KR102614898B1 - Deodorization system that discharges residual ozone using a discharge fan to prevent backflow of ozone - Google Patents

Abstract

The present invention relates to a deodorizing system that discharges residual ozone using an exhaust fan to prevent ozone backflow (indoor entry).
Accordingly, the technical gist of the present invention is a utilization invention of Patent Registration No. 10-2553178, and when the exhaust blowing fan is turned on, pollutant airflow such as odor (food smoke, excrement gas, harmful gas, toxic gas, etc. due to cooking) is removed. When the air is exhausted through the duct, the backflow prevention damper is opened by the airflow detection sensor and the ozone generator's discharge fan causes ozone to be sprayed toward the duct (backflow prevention damper + ozone generator + exhaust fan linked operation method when the exhaust blowing fan is driven). However, when the operation of the exhaust blowing fan is stopped (OFF), the operation of the ozone generating discharge pipe is simultaneously stopped (ozone generator interlocking stop), and then the backflow prevention damper and ozone discharge fan operate each valve and blade for a certain period of time ( Several seconds to several minutes (e.g., 1 to 5 minutes) while the ozone generator enclosure is kept open or rotated continuously, the ozone remaining in the ozone generator enclosure is discharged or sprayed into the duct, which prevents the residual ozone from flowing back into the room. It is characterized by preventing harmful ozone from entering the indoor residential environment by fundamentally preventing it.
This invention is directed to pollutants that generate odor (e.g., when cooking food in restaurant kitchens or livestock farms, wastewater sewage treatment plants, food waste treatment plants, department stores, outlets, hospitals, resorts, schools, etc., multiple public facilities, purification facilities requiring sewage treatment, and recycling). It is installed in all facilities that generate bad odors, such as screening facilities, and promotes sterilization while removing bad odors or harmful gases (toxic gases).

Description

Deodorization system that discharges residual ozone using a discharge fan to prevent backflow of ozone}

This invention is an invention using Patent Registration No. 10-2553178 (name: deodorizing system equipped with an ozone reactor for inducing air flow retention/patent registered by the applicant), which causes pollutants such as odor when the exhaust blowing fan is turned on (ON). When airflow (food smoke from cooking, excrement gas, harmful gas, toxic gas, etc.) is exhausted through the duct, the backflow prevention damper is opened by the airflow detection sensor, causing the ozone generator's exhaust fan to spray ozone toward the duct ( When the exhaust blowing fan is driven, the backflow prevention damper + ozone generator + exhaust fan interlocked operation method), but when the exhaust blowing fan is stopped (OFF), the operation of the ozone generating discharge pipe is simultaneously stopped (ozone generator interlocked stop), Afterwards, the backflow prevention damper and ozone discharge fan allow each valve and blade to remain open or rotate for a certain period of time (several seconds to several minutes: e.g., 1 to 5 minutes) to remove the ozone remaining in the ozone generator enclosure. It is discharged or sprayed into this duct, which fundamentally prevents residual ozone from flowing back into the room, and is equipped with an exhaust fan to prevent ozone backflow (inflow into the room), which prevents harmful ozone from flowing into the indoor residential environment. It relates to a deodorization system that discharges residual ozone.

Generally, a deodorizer is designed to remove odors from pollutants (odors, harmful gases, toxic gases, etc.) and then discharge them to the outside.

These odor-causing substances are generated from various sources. They may be generated when cooking food in a restaurant kitchen, food waste treatment facilities, recycling waste treatment facilities, sewage treatment plants, excrement or livestock wastewater treatment plants, landfills, compost factories, and chemical plants. , it is occurring throughout various manufacturing industries, including food production plants, and other regenerative industries.

These odors are unpleasant odors and are gases that irritate the nervous system. Specifically, they include ammonia (NH3), methyl mercaptan (CH3SH), hydrogen sulfide (H2S), methyl sulfide ((CH3)2S), and methyl disulfide ( (CH3)2S2), trimethylamine ((CH3)3N), acetaldehyde (CH3CHO), styrene (C6H5CH=CH2), and volatile organic compounds (VOCs) are designated as odor-causing substances.

The odor generated in this way causes environmental pollution in the surrounding area, leading to constant civil complaints, and an effective solution to the odor problem is required.

Meanwhile, in order to solve the above problems, the applicant of this application developed and registered a patent for a deodorizing system equipped with an ozone reactor for inducing air flow retention (Patent Registration No. 10-2553178 / Applicant: Yuseong Enbitec Co., Ltd. - referred to as a prior patent) there is.

This prior patent is installed at a pollutant that generates odor to remove and sterilize the generated odor or harmful gas (toxic gas). A deodorizer with an ozone generator and an ozone reactor for inducing air flow retention are provided in the duct path. The main technical point is to further strengthen deodorization (air purification) and sterilization performance by ensuring that ozone is mixed smoothly for a certain period of time with respect to the airflow being transported through the duct.

In this prior patent, when the exhaust blower is operated, the backflow prevention damper is automatically linked by the airflow detection sensor, and the ozone generating discharge pipe and the ozone discharge fan are operated simultaneously so that ozone can be sprayed and discharged into the duct.

However, when the power is turned off upon completion of use of the deodorizer, the exhaust blower stops, and the exhaust fan (or motor fan: provided on the ozone generator side) that sends ozone to the exhaust duct, the ozone generation discharge pipe, and the backflow prevention damper also stop, causing residual ozone to be released. It remains inside the ozone generator container (box), which causes residual ozone to flow back into the room, exposing residents to a harmful environment.

1. Republic of Korea Patent No. 10-0981349 (registered on September 3, 2010)

The present invention is intended to solve the above-mentioned problems, and its technical gist is that when the exhaust blowing fan is turned on, pollutant airflow such as odor (food smoke from cooking, excrement gas, harmful gas, toxic gas, etc.) is blown through the duct. When the air is exhausted, the backflow prevention damper is opened by the airflow detection sensor, causing the ozone generator's exhaust fan to spray ozone toward the duct (backflow prevention damper + ozone generator + exhaust fan interlocked operation method when the exhaust blowing fan is driven). When the operation of the exhaust blowing fan is stopped (OFF), the operation of the ozone generating discharge tube is simultaneously stopped (ozone generator interlocking stop), and then the backflow prevention damper and ozone discharge fan operate each valve and blade for a certain period of time (several seconds). to several minutes (e.g., 1 to 5 minutes) while the ozone generator enclosure is kept open or rotated continuously, the ozone remaining in the ozone generator enclosure is discharged or sprayed into the duct, preventing residual ozone from flowing back into the room. The purpose is to prevent harmful ozone from entering the indoor residential environment.

In order to achieve this purpose, the present invention provides that a hood-type collector (110) is installed in the area where the pollution source is generated, and the hood-type collector (110) is operated by an exhaust blower fan (130) connected to the conduit-type duct (120). An exhaust equipment (100) for outdoor exhaust; It is placed on one side of the path of the duct 120 so that the ozone generator enclosure communicates with it through the connection pipe 210, and an ozone generation discharge tube 220 with an airflow detection sensor 221 is provided inside the enclosure to form the duct 120. When the internal exhaust air flow is detected, the ozone generation discharge tube 220 is driven to generate ozone, and an ozone discharge fan 230 and a backflow prevention damper 240 of a simultaneous interlocking structure are provided on one side of the ozone generation discharge tube 220. an ozone generator 200 that blows ozone into the pollutant airflow rising through the duct 120 to deodorize the exhausting airflow; When the exhaust blowing fan 120 is stopped, the operation of the ozone generating discharge tube 220 is stopped at the same time, and then the backflow prevention damper 240 and the ozone discharge fan 230 operate each valve and blade for a certain period of time (several seconds). to several minutes: for example, about 1 to 5 minutes) A control unit 300 for forced exhaustion of residual ozone that allows the ozone remaining in the ozone generator enclosure to be discharged or sprayed toward the duct while the opening is maintained or rotation is continued; It is composed and made.

For reference, during normal operation (ON), when the exhaust blower fan is activated, the backflow prevention damper is automatically opened by the airflow detection sensor, the ozone generation discharge pipe is activated, and the ozone discharge fan rotates interlocked to exhaust ozone to the duct. is formed

Accordingly, the duct 120 is further provided with an interlocking damper 400 at the lower part of the longitudinal line connected to the connector 210, so that when the exhaust blowing fan 130 is operated, the interlocking damper 400 opens, and the exhaust blows. When the operation of the fan 130 is stopped, the interlocking damper 400 is stopped and is formed to block the backflow of ozone toward the odor emission source (indoor direction).

In addition, a guide plate 500 is further provided at the end of the connection pipe 210 connected to the duct 120 (part in contact with the duct) to prevent the downward flow of ozone airflow and to induce an upward flow.

At this time, the guide plate 500 is formed so that the end portion 510 facing the duct 120 has an upward slope based on the connector 210 coupled in a direction perpendicular to the duct 120, thereby maintaining the upward airflow of ozone. It is formed to prevent it from going down toward the interior, which is the source of odor emissions.

Accordingly, the ozone discharge fan 230 is equipped with a funnel-shaped booster cone 600 at the end of the discharge port so that the ozone generated within the ozone generator enclosure can be sprayed more quickly toward the duct.

As such, the present invention prevents backflow by using an airflow detection sensor when pollutant airflow such as odor (food smoke from cooking, excrement gas, harmful gas, toxic gas, etc.) is exhausted through the duct when the exhaust blowing fan is turned on (ON). As the damper opens, the exhaust fan of the ozone generator causes ozone to be sprayed toward the duct (backflow prevention damper + ozone generator + exhaust fan linked operation method when the exhaust blowing fan is driven), but the operation of the exhaust blowing fan is stopped (OFF). When this occurs, the operation of the ozone generating discharge tube is simultaneously stopped (ozone generator interlocking stop), and then the backflow prevention damper and ozone discharge fan operate each valve and blade for a certain period of time (several seconds to several minutes: for example, 1 minute to 5 minutes). minutes) It has the effect of allowing the ozone remaining in the ozone generator enclosure to be discharged or sprayed into the duct while the opening is maintained or the rotation continues.

This treatment fundamentally prevents residual ozone from flowing back into the room, thereby preventing harmful ozone from entering the indoor residential environment.

In addition, the present invention covers pollutants that generate bad odors (multiple public facilities such as restaurant kitchens when food is cooked or livestock farms, wastewater sewage treatment plants, food waste treatment plants, department stores, outlets, hospitals, resorts, schools, etc., and purification facilities that require sewage treatment) It is installed in all facilities that generate odors, such as recycling sorting plants, and is effective in promoting sterilization while removing odors or harmful gases (toxic gases) generated.

Figure 1 is a basic example showing a deodorizing system that discharges residual ozone using an exhaust fan to prevent ozone backflow (indoor entry) according to the present invention;
Figure 2 is an additional example showing an optional embodiment of the deodorization system according to the present invention, in which an interlocking damper, a guide plate, and a booster cone are applied.

Next, the present invention will be described in more detail with reference to the attached drawings.

First, as shown in FIGS. 1 and 2, the present invention is largely comprised of an exhaust equipment 100, an ozone generator 200, and a control unit 300 for forced exhaust of residual ozone.

Accordingly, the exhaust equipment 100 has a hood-type collector 110 installed in the area where the pollution source is generated, and the hood-type collector 110 is installed outdoors by the exhaust blowing fan 130 connected to the conduit-type duct 120. It is formed to allow exhaustion.

At this time, the ozone generator 200 is placed on one side of the path of the duct 120 so that the ozone generator enclosure communicates with the connection pipe 210, and inside the enclosure is an ozone generation discharge tube 220 having an airflow detection sensor 221. ) is provided so that when the exhaust air flow in the duct 120 is detected, the ozone generating discharge tube 220 is driven to generate ozone.

Accordingly, on one side of the ozone generation discharge tube 220, an ozone discharge fan 230 and a backflow prevention damper 240 of a simultaneous interlocking structure are provided to blow ozone against the pollutant airflow rising through the duct 120 to remove the airflow being exhausted. It is formed to promote deodorization.

Meanwhile, the control unit 300 for forced exhaustion of residual ozone stops operation of the ozone generating discharge tube 220 at the same time when the exhaust blowing fan 120 is stopped, and thereafter the backflow prevention damper 240 and the ozone discharge fan 230 are operated. Each valve and blade are kept open or rotated for a certain period of time (several seconds to several minutes, for example, 1 to 5 minutes), and the ozone remaining in the ozone generator enclosure is discharged or sprayed into the duct. .

For reference, during normal operation (ON), when the exhaust blower fan is activated, the backflow prevention damper is automatically opened by the airflow detection sensor, the ozone generation discharge pipe is activated, and the ozone discharge fan rotates interlocked to exhaust ozone to the duct. is formed

Accordingly, the duct 120 is further provided with an interlocking damper 400 at the lower part of the longitudinal line connected to the connector 210, so that when the exhaust blowing fan 130 is operated, the interlocking damper 400 opens, and the exhaust blows. When the operation of the fan 130 is stopped, the interlocking damper 400 is stopped and is formed to block the backflow of ozone toward the odor emission source (indoor direction).

That is, the interlocking damper is opened in conjunction with the backflow prevention damper when the exhaust blowing fan is in operation, but when the exhaust blowing fan is stopped, the backflow prevention damper is opened for a certain period of time and the valve of the interlocking damper is closed in conjunction with the exhaust blowing fan. It is formed as follows.

This means that the backflow prevention damper remains open for a certain period of time, and during the process of sending ozone into the duct, it stays closed to prevent ozone from flowing back indoors, blocking the inflow into the room.

In addition, a guide plate 500 is further provided at the end of the connection pipe 210 connected to the duct 120 (part in contact with the duct) to prevent the downward flow of ozone airflow and to induce an upward flow.

At this time, the guide plate 500 is formed so that the end portion 510 facing the duct 120 has an upward slope based on the connector 210 coupled in a direction perpendicular to the duct 120, thereby maintaining the upward airflow of ozone. It is formed to prevent it from going down toward the interior, which is the source of odor emissions.

That is, the end of the guide plate has an upward incline, so that it can be smoothly mixed with the pollutant source, which is an upward airflow, and is formed so that an upward airflow is induced by the inclination angle of the guide plate even when the exhaust blower fan stops. This ultimately helps prevent airflow from flowing backwards toward the interior.

Accordingly, the ozone discharge fan 230 is equipped with a funnel-shaped booster cone 600 at the end of the discharge port so that the ozone generated within the ozone generator enclosure can be sprayed more quickly toward the duct.

That is, the booster cone 600 is formed to have a narrowing diameter at the end of the opening toward the connection pipe 210 based on the outlet of the ozone discharge fan, so that strong and rapid wind pressure is generated, causing ozone generated in the enclosure to travel through the connection pipe. It is formed so that it can quickly flow into the duct.

The present invention is not limited to the specific preferred embodiments described above, and various modifications can be made by anyone skilled in the art without departing from the gist of the invention as claimed in the claims. Of course, such changes are within the scope of the claims.

100 ... exhaust equipment 110 ... collector
120 ... duct 130 ... exhaust blowing fan
200 ... ozone generator 210 ... connector
220 ... ozone generation discharge tube 221 ... airflow detection sensor
230 ... Ozone discharge fan 240 ... Backflow prevention damper
300 ... Control unit 400 ... Interlocking damper
500 ... Guide plate 510 ... End part
600 ... booster cone

Claims (5)

A hood-type collector 110 is installed in the area where the pollution source occurs, and the hood-type collector 110 is an exhaust facility ( 100) and; It is placed on one side of the path of the duct 120 so that the ozone generator enclosure communicates with it through the connection pipe 210, and an ozone generation discharge tube 220 with an airflow detection sensor 221 is provided inside the enclosure to form the duct 120. When the internal exhaust air flow is detected, the ozone generation discharge tube 220 is driven to generate ozone, and an ozone discharge fan 230 and a backflow prevention damper 240 of a simultaneous interlocking structure are provided on one side of the ozone generation discharge tube 220. an ozone generator 200 that blows ozone into the pollutant airflow rising through the duct 120 to deodorize the exhausting airflow; When the exhaust blowing fan 120 is stopped, the operation of the ozone generating discharge pipe 220 is stopped at the same time, but thereafter, the valves and blades of the backflow prevention damper 240 and the ozone discharge fan 230 are kept open for a certain period of time. A control unit 300 for forced exhaust of residual ozone that discharges or sprays the ozone remaining in the ozone generator enclosure toward the duct while continuing to rotate; In the deodorizing system that discharges residual ozone using an exhaust fan configured to prevent ozone backflow (indoor entry),
The duct 120 is further provided with an interlocking damper 400 at the lower part of the longitudinal line connected to the connector 210. When the exhaust blowing fan 130 is operated, the interlocking damper 400 opens, and the exhaust blowing fan ( When the operation of 130) is stopped, the interlocking damper 400 is stopped and is formed to block the reverse flow of ozone toward the odor emission source, and the end of the connector 210 connected to the duct 120 blocks the downward flow of ozone airflow and rises. A deodorizing system that discharges residual ozone using an exhaust fan to prevent ozone backflow (indoor entry), which is further provided with a guide plate 500 to guide the flow. delete delete According to claim 1, the guide plate 500 is formed so that the end portion 510 facing the duct 120 has an upward slope based on the connector 210 coupled in a direction perpendicular to the duct 120. A deodorizing system that discharges residual ozone using an exhaust fan to prevent ozone backflow (indoor entry), which promotes the upward airflow of ozone (preventing it from falling toward the indoor direction, which is the source of odor emissions). The method of claim 1, wherein the ozone discharge fan (230) is equipped with a funnel-type booster cone (600) at the end of the outlet so that the ozone generated within the ozone generator enclosure can be sprayed more quickly toward the duct. A deodorizing system that discharges residual ozone using an exhaust fan to prevent ozone backflow (inflow indoors).