SU1678769A1 - Bactericidal apparatus - Google Patents

Abstract

This invention relates to a process for the purification of natural and waste waters, and may be applied in public utilities. medicine, food industry, as well as transport, for example, on sea vessels, and it allows to improve the quality of water disinfection. The bactericidal apparatus comprises a housing 1 and a bactericidal lamp 2 of ultraviolet radiation. In this case, the apparatus 1 is made in the form of an air bell. It houses a pressure sensor 4 connected to the upper part of the cavity of the housing 1, and nozzles 6 and 7 for supplying and discharging water are located below the pressure sensor 4 and are spaced apart in height. A pump 9 is connected to the water inlet 6, the actuator 10 of which is operatively connected to the pressure sensor 4. 1 il.

Description

This invention relates to a technology for disinfecting natural and waste waters and can be used in public utilities, medicine, the food industry and other industries.

The aim of the invention is to improve the quality of water disinfection due to the utilization of the ozone produced.

The drawing shows a block diagram of a bactericidal device.

The bactericidal apparatus comprises a vertical cylindrical housing 1 and a bactericidal ultraviolet radiation lamp 2 coaxially mounted in the housing. The case 1 is made in the form of an air bell: its front part (hemisphere 3) is permanently connected to the cylindrical shell of the case. On the upper part of the bell there is a pressure sensor 4, which with

The tube 5 is connected to the cavity of the housing 1. Below the pressure sensor 4 on the housing, tangentially to the wall is placed a pipe 6 for supplying water and a pipe 7 for draining water, with the pipes spaced apart in height from one another to another by distance Hi. A pump 9 is connected to the nozzle 6 by means of a pipe and a non-returnable check valve 8, the actuator 10 of which is functionally connected (for example, by means of an electric circuit 11) to a pressure sensor 4. The pressure sensor 4 (for example, a pressure switch) is selected so that it can be adjusted (for example, using settings) to operate at maximum Pmax and minimum Pmin air pressure in the apparatus body.

Bactericidal lamp 2 is protected from water by a transparent (for example, quartz) cover-bulb 12.

h

The output end of the bulb 12 is hermetically sealed in the cap 13 with the help of a rubber weel 14. The cap 13 is hermetically fastened to the body of the apparatus by means of a flange connection. The lamp 2 is powered from the electrical network through the cable 15 and the control gear (not shown).

Bactericidal apparatus works as follows.

From the power supply through the control gear, the lamp is energized and lights up. Begin charging apparatus. For this, the apparatus is disconnected from the distribution network by closing the valve in the distribution pipeline (not shown in the drawing). Pressure sensor A is adjusted so that at Pmin the water level in the body is H2, and at pressure Pmax it is not.

The values of H2 and Hz are chosen from the ratio

,

VCp

where VCp is the average linear velocity of the water rise in the body of the apparatus when filling is ei;

F is a bactericidal flux emitted by an ultraviolet (UV) lamp (according to passport data);

D is the dose of UV irradiation, the minimum required for water disinfection.

Manually (using a magnetic starter) turn on pump 9, begins tangential (tangential to the housing wall) water supply to the housing through pipe 6. At the same time, the very first portions of water are affected by two bactericidal factors — UV rays and ozone, almost immediately from the air when the lamp ignites. As the water level in the housing rises, the air pressure above the water surface increases and, according to Henry's law, the process of dissolving the ozone-air mixture in water intensifies. When the air pressure rises to Pmax, sensor 4 is activated and the pump is turned off. The charger of the device is finished, it is ready for. dispensing of disinfected water to consumers

At the request of consumers, the issuance of water from the apparatus can be periodic or continuous. To do this, the consumer only needs to open the valve in the dispensing pipeline. Immediately, the water supply from the apparatus through the nozzle begins. 7. At the same time, the water level in the housing and, accordingly, the air pressure begin to decrease until the level reaches the level of H2, corresponding to Pmin.

10, the pump 9 starts again to feed water into the housing. Further, the duty cycle is repeated.

When the water level drops and the air pressure in the casing intensively goes, as it were, water deaeration, just as in a glass

0 water collected from the tap accumulates gas. Deaeration provides accumulation of ozone in the housing, which is necessary to process the next portion of water supplied during recharge.

5 When the water level rises and, accordingly, the air pressure is intensively reversed, the absorption (dissolution) of gases (oxygen and ozone) in water, i.e. aeration And this process can go

0 up to the complete saturation of water with oxygen and ozone, which explains the higher quality of water treatment in the proposed apparatus as compared with the known one.

5 It is also significant that the nozzles 6 and 7 are spaced apart in height. Due to this, the situation is excluded when the first, raw portion of water that has just come into the apparatus can get into the outlet nozzle, i.e. to the consumer.

If the consumer no longer needs water, he closes the valve in the pipeline. At the same time, whenever water is required, the device is ready for operation. Enough

5 just to reopen the valve on the water distribution pipeline.

Claims (1)

Bactericidal apparatus comprising a vertical cylindrical body with 0 nozzles for supplying and discharging water and a bactericidal ultraviolet lamp, coaxially installed in the housing, characterized in that, in order to improve the quality of the disinfection 5 or water due to the utilization of the ozone produced, it additionally contains a pressure sensor and a pump with a drive, while the apparatus body made in the form of a bell, the pressure sensor is placed at the top On it, parts of the housing cavity, branch pipes for inlet and outlet are located below the pressure sensor and are spaced apart in height relative to each other, and the pump drive is functionally connected to the sensor 5 pressure. Input 8y Exit dod /