JP2024118603A - Deodorizing systems and buildings - Google Patents

Abstract

[Problem] To provide a deodorizing system and building capable of deodorizing both a room and a chimney with a simple configuration. [Solution] A deodorizing system 200 is provided in an apartment 300 equipped with a garbage storage 3 and a wastewater treatment device 2a, and is equipped with a chimney pipe 10 that connects the wastewater treatment device 2a to the outdoors, an ozone generator 30 that generates ozone, an air supply duct 40 that connects the garbage storage 3 to the chimney pipe 10 and can supply the ozone generated by the ozone generator 30 to the garbage storage 3 and the chimney pipe 10, an exhaust duct 60 that connects the garbage storage 3 to the chimney pipe 10 and can exhaust air from the garbage storage 3 to the chimney pipe 10, and an exhaust fan 20 that exhausts air from the wastewater treatment device 2a to the outdoors via the chimney pipe 10 and exhausts air from the garbage storage 3 to the outdoors via the exhaust duct 60 and the chimney pipe 10. [Selected Figure] Figure 1

Description

The present invention relates to a deodorization system and building technology that removes odors from the source.

In buildings, odor problems can occur. For example, in apartment buildings and commercial facilities, garbage collection areas and chimneys connected to wastewater treatment plants are particularly common sources of odor.

In such rooms as garbage storage, odors are generally controlled by air conditioning and ventilation fans. However, air conditioning and ventilation fans are often insufficient in controlling odors. In addition, as described in Patent Document 1, deodorizing technology using ozone is also known, but installing an ozone generator in each room and each chimney tube creates the problem of complicated equipment.

JP 2006-340813 A

The present invention was made in consideration of the above-mentioned circumstances, and the problem it aims to solve is to provide a deodorizing system and building that can deodorize both living rooms and chimneys with a simple configuration.

The problem that the present invention aims to solve is as described above, and the means for solving this problem will be explained next.

That is, in claim 1, the device is provided in a building having a room and a wastewater treatment device, and includes a chimney pipe that connects the wastewater treatment device to the outdoors, an ozone generating unit that generates ozone, an air supply duct that connects the room to the chimney pipe and can supply the ozone generated by the ozone generating unit to the room and the chimney pipe, an exhaust duct that connects the room to the chimney pipe and can exhaust the air of the room to the chimney pipe, and an exhaust fan that exhausts the air in the wastewater treatment device to the outdoors through the chimney pipe and exhausts the air in the room to the outdoors through the exhaust duct and the chimney pipe.

In claim 2, the device includes a control unit capable of controlling the amount of ozone generated from the ozone generating unit, and a measurement unit that measures the odor intensity of the exhaust from the odor stack or the ozone concentration of the exhaust, and the control unit is capable of increasing the amount of ozone generated from the ozone generating unit when the measurement value by the measurement unit is equal to or less than a first threshold value, compared to when the measurement value is greater than the first threshold value.

In claim 3, when the measurement value by the measurement unit is equal to or greater than a second threshold value that is greater than the first threshold value, the control unit is capable of reducing the amount of ozone generated from the ozone generation unit compared to when the measurement value is smaller than the second threshold value.

In claim 4, the device includes an air volume adjustment unit capable of adjusting the volume of air flowing through the air supply duct supplied to the room, and a human detection unit that detects the presence of a person in the room, and the control unit is capable of controlling the air volume adjustment unit, and when it is determined that a person is present in the room based on the detection result of the human detection unit, it is capable of controlling the air volume adjustment unit to reduce the volume of air supplied to the room compared to when it is determined that no person is present in the room.

In claim 5, the exhaust duct is capable of exhausting the air in the living room to the chimney pipe via the intake duct, and the deodorizing system includes an intake fan that supplies the air flowing through the intake duct to the living room, and a second exhaust fan that is provided at the junction of the intake duct and the chimney pipe and exhausts the air in the living room to the chimney pipe via the exhaust duct and the intake duct.

In claim 6, a second exhaust duct is provided that connects the balcony to the chimney pipe and supplies air from within the balcony to the chimney pipe.

In claim 7, the living space is a trash storage room.

In claim 8, the deodorizing system according to any one of claims 1 to 7 is provided.

The effects of the present invention are as follows:

In claim 1, both the living room and the chimney pipe can be deodorized with a simple configuration.

In claim 2, it is possible to prevent insufficient deodorization in the living room and the chimney pipe.

In claim 3, it is possible to suppress the generation of unnecessary ozone.

In claim 4, the effects of ozone on humans can be suppressed.

In claim 5, it is possible to promote the diffusion of ozone into the room and suppress the backflow of air in the air supply duct.

In claim 6, it is possible to deodorize the balcony.

In claim 7, both the garbage storage and the chimney pipe can be deodorized with a simple configuration.

In claim 8, both the garbage storage and the chimney pipe can be deodorized with a simple configuration.

1 is a front view showing an apartment building equipped with a deodorizing system according to a first embodiment of the present invention. FIG. 1 is a block diagram showing a configuration of a deodorization system. FIG. 1 is a schematic diagram showing the flow of ozone (air) in a deodorization system. 4 is a flowchart showing control by the control device. FIG. 4 is a diagram showing control patterns of an ozone generator and an air volume adjustment damper. FIG. 6 is a schematic diagram showing the flow of ozone (air) in a deodorization system according to a second embodiment of the present invention. FIG. 11 is a diagram showing control patterns of an ozone generator and an air volume adjusting damper in a second embodiment. FIG. 11 is a front view showing an apartment building according to a third embodiment. FIG. 13 is a front view showing an apartment building according to another example of the third embodiment.

Below, a deodorizing system 200 and an apartment building 300 according to one embodiment of the present invention will be described with reference to Figures 1 and 2.

The deodorizing system 200 is installed in the apartment building 300 and deodorizes the rooms (garbage storage 3 described below) and the chimney 10 of the apartment building 300.

The apartment building 300 is a collective housing complex with multiple dwelling units 1. Each dwelling unit 1 is provided with a garbage disposer 1a. The garbage disposer 1a is configured to crush food waste together with tap water and discharge it into a drain pipe 1b.

The condominium 300 has a machine room 2 in the basement. The machine room 2 is equipped with a wastewater treatment device 2a. The wastewater treatment device 2a is connected to the disposer 1a via a drain pipe 1b. The wastewater treatment device 2a is configured to be supplied with wastewater from the disposer 1a via the drain pipe 1b and to be able to treat the wastewater.

The condominium 300 also has a trash storage room 3. The trash storage room 3 is a room (living room) where trash from each dwelling unit 1 is stored until a trash truck comes to collect it. The trash storage room 3 is provided with a door 3a that can be opened and closed for entry and exit.

The deodorizing system 200 is installed in the apartment building 300 configured in this manner. The deodorizing system 200 mainly comprises an inlet pipe 10, an exhaust fan 20, an ozone generator 30, an air intake duct 40, an air flow control damper 50, an exhaust duct 60, a human detection sensor 70, a door opening/closing sensor 80, an ozone concentration meter 90, and a control device 100.

The chimney pipe 10 shown in FIG. 1 is for diffusing odors generated by the wastewater treatment inside the wastewater treatment device 2a to the outdoors. The chimney pipe 10 is formed in a cylindrical shape that allows air to flow inside. One end of the chimney pipe 10 is connected to the wastewater treatment device 2a. The chimney pipe 10 extends upward from the wastewater treatment device 2a to the roof of the apartment building 300. In this way, the chimney pipe 10 connects the wastewater treatment device 2a to the outdoors.

The exhaust fan 20 shown in FIG. 1 exhausts the air in the wastewater treatment device 2a to the outdoors through the chimney pipe 10, and exhausts the air in the garbage bin 3 to the outdoors through the exhaust duct 60 and chimney pipe 10 described below. The exhaust fan 20 is provided at the other end of the chimney pipe 10 (the end opposite to the end connected to the wastewater treatment device 2a). When the exhaust fan 20 operates (rotates), it sucks in the air in the wastewater treatment device 2a through the chimney pipe 10 and exhausts it outdoors. When the exhaust fan 20 operates, it sucks in the air in the garbage bin 3 through the exhaust duct 60 and chimney pipe 10 and exhausts it outdoors.

1 and 2 generates ozone ( _O3 ). The ozone generator 30 includes an air supply fan 31, and is provided so that air containing ozone can be supplied to the air supply duct 40 by operating the air supply fan 31. The ozone generated by the ozone generator 30 can oxidize and decompose odorous substances, thereby enabling deodorization.

The ozone generator 30 can arbitrarily change the ozone concentration in the air supplied to the air intake duct 40, and can therefore arbitrarily change the amount of ozone generated (the amount of ozone generated). In this embodiment, the ozone generator 30 can generate ozone at three levels: high concentration, medium concentration, and low concentration. Note that "high concentration" has a higher ozone concentration than "medium concentration," which in turn has a higher ozone concentration than "low concentration."

The air supply duct 40 shown in FIG. 1 connects the garbage storage 3 and the chimney pipe 10, and supplies ozone generated by the ozone generator 30 to the garbage storage 3 and the chimney pipe 10. The air supply duct 40 is formed in a cylindrical shape that allows air to flow inside. The air supply duct 40 is provided in the ceiling of the garbage storage 3. One end of the air supply duct 40 is connected to the ceiling of the garbage storage 3. The other end of the air supply duct 40 is connected to the middle of the chimney pipe 10. An air supply port 41 is provided at one end of the air supply duct 40.

The air intake 41 is an outlet (blowout port) for the air sent in through the air intake duct 40. The air intake 41 is provided in the ceiling of the garbage storage bin 3.

By providing the ozone generator 30 and the air intake duct 40 in this manner, the ozone generated by the ozone generator 30 can be supplied to the garbage box 3 through the air intake duct 40. The ozone generated by the ozone generator 30 can also be supplied to the chimney tube 10 through the air intake duct 40. In order to supply ozone from the ozone generator 30 to the garbage box 3 (so that the air flowing through the air intake duct 40 does not flow back between the ozone generator 30 and the air intake duct 41), the air volume of the air intake fan 31 of the ozone generator 30 is set to be larger than the air volume of the exhaust fan 20. In addition, as shown in FIG. 3, it is preferable that the outlet of the air intake fan 31 of the ozone generator 30 is provided closer to the end (air intake duct 41) of the garbage box 3 side than the end of the air intake duct 40 on the chimney tube 10 side.

The airflow adjustment damper 50 shown in Figures 1 and 2 is for adjusting the amount of air flowing through the air supply duct 40 supplied to the trash can 3. The airflow adjustment damper 50 is provided in the middle of the air supply duct 40, and more specifically, is provided between the ozone generator 30 and the air supply port 41 in the extension direction of the air supply duct 40.

For example, a motor damper is used as the airflow adjustment damper 50. The airflow adjustment damper 50 can adjust (narrow) the cross-sectional area (flow passage area) of the internal space of the air supply duct 40 (the part where the airflow adjustment damper 50 is installed) by driving a motor to change the angle of the inner blades. For example, when the airflow adjustment damper 50 is fully opened, the ratio of the minimum flow passage area between the ozone generator 30 and the chimney tube 10 of the air supply duct 40 and the minimum flow passage area between the ozone generator 30 and the garbage box 3 of the air supply duct 40 is 50:50. Also, when the airflow adjustment damper 50 is fully closed, the ratio of the minimum flow passage area between the ozone generator 30 and the chimney tube 10 of the air supply duct 40 and the minimum flow passage area between the ozone generator 30 and the garbage box 3 of the air supply duct 40 is 100:0. In the following, the "minimum flow area between the ozone generator 30 and the chimney tube 10" of the air intake duct 40 is referred to as the "flow area on the chimney tube 10 side," and the "minimum flow area between the ozone generator 30 and the garbage bin 3" of the air intake duct 40 is referred to as the "flow area on the garbage bin 3 side of the air intake duct 40."

The airflow control damper 50 can adjust the ratio of the amount of air supplied to the garbage storage bin 3 (amount of ozone supplied) to the chimney 10 (amount of ozone supplied) by adjusting the flow path area of the internal space of the air supply duct 40.

The exhaust duct 60 shown in FIG. 1 connects the garbage storage 3 and the chimney pipe 10, and is used to exhaust air from the garbage storage 3 to the chimney pipe 10. The exhaust duct 60 is formed in a cylindrical shape that allows air to flow inside. One end of the exhaust duct 60 is connected to a midway point of the chimney pipe 10, upstream of the air supply duct 40 in the air flow direction. The other end of the exhaust duct 60 is connected to the ceiling of the garbage storage 3. An exhaust port 61 is provided at the other end of the exhaust duct 60.

The exhaust port 61 is an entrance (suction port) for the air inside the trash can 3 into the exhaust duct 60. The exhaust port 61 is provided in the ceiling of the trash can 3.

The human detection sensor 70 shown in Figures 1 and 2 detects the presence of a person inside the trash storage 3. A publicly known human detection sensor can be used as the human detection sensor 70. The human detection sensor 70 is provided at an appropriate location inside the trash storage 3, for example, on the ceiling surface of the trash storage 3.

The door opening/closing sensor 80 shown in Figures 1 and 2 detects whether the door 3a of the waste storage 3 is open or closed. A publicly known door opening/closing sensor can be used as the door opening/closing sensor 80. The door opening/closing sensor 80 is provided at an appropriate location in the waste storage 3, for example, on the door 3a.

The ozone concentration meter 90 shown in Figures 1 and 2 measures the ozone concentration in the air exhausted from the chimney 10 (more specifically, immediately before being exhausted). The ozone concentration meter 90 is provided near the outlet of the chimney 10.

The control device 100 shown in FIG. 2 controls the operation of the ozone generator 30 and the airflow adjustment damper 50. The control device 100 is electrically connected to the human detection sensor 70, the door opening/closing sensor 80, and the ozone concentration meter 90 so that the detection results of the human detection sensor 70, the door opening/closing sensor 80, and the ozone concentration meter 90 are input. The control device 100 controls the operation of the ozone generator 30 and the airflow adjustment damper 50 based on the detection results of the human detection sensor 70, the door opening/closing sensor 80, and the ozone concentration meter 90. Specifically, the control device 100 can control the ozone concentration in the air generated by the ozone generator 30 (and thus the amount of ozone generated). In addition, the control device 100 can adjust the amount of ozone supplied to the garbage box 3 and the chimney 10 by operating the airflow adjustment damper 50.

Below, we will mainly use Figure 3 to explain the air flow in the deodorizing system 200.

Because wastewater from the disposers 1a of each dwelling unit 1 is supplied to the wastewater treatment device 2a (see FIG. 1), odors are generated within the wastewater treatment device 2a. Here, the exhaust fan 20 is constantly rotating, and when the exhaust fan 20 operates, odor-containing air generated by the wastewater treatment device 2a is exhausted to the roof (outdoors) through the chimney 10. This allows the wastewater treatment device 2a to be deodorized. However, because the odor of the air exhausted to the roof has a negative impact on residents on the upper floors of the condominium 300, it is desirable to remove as much odor as possible from the exhaust from the wastewater treatment device 2a before exhausting it to the roof.

Therefore, in the deodorizing system 200 according to this embodiment, ozone generated by the ozone generator 30 can be supplied to the chimney pipe 10 via the air supply duct 40. By supplying ozone to the chimney pipe 10 in this manner, the air flowing through the chimney pipe 10 can be deodorized.

In addition, because the garbage from each dwelling unit 1 is accumulated in the garbage storage 3, odors are generated within the garbage storage 3.

Therefore, in the deodorizing system 200, the ozone generated by the ozone generator 30 can be supplied to the garbage box 3 through the air supply duct 40 and the air supply port 41 by utilizing the air volume of the air supply fan 31 and the property that ozone is heavier than air. By supplying ozone to the garbage box 3 in this way, the air in the garbage box 3 can be deodorized. Note that ozone (O ₃ ) becomes oxygen (O ₂ ) after decomposing odorous substances. By operating the exhaust fan 20, the deodorized air is sent to the chimney 10 through the exhaust port 61 and the exhaust duct 60, and is exhausted to the roof (outdoors) through the chimney 10. In this way, the air in the garbage box 3 can be deodorized by ozone.

In addition, if an excess of ozone is supplied to the garbage storage 3, some of the ozone supplied to the garbage storage 3 (ozone not used for deodorization) is not converted to oxygen and is supplied as ozone to the chimney pipe 10 via the exhaust duct 60. This allows the ozone supplied to the garbage storage 3 that is not used for deodorization to be used for deodorizing the chimney pipe 10, so that the garbage storage 3 and the chimney pipe 10 can be deodorized efficiently without wasting ozone.

In this way, in the deodorizing system 200 according to this embodiment, the ozone generated by the ozone generator 30 is supplied to the garbage storage bin 3 and the chimney pipe 10 via the air supply duct 40, so that the single ozone generator 30 can deodorize both the garbage storage bin 3 and the chimney pipe 10.

In the deodorizing system 200 according to this embodiment, the control device 100 controls the operation of the ozone generator 30 and the airflow control damper 50 to perform efficient deodorization using ozone and to keep the ozone concentration in the garbage storage bin 3 below the environmental standard value (0.1 ppm).

The control of the operation of the ozone generator 30 and the air volume control damper 50 by the control device 100 will be described below with reference to FIG. 4.

In step S1, the control device 100 determines whether or not a person is present in the waste storage 3. In this process, the control device 100 makes this determination based on the detection result of the human detection sensor 70.

If the control device 100 determines that a person is present in the trash storage 3 ("YES" in step S1), it proceeds to step S5. On the other hand, if the control device 100 determines that a person is not present in the trash storage 3 ("NO" in step S1), it proceeds to step S2.

In step S2, the control device 100 determines whether the door 3a of the trash container 3 is open. In this process, the control device 100 makes this determination based on the detection result of the door open/close sensor 80.

If the control device 100 determines that the door 3a of the trash storage 3 is open ("YES" in step S2), it proceeds to step S5. On the other hand, if the control device 100 determines that the door 3a of the trash storage 3 is not open ("NO" in step S2), it proceeds to step S3.

When it is determined that the door 3a of the trash storage 3 is open ("YES" in step S2), this indicates that there is a high possibility that a person is inside the trash storage 3. On the other hand, when it is determined that the door 3a of the trash storage 3 is not open ("NO" in step S2), this indicates that there is a low possibility that a person is inside the trash storage 3. In this way, even if there is a person inside the trash storage 3 but the person cannot be detected by the human detection sensor 70 for some reason, the presence of a person inside the trash storage 3 can be inferred by making this determination based on the detection result of the door opening/closing sensor 80.

In step S3, the control device 100 determines whether the ozone concentration in the exhaust from the chimney 10 (in the air exhausted from the chimney 10) is 0.01 ppm or less. In this process, the control device 100 makes this determination based on the detection result of the ozone concentration meter 90.

If the control device 100 determines that the ozone concentration of the air exhausted from the flue 10 is 0.01 ppm or less ("YES" in step S3), it proceeds to step S9. On the other hand, if the control device 100 determines that the ozone concentration of the air exhausted from the flue 10 is not 0.01 ppm or less (i.e., exceeds 0.01 ppm) ("NO" in step S3), it proceeds to step S4.

The ozone concentration of the exhaust air from the chimney 10 varies depending on the amount of odorous substances contained in the exhaust air. More specifically, if there is a relatively large amount of odorous substances in the garbage bin 3 and the chimney 10 compared to the amount of ozone supplied (the amount of ozone supplied to the garbage bin 3 and the chimney 10), the amount of ozone consumed by the decomposition reaction of the odorous substances will be large, and the ozone concentration of the air exhausted from the chimney 10 will tend to be small. On the other hand, if there is a relatively small amount of odorous substances in the garbage bin 3 and the chimney 10 compared to the amount of ozone supplied, the amount of ozone consumed by the decomposition reaction of the odorous substances will also be small, and the ozone concentration of the air exhausted from the chimney 10 will tend to be large.

Therefore, if the ozone concentration of the exhaust from the chimney 10 is 0.01 ppm or less (YES in step S3), this indicates that the amount of ozone supplied is insufficient and deodorization is not being performed sufficiently. On the other hand, if the ozone concentration of the exhaust from the chimney 10 is not 0.01 ppm or less (exceeds 0.01 ppm) (NO in step S3), this indicates that the amount of ozone supplied is not insufficient and deodorization is being performed sufficiently. In this way, the ozone concentration (in the air exhausted from the chimney 10) measured by the ozone concentration meter 90 serves as an indicator for estimating whether deodorization is sufficient or insufficient.

In step S4, the control device 100 determines whether the ozone concentration of the exhaust from the odor emitting tube 10 is 0.1 ppm or more. In this process, the control device 100 makes this determination based on the detection result of the ozone concentration meter 90.

If the control device 100 determines that the ozone concentration of the exhaust from the chimney 10 is 0.1 ppm or more ("YES" in step S4), it proceeds to step S8. On the other hand, if the control device 100 determines that the ozone concentration of the exhaust from the chimney 10 is not 0.1 ppm or more (i.e., less than 0.1 ppm) ("NO" in step S4), it proceeds to step S7.

When the ozone concentration of the exhaust air from the chimney 10 is 0.1 ppm or more (YES in step S4), this indicates that the amount of ozone supplied to the garbage bin 3 and the chimney 10 is excessive. On the other hand, when the ozone concentration of the air exhausted from the chimney 10 is not 0.1 ppm or more (less than 0.1 ppm) (NO in step S4), this indicates that the amount of ozone supplied to the garbage bin 3 and the chimney 10 is not excessive (is within the appropriate range). The value of "0.1 ppm" is set based on the environmental standard value for ozone concentration.

In step S7, the control device 100 performs control of pattern 6 shown in FIG. 5. Specifically, the control device 100 generates high concentration ozone from the ozone generator 30 and controls the air flow rate adjustment damper 50 to set the ratio of the flow area of the intake air duct 40 on the chimney tube 10 side to the flow area on the garbage storage 3 side to 60:40. In this way, the garbage storage 3 and the chimney tube 10 can be deodorized.

Meanwhile, in step S8, the control device 100 performs control of pattern 5 shown in FIG. 5. Specifically, the control device 100 generates ozone at a low concentration from the ozone generator 30, and controls the airflow adjustment damper 50 (fully open) to set the ratio of the flow path area of the air supply duct 40 on the chimney 10 side to the flow path area on the garbage bin 3 side to 50:50. In this way, by generating ozone at a low concentration from the ozone generator 30 and reducing the amount of ozone generated compared to pattern 6, excessive supply of ozone to the garbage bin 3 and the chimney 10 can be suppressed.

In step S9, which is a transition from step S3, the control device 100 performs control of pattern 4 shown in FIG. 5. Specifically, the control device 100 generates ozone at a high concentration from the ozone generator 30 and controls the air flow rate adjustment damper 50 to set the ratio of the flow area of the intake duct 40 on the chimney 10 side to the flow area of the garbage box 3 side to 90:10. In this way, by generating ozone at a high concentration from the ozone generator 30 and relatively increasing the amount of ozone generated, it is possible to suppress insufficient deodorization of the garbage box 3 and the chimney 10. In addition, by increasing the amount of air supplied to the chimney 10 side by setting the ratio of the flow area of the intake duct 40 on the chimney 10 side to the flow area of the garbage box 3 side to 90:10 compared to pattern 6, it is possible to suppress insufficient deodorization, especially in the chimney 10.

In step S5, which is entered from step S1 or S2, the control device 100 determines whether the ozone concentration of the exhaust from the odor emitting tube 10 is 0.01 ppm or less. In this process, the control device 100 makes this determination based on the detection result of the ozone concentration meter 90.

If the control device 100 determines that the ozone concentration of the exhaust from the flue pipe 10 is 0.01 ppm or less ("YES" in step S5), it proceeds to step S12. On the other hand, if the control device 100 determines that the ozone concentration of the exhaust from the flue pipe 10 is not 0.01 ppm or less (i.e., exceeds 0.01 ppm) ("NO" in step S5), it proceeds to step S6.

In step S6, the control device 100 determines whether the ozone concentration of the exhaust from the chimney 10 is 0.1 ppm or more. In this process, the control device 100 makes this determination based on the detection result of the ozone concentration meter 90.

When the control device 100 determines that the ozone concentration of the exhaust from the chimney 10 is 0.1 ppm or more ("YES" in step S6), it proceeds to step S11. On the other hand, when the control device 100 determines that the ozone concentration of the exhaust from the chimney 10 is not 0.1 ppm or more (i.e., exceeds 0.1 ppm) ("NO" in step S6), it proceeds to step S10.

In step S10, the control device 100 performs control of pattern 3 shown in FIG. 5. Specifically, ozone is generated at a medium concentration from the ozone generator 30, and the airflow adjustment damper 50 is controlled to set the ratio of the flow area of the intake duct 40 on the chimney 10 side to the flow area of the garbage bin 3 side to 70:30. In this way, by generating ozone at a medium concentration from the ozone generator 30 to reduce the amount of ozone generated compared to pattern 6, and by setting the ratio of the flow area of the intake duct 40 on the chimney 10 side to the flow area of the garbage bin 3 side to 70:30, the amount of air supplied to the garbage bin 3 side is reduced compared to pattern 6, and the amount of ozone supplied to the garbage bin 3 can be reduced in consideration of the impact on people in the garbage bin 3.

Meanwhile, in step S11, the control device 100 performs control of pattern 2 shown in FIG. 5. Specifically, ozone is generated at a low concentration from the ozone generator 30, and the airflow control damper 50 is controlled (fully open) to set the ratio of the flow path area of the air supply duct 40 on the chimney 10 side to the flow path area on the garbage bin 3 side to 50:50. In this way, by generating ozone at a low concentration from the ozone generator 30 and reducing the amount of ozone generated compared to pattern 3, excessive supply of ozone to the garbage bin 3 and the chimney 10 can be suppressed.

In step S12, which is a transition from step S5, the control device 100 performs control of pattern 1 shown in FIG. 5. Specifically, ozone is generated at a high concentration from the ozone generator 30, and the air volume adjustment damper 50 is controlled (fully closed) to set the ratio of the flow path area of the intake duct 40 on the chimney tube 10 side to the flow path area on the garbage box 3 side to 100:0. In this way, by generating ozone at a high concentration from the ozone generator 30 and increasing the amount of ozone generated compared to pattern 3, it is possible to suppress insufficient deodorization of the garbage box 3 and the chimney tube 10. In addition, by increasing the amount of air supplied to the chimney tube 10 side compared to pattern 3 by setting the ratio of the flow path area of the intake duct 40 on the chimney tube 10 side to the flow path area on the garbage box 3 side to 100:0, it is possible to suppress insufficient deodorization, especially in the chimney tube 10.

As described above, in the deodorizing system 200 according to this embodiment, the ozone concentration of the exhaust gas from the chimney 10 is detected by the ozone concentration meter 90, and the amount of ozone generated from the ozone generator 30 is controlled based on the ozone concentration to estimate whether deodorization is sufficient or insufficient, thereby enabling efficient deodorization.

In particular, when the ozone concentration of the exhaust from the chimney 10 is below a threshold value (0.01 ppm) that is lower than the environmental standard value (0.1 ppm) and the amount of ozone supplied to the garbage bin 3 and the chimney 10 is considered to be insufficient, the amount of ozone generated from the ozone generator 30 is increased, thereby suppressing insufficient deodorization of the garbage bin 3 and the chimney 10. On the other hand, when the ozone concentration of the exhaust from the chimney 10 is 0.1 ppm or more and the amount of ozone supplied to the garbage bin 3 and the chimney 10 is considered to be excessive, the amount of ozone generated from the ozone generator 30 is reduced, thereby suppressing excessive supply to the garbage bin 3 and the chimney 10.

In addition, when it is believed that someone is present in the trash receptacle 3, the amount of ozone supplied to the trash receptacle 3 can be reduced, thereby suppressing the impact of ozone on people.

As described above, the deodorizing system 200 according to this embodiment has the following features:
The wastewater treatment device 2a is installed in an apartment building 300 (building),
A chimney pipe 10 that communicates the wastewater treatment device 2a with the outdoors;
An ozone generator 30 (ozone generating unit) that generates ozone;
an air supply duct (40) that connects the garbage bin (3) and the chimney pipe (10) and can supply the ozone generated by the ozone generator (30) to the garbage bin (3) and the chimney pipe (10);
an exhaust duct 60 that connects the garbage storage 3 and the chimney pipe 10 and can exhaust air from the garbage storage 3 to the chimney pipe 10;
An exhaust fan 20 that exhausts the air in the wastewater treatment device 2a to the outdoors through the chimney pipe 10 and exhausts the air in the garbage storage 3 to the outdoors through the exhaust duct 60 and the chimney pipe 10;
It is equipped with the following.

With this configuration, both the garbage storage 3 and the odor vent pipe 10 can be deodorized with a simple structure.
Specifically, an air supply duct 40 is provided that connects the garbage storage bin 3 and the chimney pipe 10, and ozone generated by the ozone generator 30 can be supplied to the garbage storage bin 3 and the chimney pipe 10 via the air supply duct 40, so that both the garbage storage bin 3 and the chimney pipe 10 can be deodorized with a single ozone generator 30.
In addition, of the ozone supplied to the garbage storage 3, the ozone that is not used for deodorizing the air inside the garbage storage 3 (ozone that is not oxidized and decomposed) can be supplied to the chimney pipe 10 via the exhaust duct 60, so that the garbage storage 3 and the chimney pipe 10 can be efficiently deodorized without generating ozone unnecessarily.

Also, a control device 100 (control unit) capable of controlling the amount of ozone generated from the ozone generator 30;
an ozone concentration meter 90 (measurement unit) for measuring the ozone concentration of the exhaust gas from the chimney pipe 10;
Equipped with
The control device 100 includes:
When the measurement value by the ozone concentration meter 90 is equal to or less than 0.01 ppm (first threshold value) (YES in step S5 of FIG. 3), the amount of ozone generated from the ozone generator 30 can be increased (step S12 of FIG. 3) compared to when the measurement value is greater than 0.01 ppm.

With this configuration, insufficient deodorization of the garbage storage 3 and the chimney pipe 10 can be prevented.
Specifically, when it is considered that the amount of ozone supplied to the garbage storage 3 and the chimney pipe 10 is insufficient, the amount of ozone generated from the ozone generator 30 can be increased, thereby suppressing insufficient deodorization of the garbage storage 3 and the chimney pipe 10.

In addition, the control device 100
When the measurement value by the ozone concentration meter 90 is equal to or greater than 0.1 ppm (second threshold value) which is greater than 0.01 ppm (first threshold value) (YES in step S4 of FIG. 3, YES in step S6 of FIG. 3), the amount of ozone generated from the ozone generator 30 can be reduced compared to when the measurement value is smaller than 0.1 ppm (steps S8 and S11 of FIG. 3).

With this configuration, it is possible to suppress the generation of unnecessary ozone.
Specifically, when it is considered that the amount of ozone supplied to the garbage storage 3 and the chimney pipe 10 is excessive, the amount of ozone generated from the ozone generator 30 can be reduced, thereby preventing the ozone generator 30 from generating ozone unnecessarily.

In addition, an air volume adjustment damper 50 (air volume adjustment unit) capable of adjusting the amount of air flowing through the air supply duct 40 to the trash box 3;
A human detection sensor 70 and a door opening/closing sensor 80 (human detection unit) for detecting the presence of a person in the trash storage 3;
Equipped with
The control device 100 includes:
The air flow rate adjusting damper 50 is controllable,
When it is determined that a person is present in the trash storage 3 based on the detection results of the human detection sensor 70 and the door opening/closing sensor 80 (YES in step S1 and YES in step S2 of FIG. 3), the air volume control damper 50 can be controlled to reduce the amount of air supplied to the trash storage 3 (the control pattern is changed from pattern 6 shown in FIG. 5 to pattern 3, and the trash storage side flow path area ratio is reduced from 40 to 30. Also, the control pattern is changed from pattern 4 to pattern 1 shown in FIG. 5, and the trash storage side flow path area ratio is reduced from 10 to 0), compared to when it is determined that a person is not present in the trash storage 3 (NO in step S1 and NO in step S2 of FIG. 3).

With this configuration, the effects of ozone on humans can be suppressed.
Specifically, when it is believed that someone is present in the waste bin 3, the amount of ozone supplied to the waste bin 3 can be reduced, thereby suppressing the effects of ozone on people.

The living room is also a garbage storage room 3.

This configuration allows both the garbage storage bin 3 and the chimney 10 to be deodorized with a simple structure.

The apartment building 300 (building) in this embodiment is also equipped with a deodorizing system 200.

This configuration allows both the garbage storage bin 3 and the chimney 10 to be deodorized with a simple structure.

The deodorizing system 400 according to the second embodiment of the present invention will be described below with reference to Figures 6 and 7. The deodorizing system 400 according to the second embodiment is intended to be used when the trash storage 3 is relatively large. In the following, the same components as those in the first embodiment will be given the same reference numerals and will not be described.

The deodorizing system 400 according to the second embodiment differs from the deodorizing system 200 according to the first embodiment in that it is equipped with an exhaust duct 60A instead of the exhaust duct 60, and further equipped with a garbage storage air supply fan 110 and a garbage storage exhaust fan 120.

The exhaust duct 60A differs from the exhaust duct 60 of the first embodiment in that one end of the exhaust duct 60A is connected to the intake duct 40 instead of the chimney pipe 10. That is, the exhaust duct 60A is connected to the chimney pipe 10 via the intake duct 40.

The trash bin air supply fan 110 is for diffusing the air (ozone) flowing through the air supply duct 40 to the trash bin 3. The trash bin air supply fan 110 is provided near the air supply port 41. When the trash bin air supply fan 110 operates, it sucks in the air (ozone) flowing through the air supply duct 40 and supplies the air to the trash bin 3. In this way, by providing the trash bin air supply fan 110, air can be delivered far into the trash bin 3, so that ozone can be diffused evenly throughout the trash bin 3 even if the trash bin 3 is relatively large.

The dustbin exhaust fan 120 is for supplying the air (ozone) flowing through the intake duct 40 and the exhaust duct 60A to the chimney pipe 10. The dustbin exhaust fan 120 is provided at the part where the intake duct 40 and the exhaust duct 60A join. When the dustbin exhaust fan 120 operates, it sucks in the air (ozone) flowing through the intake duct 40 and the exhaust duct 60A and supplies the air to the chimney pipe 10. In this way, it is possible to promote the supply of ozone from the ozone generator 30 to the chimney pipe 10 and also promote exhaust from the dustbin 3. In addition, it is possible to suppress backflow in the part of the intake duct 40 on the chimney pipe 10 side (between the ozone generator 30 and the part where the intake duct 40 and the chimney pipe 10 join).

The dust box air supply fan 110 and the dust box exhaust fan 120 can change the air volume as desired, and in this embodiment, the air volume can be changed between two levels ("large" and "medium"). The air volume of the dust box air supply fan 110 and the air volume of the dust box exhaust fan 120 are controlled by the control device 100 to be the same.

In the second embodiment, the control device 100 can control the ozone generator 30, the airflow adjustment damper 50, and the garbage box air supply fan 110 in the pattern shown in FIG. 7. For example, when the control pattern is pattern 1 shown in FIG. 7, the ratio of the flow area of the air supply duct 40 on the chimney tube 10 side to the flow area of the garbage box 3 side is set to 100:0, and the operation of the garbage box air supply fan 110 is stopped. This stops the supply of ozone to the garbage box 3, and the impact on people in the garbage box 3 can be suppressed. When the control pattern is pattern 5 shown in FIG. 7, the ozone concentration in the air supplied from the ozone generator 30 to the air supply duct 40 is set to "medium concentration" and the airflow of the garbage box air supply fan 110 is set to "large", so that ozone can be distributed throughout the garbage box 3 even if the garbage box 3 is relatively large.

As described above, in the deodorization system 400 according to the second embodiment,
The exhaust duct 60A is
The air in the garbage storage 3 can be exhausted to the chimney pipe 10 through the air supply duct 40,
The deodorizing system 400 includes:
A garbage storage air supply fan 110 (air supply fan) that supplies air flowing through the air supply duct 40 to the garbage storage 3;
A garbage storage exhaust fan 120 (second exhaust fan) is provided at the junction of the air intake duct 40 and the chimney pipe 10, and exhausts the air in the garbage storage 3 to the chimney pipe 10 through the exhaust duct 60A and the air intake duct 40;
It is equipped with the following.

This configuration promotes the diffusion of ozone into the garbage storage bin 3 and suppresses backflow of air in the air supply duct 40.

The following describes a deodorizing system 500 according to a third embodiment of the present invention, using FIG. 8. In the following, the same components as those in the first embodiment are given the same reference numerals and will not be described.

The deodorizing system 500 according to the third embodiment differs from the deodorizing system 200 according to the first embodiment in that it is equipped with a second exhaust duct 130.

The second exhaust duct 130 connects the balcony 4 of the dwelling unit 1 of the condominium 300 to the chimney pipe 10, and is intended to exhaust (supply) the air within the balcony 4 to the chimney pipe 10. The second exhaust duct 130 is formed in a cylindrical shape that allows air to flow inside.

As a result, odors generated on the balcony 4 can be supplied to the chimney pipe 10, thereby deodorizing the balcony 4. Then, after deodorizing with the ozone supplied into the chimney pipe 10, the air on the balcony 4 can be discharged outdoors.

As described above, the deodorization system 400 according to the second embodiment has the following features:
It is equipped with a second exhaust duct 130 which connects the balcony 4 and the chimney pipe 10 and supplies air from within the balcony 4 to the chimney pipe 10.

This allows deodorization of the balcony 4.

Although each embodiment of the present invention has been described above, the present invention is not limited to the above configurations, and various modifications are possible within the scope of the invention described in the claims.

For example, in each embodiment, the building is an apartment building 300, but the building is not limited to an apartment building and can be any building that has an odor source, such as a commercial facility.

In addition, in each embodiment, the living room is a trash storage room 3, but the living room is not limited to a trash storage room and can be any living room that is a source of odor, such as a toilet or a kitchen.

In addition, although the measuring unit in each embodiment is an ozone concentration meter 90, an odor sensor may be used instead of the ozone concentration meter 90. More specifically, an odor sensor is provided near the outlet of the streak pipe 10, and the odor sensor measures the odor strength of the exhaust from the streak pipe 10. In this way, the odor strength measured by the odor sensor can be used as an index for estimating whether deodorization is excessive or insufficient.

In addition, in each embodiment, a human detection sensor 70 and a door opening/closing sensor 80 are provided as the human detection unit, but either a human detection sensor 70 or a door opening/closing sensor 80 may be provided. In addition, the human detection unit is not limited to the human detection sensor 70 and the door opening/closing sensor 80, and any means capable of detecting the presence of a person in the trash storage 3 may be used.

In addition, in each embodiment, the air flow control damper 50 is provided in the air intake duct 40 at a location close to the air intake port 41, but it can be provided at any location in the air intake duct 40 between the ozone generator 30 and the air intake port 41, for example, near (directly below) the ozone generator 30.

In addition, in the control shown in FIG. 4, the first threshold value is 0.01 ppm and the second threshold value is 0.1 ppm, but the first threshold value and the second threshold value are not limited to this and can be set to any value.

As a variation of the third embodiment, as shown in FIG. 9, in an apartment building 300, a configuration similar to that of the trash storage 3 (ozone generator 30, air supply duct 40, air flow control damper 50, exhaust duct 60, human detection sensor 70, etc.) can be applied to a closed space such as an interior corridor 5. This allows deodorization of the interior corridor 5. Then, after deodorizing with ozone supplied into the chimney 10, the air in the interior corridor 5 can be discharged to the outdoors.

REFERENCE SIGNS LIST 1a garbage disposer 2a wastewater treatment device 3 garbage storage 4 balcony 10 chimney 20 exhaust fan 30 ozone generator 40 air supply duct 50 air volume adjustment damper 60 exhaust duct 70 human detection sensor 80 door opening/closing sensor 90 ozone concentration meter 100 control device 110 garbage storage air supply fan 120 garbage storage exhaust fan 130 second exhaust duct 200, 400, 500 deodorizing system 300 condominium

Claims (8)

Installed in a building equipped with a room and a wastewater treatment device,
A chimney pipe connecting the wastewater treatment device to the outdoors;
An ozone generating unit that generates ozone;
an air supply duct that connects the living room and the chimney pipe and is capable of supplying the ozone generated by the ozone generating unit to the living room and the chimney pipe;
an exhaust duct that connects the living room and the chimney pipe and is capable of exhausting air from the living room to the chimney pipe;
an exhaust fan that exhausts air in the wastewater treatment device to the outdoors through the chimney pipe and exhausts air in the living room to the outdoors through the exhaust duct and the chimney pipe;
Equipped with
Deodorizing system. A control unit capable of controlling an amount of ozone generated from the ozone generating unit;
A measuring unit that measures the odor intensity of the exhaust from the chimney or the ozone concentration of the exhaust;
Equipped with
The control unit is
When the measurement value by the measuring unit is equal to or less than a first threshold value, the amount of ozone generated from the ozone generating unit can be increased compared to when the measurement value is greater than the first threshold value.
The deodorizing system of claim 1 . The control unit is
When the measurement value by the measuring unit is equal to or greater than a second threshold value that is greater than the first threshold value, the amount of ozone generated from the ozone generating unit can be reduced compared to when the measurement value is smaller than the second threshold value.
The deodorizing system of claim 2 . an air volume adjustment unit capable of adjusting the volume of air flowing through the air supply duct into the living room;
A human detection unit that detects the presence of a person in the room;
Equipped with
The control unit is
The air volume adjustment unit is controllable,
When it is determined that a person is present in the living room based on a detection result of the human detection unit, the air volume adjustment unit can be controlled to reduce the amount of air supplied to the living room, compared to when it is determined that a person is not present in the living room.
The deodorizing system of claim 3. The exhaust duct is
The air in the room can be exhausted to the chimney pipe through the air supply duct,
The deodorizing system comprises:
an air supply fan that supplies air flowing through the air supply duct to the living room;
A second exhaust fan provided at a junction of the intake duct and the chimney pipe, which exhausts air from within the living room through the exhaust duct and the intake duct to the chimney pipe;
Equipped with
The deodorizing system of claim 1 . a second exhaust duct that connects the balcony and the chimney pipe and supplies air from within the balcony to the chimney pipe;
The deodorizing system of claim 1 . The living room is a garbage storage room.
The deodorizing system of claim 1 . A building equipped with a deodorizing system according to any one of claims 1 to 7.

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