of purification.

Purified water enters the outlet pipe (4), from where it is discharged from the purification device.

The claimed device does not contain moving parts, sealing elements and is completely sealed. This ensures high reliability of the device in operation.

When working at sites of environmental disasters, it is advisable to have a set of cleaning devices with different sizes of slots and channels to ensure the possibility of choosing a device that is suitable in terms of performance, depending on the type and volume of pollution. Industrial applicability.

The proposed device for water purification in places of environmental disasters is implemented using industrially produced devices and materials, can be manufactured at any machine-building enterprise and will be widely used.

Claims (2)

1. A device for water purification, containing a housing with inlet and outlet pipes, a spiral flow channel of circular cross section, the end part of which is led into the outlet pipe, while along the outer generatrix of the flow channel, an external slot is made to remove impurities, connected along the entire length with the outer impurity removal channel, characterized in that along the inner generatrix of the flow channel, an internal slot for removal of impurities is made, connected along the entire length with the internal channel for removal of impurities, while the outer slot has a tapering cross-sectional shape, the width of the outer slot at the flow channel is greater than the width of this gap at the outer channel for removing impurities. 2. The device according to claim 1, characterized in that the outer slot has a trapezoid shape in cross section.

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