RU54371U1 - DEVICE FOR WASTE WATER DISINFECTION (OPTIONS) - Google Patents

Abstract

The device for disinfecting wastewater according to the first embodiment contains a cavitation generator (3) installed on the pressure pipe of the fluid to be treated (1) behind the hydraulic pump (2), the outlet of which is connected to an intermediate tank (5), the cavity of which communicates with the entrance to the hydraulic pump ( 2), a pipeline for draining the treated liquid (6) and shut-off and control valves (4), (7). To increase the efficiency of disinfection, reduce processing time and simplify the design of the device, the cavitation generator (3) is made in the form of a channel formed at the inlet by a confuser (8), turning into a swirling device (9), which can be made in the form of a snail (10) with a tangential exit to the working chamber (11), at the exit of which a rectifying lattice (12) is installed. The straightening grating (12) can be made in the form of plates (13) parallel to the axis of the working chamber (11), and the cavitation generator (3) can be closed by a casing (14) forming an external flow path, the input (15) of which is connected to exit from the hydraulic pump (2), and exit (16) - with the entrance to the confuser (8). According to the second variant, a cavitation generator (3) installed on the processed fluid supply pipe (1) behind the hydraulic pump (2) is connected through a two-way valve (4) to the return pipe (18) of the processed fluid to the hydraulic pump inlet (2) and to the pipeline (6) draining the treated liquid. The return pipe (18) can be made in the form of a coil (19) enclosed in a casing (20) with the formation of a heat exchanger (21), which allows to increase the degree of disinfection and reduce processing time.

Description

The inventive utility model (its variants) relates to installations for wastewater treatment and can be used for disinfection of domestic and industrial effluents, as well as for water purification in utilities and in various industries.

There are many known methods of disinfection of wastewater based on physical, chemical and biological effects on wastewater.

So, along with quite effective, but energy-intensive methods of exposure to the treated fluid by electric fields [1], low-temperature plasma [2], disinfection units are also known in which the treated fluid is subjected to mechanical vibrations, in particular, ultrasonic and / or cavitation [3] , [four].

These installations are simple and less energy intensive.

A device for disinfecting wastewater containing a cavitation generator installed on a pressure line for supplying a process fluid behind a hydraulic pump, the outlet of which is connected to intermediate tanks, the cavity of each of which is connected to the inlet of the hydraulic pump, a treated liquid drain pipe and shut-off and control valves [5] .

In this known device, which can be taken as a prototype, the cavitation generator is made in the form of a venturi, which does not allow to achieve high disinfection efficiency, despite the installation of an additional cavitation generator in front of the hydraulic pump. This is explained by the instability of the cavity forming in the venturi due to

which is not affected by the entire flow of fluid passing through the cavitation generator. To ensure the necessary level of disinfection, it is necessary to repeatedly pass the processed fluid accumulated in the intermediate tanks through cavitation generators, which significantly increases the processing time. In addition, the installation of a cavitation generator in front of the hydraulic pump worsens the operation of the latter and reduces its resource.

The technical result that can be achieved by using the claimed utility model (its variants) is to increase the efficiency of wastewater disinfection, reduce processing time, simplify the design of the device and increase the reliability of its operation.

To achieve this result, in the first embodiment of the device for disinfection of wastewater containing a cavitation generator installed on the pressure line of the processed fluid supply behind the hydraulic pump, the outlet of which is connected to at least one intermediate tank, the cavity of which is connected to the inlet of the hydraulic pump, the treated drain pipe liquids and shut-off and control valves, it is proposed to perform a cavitation generator in the form of a channel formed at the inlet by a confuser, passing into a swirling apparatus with a tangential exit into the working chamber of a cylindrical shape, at the exit of which a straightening grating is installed.

To increase the efficiency of liquid disinfection due to its heating by the heat released in the working chamber of the cavitation generator, the cavitation generator can be equipped with a casing forming an external flow circuit, the inlet of which is connected to the outlet of the hydraulic pump, and the outlet - to the inlet to the confuser.

The spinning apparatus of the cavitation generator can be made in the form of a cochlea, and the straightening lattice can be made in the form

intersecting plates, the plane of which is parallel to the axis of the working chamber.

In the second embodiment of the device for disinfecting wastewater, comprising a cavitation generator installed on the processed fluid supply line behind the hydraulic pump, made as in the first embodiment, and a processed fluid draining pipeline, it is proposed to install a two-way valve at the outlet of the cavitation generator, which communicates the cavitation generator with the pipeline return of the treated fluid to the inlet to the hydraulic pump and with the discharge pipe of the treated fluid, which allows to increase effectively be decontamination and reduce processing time by reducing the degree of contamination of the treated fluid by repeated cycle of its processing residues wastewater passed through the device in the previous cycle.

For utilization of heat generated during liquid processing, the return pipeline can be made in the form of a coil enclosed in a casing forming a heat exchange chamber.

Embodiments of the utility model are illustrated in the accompanying drawings.

Figure 1 presents a diagram of a device in the first embodiment.

Figure 2 shows a cavitation generator, side view.

In Fig.3, section AA in Fig.3.

Figure 4 is a diagram of a device for disinfection according to the second embodiment.

The device for disinfecting wastewater contains a pipeline for supplying the treated fluid 1, on the pressure section of which a cavitation generator 3 is installed behind the hydraulic pump 2.

The exit from the cavitation generator 3 is connected through a multi-way valve 4 to the intermediate tanks 5 and to the discharge pipe 6 of the treated liquid.

Intermediate tanks 5 communicate through a multi-way valve 7 with the entrance to the hydraulic pump 2.

The cavitation generator 3 is made in the form of a channel (see Fig. 2), formed at the inlet by a confuser 8, turning into a swirling apparatus 9, which can be made in the form of a cochlea with a spiral channel 10 tangentially emerging into the working chamber 11 of a cylindrical shape.

At the exit of the working chamber 11, a rectifying lattice 12 is installed, which can be made in the form of plates 13 intersecting each other, the plane of which is parallel to the axis of the working chamber 11.

The cavitation generator 3 can be equipped with a casing 14 (Fig. 1), forming an external flow path, the input 15 of which is connected to the outlet of the hydraulic pump 2, and the output 16 is connected to the entrance to the confuser 8.

The device operates as follows.

The wastewater to be disinfected is piped 1 through a hydraulic pump 2 to a cavitation generator 3. In the confuser 8, the liquid accelerates and enters the swirling apparatus 9. The flow swirling in the spiral channel 10 tangentially enters the working chamber 11, where the pressure in the accelerated and swirling flow drops sharply to critical, leading to the occurrence of hydrodynamic cavitation. The flow parameters (velocity, pressure, swirl) provide stable volumetric cavitation in the zone 17, which occupies almost the entire cross section of the working chamber 11 in front of the straightening grating 12, with the formation of a low-temperature plasma in this zone. The combined effect of the factors accompanying this process (dynamic shock loads, radiation and high temperature) leads to the destruction of the shells of bacteria, viruses, helminths and other pathogenic microorganisms and to their death.

If the degree of pollution of wastewater by pathogenic flora and helminth eggs is insignificant, then their treatment can be carried out in

continuous operation, and after passing through the cavitation generator, the treated liquid enters the discharge pipe 6.

With a high degree of contamination of effluents, despite the high disinfection efficiency (up to 99%), the treatment is carried out in a cyclic mode. Having passed the cavitation generator 3, the liquid is supplied to one of the intermediate containers 5 and, after filling it, by switching the valve 7, the treated liquid is fed by the hydraulic pump 2 to the cavitation generator for reprocessing.

This process can be repeated several times, using one or two intermediate containers 5 until the desired degree of disinfection is achieved, after which the liquid is drained through line 6.

In the second embodiment of the device for disinfection (Fig. 4), a cavitation generator 3 is also installed on the pipeline for supplying the treated liquid 1 behind the hydraulic pump 2, and the outlet from it is connected through a two-way valve 4 to the pipeline for draining the treated liquid 6 and to the pipeline 18 for returning the treated liquid in the hydraulic pump 2. The pipe 18 return of the processed fluid can be made in the form of a coil 19, which can be enclosed in a casing 20, forming a heat exchanger 21.

In this embodiment, if it is necessary to re-treat the effluents, the liquid after the cavitation generator 3 enters the return pipe 18 and through the two-way valve 7 to the inlet of the hydraulic pump 2. Heat recovery in this scheme is carried out by performing the pipe 18 in the form of a coil 19 enclosed in a casing 20 with the formation heat exchanger 21, the coolant in which can be any liquid, including treated effluents.

The absence in this embodiment of intermediate containers 5 and a flow path formed by the casing 14 around the cavitation generator 3, reducing the amount of liquid processed in one cycle, can increase the efficiency of disinfection and reduce processing time due to

reducing the degree of contamination of the treated liquid during the second cycle of its treatment with wastewater residues (in the flow path under the casing 14 and in the intermediate tank 5) passed through them in the previous cycle (i.e., by reducing the mixing of the residues of untreated effluents with the treated liquid) .

The claimed variants of the utility model are simple, reliable in operation and provide a high degree of disinfection of wastewater (> 99%) at low energy costs - only on the drive of the hydraulic pump 2.

Information sources:

[1] RU, from US Pat. No. 2088536, C 02 F 1/30, 1997

[2] RU Pat. No. 2129991, C 02 F 1/30, 1999

[3] WO 00/07941 C 02 F 1/36

[4] WO 94/13587, C 02 F 1/34, 1993

[5] RU Pat. No. 2057079, C 02 F 1/34, 1996

Claims (7)

1. A device for disinfecting wastewater, comprising a cavitation generator installed on the pressure line of the treated fluid supply behind the hydraulic pump, the outlet of which is connected to at least one intermediate tank, the cavity of which communicates with the inlet of the hydraulic pump, the treated fluid drain pipe and a shut-off and control valve armature, characterized in that the cavitation generator is made in the form of a channel formed at the inlet by a confuser, turning into a swirling device with a tangential exit to the slave I perceive a cylindrical chamber, at the exit of which a straightening grating is installed. 2. The device according to claim 1, characterized in that the cavitation generator is equipped with a casing forming an external flow path, the entrance to which is connected to the outlet of the hydraulic pump, and the output to the entrance to the confuser. 3. The device according to claim 1, characterized in that the straightening lattice is made in the form of plates intersecting each other, the planes of which are parallel to the axis of the working chamber. 4. The device according to claim 1, characterized in that the twisting apparatus is made in the form of a snail. 5. A wastewater disinfection device comprising a cavitation generator installed on the processed fluid supply line behind the hydraulic pump and a processed fluid discharge pipe, characterized in that a two-way valve is installed at the outlet of the cavitation generator, communicating the cavitation generator with the processed fluid return pipe to the hydraulic pump inlet and with a pipeline for draining the treated liquid. 6. The device according to claim 5, characterized in that the return pipe of the processed fluid is made in the form of a coil. 7. The device according to claim 6, characterized in that the coil is enclosed in a casing forming a heat exchanger chamber.