JPH07113100A - Cleaning fluid production unit and cleaning unit using the same - Google Patents

Abstract

PURPOSE:To provide a cleaning fluid production unit capable of easily producing highly effective cleaning fluids and provide a cleaning unit using the same. CONSTITUTION:Air put to suction via an intake vent 2a comes into contact, through a separator 3, with the cleaning fluid L in the body case 2, being freed from contaminants such as oil and dust by this fluid L, and guided to an exhaust vent 2b. The resultant cleaning fluid L is then discharged via a discharge pipe 2d and exchanged for a fresh cleaning fluid L by adding a surfactant and a deodorizing bactericide from respective addition devices 7, 8 to alkaline ionic water produced by an electrolytic water production unit 6 followed by feeding the resultant ionic water into the body case. That is, as the cleaning power of the surfactant can be promoted at high alkaline pH levels, the cleaning effect of the air is further raised, while offensive odor generation and sundry germ propagation can be prevented by the deodorizing bactericide. Also, owing to the utility of the alkaline ionic water, there occurs no adherence of oil stains to the inside of the body case even after long-term operation.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cleaning liquid generating device for generating a cleaning liquid used for cleaning various articles or air and an air cleaning filter, and a cleaning device using the cleaning liquid.

[0002]

2. Description of the Related Art Conventionally, tap water is generally used for washing dishes, utensils, foodstuffs, etc., or for supplying a washing liquid to a washing device such as a dishwasher.
Further, Japanese Patent Laid-Open No. 1-159015 discloses a separating device for cleaning air as an example of a cleaning device. In this separating device, the cleaning liquid stored in the bottom of the main body case is brought into contact with the air sucked into the main body case. By doing so, contaminants such as oil and dust contained in the air are removed.

[0003]

However, when washing dishes or the like, oil stains cannot be removed unless detergent is used.
There is a problem that it takes a lot of time and labor to wash stains that are difficult to remove even if a detergent is used. Further, in a cleaning device such as a dishwasher, dirt is removed only by spraying water, so that a large amount of cleaning liquid is used, which is economically disadvantageous. On the other hand, in the case of the above separating device, a certain amount of cleaning liquid is stored in the main body case, so it is necessary to replace this cleaning liquid regularly to clean the inside. However, such replacement work and cleaning work are extremely troublesome, and particularly in the cleaning work, there is a problem that it is extremely difficult to remove oil stains adhering to the inside.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a cleaning liquid generating apparatus capable of easily generating a cleaning liquid having a high cleaning effect. Another object of the present invention is to provide a cleaning device that can easily exchange and clean the cleaning liquid.

[0005]

In order to achieve the above-mentioned object, the present invention provides that, in claim 1, by flowing raw water between a pair of electrodes for electrolysis, alkaline ionized water is provided on one electrode side. The electrolytic water generating means for generating acidic water on the other electrode side, the cleaning liquid outflow path for supplying the alkaline ionized water generated from one electrode side of the electrolytic water generating means to the outside as a cleaning solution, and the cleaning solution outflow path A cleaning liquid generation device is provided with an additive mixing means for adding at least one of a surfactant and a deodorant germicide to alkaline ionized water.

According to a second aspect of the present invention, in the cleaning liquid production apparatus of the first aspect, the acidic water produced from the other electrode side of the electrolyzed water producing means is neutralized to feed raw water into the electrolyzed water producing means. It is provided with a means for reforming electrolyzed water supplied to the side.

In the third aspect, the raw water is circulated between the pair of electrodes to be electrolyzed, so that the alkaline ionized water or the acidic water is supplied to one electrode side and the acidic water or the alkaline ionized water is supplied to the other electrode side. The electrolyzed water producing means for producing the electrolyzed water producing means, a cleaning liquid outflow path for supplying the alkaline ionized water or acidic water produced from one electrode side of the electrolyzed water producing means to the outside as a cleaning liquid, and the polarity of each electrode of the electrolyzed water producing means A cleaning liquid generating device is provided with switching means for switching and additive mixing means for adding at least one of a surfactant and a deodorant bactericide to alkaline ionized water or acidic water in the cleaning liquid outflow path.

According to the present invention, the raw water is circulated between the pair of electrodes and electrolyzed to generate alkaline ionized water on one electrode side and acidic water on the other electrode side to generate electrolyzed water. Means, a first cleaning liquid outflow path for supplying the alkaline ionized water generated from one electrode side of the electrolyzed water generating means to the outside as a cleaning liquid, and acidic water generated from the other electrode side of the electrolyzed water generating means. A second cleaning solution outflow path supplied to the outside as a cleaning solution, a switching means for switching each cleaning solution outflow path, and an addition for adding at least one of a surfactant and a deodorant bactericide to alkaline ionized water or acidic water in the cleaning solution outflow path. A cleaning liquid generation device including an agent mixing means is configured.

According to a fifth aspect of the present invention, in the cleaning liquid generator according to the third or fourth aspect, an alkaline water mode for generating an alkaline cleaning liquid by the switching means and an acidic water mode for generating an acidic cleaning liquid by the switching means. And a mode switching unit capable of arbitrarily switching between a neutral water mode in which a neutral cleaning liquid is generated by canceling the application of the electrolysis voltage of the electrolyzed water generating unit.

According to claim 6, claims 1, 2, 3 and
In the cleaning liquid generating device according to 4 or 5, the pH of the electrolytic water supplied from the electrolytic water generating means to the cleaning liquid outflow path.
It is provided with a pH value detecting means for detecting a value, and a pH value controlling means for controlling the electrolysis voltage or current of the electrolyzed water producing means based on the detection value of the pH value detecting means.

Further, in claim 7, claims 1, 2, 3,
In the cleaning liquid generation device according to 4, 5, or 6, the pH value detection means for detecting the pH value of the electrolyzed water supplied from the electrolysis water generation means to the cleaning liquid outflow path, and the addition based on the detection value of the pH value detection means. And an addition amount control means for controlling the addition amount of the agent mixing means.

Further, according to the present invention, the main body case which contains the cleaning liquid in the bottom part and has the intake port and the exhaust port in the upper part, and the main body case is arranged so as to be partitioned into the intake port side and the exhaust port side, A separation plate for contacting the cleaning liquid with the air flowing from the mouth side to the exhaust port side, a discharging means for discharging the cleaning liquid in the main body case, an electrolyzed water generating means for electrolyzing raw water to generate alkaline ionized water, and an electrolysis. A cleaning solution outflow path for supplying the alkaline ionized water generated from the water generating means as a cleaning solution into the main body case, and an additive mixing means for adding at least one of a surfactant and a deodorant germicide to the alkaline ionized water in the cleaning solution outflow path. And a cleaning device having

[0013]

According to the cleaning liquid generator of the first aspect, alkaline ionized water is generated on one electrode side of the electrolyzed water generating means, and acidic water is generated on the other electrode side thereof, and is generated from one electrode side. The alkaline ionized water is added with at least one of a surfactant and a deodorant sterilizer by an additive mixing means to form a cleaning liquid, which is supplied to the outside through a cleaning liquid outflow path. That is, since the detergent promotes the detergency at a highly alkaline pH value, a detergent having a high detergent effect can be easily produced, and the deodorant germicide prevents the generation of malodor and the propagation of germs. .

According to the cleaning liquid generator of claim 2, in addition to the function of claim 1, after the acidic water generated by the electrolytic water generating means becomes neutral water by the electrolytic water reforming means, the electrolytic solution is electrolyzed. Since the acid water is supplied to the inlet side of the water generating means, the acidic water is not wasted and can be reused as raw water.

According to the third aspect of the cleaning liquid generator, when one electrode of the electrolyzed water generating means is made the cathode and the other electrode is made the anode by the switching means, one side of the electrode is alkaline ionized water and the other side is the other side. Acidic water is generated on the electrode side of, respectively, and the alkaline ionized water generated from one electrode side becomes a cleaning liquid by adding at least one of a surfactant and a deodorant germicide by the additive mixing means, and the cleaning liquid outflow route It is supplied to the outside via. That is, since the surfactant promotes detergency at a highly alkaline pH value,
A cleaning liquid having a high cleaning effect is easily produced, and the deodorant bactericide prevents the generation of malodor and the propagation of various bacteria. When one electrode of the electrolyzed water producing means is made an anode and the other electrode is made a cathode by the switching means, acidic water is produced on one electrode side and alkaline ionized water is produced on the other electrode side, respectively. Acidic water generated from the electrode side is supplied to the outside as a cleaning liquid via the cleaning liquid outflow path. In this case, the acidic water has a bactericidal effect without mixing additives.

According to the cleaning liquid generator of claim 4, alkaline ionized water is generated on one electrode side of the electrolyzed water generating means, and acidic water is generated on the other electrode side of the electrolytic water generating means, and the switching means changes the cleaning liquid. By making the outflow path the first cleaning solution outflow path, the alkaline ionized water generated from one electrode side is added with at least one of the surfactant and the deodorant bactericide by the additive mixing means to become the cleaning solution, It is supplied to the outside through the cleaning liquid outflow route 1. That is,
Since the detergent promotes the detergency at a highly alkaline pH value, a detergent having a high detergent effect can be easily produced, and the deodorant bactericide can prevent the generation of malodor and the propagation of germs. Further, by setting the outflow path of the cleaning liquid to the second cleaning liquid outflow path by the switching means, the acidic water generated from the other electrode side is supplied to the outside as the cleaning liquid via the second cleaning liquid outflow path. In this case, the acidic water has a bactericidal effect without mixing additives.

According to the cleaning liquid generator of claim 5, in addition to the function of claim 3 or 4, an alkaline water mode for generating an alkaline cleaning liquid, an acidic water mode for generating an acidic cleaning liquid, and a neutral Since the neutral water mode for generating the cleaning liquid of (3) is switched, the cleaning liquid is arbitrarily selected as necessary.

According to the cleaning liquid generator of claim 6, in addition to the action of claim 1, 2, 3, 4 or 5, p of electrolytic water supplied from the electrolytic water generating means to the cleaning liquid outflow path.
The H value is detected, and the electrolysis voltage or current of the electrolyzed water generating means is controlled based on the detected value, so that the cleaning power of the cleaning liquid is always maintained properly.

According to the cleaning liquid generator of claim 7, in addition to the function of claim 1, 2, 3, 4, 6 or 7,
The pH value of the electrolyzed water supplied from the electrolyzed water generating means to the cleaning liquid outflow path is detected, and the amount of addition of the additive mixing means is controlled based on this detected value, so that the cleaning power of the cleaning liquid is always maintained properly. Be drunk

Further, according to the cleaning device of the eighth aspect, the air sucked from the intake port comes into contact with the cleaning liquid in the main body case by the separation plate, and the cleaning liquid removes contaminants such as oil and dust, and the exhaust port. Be led to. Further, the cleaning liquid in the main body case is discharged by the discharging means, and at least one of the surfactant and the deodorant bactericide is added to the alkaline ionized water generated by the electrolyzed water generating means by the additive mixing means, and then the main body case is discharged. By supplying, the cleaning liquid in the main body case is replaced with a new cleaning liquid. That is, since the surfactant promotes detergency at a highly alkaline pH value,
The air cleaning effect is further enhanced, and the deodorant germicide prevents the generation of offensive odors and the propagation of germs. Further, due to the effect of the alkaline ionized water, oil stains do not adhere to the inside of the main body case even after long-term use.

[0021]

1 to 9 show a first embodiment of the present invention. FIG. 1 is a sectional view of a separation apparatus equipped with the cleaning liquid generator of the present invention, and FIG. FIG. 3 is an exploded perspective view of a porous element, FIG. 4 is a cross-sectional view of an electrolyzed water generator, FIG. 5 is a cross-sectional view of a surfactant additive and a deodorant additive, and FIGS. FIG.

First, the structure of the separation device will be described.
That is, the separation device 1 shown in the figure is composed of a main body case 2, a pair of separation plates 3, and a bracket 4 that supports each separation plate 3, and the cleaning liquid L is stored in the bottom of the main body case 2. ing.

The main body case 2 is formed of a metal material or a plastic material into a substantially box shape, has an intake port 2a having a horizontally long rectangular shape on two opposite side surfaces, and an exhaust port 2b having a horizontally long rectangular shape is provided on the upper surface. Has been. In addition, a drain pipe 2d having a valve 2c interposed is connected to the bottom surface of the main body case 2 so that the valve 2c can be opened to appropriately discharge the dirty cleaning liquid L.

Each separating plate 3 has a horizontally long rectangular porous element 3a.
And ventilation plates 3b and 3c having a horizontally long rectangular shape that cover the tops of both sides of the porous element 3a, and a shield plate 3 that covers the bottoms of both sides of the porous element 3a.
It is composed of d and 3e. As shown in FIG. 3, the porous element 3a is formed by laminating a plurality of grid-shaped metal nets K having the same shape, and has a large number of fine gaps continuously. The ventilation plates 3b and 3c are made of a ventilation material such as a porous plastic material or ceramic, or a well-known filter material, and assist in separating and removing contaminants in addition to rectifying the passing air. The shielding plates 3d and 3e are made of a non-breathable material such as a metal material or a plastic material, and restrict the intake and exhaust from the ventilation plates provided on both side surfaces of the porous element 3a, as well as the porous element 3
a The suction of the cleaning liquid L from the bottom surface is supplemented. Each of the separating plates 3 is fixed in parallel to each other, and the upper surface thereof is fixed to the upper surface in the main body case 2 via the bracket 4 so that the ventilation plate 3b and the shielding plate 3d on one side face the intake port 2a.
In this fixed state, each separation plate 3 has its longitudinal edge closely attached to the inner surface of the main body case 2 together with the bracket 4 via a sealing material or the like, and the lower end thereof is immersed in the cleaning liquid L. Further, in the fixed state, the boundary line between the ventilation plate 3b and the shielding plate 3d facing the intake port 2a is located in the middle of the same plane, while the boundary line between the ventilation plate 3c and the shielding plate 3e facing the exhaust port 2b is the intake port. It substantially coincides with the lower edge of 2a. Further, the intake port 2a
As the ventilation plate 3b facing to the plate, a plate having a smaller hole shape and a smaller porosity than the inner ventilation plate 3c is used.

Next, the structure of the cleaning liquid generating device 5 provided in the separating device 1 will be described. The cleaning liquid generator 5 shown in the figure comprises an electrolyzed water generator 6, a surfactant additive 7 as an additive mixing means, and a deodorant disinfectant additive 8 as well. It is designed to produce a cleaning solution from raw water.

The cleaning liquid generator 5 has a cleaning liquid outflow passage 5a at one outlet side of the electrolyzed water generator 6, and the cleaning liquid outflow passage 5a is connected to the side surface of the main body case 2. Further, the inlet side of the electrolyzed water generator 6 is connected to a water pipe (not shown), and a valve 5b is provided on this.

As shown in FIG. 4, the electrolyzed water generator 6 has an inlet 6a and two outlets 6b and 6c, a passage 6d connecting these inlets and outlets, an anode 6e and a cathode 6f which are arranged to face each other in the passage 6d, It is composed of an ion-permeable membrane 6g for partitioning between both electrodes, and tap water is allowed to flow in from an inlet 6a. In this electrolyzed water generator 6, by applying an electrolysis voltage to both electrodes 6e and 6f, the water flowing through the passage 6d is electrolyzed to contain a large amount of OH ⁻ , Ca ²⁺ , Mg ²⁺ , Na ^{+ and the} like. The alkaline ionized water and the acidic water containing a large amount of H ⁺ and ClO ⁻ are generated, and the alkaline ionized water is discharged from one of the outlets 6b.
From the outlet 6 to the liquid supply line 5, and the acidic water is discharged from the other outlet 6.
It is designed to be discharged from c.

As shown in FIG. 5, the surfactant adding device 7 is provided with a container 7a for containing the surfactant A, and the lower end of the container 7a is provided with one outlet 6 of the electrolyzed water generator 6 via a valve 7b.
It is branched and connected to the flow path on the b side. Further, a lid 7c is provided on the upper surface of the container 7a, and the lid 7c is opened to open the surfactant A.
Can be replenished. As the surfactant A, cationic or anionic surfactants such as lauryl sulfate triethanolamine salt, coconut fatty acid triethanolamine soap or sucrose fatty acid ester are highly safe and effective. % Aqueous solution. In this surfactant adding device 7, the surfactant A can be added to the liquid flowing through the liquid supply pipe 5 by opening the valve 7b and letting out the surfactant A in the container 7a.

As shown in FIG. 5, the deodorant bactericidal agent adder 8 is provided with a container 8a for containing the deodorant bactericidal agent B, and the lower end of the container 8a is provided with one outlet of the electrolyzed water generator 6 via a valve 8b. 6
It is branched and connected to the flow path on the b side. Further, a lid 8c is provided on the upper surface of the container 8a, and the lid 8c can be opened to replenish the deodorant B. As the deodorant B, a disinfectant or antibacterial agent such as ethanol, propylene glycol, glycerin, thiabendazole, lytic enzyme, rhizotium chloride, benzalnium chloride or chlorhexidine gluconate can be used as a deodorant such as fittintide, hinokitiol or degrading enzyme. A mixture of at least one kind is also highly safe, and 0.01 to 0.0 depending on the efficacy.
Used as a 5 wt% aqueous solution. In this deodorant additive device 8, the deodorant B can be added to the liquid flowing through the liquid supply conduit 5 by opening the valve 8b and allowing the deodorant B in the container 8a to flow out.

Next, the operation of the separating device will be described with reference to FIGS. 6 and 7. As shown in FIG. 8, the separation device 1 of the present embodiment has an exhaust hole T formed in a top plate T of a kitchen, kitchen or the like.
It is used by connecting its exhaust port Ta to a. The top T
An exhaust duct D with a built-in fan is connected to the exhaust hole Ta.

When a fan (not shown) of the exhaust duct D is operated during exhaust, the water level on the exhaust port 2b side rises and the water level on the intake port 2a side falls due to the air pressure. At that time, when the water level on the side of the intake port 2a slightly drops below the lower end of the shielding plate 3d of the separation plate 3, a part of the air sucked from the intake port 2a passes under the shielding plate 3d and reaches the lower end of the porous element 3a. Be guided.

Since the porous element 3a has a large number of minute gaps continuously, the air rises in the state of fine bubbles in the porous element 3a, in other words, the inside of the porous element 3a becomes bubbling, which is accompanied by it. The water level inside the porous element 3e rises to the upper end of the inner shield plate 3e, and the cleaning liquid L permeates to the upper end of the porous element 3a by the synergistic action of the capillary force. In this permeation, as shown in FIG. 9, a liquid film is formed in the holes of the wire netting K and the gaps between the wire nets, and the cleaning liquid L is attached to the holes and the gaps around the gaps where the film is not formed.

The air guided to the lower end of the porous element 3a ascends in the porous element 3a in the bubble state as described above, and in the course of this rising, contaminants such as oil, dust and malodorous gas are removed by the cleaning liquid L. , Through the inner ventilation plate 3c to the exhaust port 2b. On the other hand, the other part of the air taken in from the intake port 2a is passed through the ventilation plate 3b facing the intake port 2a, and the porous element 3
a, relatively large contaminants are trapped in the process of being guided to the upper side surface of a and passing through the ventilation plate 3b, and the porous element 3a
In the process of passing through the
Dust, malodorous gas, and other contaminants are removed, and the inner ventilation plate 3
It is guided to the exhaust port 2b through c. By the way, the split ratio of the intake air can be adjusted by the height of the shielding plate 3d on the intake port side, the submerged depth of the separation plate 3, and the like.

Further, in the above separating apparatus 1, since the oil and dust separated from the air remain in the cleaning liquid L in the main body case 2, the cleaning liquid L becomes dirty due to long-term use. In this case, the valve 2c of the main body case 2 is opened to drain the drain pipe 2d.
A new cleaning liquid L is supplied into the main body case 2 by discharging the dirty cleaning liquid L from the container and opening the valve 5a of the liquid supply conduit 5 of the cleaning liquid generator 5.

In the cleaning liquid generator 5, alkaline ionized water is generated on one electrode 6f (cathode) side of the electrolyzed water generator 6, and acidic water is generated on the other electrode 6e (anode) side. Is discharged from the outlet 6b, the surfactant A is added by the surfactant adder 7 and the deodorant B is added by the deodorant adder 8, and the cleaning liquid L is supplied into the main body case 2. The acidic water generated by the electrolyzed water generator 6 is discharged to the outside via the outlet 6c.

The surfactant used in this example is one that lowers the surface tension, increases the hydrophilicity, and promotes the cleaning action by emulsification with oil, that is, the emulsion effect. The surfactant has a property that the detergency is further improved at a highly alkaline pH value. That is, in this example, since the surfactant A is added to the alkaline ionized water generated in the electrolyzed water generator 6,
The cleaning liquid L having high cleaning power is generated.

As described above, according to the cleaning liquid generator of this embodiment, the raw water such as tap water is electrolyzed to generate alkaline ionized water, and the surfactant A and the deodorant germicide B are added thereto. As a result, the cleaning liquid L having a high detergency can be generated very easily, and the amount of the surfactant A used can be reduced by the amount corresponding to the improved detergency, which is economical and environmentally friendly. It is also advantageous in terms of aspects. Further, since the surfactant A and the deodorant bactericide B are added to the liquid supply pipe 5 by the adders 7 and 8, not only the amount of addition is adjusted but also mixing with alkaline ionized water is always performed. It can be performed uniformly.

Further, in the separation device 1 using the cleaning liquid generating device, the cleaning liquid L in the main body case 2 is discharged from the drain pipe 2c, and the cleaning liquid generating device 4 supplies new cleaning liquid L. The cleaning liquid L in the case 2 can be replaced very easily. In this case, the alkaline ionized water improves the bubbling of the cleaning liquid L and can enhance the air cleaning effect, and due to the effect of the alkaline ionized water, oil stains are left on the main body case 2 even after long-term use.
Does not adhere inside. Further, since the deodorant bactericidal agent B having an antibacterial effect is added to the cleaning liquid L, it is possible to reliably prevent generation of germs, putrid odors and the like in the cleaning liquid L.

FIGS. 8 and 9 show a second embodiment of the present invention, in which the cleaning liquid producing device is used in a separating device having a structure different from that of the first embodiment.

The separating device 11 shown in FIG.
2, a pair of separation plates 13, a bracket 14 that supports each separation plate 13, a pair of water discharge heads 15, and a bracket 16 that supports each water discharge head 15. The cleaning liquid L is stored. Further, the cleaning liquid generation device 17 shown in the figure comprises a cleaning liquid outflow path 17a, a valve 17b, an electrolyzed water generator 18, a surfactant addition device 19, and a deodorant germicide addition device 20. Since the configuration is the same as that of the above-mentioned embodiment, detailed description will be omitted.

The body case 12 is formed of a metal material or a plastic material in a box shape, and has a horizontally long rectangular inlet port 12a on two opposite side surfaces, and a horizontally long rectangular exhaust port 12b is formed on the upper surface thereof. There is. Each intake port 2 of the body case 2
A horizontally elongated rectangular airflow direction plate 2c is provided on the inner side of the upper end of a so that the inflow of intake air to the water discharge head 15 side can be suppressed. Also, a drain pipe 12d having a valve 12c interposed is connected to the bottom surface of the main body case 12 so that the valve 12c can be opened to appropriately discharge the dirty cleaning liquid L. Further, one end of the drain pipe 12d is provided above the valve at a water supply port 15a of the water discharge head 15.
The water supply pipe 12e connected to is connected in a branched manner, and the cleaning liquid L can be sent to the water discharge head 15 by a pump 12f provided in the middle of the water supply pipe 12e.

Each separating plate 13 is formed by laminating a plurality of grid-like metal nets having the same shape as in the above embodiment, and has a large number of fine gaps continuously. These separation plates 13 are fixed to the inner upper surface of the main body case 12 via brackets 14 at the upper portions of the inner side surfaces of the separation plates 13 so that they are parallel to each other and one surface faces the intake port 12a. Is closely attached to the inner surface of the main body case 12 together with the bracket 14 via a sealing material or the like, and the lower end thereof is immersed in the cleaning liquid L.

Each of the water discharge heads 15 has a laterally long shape extending orthogonally to the drawing, and has a water supply port 15a at the center of the upper surface and a plurality of water discharge ports 15b at the lower surface at equal intervals. The water discharge head 15 has an intermediate flange portion fixed to the inner upper surface of the main body case 12 via a bracket 16 so that the water discharge port 15b faces the upper end surface of the separation plate 13.

In the separation device 11 of this embodiment, the cleaning liquid L of the main body case 12 is sent to each water discharge head 15 through the water supply pipe 12e, and is evenly distributed over the entire upper end surface of each separation plate 13 from each water discharge port 15b. Is released. The discharge may be performed by natural flow, free flow, etc., instead of being carried out in the form of mist as shown. The cleaning liquid L discharged to the upper end surface of each separation plate 13 flows down along the separation plate 13, and as a result, a water film is fluidly formed in the fine gaps of the entire separation plate 13.

When the fan of the exhaust duct D is operated in the above-mentioned water discharge state, the air sucked from the intake port 12a is guided to the side face of the intake port of the separating plate 13 and is guided to the exhaust port 12b through the separating plate 13. The contaminants such as oil, dust and malodorous gas contained in the intake air are removed in the process of the intake air passing through the water film in the separation plate 13.

In the separating device 11 as well, as in the previous embodiment, the valve 12c of the main body case 12 is opened to discharge the dirty cleaning liquid L from the drain pipe 12d, and the liquid supply conduit 1
The cleaning liquid L is exchanged by opening the valve 15a of No. 5 and supplying a new cleaning liquid L into the main body case 12.

Further, in FIG. 9, shield plates 13a and 13b are provided on both sides of each of the separation plates 13 to cover from the lower end to a position higher than the water surface of the contained cleaning liquid L. The shield plates 13a and 13b are made of a non-permeable material such as a metal material or a plastic material and limit the intake / exhaust area of the separation plate 13.

In this case, as in the case described above, the cleaning liquid L contained in the main body case 12 is passed through the water supply pipe 12e to the respective water discharge heads 15.
Is sent to each separation plate 1 from each water discharge port 15b.
It is evenly discharged to the entire top surface of No. 3. The cleaning liquid L discharged to the upper end surface of each separation plate 13 flows down along the separation plate 13, and as a result, a water film is fluidly formed in the fine gaps of the entire separation plate 13.

When the fan of the exhaust duct D is operated in the above-mentioned water discharge state, the water level on the exhaust port 12b side rises and the water level on the intake port 12a side falls due to the air pressure. Intake port 12a
When the water level on the side is slightly lower than the lower end of the shield plate 13a of the separation plate 13, a part of the air sucked from the intake port 12a goes around under the shield plate 13a and is guided to the lower end of the separation plate 13. Since the separation plate 13 has a large number of fine gaps continuously, the air rises in the separation plate 3 in the form of fine bubbles, in other words, the inside of the separation plate 13 becomes bubbling, and the separation plate 13 is accompanied with this. The water level in 13 rises to the upper end of the inner shield plate b.

The air guided to the lower end of the separating plate 13 rises in the separating plate 13 in the state of bubbles as described above, and in the course of this rising, contaminants such as oil and dust are removed by the cleaning liquid L and the exhaust port 12b. Be led to. On the other hand, the other part of the air sucked from the intake port 12a is guided to the upper side surface of the separation plate 13, and in the process of passing through the separation plate 13, it comes into contact with the water film to remove contaminants such as oil and dust. It is guided to the exhaust port 12b.

According to the separating apparatus 11 of this embodiment, as shown in FIG. 8, the cleaning liquid L is discharged onto the upper end surface of the separating plate 13 to fluidly form a water film in a large number of minute gaps in the separating plate 13. In such a case, as shown in FIG. 9, in addition to discharging water to the separating plate 13, a part of the air sucked from the intake port 12a is guided to the lower end of the separating plate 13 to raise the inside of the separating plate 3 in a bubble state. In either case, the same effect as that of the first embodiment can be obtained.

As described above, in the first and second embodiments, the cleaning liquid generating device is used as the separating device for air cleaning. However, the cleaning liquid generating device of the present invention is not limited to the separating device, for example, a dishwasher. It can also be connected to other cleaning devices such as the above, a faucet of a sink, and the like. Hereinafter, another embodiment of the cleaning liquid generator will be described.

FIGS. 10 and 11 show a third embodiment of the present invention, and FIG. 10 is a schematic configuration diagram of a cleaning liquid producing apparatus.

The cleaning liquid generator 21 shown in the same figure has an electrolyzed water generator 22, a surfactant additive 23, a deodorant sterilizer additive 24, and a power supply 2 for supplying electric power to the electrolyzed water generator 22.
5, a pH sensor 26 for detecting a pH value, an electrolytic water reforming device 27 for reforming alkaline water to neutral, and a controller 2
8 and a cleaning liquid outflow path 21a is formed at one outlet side of the electrolyzed water generator 22.

Electrolyzed water generator 22, surfactant adder 23
The deodorant bactericidal agent adder 24 is configured in the same manner as in the above embodiment, and the adders 23 and 24 are provided in the flow path on the electrode 22a side of the electrolyzed water generator 22. In addition, each adder 2
3 and 24 are configured to be able to adjust the outflow amount of the liquid agent inside by automatic opening / closing mechanisms 23a and 24a each including an electromagnetic valve or an aspirator.

The power source 25 is the electrode 22 of the electrolyzed water generator 22.
The electrodes 22a and 22b are connected to each other, and a voltage is applied so that one electrode 22a serves as a cathode and the other electrode 22b serves as an anode. Further, the power supply 25 controls the electrolysis voltage or current by the control unit 27.
It can be changed arbitrarily by the signal from.

The pH sensor 26 is provided in the flow path on the one electrode 22a side of the electrolyzed water generator 22, and detects the pH value of the alkaline ionized water produced from the electrolyzed water generator 22.

The electrolyzed water reforming device 27 has one end connected to the outlet on the other electrode 22b side of the electrolyzed water generator 22, and the other end connected to the inlet side of the electrolyzed water generator 22 via the pump 27a. . The electrolyzed water reforming device 27 recovers the acidic water generated from the electrolyzed water generator 22, reforms it to neutral water, and supplies it to the electrolyzed water generator 22 again. Anion exchanger that removes anions, for example, a porous strongly basic anion exchange resin (having a quaternary ammonium group bonded) or a weakly basic anion exchange resin (1
To a tertiary amine), a hypochlorite ion (C
lO ^-), is adapted to generate a neutral water to remove SO ₄ ^2-or NO ₃ ^over like. In addition, it is also possible to use activated carbon for the ion exchanger instead of the anion exchange resin.

The control unit 28 is constituted by a microcomputer or the like, and is connected to the automatic opening / closing mechanisms 23a and 24a of the surfactant adding device 23 and the deodorant disinfectant adding device 24, the power supply 25 and the pH sensor 26.

The operation of the cleaning liquid generator 21 will be described below. First, alkaline ionized water is generated on one electrode 22a (cathode) side of the electrolyzed water generator 22, and acidic water is generated on the other electrode 22b (anode) side, and alkaline ionized water is discharged from one outlet. A surfactant is added by the surfactant adder 23, and a deodorant sterilizer is added by the deodorant sterilizer adder 24 to form a cleaning liquid. In addition, the acidic water generated in the electrolyzed water generator 22 is discharged from the other outlet and flows into the electrolyzed water reforming device 27, and becomes neutral water by the electrolyzed water reforming device 27, and then the electrolyzed water generator. 22
Is supplied to the entrance side of. As a result, the raw water (neutral) can be obtained without wasting the acidic water that had been discarded in the above-mentioned embodiment.
Since it is reused as, it is possible to reduce the amount of water used.

Next, the operation of the control unit 28 will be described with reference to the flow chart shown in FIG. First, the alkaline ionized water generated from the electrolyzed water generator 22 has pH
When the pH value is detected by the sensor 26 and the detected value A is smaller than the set value A1 (S1), the voltage V of the power supply 25 is increased by a minute value α (S2), and the detected value A is set below the set value A1. Is also large (S3), the voltage V of the power supply 25
Is decreased by a minute value α (S4). Thereby, the pH value of the cleaning liquid L is always kept proper. In addition, the control unit 28
Then, based on the detection value of the pH sensor 26, each automatic opening / closing mechanism 23 of the surfactant adding device 23 and the deodorant germicide adding device 24
The opening amounts of a and 24a may be adjusted to control the addition amounts of the surfactant and the deodorant germicide.

12 and 13 show a fourth embodiment of the present invention, and FIG. 12 is a schematic configuration diagram of a cleaning liquid generator.

The cleaning liquid generator 31 shown in the figure has an electrolyzed water generator 32, a surfactant additive 33, a deodorant sterilizer additive 34, and a power source 3 for supplying electric power to the electrolyzed water generator 32.
5, a pH sensor 36 for detecting a pH value, and a controller 37
And a cleaning liquid outflow passage 31a is formed on one outlet side of the electrolyzed water generator 32.

Electrolytic water generator 32, surfactant adder 33
The deodorant bactericidal agent adder 34 is configured in the same manner as in the above-described embodiment, and the adders 33 and 34 are provided in the flow path on the one electrode 32a side of the electrolyzed water generator 32. In addition, each adder 3
Reference numerals 3 and 34 are such that the amount of outflow of the liquid agent inside can be adjusted by automatic opening / closing mechanisms 33a and 34a including electromagnetic valves or aspirators.

The power source 35 is the electrode 32 of the electrolyzed water generator 32.
A voltage is applied so that the polarities of the one electrode 32a and the other electrode 32b can be arbitrarily switched. Further, the power source 35 can arbitrarily change the electrolysis voltage or current by a signal from the control unit 37.

The pH sensor 36 is provided in the flow path on the one electrode 32a side of the electrolyzed water generator 32, and is the same as in the above embodiment.
P of alkaline ionized water generated from the electrolyzed water generator 32
The H value is detected.

The control unit 37 is constituted by a microcomputer or the like, and is connected to the automatic opening / closing mechanisms 33a and 34a of the surfactant adding device 33 and the deodorant sterilizing agent adding device 34, the power source 35 and the pH sensor 36. In addition, the control unit 37
An operating unit 37a is connected to the operating unit 37a, and the operating unit 37a can perform mode switching for selectively switching the cleaning liquid between alkaline, acidic and neutral.

The operation of the cleaning liquid generator 31 will now be described with reference to the flow chart shown in FIG. First, the electrolyzed water generated on the one electrode 32a side of the electrolyzed water generator 32 is discharged from one outlet and supplied to the outside as a cleaning liquid, and the electrolyzed water generated on the other electrode 32b side passes through the other outlet. Exhausted through.

At this time, in the control unit 37, when a mode change command is issued from the operation unit 37a (S10), the operation unit 37a is operated.
If the mode is set to alkaline (S1
1) The polarity of the power source 35 is switched so that one electrode 32a of the electrolyzed water generator 32 serves as a cathode and the other electrode 32b serves as an anode (S12). As a result, the surfactant and the deodorant bactericide are added to the alkaline ionized water generated at the one electrode 32a and supplied to the outside as an alkaline cleaning liquid. When the mode of the operation unit 37a is set to acidic (S13), the one electrode 3 of the electrolyzed water generator 32 is used.
The polarity of the power source 35 is switched so that the electrode 2a serves as an anode and the other electrode 32b serves as a cathode (S14). As a result, the acidic water generated at the one electrode 32a is supplied to the outside as an acidic cleaning liquid. In this case, the additives (surfactant and deodorant germicide) are not mixed. Further, when the mode of the operation unit 37a is neutral, that is, when neither the alkaline mode nor the acidic mode is selected in steps S11 and S13, the power supply 35 is turned off to cancel the application of the voltage to the electrolyzed water generator 32 (S15). . As a result, the tap water flowing into the electrolyzed water generator 32 is supplied to the outside as a neutral cleaning liquid without being electrolyzed.

Such a mode change can be performed, for example, in a washing liquid generator connected to a faucet of a sink or the like, when washing dishes or the like in an alkaline mode, after washing, the neutral mode is switched to a neutral washing liquid ( It is effective when the alkaline cleaning solution is washed off with tap water) or when the ingredients such as vegetables are washed in acidic mode and washed with acidic water (acidic water has a bactericidal effect). Incidentally, the control of the pH value of the cleaning liquid and the control of the addition amounts of the surfactant and the deodorant bactericide are the same as those in the above examples.

14 and 15 show a fifth embodiment of the present invention, and FIG. 14 is a schematic configuration diagram of a cleaning liquid producing apparatus.

The cleaning liquid generator 41 shown in the figure has an electrolyzed water generator 42, a surfactant additive 43, a deodorant germicide additive 44, and a power source 4 for supplying electric power to the electrolyzed water generator 42.
5, a pH sensor 46 for detecting a pH value, a solenoid valve 47 for switching the flow path of electrolyzed water, a three-way valve 48, and a controller 49, which are provided at one outlet side of the electrolyzed water generator 42. Is a second cleaning liquid outflow path 41a which is connected to the first cleaning liquid outflow path 41a by bypassing the surfactant addition device 43 and the deodorant germicide addition device 44 on the other outlet side.
The cleaning liquid outflow paths 41b are formed respectively.

Electrolyzed water generator 42, surfactant adder 43
The deodorant bactericidal agent adder 44 is configured in the same manner as in the above-described embodiment, and the adders 43 and 44 are provided in the flow path on the electrode 42a side of the electrolyzed water generator 42. In addition, each adder 4
3, 44 are automatic opening / closing mechanisms 43a, 44a, which are electromagnetic valves or aspirators, for adjusting the outflow amount of the liquid agent inside.

The power source 45 is the electrode 42 of the electrolyzed water generator 42.
The electrodes 42a and 42b are connected to each other, and a voltage is applied so that one electrode 42a serves as a cathode and the other electrode 42b serves as an anode. Further, the power supply 45 controls the electrolysis voltage or current by the control unit 49.
It can be changed arbitrarily by the signal from.

The pH sensor 46 is provided in the flow path on the one electrode 42a side of the electrolyzed water generator 42, and as in the above embodiment,
P of alkaline ionized water generated from the electrolyzed water generator 42
The H value is detected.

The solenoid valve 47 is the first cleaning liquid outflow path 41a.
It is provided in a flow path that branches off from, and the alkaline ionized water generated from the electrolyzed water generator 42 is discharged by opening this flow path.

The three-way valve 48 is the second cleaning liquid outflow passage 41b.
And the other electrode 4 of the electrolyzed water generator 42 provided on one end side
Electrolyzed water generator 4 by communicating with the flow path on the 2b side
The acidic water generated from the first cleaning liquid outflow path 41a
To the other electrode 4 of the electrolyzed water generator 42 on the other end side.
Electrolyzed water generator 4 by communicating with the flow path on the 2b side
The acidic water generated from No. 2 is discharged from the other end side.

The control unit 49 is composed of a microcomputer or the like, and has automatic opening / closing mechanisms 43a and 44a for the surfactant adding device 43 and the deodorant sterilizing agent adding device 44, a power supply 45,
It is connected to the pH sensor 46, the solenoid valve 47, and the three-way valve 48. Further, an operation section 49a is connected to the control section 49, and the operation section 49a can perform mode switching for selectively switching the cleaning liquid between alkaline, acidic and neutral.

Now, the operation of the cleaning liquid generator 41 will be described with reference to the flow chart shown in FIG. First, alkaline ionized water is generated on one electrode 42a (cathode) side of the electrolyzed water generator 42 and acidic water is generated on the other electrode 42b (anode) side, respectively, and the alkaline ionized water is discharged from one outlet to generate acidic water. Water is discharged from the other outlet.

At this time, in the control unit 49, when a mode change command is issued from the operation unit 49a (S20), the operation unit 49a is operated.
When the mode is set to alkaline (S2
1), the solenoid valve 47 is closed (S22), one end of the three-way valve 48 is closed (S23), and the drain side of the other end is opened (S2).
4). Accordingly, the alkaline ionized water generated from the electrolyzed water generator 42 is supplied to the outside as an alkaline cleaning liquid with the addition of the surfactant and the deodorant germicide, and the acidic water generated from the electrolyzed water generator 42 is Exhausted via valve 48. Further, when the mode of the operation unit 49a is set to acidic (S25), the solenoid valve 47 is opened (S2).
6) Open one end of the three-way valve 48 (S27) and close the drain side of the other end (S28). As a result, the acidic water generated from the electrolyzed water generator 42 is supplied to the outside as an acidic cleaning liquid, and the alkaline ionized water generated from the electrolyzed water generator 42 is discharged via the solenoid valve 47. Further, the mode of the operation unit 49a is neutral, that is, the steps S21 and S.
When it is neither in the alkaline mode nor in the acidic mode in 25, the power supply 35 is turned off and the application of the voltage to the electrolyzed water generator 44 is canceled (S29). As a result, the tap water flowing into the electrolyzed water generator 42 is supplied to the outside as a neutral cleaning liquid without being electrolyzed. Incidentally, the control of the pH value of the cleaning liquid and the control of the addition amounts of the surfactant and the deodorant bactericide are the same as those in the above examples.

[0081]

As described above, according to the cleaning liquid generating apparatus of the first aspect, a cleaning liquid having a high cleaning effect can be generated very easily. Therefore, it is possible to clean various articles or the cleaning effect of the cleaning device. It is possible to remarkably increase the odor, and it is also possible to prevent the generation of offensive odor and the propagation of various bacteria. Further, since the amount of the cleaning liquid used can be reduced by the amount that the cleaning effect is improved, it is also advantageous in terms of economy and environmental hygiene.

According to the cleaning liquid generator of claim 2, in addition to the effect of claim 1, the acidic water generated from the electrolyzed water generating means can be reused as raw water without being wasted. Can save money.

According to the cleaning liquid generator of claims 3 and 4, in addition to the effect of claim 1, not only an alkaline cleaning liquid but also an acidic cleaning liquid having a bactericidal effect without mixing an additive is generated. This is advantageous when washing foodstuffs.

According to the cleaning liquid generator of the fifth aspect, in addition to the effect of the third or fourth aspect, the generated cleaning liquid can be arbitrarily switched between alkaline, acidic and neutral. Each of the cleaning liquids can be selected as necessary, such as an alkaline cleaning liquid for removing stains, and a neutral cleaning liquid for washing away, and an acidic cleaning liquid for cleaning foods.

According to the cleaning liquid generator of claims 6 and 7, in addition to the effect of claim 1, 2, 3, 4 or 5,
Since the cleaning power of the cleaning liquid can always be maintained properly, it is advantageous when the cleaning operation is automated, such as in a cleaning device.

According to the cleaning device of the eighth aspect, the cleaning liquid in the main body case can be exchanged very easily, so that the labor of the user can be greatly reduced. In addition, the alkaline ionized water improves the foaming of the cleaning liquid, which can enhance the cleaning effect of the air and air purification filter, and since oil stains do not adhere inside the main body case even after long-term use, the main body case The cleaning work inside can be performed very easily. Furthermore, it is possible to prevent the generation of offensive odor and the propagation of various bacteria.

[Brief description of drawings]

FIG. 1 is a sectional view of a separation device showing a first embodiment of the present invention.

FIG. 2 is an external perspective view of a separation device excluding one side surface.

FIG. 3 is an exploded perspective view of a porous element

FIG. 4 is a sectional view of an electrolyzed water generator

FIG. 5 is a cross-sectional view of a surfactant adder and a deodorant adder.

FIG. 6 is an operation explanatory diagram of the separation device.

FIG. 7 is an explanatory view of the action of the porous element.

FIG. 8 is a sectional view of a separation device showing a second embodiment of the present invention.

FIG. 9 is a sectional view of a separation device showing a modified example of the second embodiment.

FIG. 10 is a schematic configuration diagram of a cleaning liquid generator showing a third embodiment of the present invention.

FIG. 11 is a flowchart showing the operation of the control unit.

FIG. 12 is a schematic configuration diagram of a cleaning liquid generation device showing a fourth embodiment of the present invention.

FIG. 13 is a flowchart showing the operation of the control unit.

FIG. 14 is a schematic configuration diagram of a cleaning liquid generation device showing a fifth embodiment of the present invention.

FIG. 15 is a flowchart showing the operation of the control unit.

[Explanation of symbols]

1 ... Separation device, 2 ... Main body case, 2a ... Intake port, 2b ...
Exhaust port, 2d ... Drain pipe, 3 ... Separation plate, 5 ... Cleaning liquid generating device, 5a ... Cleaning liquid outflow path, 6 ... Electrolyzed water generator, 6e,
6f ... Electrode, 7 ... Surfactant adder, 8 ... Deodorant adder, L ... Cleaning liquid, 11 ... Separator, 12 ... Main body case,
12a ... intake port, 12b ... exhaust port, 12d ... drainage pipe, 1
3 ... Separation plate, 17 ... Cleaning liquid generator, 17a ... Cleaning liquid outflow path, 18 ... Electrolyzed water generator, 19 ... Surfactant additive, 20 ... Deodorant additive, 21 ... Cleaning liquid generator, 21
a ... Cleaning liquid outflow path, 22 ... Electrolyzed water generator, 22a, 2
2b ... Electrode, 23 ... Surfactant adder, 24 ... Deodorant adder, 26 ... Electrolyzed water reforming device, 27 ... pH sensor, 28
... control unit, 31 ... cleaning liquid generator, 31a ... cleaning liquid outflow path, 32 ... electrolyzed water generator, 32a, 32b ... electrode, 3
3 ... Surfactant adder, 34 ... Deodorant adder, 36 ... p
H sensor, 37 ... Control unit, 41 ... Cleaning liquid generating device, 41
a ... 1st washing | cleaning liquid outflow path, 41b ... 2nd washing | cleaning liquid outflow path, 42 ... Electrolyzed water generator, 42a, 42b ... Electrode, 4
3 ... Surfactant adder, 44 ... Deodorant adder, 46 ... p
H sensor, 47 ... Solenoid valve, 48 ... Three-way valve, 49 ... Control part.

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI technical display C11D 17/00

Claims (8)

[Claims] 1. Electrolyzed water producing means for producing alkaline ionized water on one electrode side and acidic water on the other electrode side by causing raw water to flow between a pair of electrodes and electrolyzing, respectively. A cleaning liquid outflow route for supplying the alkaline ionized water generated from one electrode side of the generating means to the outside as a cleaning liquid, and an additive for adding at least one of a surfactant and a deodorant germicide to the alkaline ionized water in the cleaning liquid outflow route. A cleaning liquid generation apparatus comprising: a mixing unit. 2. An electrolytic water reforming means for reforming the acidic water generated from the other electrode side of the electrolytic water generating means to neutral and supplying it to the raw water inflow side of the electrolytic water generating means. The cleaning liquid generator according to claim 1. 3. Electrolyzed water which produces alkaline ionized water or acidic water on one electrode side and acidic water or alkaline ionized water on the other electrode side by causing raw water to flow between a pair of electrodes for electrolysis. Generating means, a cleaning liquid outflow path for supplying the alkaline ionized water or acidic water generated from one electrode side of the electrolytic water generating means to the outside as a cleaning liquid, and a switching means for switching the polarity of each electrode of the electrolytic water generating means, A cleaning liquid generating apparatus, comprising: an additive mixing means for adding at least one of a surfactant and a deodorant bactericide to alkaline ionized water or acidic water in the cleaning liquid outflow route. 4. Electrolyzed water producing means for producing alkaline ionized water on one electrode side and acidic water on the other electrode side by causing raw water to flow between a pair of electrodes for electrolysis, and electrolytic water. A first cleaning liquid outflow path for supplying the alkaline ionized water generated from one electrode side of the generating means to the outside as a cleaning liquid, and an acidic water generated from the other electrode side of the electrolyzed water generating means as a cleaning liquid to the outside. A second cleaning liquid outflow route, a switching means for switching each cleaning liquid outflow route, and an additive mixing means for adding at least one of a surfactant and a deodorant germicide to the alkaline ionized water or the acidic water in the cleaning liquid outflow route. A cleaning liquid generation device comprising: 5. An alkaline water mode in which an alkaline cleaning liquid is generated by the switching means, an acidic water mode in which an acidic cleaning liquid is generated by the switching means, and the application of an electrolytic voltage to the electrolyzed water generating means is canceled. 5. The cleaning liquid generation device according to claim 3, further comprising a mode switching means capable of arbitrarily switching between a neutral water mode for generating a neutral cleaning liquid and a neutral water mode. 6. A pH value detecting means for detecting a pH value of the electrolyzed water supplied from the electrolyzed water producing means to the cleaning liquid outflow path, and an electrolysis voltage of the electrolyzed water producing means based on the detection value of the pH value detecting means or The cleaning liquid generation apparatus according to claim 1, further comprising a pH value control unit that controls an electric current. 7. A pH value detecting means for detecting a pH value of electrolyzed water supplied from the electrolyzed water generating means to the cleaning liquid outflow path, and an addition amount of the additive mixing means based on the detected value of the pH value detecting means. 7. The cleaning liquid generation device according to claim 1, further comprising: an addition amount control unit that controls the amount. 8. A main body case having a bottom part containing a cleaning liquid and having an intake port and an exhaust port on its upper part, and the main body case is arranged so as to be partitioned into an intake port side and an exhaust port side. Separation plate for contacting the air flowing to the side with the cleaning liquid, a discharge means for discharging the cleaning liquid in the main case, electrolyzed water generation means for electrolyzing raw water to generate alkaline ionized water, and electrolysis water generation means A cleaning solution outflow path for supplying the alkaline ionized water as a cleaning solution into the main body case, and an additive mixing means for adding at least one of a surfactant and a deodorant germicide to the alkaline ionized water in the cleaning solution outflow path. Cleaning device characterized by.