KR20240062294A - The smart system for sterilizing the sewage pumping station and reducing the bad smell of it - Google Patents

Abstract

The present invention discloses a smart system for sterilizing sewage pumping stations and reducing odor. Specifically, a sensing means installed inside the sewage pumping station to measure odor or harmful gas; A sterilization means installed inside the sewage pumping station to sterilize the wastewater within the sewage pumping station; A management server that receives the measured value detected by the sensing means through a wired or wireless network, monitors the status of each sewage pumping station, and operates the sterilization means through a wired or wireless network when the measured value is outside the range of a preset reference value. In the system for reducing harmful bacteria and odor at a sewage pumping station, the sterilizing means includes: a rectangular case; an ultraviolet lamp provided inside the case and emitting ultraviolet rays; a transparent quartz glass light transmitting plate that covers the front of the case and transmits ultraviolet rays emitted from the ultraviolet lamp; It is characterized by comprising a photocatalyst coated on the quartz glass light transmitting plate.

Description

Smart system for sterilizing the sewage pumping station and reducing the bad smell of it}

The present invention relates to a sewage pumping station sterilization and odor reduction system. Specifically, it detects various harmful bacteria generated in a sewage pumping station and the resulting odor, suppresses the growth of harmful bacteria and prevents corruption by using ultraviolet LEDs and photocatalysts. This is about a smart system for sterilizing sewage pumping stations and reducing odors that can reduce odors by doing so.

A sewage pumping station is a stopover and route where all kinds of wastewater collects before entering the sewage treatment plant.

As a result, various problems arise and are inherent in sewage pumping stations.

Sewage pumping stations are recognized as hotbeds where viruses and bacteria multiply and spread as suspended matter such as food and excrement mixed in wastewater decays, and foul odors and harmful gases are generated due to the decay.

These days, a healthy air environment is essential for comfortable residential facilities, but residential facilities and river trails are often painful due to foul odors still leaking from sewage pumping stations.

In particular, as accidents in which workers suffocate due to bad odors or harmful gases generated in sewage pumping plant-related workplaces occur, appropriate measures and accident prevention systems are needed.

There are approximately 2.2 million sewage pumping stations installed throughout Korea, but most of them are small pumping stations that are not equipped with actual deodorization facilities.

Various attempts have been made to reduce odor from sewage pumping stations.

For example, various technologies have been proposed, such as aeration method by injecting air into wastewater, decomposition and fermentation method using microorganisms, heating method, and sterilization method using ultraviolet lamps.

However, although these methods have pros and cons, they are only temporary and one-time processing methods, and active, intelligent, and smart processing methods are required.

Republic of Korea Patent Publication No. 10-2017-0108519 “BOD, nitrogen and odor reduction device for wastewater storage tank or aeration tank“ Republic of Korea registered patent 10-0991403 “Odor reduction wastewater treatment facility and method”

The purpose of the present invention to solve the above-mentioned problems is to provide a smart system for sterilizing sewage pumping stations and reducing odors that can detect and automatically sterilize various harmful gases and odors generated from sewage pumping stations.

Another object of the present invention is to perform powerful sterilization and air purification by irradiating an ultraviolet lamp through a quartz glass light transmitter coated with a photocatalyst to sterilize harmful bacteria, and to prevent a decrease in ultraviolet transmittance by allowing the quartz glass light transmitter to clean itself. The goal is to provide a smart system for sterilizing sewage pumping stations and reducing odor.

The smart system for sterilizing sewage pumping stations and reducing odor according to the present invention to achieve this purpose includes a sensing means installed inside the sewage pumping station to measure odor or harmful gases; A sterilization means installed inside the sewage pumping station to sterilize the wastewater within the sewage pumping station; A management server that receives the measured value detected by the sensing means through a wired or wireless network, monitors the status of each sewage pumping station, and operates the sterilization means through a wired or wireless network when the measured value is outside the range of a preset reference value. In the system for reducing harmful bacteria and odor at a sewage pumping station, the sterilizing means includes: a rectangular case; an ultraviolet lamp provided inside the case and emitting ultraviolet rays; a transparent quartz glass light transmitting plate that covers the front of the case and transmits ultraviolet rays emitted from the ultraviolet lamp; It may include a photocatalyst coated on the quartz glass light transmitting plate.

Here, it is preferable to use UV-C LED as the ultraviolet lamp.

In addition, the photocatalyst can be coated by making TiO ₂ in powder form into a coating sol, applying it to the entire surface of the quartz glass light transmitting plate, and baking it through drying and heat treatment.

In addition, a surveillance camera may be attached to the inside of the sewage pumping station to further include video means for capturing the internal environment or the worker's work status and transmitting the images to the management server.

In addition, the management server includes a receiving unit that receives measured value signals detected from the sensing means, a determining unit that compares the signals received from the receiving unit with a preset value and determines, and the determining unit determines whether the measured value signal is outside the preset value. If it is determined that the ultraviolet ray lamp of the sterilizing means operates through a wired or wireless network, it may be configured to include a transmitting unit that transmits and a display unit that displays image data transmitted from the imaging means.

According to the present invention described above, the following effects are achieved.

First, when the measured value of harmful gases or odors detected by the sensing means exceeds a certain concentration, the ultraviolet lamp is automatically activated to perform sterilization and air purification, thereby significantly reducing various harmful gases or odors generated at the sewage pumping station. there is.

Second, by coating the photocatalyst on the quartz glass light transmitting plate through which the ultraviolet lamp transmits light, powerful, environmentally friendly sterilization is possible, and the quartz glass light transmitting plate has the effect of self-cleaning contaminants, thereby preventing a decrease in ultraviolet light transmittance.

1 is a configuration diagram showing the overall configuration of a smart system for sterilizing a sewage pumping station and reducing odor according to an embodiment of the present invention.
Figure 2 is a perspective view showing the appearance of the sterilizing means of the present invention shown in Figure 1
Figure 3 is a cross-sectional perspective view of the sterilization means of the present invention shown in Figure 2
Figure 4 is a rear perspective view of the sterilization means of the present invention shown in Figure 2

Hereinafter, the examples of the present invention are provided for easier understanding of the present invention, and the scope of the present invention is not limited thereto. In other words, the following examples are provided to ensure that the disclosure of the present invention is complete and to fully inform those skilled in the art of the invention of the scope of the invention, and that the present invention is governed by the scope of the claims. It is only defined.

Additionally, the terms used in this specification are for describing embodiments and are not intended to limit the present invention. In this specification, singular forms also include plural forms unless specifically stated in the phrase. As used in the specification, “comprises” and/or “comprising” does not exclude the presence or addition of one or more other elements in addition to the mentioned elements.

Additionally, unless otherwise defined, all terms (including technical and scientific terms) used in this specification may be used with meanings that can be commonly understood by those skilled in the art to which the present invention pertains. Additionally, terms defined in commonly used dictionaries are not interpreted ideally or excessively unless clearly specifically defined.

Additionally, when describing the present invention, if it is determined that a detailed description of related known technology may unnecessarily obscure the gist of the present invention, the detailed description may be omitted.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the attached drawings.

Figure 1 is a configuration diagram showing the overall configuration of a smart system for sterilizing a sewage pumping station and reducing odor according to an embodiment of the present invention.

The present invention can be largely configured to include a sensing means 100, a sterilizing means 200, and a management server 400, and may further include an imaging means 300.

First, the sensing means 100 will be described.

The sensing means 100 is installed inside the sewage pumping station to detect various odors or harmful gases and measure the concentration.

The sensing means 100 may be a sensor that detects gas.

For example, one or more gas sensors (S) that detect carbon dioxide, carbon monoxide, hydrogen sulfide, methane, ammonia, etc. contained in harmful gases may be installed. At this time, it is desirable to provide separate gas sensors for each type of harmful gas.

In addition, an oxygen sensor that can detect oxygen concentration in real time can be installed to prevent workers from lacking oxygen while working.

Next, the core technical features of the present invention will be explained regarding the sterilization means (200).

The sterilizing means 200 is installed inside a sewage pumping plant to sterilize and reduce odor harmful gases filled in a closed space, or is installed to sterilize sewage by being immersed in sewage. The case 210 and ultraviolet rays are used to sterilize sewage. It can be implemented including a lamp 220, a quartz glass light transmitting plate 230, and a photocatalyst.

The case 210 has a rectangular frame shape, a hollow front frame 211, a rear plate 212 coupled to the front frame 211, and a plurality of heat dissipation fins 213 protruding from the rear plate 212. It can be composed of:

The ultraviolet lamp 220 is coupled to the inner surface of the back plate 212.

As is known, ultraviolet rays can sterilize microorganisms by destroying their protein cell walls, and are the most environmentally friendly of the existing sterilization methods.

In the present invention, it is preferable to use UV-C LED as the ultraviolet lamp 220.

UV-C LED emits ultraviolet wavelengths in the range of 200 to 280 nm, and the emitted wavelengths not only sterilize harmful gases, but also decompose organic matter in the water, fundamentally solving corruption and odor problems by removing viruses and bacteria. possible.

And UV-C LEDs are more efficient, have a longer lifespan, and are eco-friendly than existing UV mercury lamps, so they are used for air purification, water purification, and sterilization.

Additionally, the ultraviolet lamp 220 is further equipped with an inverter 221, which is a power supply module. The inverter 221 is coupled to the rear side of the ultraviolet lamp 220 and can be coupled with the heat dissipation fin 213 to dissipate heat.

The quartz glass light transmitting plate 230 is attached to the front frame 211 to protect the ultraviolet lamp 220 and at the same time transmit emitted ultraviolet rays.

The quartz glass light transmitting plate 230 is made of only quartz glass (SiO ₂ ), and is a material highly durable against acids or alkalis due to its very low thermal expansion coefficient and high ultraviolet ray transmittance.

However, in order to prevent the surface of quartz glass from becoming contaminated when exposed to sewage or harmful gases for a long period of time and reducing the amount of ultraviolet rays transmitted, and to sterilize and purify the air, in the present invention, the quartz glass transparent plate is coated with a photocatalyst.

The photocatalyst is an eco-friendly material that can safely decompose harmful substances by receiving light and promoting the chemical reaction of compounds attached to the surface.

In other words, when ultraviolet rays are irradiated to a photocatalyst coating made of titanium dioxide (TiO ₂ ), the holes from which electrons are released on the crystal surface react with water molecules to produce active oxygen, hydroxy radicals (hydroxide), and superoxide, which have strong oxidizing power. is created. These hydroxy radicals and superoxide decompose organic compounds and change them into carbon dioxide gas.

With this principle, organic compounds, which are contaminants in the air and water, are converted into harmless water and carbonic acid. Since they are organic compounds made of bacteria or viruses, they are decomposed by the strong oxidation effect of the photocatalyst, resulting in sterilization, deodorization, and antibacterial properties. This substance has a stronger oxidizing power than chlorine or ozone.

When the ox compound on the surface of titanium dioxide is exposed to light, it reacts with moisture in the air and converts to ?OH, becoming hydrophilic. It suppresses the surface tension of the water attached to the surface, so even if water droplets get on it, the water droplets spread immediately and a thin water film is created. do. Therefore, self-cleaning is possible, in which contaminants are removed by rainwater.

In the present invention, sterilization and odor reduction are activated by coating the quartz glass light transmitting plate 230 with a photocatalyst and irradiating ultraviolet rays from the ultraviolet lamp 220, and also using the hydrophilic function to By continuously removing adhering and sticking contaminants, the ultraviolet light transmittance can be prevented from being lowered.

The photocatalyst can be manufactured through various processes. In the present invention, powdered titanium dioxide (TiO ₂ ) is made into a coating sol, applied to the front of the quartz glass light transmitting plate 230, and heated to a certain temperature. It can be coated by removing moisture and performing heat treatment by applying a higher temperature.

The sterilizing means 200 described above may be operated manually by an operator, but is preferably operated by the management server 400, which will be described later.

For this purpose, an operating receiver (not shown) that receives signals from the management server 400 through a wired or wireless network may be installed in the inverter 221.

Holders 240 may be further provided on both sides of the case 210.

The holder 240 is roughly shaped like a 'ㄷ' and is rotatably attached to both sides of the case 210. The holder 240 can be fixed at a specific location within the sewage pumping station, and the case 210 can be rotated to irradiate ultraviolet rays at an appropriate point.

In the present invention, an imaging means 300 may be further provided within the sewage pumping station.

The video means 300 can be installed in the form of a surveillance camera or CCTV, and can capture images of the internal environment of the sewage pumping plant or the working status of workers and transmit them to the management server 400.

Next, the management server 400 will be described.

The management server 400 is a means for monitoring the situation in the sewage pumping station and controlling whether the sterilization means 200 operates, and includes a receiving unit 410, a determining unit 420, a transmitting unit 430, and a display unit 440. ), and may additionally include a deep learning unit 450.

The receiving unit 410 is connected to the sensing means 100 through a wired or wireless network, receives the measurement value signal measured by the sensing means 100, converts it into data, and stores it.

And the determination unit 420 determines the operation of the sterilizing means 200 by comparing and analyzing the measurement data received from the receiving unit 410.

To this end, when the measurement value measured by the sensing means 100 is greater than or equal to a preset reference value, a command may be issued to operate the ultraviolet lamp 220 of the sterilizing means 200.

If measurement values are received from a plurality of sensors, if any one measurement value is above the reference value, the sterilization means 200 can be operated unconditionally. Alternatively, if any two or more measurement values are above the reference value, the sterilization means is activated. The means 200 can be controlled to operate.

And after a certain period of time, the operation of the sterilizing means 200 can be stopped, or when the measurement value received from the receiver 410 falls below a certain value, the operation of the sterilizing means 200 can be stopped.

The transmitting unit 430 is connected to the sterilizing means 200 through a wired or wireless network, and when the determination unit 420 determines to operate the sterilizing means 200, it transmits a signal instructing the operation to the sterilizing means 200. do.

The display unit 440 is connected to the imaging unit 300 through a wired or wireless network and can receive images captured from the imaging unit 300 and display them to the manager.

Preferably, the management server 400 may further include a deep learning unit 450.

The deep learning unit 450 continuously learns the image data captured by the imaging means 300 and the measurement value data for each gas measured by the sensing means 100 to monitor the status of harmful gases by sewage pumping station location and time. The optimal sterilization time and method can be selectively applied to each sewage pumping station.

In addition, it learns the specific state of the worker to identify signs of accidents in advance and respond accordingly.

Although the present invention has been described above with reference to the drawings according to embodiments of the present invention, those skilled in the art will be able to make various applications and modifications within the scope of the present invention based on the above contents.

100: Sensing means
200: Sterilization means
210: Case 211: Front frame
212: back plate 213: heat dissipation fin
220: UV lamp 221: Inverter (stabilizer, power supply module)
230: Quartz glass floodlight panel 240: Holder
300: Video means
400: Management server 410: Receiving unit
420: Judgment unit 430: Transmitting unit
440: Display unit 450: Deep learning unit
S: sensor

Claims (5)

Sensing means installed inside the sewage pumping station to measure odor or harmful gases; A sterilization means installed inside the sewage pumping station to sterilize the wastewater within the sewage pumping station; A management server that receives the measured value detected by the sensing means through a wired or wireless network, monitors the status of each sewage pumping station, and operates the sterilization means through a wired or wireless network when the measured value is outside the range of a preset reference value. In the sewage pumping station harmful bacteria and odor reduction system,
The sterilization means is,
Square case;
an ultraviolet lamp provided inside the case and emitting ultraviolet rays;
a transparent quartz glass light transmitting plate that covers the front of the case and transmits ultraviolet rays emitted from the ultraviolet lamp;
A smart system for sterilizing sewage pumping stations and reducing odor, comprising a photocatalyst coated on the quartz glass light transmitting plate. According to claim 1,
A smart system for sterilizing sewage pumping stations and reducing odor, characterized in that the ultraviolet lamp is a UV-C LED. According to claim 1,
The photocatalyst is a smart system for sterilizing sewage pumping stations and reducing odor, characterized in that TiO ₂ in powder form is made into a coating sol, applied to the front of the quartz glass light transmitting plate, and then baked through drying and heat treatment to coat the photocatalyst. According to claim 1,
A smart system for sterilizing and reducing odor at a sewage pumping station, characterized in that a surveillance camera is attached to the inside of the sewage pumping station and further includes video means for filming the internal environment or the working state of workers and transmitting the images to the management server. According to claim 4,
The management server is,
A receiving unit that receives measured value signals detected from the sensing means, a determining unit that compares the signals received from the receiving unit with a preset value, and if the determining unit determines that the measured value is out of the preset value, the signal is measured through a wired or wireless network. A smart system for sterilizing a sewage pumping station and reducing odor, comprising a transmitting unit that transmits the ultraviolet lamp of the sterilizing means to operate and a display unit that displays image data transmitted from the imaging means.