CZ201477A3 - Self-cleaning tank - Google Patents

Abstract

The self-cleaning tank (1), for the continuous storage of cooling process water containing solids particles, composed of the bottom (2) and the peripheral wall (3) surrounding the floor plan (2) is provided with a liquid inlet (6) and a drain (5 ) a liquid, and further comprises a tangential chamber (13) with a liquid inlet (4) and a liquid outlet (7). The tangential chamber (13) is formed by tangent walls (14) tangentially connected to a plan view of the peripheral wall (3) at the vertical cutouts (10, 11) of the peripheral wall (3). In the tangential chamber there is means (16) for rotating the volume of stored cooling process water in the self-cleaning tank (1).

Description

Self-cleaning tank

Field of technology

The invention relates to a self-cleaning tank for the continuous storage of process cooling water supplied from machining tools of process equipment and containing waste in the form of solid particles from the processing or machining of materials having a specific gravity greater than the specific gravity of water, especially glass, ceramics and stone.

Prior art

At present, technological cooling water storage tanks for machining tools of technological equipment for processing glass, stone, ceramics and other materials are known, which have a plan view in the shape of a quadrangle, especially a rectangle, for effective use of the occupied floor area / volume ratio. Technological water containing material particles is fed into the tank. From this tank, water is pumped to the cleaning device and to the tool cooling system.

The disadvantages of the current solution are that the rectangular shape of the tank prevents sufficient movement of the entire volume of water in the tank and there is a gradual sedimentation of waste particles in the tank, which results in shutting down the work line due to the need to clean the tank. This leads to a loss of production time capacity of the technological equipment. If the tank was not cleaned regularly, the waste particles would sediment and the cooling lines leading to the water to the cutting tools would become clogged, the cutting tools would be damaged, or the products could be machined incorrectly.

The object of the invention is to provide a self-cleaning tank in which no sludge waste from solid material particles floated after machining into cooling process water, which could store cooling process water continuously, which is structurally simple and efficient, and which has low acquisition costs, does not sediment. and operating costs.

The essence of the invention

This object is achieved by providing a self-cleaning tank according to the invention.

The self-cleaning tank for continuous storage of cooling process water containing solid material particles consists of an impermeable bottom and a peripheral wall. The self-cleaning tank is provided with at least one liquid inlet and at least one liquid outlet connected to the technological device, at least one liquid inlet and at least one liquid outlet connected to the cleaning device. At the same time, each of the outlets is equipped with at least one pump.

The essence of the invention lies in the fact that the floor plan of the tank bottom is substantially circular in shape, to which belongs a circumferential wall having a tangential chamber outside the floor plan of the tank bottom. The tangential chamber is formed by two tangent walls arranged tangentially to the floor plan of the tank bottom and connected to each other at the top. At the same time, a dividing partition is formed on the circumference of the floor plan, which is arranged against the top of the tangential chamber. The dividing partition forms an outlet cut-out for the flow of liquid into the tangential chamber and an inlet cut-out for the flow of liquid into the self-cleaning tank, the inlet from the cleaning device and the outlet connected to the process equipment opening into the central area of the self-cleaning tank. they open into a tangential chamber, and at the same time the self-cleaning tank is provided with at least one means for rotating the volume of stored cooling process water in the self-cleaning tank.

It is advantageous that in the rotating volume of stored cooling process water, most solid material particles are concentrated by centrifugal force in a circumferential stream washing the circumferential wall of the tank, so relatively clean cooling process water can be pumped from the center of the self-cleaning tank and purified water fed from external cleaning station. In the tangential chamber, through which the circumferential current passes through the cut-outs of the circumferential wall, the polluted water is taken for cleaning and at the same time the polluted water from the technological device is returned to this tangential chamber without breaking the circumferential «·

current and the formation of disturbing vortices which would reduce the efficiency of the continuous entrainment of the solid particles contained.

In another preferred embodiment of the self-cleaning tank according to the invention, the means for rotating the volume of stored cooling process water is arranged in the tangential chamber region and is formed by a nozzle emerging from the pump, the outlet of which is directed parallel to the peripheral wall of the self-cleaning tank. The stream of water exiting the nozzle continuously supplies the necessary energy to create and maintain a peripheral stream of water. This keeps the peripheral speed of the current constant. The orientation of the nozzle allows the nozzle stream to merge seamlessly with the peripheral stream in the tank outside the tangential chamber, and thus no vortices are created which would disturb the rotation of the cooling process water volume.

In another preferred embodiment of the self-cleaning tank according to the invention, the floor plan of the bottom and the circumferential wall is divided into individual circular sections forming arcuate angles, the sizes of the vertical cut-outs and the dividing partition being determined by angles. When determining the size of the width of the vertical cut-outs of the perimeter wall, the size of the diameter of the self-cleaning tank does not matter, as the arc dimension is still the same.

In another preferred embodiment of the self-cleaning tank according to the invention, the pump for pumping cooling water to the cooling system of the process device is located in the middle of the self-cleaning tank. The pump for draining the contaminated cooling water to the treatment plant is located in the tangential chamber. The pumps are preferably arranged in areas of the self-cleaning tank where stored water with the required contamination parameters occurs, which the pumps are to extract from the self-cleaning tank.

In another preferred embodiment of the self-cleaning tank according to the invention, the apex of the tangential wall connection of the tangential chamber is provided with a rounding and the size of the angles defining the size of the cut-outs of the peripheral wall of the tank is equal. The most optimal for the peripheral flow of stored cooling process water are equally large cut-outs of the peripheral wall. The tank can then be used for both directions of rotation of the cooling water according to »

disposition of technological equipment. However, it is also possible to adjust the hydrodynamic conditions in the volume of stored cooling process water by changing the size of the self-cleaning tank for different requirements.

In another preferred embodiment of the self-cleaning tank according to the invention, the rotational speed of the volume of stored cooling process water is in the range from 0.5 to 2 m / s to achieve self-cleaning. The resulting speed of rotation of the cooling water is adjusted according to the ratio of the specific gravity of the material to the specific gravity of the water to separate the particles floated from the treatment.

In another preferred embodiment of the self-cleaning tank according to the invention, the size of the diameter of the bottom of the self-cleaning tank, which is controlled by the intensity of cooling water contamination, the size of the process equipment and the space available, is in the range from 1 iRff to 4 m.

In another preferred embodiment of the self-cleaning tank according to the invention, it is provided with a safety cover. The safety cover prevents personal injury or dropping objects into the tank, which would disrupt the smooth rotation of the stored water volume.

In another preferred embodiment of the self-cleaning tank according to the invention, the bottom and the wall of the self-cleaning tank are made of a material from the group of plastic, steel, stainless steel, being provided with a surface treatment from the group of varnish, laminate, rubberizing, etc.

The advantages of the self-cleaning tank according to the invention include almost zero sedimentation of solid material particles contained in process water, possibility of continuous operation with process equipment, low acquisition costs, easy operation, low operating costs, high quality of relatively clean water discharged into process equipment and safe operation of self-cleaning tank .

The invention will be further elucidated in the following figures, where Fig. 1 is a functional diagram of a self-cleaning tank and Fig. 2 is a plan view of a self-cleaning tank.

y

Example of an embodiment of the invention

It is to be understood that the specific embodiments of the invention described and illustrated below are presented by way of illustration and not by way of limitation. Those skilled in the art will find, or be able to ascertain using routine experimentation, a greater or lesser number of equivalents to the specific embodiments of the invention specifically described herein. These equivalents will also be included within the scope of the following claims.

Fig. 1 shows a diagram of a self-cleaning tank 1 and Fig. 2 shows a plan view of the same self-cleaning tank 1, which is used to store process water intended for cooling tools of technological equipment processing mainly stone, glass, ie generally materials having a specific mass greater than the specific gravity of water.

The bottom 2 and the wall 3 of the self-cleaning tank 1 are made of stainless steel. The diameter of the self-cleaning tank 1 is 2000 mm and its depth is 250 mm. In the middle of the self-cleaning tank 1 there is a pump 8, which discharges its discharge to a drain 5 of clean water with a low solids content, which is connected to various technological devices (cutters, grinders, etc.) that need this water for trouble-free operation. At the center of the self-cleaning tank, an inlet 6 of purified water also opens, which is returned to the self-cleaning tank 1 from an external cleaning device. The self-cleaning tank 1 is provided with a plastic cover.

The self-cleaning tank 1 is provided on the circumference with a tangential chamber 13. The tangential chamber 13 is formed by tangent walls 14 which run tangentially to the plan view of the circumferential wall 3. The tangent walls 14 intersect to form an apex 15 which is better for tangential properties inside the tangential chamber 13. rounded. The tangential chamber 13 is separated by a dividing partition 12, into which it emerges from the self-cleaning tank

through the outlet cut-out 10 of the circumferential wall 3 a stream of rotating volume of stored water. In the tangential chamber 13 there is a pump 9 with a drain 7 of polluted water to an external purification device and a supply 4 of polluted water from the technological device.

In the direction of the circumferential flow, a means 16 - a nozzle for rotating the volume of the stored cooling water is arranged in the tangential chamber 13 at the inlet cut-out 11 of the circumferential wall 3. The nozzle is supplied with water in part from the discharge of the dirty water pump 9 and is fixed in the self-cleaning tank 1 so that its outlet flow is parallel to the circumferential wall 3 of the self-cleaning tank 1.

The volume of stored water rotates in the self-cleaning tank 1 at a peripheral speed of 1 m / s and thus of glass or stone particles with a specific weight approximately 2.5 times higher than the specific weight of the water contained in. water, are grouped by centrifugal force at the wall 3 of the self-cleaning tank 1, where they are entrained in the stream until they are sucked with water by the pump 9 into the dirty water outlet 7.

There is a minimum of solid material particles in the central area of the self-cleaning tank 1, so that the cooling water stored in the central area of the self-cleaning tank 1 can be considered clean and this process water is not harmful for use in associated process equipment.

The size of the cut-outs 10 and TI of the circumferential wall 3 of the self-cleaning tank 1 and the dividing partition 12 can be determined according to the size of the angle g, β, γ of individual circular segments, the apex of which lies in the center of the tank 1. units of length. In the exemplary embodiment, the size of the angles α and β is 26 °, so that the size of the width of the slots 10 and 11 is 449 mm.

Industrial applicability

The self-cleaning tank according to the invention can be used in plants where process water is used for cooling the processed materials. During the processing of the material, before being returned to the storage tank, the water floats solid waste particles which do not settle in the self-cleaning tank, and thus the self-cleaning tank can be used continuously. The operation of the technological equipment does not stop due to tank cleaning.

Overview of reference marks self-cleaning tank impermeable bottom self-cleaning tanks perimeter wall self-cleaning tanks coolant supply from technological equipment coolant discharge to process equipment supply of cleaned liquid from cleaning equipment equipment perimeter wall outlet cut-out perimeter wall inlet cut-out dividing partition between self-cleaning tank and tangential chamber tangential chamber tangent wall top of tangential chamber tangential wall interconnection means (nozzle) for rotating stored cooling water volume and circular section angle for determining perimeter wall outlet size circular sections for determining the size of the inlet cut-out of the circumferential wall Y angle of the circular section for determining the size of the dividing partition

Claims (9)

A self-cleaning tank (1) for the continuous storage of cooling process water containing solid material particles consisting of an impermeable bottom (2) and a peripheral wall (3) is provided with at least one liquid inlet (4) and at least one liquid outlet (5) connected to technological device, at least one liquid inlet (6) and at least one liquid outlet (7) connected to the cleaning device, each of the outlets (5, 7) being provided with at least one pump (8, 9), characterized in that the floor plan of the bottom (2) of the tank (1) is substantially circular in shape, to which belongs a circumferential wall (3) having a tangential chamber (13) outside the floor plan of the bottom (2) of the tank (1) formed by two tangent walls (14) arranged tangential to the floor plan. bottoms (2) of the tank (1) and interconnected at the top (15), on the circumference of the floor plan of the bottom (2) a dividing partition (12) is formed arranged against the top (15) of the tangential chamber (13), which forms the outlet cutout (10) for the flow of liquid into the tangential chamber (13) and the inlet part ez (11) for the flow of liquid into the self-cleaning tank (1), wherein the inlet (6) and the outlet (5) open into the central region of the self-cleaning tank (1), and the inlet (4) and the outlet (7) open into the tangential chamber (13), and at the same time the self-cleaning tank (1) is provided with at least one means (16) for rotating the volume of stored cooling process water in the self-cleaning tank (1). Self-cleaning tank according to claim 1, characterized in that the means (16) for rotating the volume of stored cooling process water is arranged in the region of the tangential chamber (13) and is formed by a nozzle emerging from the pump (9). the outlet of which is directed parallel to the circumferential wall (3) of the self-cleaning tank (1) in the direction from the tangential chamber (13) to the self-cleaning tank (1). Self-cleaning tank according to claim 2, characterized in that the floor plan of the bottom (2) and the peripheral wall (3) is divided into individual circular segments forming angles (α, β, y), the size of the outlet the cut-out (10) of the circumferential wall (3) is determined by the arcuate angle (α), the size of the inlet cut-out (11) of the circumferential wall (3) is determined by the arcuate angle (β) and the size of the partition (12) is determined by the magnitude of the angle (y). «I 9 -» Self-cleaning tank according to at least one of Claims 1 to 3, characterized in that the drain pump (8) is arranged in the center of the self-cleaning tank (1) and the drain pump (9) is arranged in the tangential chamber (7). 13). Self-cleaning tank according to at least one of Claims 1 to 4, characterized in that the apex (15) of the tangent wall (14) of the tangential chamber (13) is provided with a rounding and the size of the angles (α, β) defining the size of the slots (10, 11) the perimeter wall (3) is equal. Self-cleaning tank according to claim 2, characterized in that the speed of rotation of the volume of stored cooling process water is in the range from 0.5 to 2 m / s. Self-cleaning tank according to at least one of Claims 1 to 6, characterized in that the size of the diameter of the bottom (2) of the self-cleaning tank (1) is in the range from 1 M to 4 m. Self-cleaning tank according to at least one of Claims 1 to 7, characterized in that it is provided with a safety cover. Self-cleaning tank according to at least one of Claims 1 to 8, characterized in that the bottom (2) and the wall (3) of the self-cleaning tank (1) are made of a material from the group consisting of plastic, steel and stainless steel. by treatment from the group varnish, laminate, or rubber coating.