RU2688341C1 - Inner device for thin-layer settlers - Google Patents

Abstract

FIELD: oil, gas and coke-chemical industries.SUBSTANCE: invention relates to equipment for separation of emulsions and suspensions and can be used in chemical, petrochemical and other industries. Inner device for thin-layer settlers is a system of alternating chutes with inclined walls and vertices, facing up and down, in which at the tops of the chutes there are channels located in the vertical plane in a direction transverse to the axis of the chutes, connecting the vertices of the chutes with the tops of the chutes of the next layer, there are gaps at the end of the channels between the walls of the channels and the walls of the grooves of the next layer. Channels walls touch the walls of the next layer chutes and are the support for the next layer of internal devices. Increase in settling efficiency is achieved due to movement of settled particles or drops between layers and avoiding repeated ingress of settled particles or drops into a layer of liquid at the outlet of the thin-layer settling unit.EFFECT: solution simplifies the design of thin-layer settlers, enables to use single-type internal devices in thin-layer settlers of different purpose and size.4 cl, 3 dwg

Description

The invention relates to equipment for the separation of emulsions and suspensions and can be used in chemical, petrochemical and other industries.

Known thin settlers, in which there is a set of inclined plates located in the housing of the apparatus. In the sump there are additional devices for fixing the plates in the desired position. (Patent of the Russian Federation №2145513, IPC B01D 21/02 Horizontal cylindrical tray shelter, Publ. 20.02.2000, bull. №5.)

The closest analogue (prototype) is the internal device for thin-layer settling tanks, in which corrugated plates with longitudinal (flow-parallel) corrugations are used. Essentially, the corrugations form a system of alternating gutters with inclined walls and peaks facing up and down. (Patent of the Russian Federation No. 2346722, IPC B01D 21/02 The lamellar module and the decanting unit with plates, in particular, placed vertically, Publ. 10.10.2007, bull. No. 28.)

It is known that the capacity of the settling tanks depends on the area of settling and thin-layer settlers make it possible to obtain a large area of settling in devices of relatively small size. In addition, the Reynolds number is significantly reduced, which makes it possible to obtain a laminar mode of motion at a higher flow rate, and the internal devices of the thin-layer sump prevent the liquid from mixing in the vertical direction. These features improve settling conditions. Solids on settling can linger and accumulate on the horizontal sections of the internal devices of the sump, therefore, use inclined elements. In inclined clarifiers, slope is used along the stream, and in horizontal across the stream, and the internal devices of the thin sedimentation tank may have areas with different slopes. A significant disadvantage of the known designs of settling tanks with internal devices in the form of a gutter system or tubes is that settled solid particles and droplets again enter the volume of the purified liquid at the exit of the block of internal devices, essentially re-mixing and deterioration of the settling results. In horizontal shelving pans with inclined plates, solid particles and droplets of poorly exfoliating emulsions reach the surface of the plates and move along the surface of the plates both along and across the stream. Due to the movement across the flow, the settled particles are collected at the wall or in the center of the apparatus and do not enter the volume of the purified liquid as they exit the block of internal devices. However, the general way of settling is the sum of the distance between the plates in height and the path that particles and drops travel along the plates in the transverse direction. The general way of settling is many times greater than the distance between the plates and the effectiveness of settling decreases. Devices for fixing the plates complicate the design, increase the consumption of materials for the structure, and additionally turbulize the flow. When installing the plates through the manholes, it is necessary to use plates with a small width, which further complicates the design of the devices for fixing them. It is difficult to repair and maintain the device. The structures of the internal devices of the thin-layer settling tanks are not universal enough and it is necessary to use the internal devices of various designs and sizes for the settlers for various purposes and sizes. In sedimentation tanks with oblique movement of the flow to prevent the re-entry of settled particles in the purified liquid using the reverse slope. The settled particles move along inclined surfaces against the direction of flow of the fluid and exit from the liquid inlet side. But in this case, only relatively large particles are separated in the sump, whose settling rate is higher than the flow rate of the liquid. Such septic tanks are not capable of purifying, for example, water containing mechanical impurities and oil products at the same time, that is, liquids containing particles with densities both higher and lower than the density of the liquid. These drawbacks significantly reduce the efficiency of thin-layer clarifiers and narrow the scope of their application. Production of small series of internal devices of various designs and sizes increases their value.

The objective of the invention is to increase the efficiency of sedimentation, simplify the design of thin-layer settlers, the use of similar internal devices in thin-layer settlers for various purposes and sizes.

The technical result is achieved by the fact that in a well-known internal device for thin-layer settlers, which is a system of alternating troughs with inclined walls and peaks facing up and down, according to the invention, there are channels in the tops of the grooves transverse to the axis of the grooves, connecting the tops of the grooves with the tops of the grooves of the next layer, at the end of the channels between the walls of the channels and the walls of the grooves of the next layer there are gaps.

The technical result is also achieved by the fact that, according to the invention, the walls of the channels touch the walls of the grooves of the next layer and are the support for the next layer of internal devices.

The technical result is also achieved by the fact that in one of the embodiments, in which the system of gutters is formed by corrugated plates with longitudinal corrugations, according to the invention, the channels are branch pipes installed in the tops of the corrugations.

The technical result is also achieved by the fact that in one of the embodiments according to the invention, the grooves are assembled from inclined plates with vertically bent edges that form the walls of the channel, and the plates are interconnected by connecting elements that simultaneously provide the required distance between the walls of the channel and perform the function transverse partitions in the channel.

Internal devices for thin sedimentation tanks, which are a system of alternating gutters with inclined walls and peaks facing up and down, are mounted on supporting devices along the settler in layers directly on top of each other. In the tops of the grooves there are channels located in a vertical plane in the direction transverse to the axis of the grooves, connecting the tops of the grooves with the tops of the grooves of the next layer, at the end of the channels between the walls of the channels and the walls of the grooves of the next layer there are gaps. The walls of the channels touch the walls of the grooves of the next layer and are the support for the next layer of internal devices. The gutters in the adjacent layers are arranged in the same way, that is, the tops of the gutters facing, for example, lie down one above the other. Settling is as follows. Liquid containing suspended solids and (or) droplets with a density greater or less than the density of the liquid enters the internal devices of the thin-layer clarifier and moves along the gutters. More dense particles settle and accumulate in the lower part of the gutters, less dense particles in the upper part of the gutters. Liquid droplets partially merge with each other, and a complete or partial delamination of the emulsion occurs. Coagulation may occur, in which solid particles stick together with each other to form larger particles. Condensed suspension or emulsion through the gaps between the walls of the channels at the end of the channels and the walls of the grooves into the channels and due to the difference in density flows through the channels in the tops of the grooves of the next layer of internal devices. Further, the condensed emulsion or suspension can from the channels get into the tops of the grooves of the next layer through the gaps or directly get into the channels of the next rad. Condensed suspension or emulsion in the channels moves across the main flow and there is no transfer along the flow. Next, the thickened suspension or emulsion is mixed with the suspension or emulsion, settled in the adjacent layer, and flows through the channels of the adjacent layer into the next layer. Thus, a dense condensed suspension or emulsion through the channels reaches the bottom of the apparatus, and the less dense top of the apparatus. The fact that the condensed emulsion or suspension is actually removed from each radar of the internal devices of the thin-layer clarifier makes it possible to practically exclude the repeated ingress of settled particles into the layer of purified liquid at the outlet of the internal devices. When moving in the channels, the deposition rate of the particles is added up with the speed of movement of the thickened suspension or emulsion itself, which significantly increases the efficiency of settling. Two versions of the internal devices for thin-bed sedimentation tanks are proposed. In one of the embodiments, the system of gutters is formed by corrugated plates with longitudinal corrugations, and the channels are the branch pipes installed in the tops of the corrugations. In another embodiment, the internal device is assembled from inclined plates with vertically bent edges that form the walls of the channel, and the plates are interconnected by connecting elements that simultaneously provide the required distance between the walls of the channel and function as transverse partitions in the channel. The connecting elements can be made in the form of individual parts or made integral with other elements, for example, in the manufacture by stamping from polymeric materials. The fact that the internal devices for thin layer settlers can be installed layer by layer directly on top of each other eliminates the need for fixing devices or greatly simplifying their design. Due to the installation of internal devices with a small transverse displacement and the use of a different number of grooves in the layer, it is possible to completely fill the apparatus of circular cross section of any size and maximize the use of apparatus volume. The same type of internal devices can be installed in both horizontal and inclined sumps and used to separate emulsions and suspensions with particles more dense and less dense than liquid. Internal devices can be mounted through the manhole, including in existing devices. The design is collapsible, ease of assembly and disassembly facilitates maintenance and repair of the device.

FIG. 1 shows an internal device for thin-layer settling tanks, in which a system of grooves is formed by corrugated plates with longitudinal corrugations with nozzles installed at the tops of the corrugations. FIG. 2 shows a cross-section of the internal devices for thin-lagoons, arranged in two rows, and shown in FIG. 1. In FIG. 3 shows a cross-section of the internal device for thin-layer settlers, in which the gutters are assembled from inclined plates with vertically bent edges.

The internal device for thin sedimentation tanks is a system of alternating gutters 1 with inclined walls and peaks facing up and down. In the tops of the grooves 1 there are channels 2, located in a vertical plane in the direction transverse to the axis of the grooves 1, connecting the tops of the grooves 1 with the tops of the grooves of the next layer. At the end of the channels 2 between the walls of the channels 2 and the walls of the grooves 1 of the next layer there are gaps 3. In FIG. 1 and FIG. 2, the gutter system 1 is formed by corrugated plates with longitudinal corrugations, and the channels 2 are the branch pipes 4 installed in the tops of the corrugations. The walls of the channels 2, that is, the nozzles 4 touch the walls of the grooves 1 of the next layer and are the support for the next layer of internal devices. FIG. 3 shows a variant of the internal devices in which the troughs 1 are assembled from inclined plates with vertically bent edges 5, which form the walls of the channel 2. The plates are interconnected by connecting elements 6, which simultaneously provide the required distance between the walls of the channel 2 and function as transverse partitions in the channel 2. The connecting elements 6 can be manufactured as separate parts or made integral with the grooves 1, for example, in the manufacture of polymeric materials by stamping or casting.

Settling is as follows. Liquid containing suspended solids and (or) droplets with a density greater or less than the density of the liquid enters the internal devices of the thin-layer sump and moves along the grooves 1. The denser particles settle and accumulate in the lower part of the grooves 1, the less dense particles - in the top of the grooves 1. The thickened suspension or emulsion through the gaps 3 between the walls of the channels 2 ends of the channels and the walls of the grooves 1 enters the channels 2 and due to the difference in density flows to the tops of the grooves 1 of the next layer of internal devices ostv. Further, the condensed emulsion or suspension can from the channels 2 get into the tops of the grooves 1 of the next layer, through the gaps 3 or directly into the channels 2 of the next rad. The thickened suspension or emulsion in the channels 2 moves across the main flow and there is no transfer along the flow. Next, the thickened suspension or emulsion is mixed with the suspension or emulsion, settled in the adjacent layer, and through channels 2 of the adjacent layer flows into the next layer. Thus, a dense condensed suspension or emulsion through channels 2 reaches the bottom of the apparatus, and the less dense top of the apparatus. The fact that the condensed emulsion or suspension is actually removed from each radar of the internal devices of the thin-layer clarifier makes it possible to practically exclude the repeated ingress of settled particles into the layer of purified liquid at the outlet of the internal devices. When moving in channels 2, the deposition rate of the particles is added up with the speed of movement of the thickened suspension itself. The fact that the internal devices for thin layer settlers can be installed layer by layer directly on top of each other eliminates the need for fixing devices or greatly simplifying their design. Due to the installation of internal devices with a small transverse displacement and the use of different numbers of grooves 1 in a layer, it is possible to completely fill an apparatus of circular cross section of any size and maximize the use of apparatus volume. The same type of internal devices can be installed in both horizontal and inclined sumps and used to separate emulsions and suspensions with particles more dense and less dense than liquid. Internal devices can be mounted through the manhole, including in existing devices. The design is collapsible, ease of assembly and disassembly facilitates maintenance and repair of the device.

Claims (4)

1. Internal device for thin sedimentation tanks, representing a system of alternating gutters with sloping walls and peaks facing up and down, characterized in that the tops of the grooves have channels located in the vertical plane in the direction transverse to the axis of the grooves, connecting the tops of the grooves with the tops of the grooves of the next layer, at the end of the channels between the walls of the channels and the walls of the grooves of the next layer there are gaps. 2. Internal device according to Claim. 1, characterized in that the walls of the channels touch the walls of the grooves of the next layer and support the next layer of internal devices. 3. Internal device according to any one of paragraphs. 1 or 2, characterized in that the system of grooves form a corrugated plate with longitudinal corrugations, and the channels are the nozzles installed in the tops of the corrugations. 4. Internal device according to any one of paragraphs. 1 or 2, characterized in that the gutters are assembled from inclined plates with vertically bent edges that form the walls of the channel, and the plates are interconnected by connecting elements that simultaneously provide the required distance between the walls of the channel and function as transverse to the channel gutters.

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