JPH03267426A - Toilet bowl equipped with ozonic deodorizing device - Google Patents

Abstract

PURPOSE:To secure the deodorization by a method wherein an ozonizer is provided in an ozonic deodorizing passage of which sucking port is opened to the internal space of a toilet bowl while discharge port is opened to a space in a toilet room, and rectifying plates are provided to a place in the vicinity of the ozonizer. CONSTITUTION:When a toilet seat (R) of a toilet bowl (A) equipped with an ozonic deodorizing device is occupied, an occupation sensor (S) detects the occupied situation and sends signals to a control device (I). A signal for driving outputted from the control device (I) drives an exhaust blower 16 and makes a high-voltage-generating device 19 generate high voltage and impress 1 the same to an ozonizer 18 and, at the same time, flowed-in air is made to approach rectifying plates 21, 22 and thereby ozone is generated in an ozonic deodorizing passage (G). Offensive odor generated in the internal space (Q) of a toilet bowl main body (T) is sucked into the passage (G) and is deodorized being mixed with ozone in an ozone mixing section 20. The deodorized air is exhausted to a space in a toilet room from an exhaust air outlet 17 through an exhausting section 13 and the exhaust blower 16.

Description

DETAILED DESCRIPTION OF THE INVENTION (A) Field of Industrial Application The present invention relates to a toilet bowl with an ozone deodorizing device that can effectively deodorize bad odors generated in the toilet bowl by ozone.

(B) Conventional technology In recent years, it has become known that ozone has a strong deodorizing effect due to its strong oxidizing effect. , Japanese Unexamined Patent Publication No. 60-31719 has proposed a toilet bowl with a built-in ozone generator.

In other words, the toilet bowl described in the same publication has an ozone deodorizing device built into the main body installed at the rear of the toilet seat, and the odor generated in the toilet bowl is sucked into the ozone deodorizing device through a suction port opened in the toilet bowl. The ozone generated by the discharge action of the ozone deodorizing device decomposes and deodorizes bad odors, and then the deodorized air can be discharged into the toilet.

(c) Problems to be solved by the invention However, such toilets still have the following problems to be solved.

That is, the amount of ozone generated by the ozone generator provided in the toilet bowl is set to an amount that can deodorize the strongest odor generated inside the toilet bowl.

Therefore, when a strong odor occurs during defecation, a sufficient amount of ozone generated by the ozone generator reacts with the odor and deodorizes effectively. The ozone concentration in the exhaust gas has also been sufficiently reduced, and it is considered that there are no safety issues for the human body.

However, ozone deodorizing equipment generates ozone by sucking air as well as bad odor and bringing the oxygen in the air into contact with the ozone generating part. The ozone reaches the exhaust port without getting close to the ozone, and is then exhausted from the same exhaust port, resulting in insufficient ozone generation and the ozone being unable to mix smoothly with ozone. deodorizing efficiency was reduced.

The present invention relates to a toilet bowl with an ozone deodorizing device that can solve the above problems.

(d) Means for Solving the Problems The present invention provides a toilet bowl equipped with an ozone deodorizing device that deodorizes bad odors generated in the toilet bowl using an ozone deodorizing device. , an ozone deodorizing processing flow path having an outlet at the other end opened into the toilet space, an ozone generation section interposed within the ozone deodorization processing flow path, and a rectifying plate installed near the ozone generation section. The present invention relates to a toilet bowl equipped with an ozone deodorizing device characterized by the following configuration.

(E) Function/Effect In the present invention, when defecating using this toilet bowl, the bad odor is sucked through the suction port opened in the interior space of the toilet bowl and reaches the ozone deodorization processing flow path, where the bad odor is generated from the ozone generating part. The air is deodorized by the deodorizing action of ozone, and the deodorized air is discharged from the outlet at the other end.

In addition, by bringing the sucked air closer to the ozone generating part using a rectifying plate installed near the ozone generating part, the oxygen in the air can surely come into contact with the ozone generating part, and a sufficient amount of ozone can be produced. can be effectively generated.

Furthermore, the odor in the air brought close to the ozone generating part is easily mixed with ozone, and the efficiency of deodorizing odor by ozone can be improved.

In this way, in the ozone generating section, the air and the odor in it are brought closer to the ozone generating section using a rectifying plate, and the ozone is easily generated from the ozone generating section and the ozone and the odor are mixed. , it is possible to reliably perform deodorization treatment using ozone.

(f) Examples The present invention will be specifically described below with reference to examples shown in the accompanying drawings.

Figures 1 and 2 show the overall structure of a toilet bowl A with an ozone deodorizing device according to the present invention. An ozone deodorizing device C is removably attached to the machine.

Furthermore, in addition to the ozone deodorizing device C, a private part cleaning device including a jet nozzle 10 and a low tank (none of which are shown) are integrally arranged inside the functional part casing B.

Furthermore, in an example of the rear part of the toilet seat R, detecting that the user has sat on the toilet seat R and that the user has left the toilet seat R,
As will be described later, a seating sensor S is provided which causes the ozone generating section H to generate and stop ozone via the control section I. On the other hand, on the other side of the rear part of the toilet seat R, as shown in Figure 1, a backup controller U is attached that can be used in the event that the remote controller P that controls the private parts cleaning device etc. attached to the wall fails. There is.

Hereinafter, with reference to FIG. 3, a specific configuration of the ozone deodorizing device C, which constitutes the gist of the toilet bowl A with an ozone deodorizing device according to the present invention, will be explained.

As shown in the figure, a long cylindrical body 11 is provided in a slightly inclined state in a mounting frame F that is detachably provided at the bottom of the functional part casing B, and the cylindrical body 11 is located inside the mounting frame F. A long ozone deodorization processing channel G is formed.

Both ends of the cylindrical body 11 form a suction part 12 and a discharge part 13, respectively. (See Figure 2) Through the internal space Q of the toilet main body T
It communicates with

On the other hand, the exhaust section 13 is connected to an exhaust blower 16,
The exhaust blower 16 has an exhaust port 17 formed on its lower surface.

Further, in the center of the ozone deodorizing flow path G formed in the cylindrical body 11, an ozonizer 18 with a heater 18a, which constitutes a main part of the ozone generating section H, is disposed.

The ozonizer 18 is connected to a high pressure generator 19 provided on the outer peripheral surface of the cylindrical body 11.
9 is connected to a control unit I installed on the mounting frame F.

With this configuration, the high-pressure generator 19 can apply a high voltage to the ozonizer 18 to generate ozone in the ozone deodorizing flow path G based on the drive output from the control section (1).

Further, by heating the ozonizer 18 with the heater 18a, generation of ozone can be promoted.

Further, in the ozone deodorizing flow path G, an ozone mixing section 20 is formed downstream of the ozonizer 18.

The ozone mixing section 20 has semicircular rectifying plates 21 and 22 provided on the upper and lower surfaces of the ozone deodorizing flow path G at regular intervals in the axial direction.

Furthermore, in this embodiment, as shown in FIG. 5, a rectifier plate 21 is attached above the ozonizer 18 attached to the lower surface of the ozone deodorizing flow path G with its protrusion facing downward. , one rectifier plate 22 is attached to the side of the ozonizer 18 in close proximity.

This configuration facilitates the generation of ozone and the mixing of ozone and bad odor.

That is, by forcibly bringing the air flowing into the ozone deodorizing flow path G from the ozone deodorizing toilet bowl A into contact with the ozonizer 18 using the upper rectifying plate 21, the discharge from the ozonizer 18 is reduced. As a result, oxygen in the air is reliably changed into ozone, and a sufficient amount of ozone can be easily generated.

In addition, the odor in the incoming air can be brought close to the ozonizer 18 by the upper baffle plate 21, and mixing with the ozone from the ozonizer 18 can be ensured.

Moreover, at that time, the rectifier plate 2 on the side of the ozonizer 18
Stir the mixture with ozone by hitting ozonizer-1
Effective mixing with ozone from 8.

In this way, the baffle plates 21 and 22 can promote the deodorizing effect within the ozone deodorizing treatment channel G.

In addition, in the ozone deodorization processing flow path G, on the downstream side of the ozone mixing section 20, there are first and second catalyst installation spaces 23 and 24.
are formed in series, and these catalyst installation spaces 23.2
A catalyst 2526, which can be replaced periodically, is removably disposed inside the catalyst 4.

Furthermore, in this embodiment, the first and second catalyst position spaces 23
．． 24, two catalysts 25, 26 are housed with an interval between them, and the gap between each catalyst 25, 26 allows the exhaust gas after deodorization to flow smoothly inside each catalyst 25, 26. .

The second catalyst installation space 24 communicates with the discharge section 13 .

In the present invention, the above-mentioned catalysts 25 and 26 have the characteristics, and the structure thereof will be explained in detail below.

That is, such catalysts 25 and 26 may have various compositions and forms, and are preferably those in which a predetermined metal or metal oxide is supported on a carrier. Examples of the metal or metal oxide include manganese, iron, nickel, cobalt, silver, platinum, palladium, rhodium, chromium, molybdenum, lead, tungsten, copper, and vanadium, which may be used alone or in combination.

Supports include alumina, silica, alumina silica, bentonite, diatomaceous earth, silicon carbide, titania, zirconia, magnesia, cobylite, mullite,
Examples include activated carbon, and more preferred examples include binary composite oxides consisting of titanium-silicon, binary composite oxides consisting of titanium-zirconia, and ternary composite oxides consisting of titanium-silicon-zirconia. It will be done. Further, the shape of the catalyst is not particularly limited, and honeycomb, granular, cylindrical, and various other shapes are applicable.

In this embodiment, as shown in FIG. 6, such a catalyst 25.
26 is a thin side plate 25-1 formed from the above-mentioned material.
are connected in a crosswise manner in the vertical and horizontal directions, and each side plate 25-
1, a large number of small diameter through holes 25a and 26a are formed in the front and rear sides of the catalyst 25, 26.

As another example, as shown in FIG. 7, a corrugated plate 25-2 is interposed between each side plate 25-1 disposed in the vertical direction, and openings are formed on the front and rear sides of the catalyst 25.26. A large number of small diameter through holes 25a and 26a are formed.

Further, the catalysts 25 and 26 of the present invention are not limited to the number or configuration described above, and other configurations are also possible.

Then, when the exhaust gas after deodorization passes through the through holes 25a and 26a of the catalyst 25.26, the catalyst 25.2
6, the odor removal process due to ozone in the exhaust gas is performed again, and the deodorization efficiency can be increased.

Here, ozone deodorization treatment using this catalyst 25 and 26 will be explained in detail.

In other words, the catalysts 25 and 26 convert ozone in the exhaust gas into O5
→0. Actively perform decomposition into +0-.

Active oxygen 〇- and oxygen 02 are malodorous components H, S
It reacts with the chemical reaction and changes into H,0 and S02, thereby deodorizing the bad odor.

In this way, the catalysts 25 and 26 promote the decomposition of ozone into oxygen and active oxygen, thereby further promoting the deodorizing effect caused by the above-mentioned mixing of ozone and malodor.

In addition, this catalyst 25.26 reduces the amount of ozone remaining in the exhaust gas after deodorization treatment by decomposing ozone into oxygen and active oxygen, thereby reducing the concentration of residual ozone in the air after deodorization treatment with ozone. can be kept below a certain value.

Therefore, if a large amount of ozone remains in the exhaust gas, the catalyst 25, 26 decomposes the ozone into oxygen, reducing the amount as much as possible, and ensuring sufficient safety to the human body. can.

Furthermore, an ozone sensor 27 is disposed within the exhaust section 13 to detect the ozone concentration contained in the exhaust gas after deodorizing treatment, and the sensor 27 is connected to the control section 1 .

As such an ozone sensor 27, for example, a sensor using an ultraviolet absorption method, a metal oxide semiconductor sensor, or a commercially available simple ozone concentration needle can be used.

Based on the detection output of the sensor 27, the control unit I
As described below, the ozone generating section H can be controlled to adjust the amount of ozone generated.

Hereinafter, with reference to FIG. 4, a description will be given of a method for deodorizing a bad odor generated in the toilet main body T using the ozone deodorizing apparatus C having the above configuration.

First, when a person sits on the toilet seat R of the toilet bowl A with an ozone deodorizing device, the seating sensor S installed behind the toilet seat R sends a detection output to the control unit I, and the exhaust blower 16 is activated by the drive output from the control unit I. At the same time, the high voltage generator 19 generates a high voltage, which is applied to the ozonizer 18 to generate ozone in the ozone deodorizing flow path G.

As a result, the bad odor generated in the internal space Q of the toilet main body T is sucked into the ozone deodorization processing flow path G, and the ozone mixing part 2
At 0, it is effectively mixed with ozone and deodorized.

Further, since catalysts 25 and 26 are disposed downstream of the ozone mixing section 20, ozone is decomposed into oxygen and active oxygen when passing through the catalyst 25 and 26, and this active oxygen produces a bad odor. By reacting with the components, the deodorizing process is further promoted.

Thereafter, the completely deodorized exhaust gas passes through the exhaust section I3 and the exhaust blower 16, and is discharged from the exhaust port 17 into the toilet space.

In addition, in this embodiment, the rectifying plates 21 and 22 allow the incoming air to approach the ozonizer 18, thereby facilitating the generation of ozone from the ozonizer 18 and mixing of this ozone and bad odor. By doing so, effective deodorizing treatment can be performed, and the ozone concentration in the exhaust gas can be kept below a certain value at all times, for example, 0.00000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000.0 lppm or less, and furthermore, ozone odor does not occur. O2 can be suppressed to less than 2 ppm, and the safety of the human body can be sufficiently ensured, and the discomfort caused by ozone odor when using the toilet can be completely eliminated.

Further, by optimally controlling the amount of ozone generated, the amount of electric power required to drive the ozone generating section H can be reduced, and energy saving can be achieved.

Note that when the user leaves the seat after using the toilet, the seating sensor S detects this movement, and based on the detection output, the control unit I
stops the operation of the exhaust blower 16 and the ozone generator H.

Although the toilet bowl with an ozone deodorizing device according to the present invention has been described above based on the embodiments shown in the attached drawings, the following modifications of the present invention are also possible.

That is, in the embodiment shown in FIG. 3, the cylindrical body 11 is made of an ozone-resistant (oxidation-resistant) material such as Teflon, fluorocarbon resin, or silicone resin, or an inorganic material such as ceramic, or a metal material. I can do it.

Moreover, the ozone deodorizing device C is not limited to the inside of the functional part casing B, but can also be provided at other locations, for example, on the side or front of the toilet main body T.

Furthermore, the ozone deodorizing device C according to the present invention can be applied to living spaces other than the above-mentioned toilets, such as kitchens, washrooms, bathrooms, living rooms, etc., as appropriate.

[Brief explanation of drawings]

Fig. 1 is an overall side view of a toilet bowl with an ozone deodorizing device according to the present invention, Fig. 2 is an overall perspective view of the same, Fig. 3 is an explanatory diagram of the internal structure of the ozone deodorizing device, and Fig. 4 is a control block of the ozone deodorizing device. FIG. 5 is an explanatory diagram of the rectifying plate, and FIGS. 6 and 7 are explanatory diagrams showing the structure of the catalyst. In the figure: A Toilet bowl with niosin deodorizing device B: Functional part Casing C Niosin deodorizing device G Niosin deodorizing process flow path H Niosin fumes generating part = Control part P: Remote controller Q: Internal space R: Toilet seat S: Seating sensor T :Toilet bowl body 10:Blowout nozzle 18:Ozonizer 18a:Heater 19:High voltage generator 27:Ozone sensor

Claims (1)

[Claims] 1. In a toilet bowl equipped with an ozone deodorizing device that deodorizes bad odors generated in the toilet bowl using an ozone deodorizing device (C), the ozone deodorizing device (C) is connected to a suction port at one end in the interior space of the toilet bowl, The ozone deodorizing process flow path (G) has its other end outlet opened into the toilet space, and the ozone deodorizing process flow path (G)
) and an ozone generating part (H) interposed in the ozone generating part (H).
H) A toilet bowl with an ozone deodorizing device, characterized in that it is constructed of rectifier plates (21) and (22) provided near the toilet.