JP2016506301A - Sterilization washing water - Google Patents

Abstract

The sterilizing and washing water device includes a cylindrical outer casing having a fixed space inside, and a filtration filter that is provided inside the outer casing and filters floating matter and sludge that can be confirmed with the naked eye. Backwashing function that concentrates suspended matter and sludge in the space or the space between the inner wall surface of the outer casing and the outer wall surface of the filtration filter, and periodically discharges the concentrated suspended matter and sludge to the outside. The first filter that discharges the first source water that has passed through the filtration filter and the second source water that contains concentrated suspended matter and sludge; the first source water that has passed through the first filter is filtered to produce bacteria and disease A second filter that removes the inducing substance; a purified water discharge portion that discharges the first source water that has passed through the second filter; and electrolyzed the second source water that has passed through the first filter. A sterilizing water generating unit that generates sterilizing water; and a sterilizing water discharging unit that discharges sterilizing water that has passed through the sterilizing water generating unit.

Description

  The present invention relates to an apparatus for producing sterilized water and purified water, and in particular, a backwashing filter that discharges suspended matters and sludge to the outside, and the filtered water is electrolyzed and sterilized during backwashing filtration. It is related with the sterilization washing water machine which manufactures sterilization water and purified water by implement | achieving the sterilization water production | generation apparatus which manufactures water.

  A water purification filter is a device having a structure that takes tap water, ground water, and other source water, and converts them into potable water through a filtration process.

  The filtration process in such an apparatus is a stage for removing various impurities contained in the source water and contamination sources such as bacteria, and is performed using a plurality of filters each having a functional role.

  The primary filtration filter functions to remove relatively large sources of contamination such as various suspended solids and foreign matters that can be confirmed with the naked eye, and is replaced and managed in units of about 3 to 6 months.

  When the water passes through the primary filter, the secondary filter uses a filter that adsorbs a gas-like contamination source contained in the water or a fine substance with a size that is difficult to identify with the naked eye, and is about 6 to 9 months. Exchange and manage at.

  The water that has passed through the secondary filtration filter enters the tertiary filtration filter, and this filter uses a membrane filter that can remove bacteria and disease-inducing substances, and is exchanged in units of about one year to one year and six months.

  The filtration filter installed thereafter is used as a filter for giving aesthetic stability to consumers and improving the taste of water, and is exchanged and managed in units of about one year to one year and six months.

  As described above, the plurality of filtration filters are sequentially attached to perform the filtration process. Since each filter has a different life depending on the filtration capacity, it is necessary to periodically replace and manage the filter.

  The filter filter described above does not have a constant filter life depending on the water quality level of the source water, and in some cases has a life that is less than the expected value, so its functionality is significantly reduced. For this reason, the irregular life of the filter is very troublesome not only from the user's standpoint but also from the manager's standpoint.

  Despite these problems, from the consumer's standpoint, they must be used even if they are inconvenient due to structural limitations. This increases consumer dissatisfaction.

  The present invention, which has been made to solve such problems, includes a backwashing filter that discharges suspended matter and sludge to the outside, and electrolyzes the filtered water during backwashing filtration to produce sterilized water. The purpose of the present invention is to provide a sterilizing / washing water device for producing sterilized water and purified water by realizing the sterilized water producing device to be manufactured.

  A sterilizing / washing water device according to the features of the present invention for achieving the above-described object includes a cylindrical outer casing having a fixed space inside, a floating substance provided inside the outer casing, and visible to the naked eye. A filtration filter for filtering sludge, and the filtration filter concentrates suspended matter and sludge in the internal space of the filtration filter or the space between the inner wall surface of the outer casing and the outer wall surface of the filtration filter, and periodically Backwashing function to discharge suspended matter and sludge concentrated to the outside.

  A sterilizing / washing water device according to the characteristics of the present invention includes a cylindrical electrode housing having a constant space therein, a housing upper cap coupled to an upper portion of the electrode housing, and a housing lower cap coupled to a lower portion of the electrode housing. And a (+) or (−) electrode terminal that is extended in the cylindrical length direction and receives external power supply, and is connected to the inside of the electrode housing. A plurality of circular electrode plates that are arranged in order in the inner direction of the electrode housing with a constant distance in order from the smallest diameter and that function as (+) or (−) pole electrodes, The source water that has flowed into the space between them is electrolyzed while passing to produce sterilized water.

  A sterilizing and washing water apparatus according to the characteristics of the present invention includes a cylindrical outer casing having a fixed space inside, a filtration filter that is provided inside the outer casing and filters floating matter and sludge that can be confirmed with the naked eye, Concentrate suspended matter and sludge in the internal space of the filtration filter or the space between the inner wall surface of the outer casing and the outer wall surface of the filtration filter, and periodically discharge the concentrated suspended matter and sludge to the outside. The first filter that performs the back washing function and discharges the first source water that has passed through the filtration filter and the second source water that contains concentrated suspended matter and sludge; the first source that has passed through the first filter A second filter that removes bacteria and disease-inducing substances by filtering water; a purified water outlet that discharges the first source water that has passed through the second filter; and passed through the first filter Sterilizing water producing section 2 raw water by electrolyzing to produce sterilizing water; and sterilizing water water output for discharging the sterilizing water which has passed through the sterilizing water producing section; including.

  With the configuration described above, the present invention regenerates the function of the filter by detaching suspended matter and contamination sources adhering to the block filter provided inside the outer casing at any time by the backwashing function, thereby greatly increasing the filter life. There is an effect to make.

  In addition, the present invention uses a backwashing filter to regenerate the function of the filter, thereby reducing the cost of users that are excessively generated by a short filter replacement cycle and generating filter waste that may adversely affect the environment. By reducing this, many economic ripple effects can be expected.

  In the present invention, the space between each circular electrode plate is formed as a flow path to increase the length of the flow path, and the contact time is maximized by causing rotation and eddy current phenomenon in the inflowing source water. And having a reaction of substituting the electrolyte in the source water with radicals has an effect of exerting strong sterilizing power and cleaning power.

It is a figure which shows the structure of the sterilization washing apparatus which concerns on embodiment of this invention. It is a figure which shows the structure of the microbubble apparatus which concerns on embodiment of this invention. It is sectional drawing which shows the structure of the backwashing filter part which concerns on 1st Embodiment of this invention. It is sectional drawing which shows the structure of the backwashing filter part which concerns on 2nd Embodiment of this invention. It is sectional drawing which shows the structure of the backwashing filter part which concerns on 3rd Embodiment of this invention. It is sectional drawing which shows the structure of the backwashing filter part which concerns on 4th Embodiment of this invention. It is sectional drawing which shows the structure of the sterilization water production | generation part which concerns on 1st Embodiment of this invention. It is sectional drawing which shows the structure of the sterilization water production | generation part which concerns on 2nd Embodiment of this invention. It is sectional drawing which shows the structure of the elastic seal structure part of the sterilization water production | generation part which concerns on 2nd Embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that a person having ordinary knowledge in the technical field to which the present invention can easily carry out. However, the present invention can be implemented in a variety of different forms and is not limited to the embodiments described herein. In the drawings, in order to clearly describe the present invention, unnecessary portions for the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

  Throughout the specification, when a part “includes” a component, this means that the component may further include other components, unless otherwise stated, unless otherwise stated. To do.

  FIG. 1 is a diagram showing a configuration of a sterilizing and cleaning apparatus according to an embodiment of the present invention.

  The sterilizing and cleaning apparatus according to the embodiment of the present invention includes a backwashing filter unit 100, a sterilizing water generation unit 200, a block carbon filter unit 300, water discharge units 400 and 500, and a cold / hot water supply device 600.

  The backwashing filter unit 100 is a filtration filter for filtering floating substances and sludge that can be visually confirmed, and concentrates the floating substances and sludge, and periodically discharges the concentrated floating substances and sludge to the outside. A washing function is performed.

  The backwashing filter unit 100 discharges the first source water that has passed through the filtration filter and the second source water including the concentrated suspended matter and sludge.

  The block carbon filter unit 300 filters the first source water discharged from the backwashing filter unit 100 to remove bacteria and disease-inducing substances. Here, besides the block carbon filter, the block carbon filter unit 300 can use any of various filters such as a membrane filter and a ceramic filter, or can be configured by combining a plurality of filters. You can also.

  The sterilizing water generator 200 electrolyzes the second source water discharged from the backwashing filter unit 100 to generate and supply sterilizing water.

  The water outlet includes a purified water outlet 400 and a sterilized water outlet 500.

  The sterilizing water discharge unit 500 passes the sterilizing water that has passed through the sterilizing water generation unit 200 through the microbubble device 700, and generates and injects particles in the form of microbubbles or mist.

  The purified source water that has passed through the block carbon filter unit 300 is discharged through the purified water discharge unit 400, or passes through the cold / hot water supply device 600 and is discharged through the purified water discharge unit 400 in the form of cold water or hot water.

  Here, the cold / hot water supply device 600 is a vacuum latent heat type cold / hot water supply device that cools and cools a heat source generated by applying electric power to a thermoelectric element located outside via a heat transfer housing that is in close contact with the thermoelectric element. Heat is directly transmitted to the inside of the cold / hot water supply device 600 as a heat source for heating, or the heat is directly transferred to the inside of the cold / hot water supply device 600 through a heat pipe integrated with the heat transfer housing.

  The cold / hot water supply device 600 uses the technology disclosed in Korean Patent Application No. 10-2013-0002164 (Title of Invention: Vacuum Latent Heat Type Cold / Hot Water Supply Device), and detailed description of the components is omitted. .

  FIG. 2 is a diagram showing the configuration of the microbubble device according to the embodiment of the present invention.

  The sterilized water that has passed through the sterilized water generating unit 200 flows into the source water inlet 710.

  The microbubble device 700 includes a first fluid spin hole 720 that has a spiral rotation groove formed on the outer edge and through which the sterilizing water passes in order to rotate the sterilizing water that has flowed through the source water inlet 710.

  The first fluid spin hole 720 is located in the front end of the microbubble device 700 and increases the flow rate of water.

  In these microbubble devices 700, the second fluid spin hole 740 is also provided in the rear end portion of the microbubble device 700 to further accelerate the flow rate of the sterilizing water that has passed through the flexible bellows 730.

  As described above, the microbubble device 700 includes the two fluid spin holes 720 and 740, so that a large amount of air is mixed in the process of passing the sterilized water having an accelerated flow rate through the air inlet 750. Increase the effect of.

  In addition, a magnet 760 is provided at the rear end of the second fluid spin hole body 740 to soften the water by splitting and ionizing the sterilized water cluster that has passed through the second fluid spin hole body 740 and accelerated. To do.

  The air inflow port 750 has a structure in which a female screw and a male screw having a gap enough to allow air to flow in are screwed together, and a sufficient amount of air is introduced so that a bubble can be formed. Let

  The sterilized water that has passed through the second fluid spin hole 740 is mixed with the air that flows in at a flow rate, and microbubbles in which water and air are mixed are formed.

  The mesh network 770 subdivides the cluster of bubble water once again while passing before the microbubbles are ejected.

  The bubble outlet 780 injects bubble water in the form of micro bubbles or mist that has passed through the mesh net 770.

  FIG. 3 is a cross-sectional view showing the configuration of the backwashing filter unit according to the first embodiment of the present invention.

  The backwashing filter unit 100 according to the first embodiment of the present invention has an outer case having a structure in which a cylindrical outer casing 110 and an outer casing cap 120 coupled to a lower end of the outer casing 110 to prevent water leakage are connected. A source water inlet 122 through which source water flows is formed through the center of the lower surface of the outer casing cap 120, and a block filter 130 having a smaller diameter than the outer casing 110 is provided inside the outer casing 110. .

  The block filter 130 has a cylindrical shape and penetrates the inside in the vertical direction, and the opening at the lower end communicates with the source water inlet.

  An antibacterial ball 140 is disposed in the internal space 142 of the block filter 130. The antibacterial ball 140 floats together with the source water in the space by the source water that has flowed in.

  In the internal space 142 of the block filter 130, there is a spin structure 150 in which a spiral rotation groove is formed on a circular outer edge in order to rotate the source water flowing into the opening on the lower surface and enhance the straightness. Provided. A mesh net 152 for preventing the antibacterial ball 140 from being detached from the outside is provided under the spin structure 150.

  A side flow path formation prevention cap 154 is formed on the lower surface of the block filter 130, and a water discharge blocking cap 156 is formed on the upper surface.

  The side flow path formation prevention cap 154 is a member that prevents the source water and the antibacterial ball 140 that have flowed in from coming out to the side. The water discharge blocking cap 156 is a member that prevents the source water that has flowed in from flowing out without passing through the block filter 130.

  When the source water flows in through the source water inlet 122, rotation is induced in the source water that has passed through the side surface flow path formation prevention cap 154 and the mesh net 152, and the inflowed water is increased by the spin structure 150. It is formed.

  In the internal space 142 of the block filter 130, the antibacterial ball 140 is moved with very irregular kinetic energy by the source water in which the increased flow velocity and vortex are formed, so that the block filter 130 does not pass through the block filter 130. Remove floating substances and pollution sources that have adhered to the inner wall.

  The backwashing water outlet 160 is formed through the center of the upper surface of the outer casing 110 and communicates with the internal space 142 of the block filter 130 to discharge floating substances and contamination sources.

  These floating substances and contamination sources are concentrated in the internal space 142 of the block filter 130 by water pressure, vortex flow, and antibacterial balls 140, and the backwashing outlet 160 is formed by a valve or switch formed on the upper side of the backwashing filter unit 100. Is selectively opened and discharged to the outside.

  The purified water outlet 170 is formed through the upper edge of the outer casing 110 and communicates with the space between the outer casing 110 and the block filter 130 to discharge the purified water.

  A purified water outlet 170 and a backwashing outlet 160 are arranged side by side on the outer upper surface of the backwashing filter unit 100.

  When the source water flows in through the source water inlet 122, the source water that has flowed in is sterilized by the antibacterial ball 140 and filtered while moving along the side direction from the inner wall surface of the block filter 130 to the outer wall surface.

  The filtered water is discharged from the purified water outlet 170.

  In addition to the sterilization and antibacterial functions, the antibacterial ball 140 reciprocates by water pressure along the inner wall surface of the block filter 130 and removes the suspended matter attached to the inner wall surface of the block filter 130.

  The detached floating substance and the contamination source are forcibly discharged through the backwashing water outlet 160 that is opened at any time.

  The operation principle of backwashing that forcibly discharges these floating substances and pollution sources restores the function of the filter normally, extends the life of the filter, and increases the water purification capacity.

  FIG. 4 is a cross-sectional view showing a configuration of a backwashing filter unit according to the second embodiment of the present invention.

  FIG. 4 is the same as the configuration of the backwashing filter unit 100 according to the first embodiment of the present invention described above, and the same components are denoted by the same reference numerals, redundant description is omitted, and differences are mainly described. explain.

  In the backwashing filter unit 100 of the second embodiment of the present invention, the backwashing outlet 160 of the first embodiment described above is the source water inlet 122, the purified water outlet 170 is the backwash outlet 160, and the source water inlet. 122 is replaced with the purified water outlet 170, respectively.

  The backwashing filter unit 100 according to the second embodiment of the present invention has an outer case having a structure in which a cylindrical outer casing 110 and an outer casing cap 120 formed at the lower end portion of the outer casing 110 to prevent water leakage are connected. Composed.

  The outer casing 110 is formed with a source water inlet 122 through which source water flows into the center of the upper surface.

  The purified water outlet 170 is formed through the central portion of the lower surface of the outer casing 110 and communicates with the internal space 142 of the block filter 130 to discharge purified water.

  A circular edge of the upper surface of the block filter 130 is closed by a water blocking cap 158. In the block filter 130, a spin structure is formed so as to surround the periphery of the water blocking cap 158.

  With such a structure, the source water that has flowed in through the source water inlet 122 is guided between the inner wall surface of the outer casing 110 and the outer wall surface of the block filter 130 by the incoming water blocking cap 158, and from the outer wall surface of the block filter 130 to the inner side. Filtered while passing through the wall. The water thus filtered moves downward from the internal space 142 of the block filter 130 and is discharged from the purified water outlet 170.

  The block filter 130 transmits a strong impact and pressure to the outer wall surface of the block filter 130 for smooth discharge when performing a backwashing function for removing floating substances and contamination sources attached to the outer wall surface of the block filter 130. There must be.

  For this reason, the spin structure is provided so as to surround the outer edge of the water blocking cap 158, thereby increasing the flow rate of the source water that has flowed in and increasing the kinetic energy so that suspended matter and contamination sources are present on the outer wall surface of the block filter 130. Prevent sticking.

  These spin structures can be selectively applied depending on the quality of the source water.

  The backwashing outlet 160 is formed to penetrate the upper surface edge of the outer casing 110 and communicates with the space between the inner wall surface of the outer casing 110 and the outer wall surface of the block filter 130 to discharge floating substances and contamination sources.

  The backwashing filter unit 100 has a backwashing water outlet 160 and a source water inlet arranged side by side on the outer upper surface.

  The source water that has flowed in through the source water inlet is filtered through the inner space 142 of the block filter 130 along the inner wall surface of the outer casing 110 and the outer wall surface of the block filter 130 by water pressure.

  The source water that has flowed into the internal space 142 of the block filter 130 is sterilized by the antibacterial balls 140 and is discharged from the purified water outlet 170 through the mesh net 152.

  Floating matter and contamination sources that have not passed through the block filter 130 are discharged to the outside when the backwashing outlet 160 is opened by the action of water pressure, so that the function of the filter can be restored to normal and the life of the filter can be extended. Increase water purification capacity.

  FIG. 5 is a cross-sectional view showing a configuration of a backwashing filter unit according to the third embodiment of the present invention.

  FIG. 5 is the same as the configuration of the backwashing filter unit 100 according to the first embodiment of the present invention described above, and the same components are denoted by the same reference numerals, redundant description is omitted, and differences are mainly described. explain.

  The backwashing filter unit 100 according to the third embodiment of the present invention has an outer case having a structure in which a cylindrical outer casing 110 and an outer casing cap 120 formed at the lower end of the outer casing 110 to prevent water leakage are connected. In the center of the upper surface of the outer casing 110, a purified water outlet 170 through which source water is discharged is formed.

  The source water inlet 122 is formed through the center of the lower surface of the outer casing cap 120 so that the source water flows in.

  The backwashing filter unit 100 communicates the internal space 142 of the upper block filter 132 and the internal space 142 of the lower block filter 134 with the separation membrane 180, and between the inner wall surface of the outer casing 110 and the outer wall surface of the block filter 130. By closing this space, the upper block filter 132 and the lower block filter 134 are partitioned.

  In the block filter, a separation membrane 180 having a circular shape in plan view is inserted in the horizontal direction by the thickness thereof, and the other end of the separation membrane 180 is coupled to the inner wall surface of the outer casing 110 so that the upper block filter 132 and the lower block filter are combined. 134.

  The circular edge of the lower surface of the lower block filter 134 is closed by a source water inflow blocking cap 157, and the circular edge of the upper surface of the upper block filter 132 is closed by a purified water discharge blocking cap 159.

  With such a structure, the source water flowing in through the source water inlet 122 is guided between the inner wall surface of the outer casing 110 and the outer wall surface of the lower block filter 134 by the source water inflow blocking cap 157, It is filtered from the wall surface through the inner wall surface.

  Thus, the water filtered in the internal space 142 of the lower block filter 134 moves to the internal space 142 of the upper block filter 132 located above by the water pressure, and the internal space 142 and the upper block filter 132 of the lower block filter 134 are moved. The antibacterial ball 140 in the internal space 142 is sterilized, passes through the outer wall surface from the inner wall surface of the upper block filter 132, and is filtered again.

  The water filtered by the upper block filter 132 moves upward along the outer wall surface of the upper block filter 132 and the inner wall surface of the outer casing 110 and is discharged from the purified water outlet 170.

  The lower surface of the outer casing 110 communicates with a backwashing water outlet 160 that communicates with the space between the inner wall surface of the outer casing 110 and the outer wall surface of the block filter 130 and discharges floating substances and contamination sources.

  The backwashing filter unit 100 has a backwashing water outlet 160 and a source water inlet arranged side by side on the outer lower surface.

  FIG. 6 is a cross-sectional view showing the configuration of the backwashing filter unit according to the fourth embodiment of the present invention.

  FIG. 6 is the same as the configuration of the backwashing filter unit 100 according to the first embodiment of the present invention described above, and the same components are denoted by the same reference numerals, redundant description is omitted, and differences are mainly described. explain.

  The backwashing filter unit 100 according to the fourth embodiment of the present invention realizes a filter that performs a backwashing function using a membrane filter 190 or a ceramic filter having fine pores compared to the block filter 130.

  The backwashing filter unit 100 according to the fourth embodiment of the present invention has an outer case having a structure in which a cylindrical outer casing 110 and an outer casing cap 120 formed at the lower end of the outer casing 110 to prevent water leakage are connected. The purified water outlet 170 through which the source water is discharged is formed through the central portion of the upper surface of the outer casing 110.

  The outer casing 110 is formed with a source water inlet 122 through which source water flows into the central portion of the lower surface, and a backwashing outlet 160 for discharging floating substances and contamination sources is formed on the side surface.

  The backwashing filter unit 100 is divided into an upper block filter 132 and a lower block filter 134 by a separation membrane 182, and the internal space 142 of the upper block filter 132 and the internal space 142 of the lower block filter 134 are configured not to communicate with each other. Is done.

  The block filter is provided with a separation membrane 182 having a circular shape in plan view in the horizontal direction, and the space between the upper block filter 132 and the lower block filter 134 is vertically divided. While the internal space 142 does not communicate with each other, the upper and lower spaces formed between the inner wall surface of the outer casing and the outer wall surfaces of the upper block filter 132 and the lower block filter 134 communicate with each other.

  A membrane filter 190 is provided below the lower block filter 134.

  The source water flowing in through the source water inlet 122 is filtered while moving in the inner direction of the membrane filter 190, and then moves to the inner space 142 of the upper lower block filter 134.

  The water that has moved to the inner space 142 of the lower block filter 134 is sterilized by the antibacterial balls 140 and is filtered from the inner wall surface of the lower block filter through the outer wall surface.

  Water guided between the inner wall surface of the outer casing 110 and the outer wall surface of the lower block filter 134 is filtered from the outer wall surface of the upper block filter 132 through the inner wall surface.

  As described above, the water filtered into the inner space 142 of the upper block filter 132 is sterilized by the antibacterial ball 140, moved upward by the water pressure, and discharged from the purified water outlet 170.

  As another embodiment, the backwashing filter unit 100 is a method in which at least two or more membrane filters 190 or ceramic filters are connected in series, and a microfiltration membrane filter 190 or ceramic filter is mixed with a block filter. The back cleaning function can also be performed by the method used.

  FIG. 7 is a cross-sectional view showing the configuration of the sterilizing water generator according to the first embodiment of the present invention.

  The sterilizing water generator 200 according to the first embodiment of the present invention is coupled to a cylindrical electrode housing 210, a housing lower cap 212 coupled to the lower end of the electrode housing 210, and an upper end of the electrode housing 210. The outer case is configured by a structure in which the housing upper cap 213 is connected.

  A source water inlet 220 through which source water flows laterally is formed on one side of the housing lower cap 212, and the source water that has flowed in is electrolyzed and discharged as sterilizing water on the other side of the housing lower cap 212. A sterilizing water discharge port 222 is formed.

  The sterilizing water outlet 222 and the source water inlet 220 are formed in the horizontal direction, and the circular electrode plate is formed in the vertical direction.

  Since the sterilizing water discharge port 222 is formed with a smaller diameter than the source water inlet port 220, a reverse pressure is generated at the sterilizing water discharge port 222, and a vortex flow that is a vortex phenomenon is formed.

  In the present invention, the source water inlet 220 is connected to the backwashing outlet 160, and the sterilizing water outlet 222 is connected to the sterilizing water outlet 500 through the water pipe. However, the present invention is not limited to this, and the sterilizing water discharge port 222 and the source water inlet 220 can be directly connected to piping of tap water or ground water, or can be attached to other equipment or instruments.

  The electrode housing 210 includes three cylindrical circular electrode plates 230, 232 and 234 mounted in the internal space of the electrode housing 210.

  Inside the electrode housing 210, a first circular electrode plate 230, a second circular electrode plate 232, and a third circular electrode plate 234 are sequentially arranged in the inner direction of the electrode housing 210 with a certain distance in ascending order of diameter. ing.

  In other words, the first circular electrode plate 230 is provided inside the electrode housing 210, the second circular electrode plate 232 is provided inside the first circular electrode plate 230, and the third circular electrode plate is provided inside the second circular electrode plate 232. 234 is provided.

  In order to keep the electrode interval between the circular electrode plates 230, 232, and 234 constant, these electrode plates are fixed by a structure having a fixed frame shape.

  The first circular electrode plate 230 and the third circular electrode plate 234 are applied with an anode-cathode or anode-cathode current to form a (+)-pole or (-)-pole electrode.

  The (+) or (−) electrode terminals 270 and 272 for receiving power supply from the outside are fixed to the upper ends of the first circular electrode plate 230 and the third circular electrode plate 234, and the upper part of the housing The cap 213 is exposed upward through the cap 213.

  When using at least three or more electrodes, two electrodes of (+) pole and (−) pole are applied to the first circular electrode plate 230 and the third circular electrode plate 234, and the second circular electrode plate 232 is applied. It is not necessary to apply a current to.

  When an electric current is applied to the first circular electrode plate 230 and the third circular electrode plate 234, an induced current is formed in the adjacent second circular electrode plate 232, so that it can serve as an electrode even without a separate current supply. Can do.

  The present invention can use a diaphragm electrolysis method in which various radicals are generated by a chemical reaction occurring during electrolysis using an electrolyte of tap water without using a diaphragm.

  The circular electrode plates 230, 232, and 234 of the present invention are composed of three electrode plates, but are composed of at least two or more electrode plates in order to maximize the length of the flow path through which water flows. It is preferable.

  The electrode housing 210 forms a source water inlet 220 at the lower end of the side surface so that the source water flows in the lateral direction.

  The reason why the source water is caused to flow in the lateral direction is that the introduced source water is guided to rotate inside the electrode housing 210.

  A spring spin structure 250 is provided in the space between the circular electrode plates 230, 232, and 234 in order to maintain the continuous spin phenomenon of the source water that has flowed in.

  The spring spin structure 250 increases the contact time and area between the source water that has flowed in and the circular electrode plates 230, 232, and 234, and guides the rotation efficiency of the source water to maximize the efficiency of electrolysis. .

  When the source water rotates inside the electrode housing 210, it is preferable to maximize the electrolysis efficiency by maximizing the contact time with the electrode.

  The electrode housing 210 has a plurality of circular electrode plates 230, 232, and 234 arranged in parallel, and a space between the circular electrode plates 230, 232, and 234 is formed as a flow path to increase the length of the flow path. In order to maximize the contact time by inducing rotation and eddy current phenomenon in the source water that has flowed in, and by causing a reaction to replace the electrolyte in the source water with radicals, it exerts a strong sterilizing power and cleaning power effective.

  The elastic seal structure 240 is formed in the lower part of the housing upper cap 213, is coupled to the upper stage surface of the plurality of circular electrode plates, and maintains a certain distance between the circular electrode plates 230, 232, and 234 Thus, the circular electrode plates 230, 232, and 234 are fixedly supported while being in close contact with each other (FIG. 9 below).

  The elastic seal structure 240 is formed with a spin hole 242 having a shape capable of rotating water, and two or more terminal holes 244 into which (+) and (−) electrode terminals are inserted are formed.

  Since the elastic seal structure 240 has a step in the region where the spin hole 242 is formed, water falls while rotating along the direction of the spin hole 242.

  The source water flows from the backwashing outlet into the side surface of the electrode housing 210 and moves upward while rotating between the first circular electrode plate 230 and the second circular electrode plate 232.

  At this time, electrolysis is performed while maintaining the rotational force of the source water by the spring structure formed between the first circular electrode plate 230 and the second circular electrode plate 232.

  The source water that has flowed in moves upward while being electrolyzed in the space between the first circular electrode plate 230 and the second circular electrode plate 232, and the upper ends of the first circular electrode plate 230 and the second circular electrode plate 232. The elastic seal structure 240 is formed in a space between the second circular electrode plate 232 and the third circular electrode plate 234 while causing a vortex phenomenon in contact with the spin hole 242 of the elastic seal structure 240.

  The source water that has moved into the space between the second circular electrode plate 232 and the third circular electrode plate 234 is supplied to the source water by a spring structure formed between the second circular electrode plate 232 and the third circular electrode plate 234. While the electrolysis is performed, the rotating force is moved downward.

  In the present invention, a plurality of circular electrode plates 230, 232, and 234 are formed, and a space between the circular electrode plates 230, 232, and 234 is formed as another flow path to extend the contact area and contact time between the source water and the electrode. . The electrolyzed sterilizing water is discharged through the sterilizing water discharge port 222.

  FIG. 8 is a cross-sectional view showing the configuration of the sterilizing water generator according to the second embodiment of the present invention.

  FIG. 8 is the same as the configuration of the sterilizing water generator 200 according to the first embodiment of the present invention described above. explain.

  A source water inlet 220 through which source water flows is formed through the center of the lower housing cap 212.

  A sterilizing water discharge port 222 through which the inflowed source water is electrolyzed and discharged as sterilizing water is formed through one side of the housing upper cap 213 and the elastic seal structure 240.

  The casing lower cap 212 has a stepped portion formed along a circular inner edge inside. In order to maintain the continuous spin phenomenon of the source water that has flowed into the stepped portion, a spin structure 260 in which a spiral rotation groove is formed on a circular outer edge is mounted.

  The spin structure 260 coupled and fixed to the lower end of the circular electrode plate serves to form a rotational force in the source water that has flowed in through the source water inlet 220.

  The sterilizing water discharge port 222 is formed so as to penetrate one side of the housing upper cap 213 and one side of the elastic seal structure 240. Therefore, the elastic seal structure 240 forms the sterilizing water discharge hole 246 on one side (FIG. 9).

  The source water inlet 220 and the sterilizing water outlet 222 can be variously configured according to the installation environment of the module.

  The sterilizing water generator 200 of the first embodiment described above is configured by arranging the source water inlet 220 and the sterilizing water outlet 222 in the vertical direction with the circular electrode plate, but the sterilizing water generator of the second embodiment. 200 includes a source water inlet 220 and a sterilizing water outlet 222 arranged in a horizontal direction with the circular electrode plate.

  The source water flows from the backwashing outlet to the lower part of the lower casing cap 212 and moves upward while rotating between the first circular electrode plate 230 and the second circular electrode plate 232.

  The source water that has flowed in moves upward while being electrolyzed in the space between the first circular electrode plate 230 and the second circular electrode plate 232, and reaches the upper ends of the first circular electrode plate 230 and the second circular electrode plate 232. It descends into the space between the second circular electrode plate 232 and the third circular electrode plate 234 while causing a vortex phenomenon in contact with the spin hole 242 of the formed elastic seal structure 240 (FIG. 9).

  The sterilized water electrolyzed through such a process moves upward from below the internal space of the third circular electrode plate 234 and is discharged through the sterilized water discharge port 222.

  The embodiment of the present invention described above is not realized only through the apparatus and / or method, but a program for realizing a function corresponding to the configuration of the embodiment of the present invention, and a recording medium on which the program is recorded Such an implementation can be easily performed by a specialist in the technical field to which the present invention belongs from the description of the above-described embodiment.

  Although the embodiment of the present invention has been described in detail above, the scope of the present invention is not limited to this, and those skilled in the art using the basic concept of the present invention defined in the following claims. Various modifications and improvements are also within the scope of the present invention.

  With the configuration described above, the present invention regenerates the function of the filter by detaching suspended matter and contamination sources adhering to the block filter provided inside the outer casing at any time by the backwashing function, thereby greatly increasing the filter life. There is an effect to make.

  In addition, the present invention uses a backwashing filter to regenerate the function of the filter, thereby reducing the cost of users that are excessively generated by a short filter replacement cycle and generating filter waste that may adversely affect the environment. By reducing this, many economic ripple effects can be expected.

  In the present invention, the space between each circular electrode plate is formed as a flow path to increase the length of the flow path, and the contact time is maximized by causing rotation and eddy current phenomenon in the inflowing source water. And having a reaction of substituting the electrolyte in the source water with radicals has an effect of exerting strong sterilizing power and cleaning power.

Claims (21)

A cylindrical outer casing having a fixed space inside, and a filtration filter provided inside the outer casing for filtering floating substances and sludge that can be confirmed with the naked eye,
The filtration filter concentrates the suspended matter and sludge in an internal space of the filtration filter or a space between an inner wall surface of the outer casing and an outer wall surface of the filtration filter, and the suspended matter is periodically concentrated. A sterilizing and cleaning water device that performs a back-washing function for discharging sludge and sludge to the outside. An outer casing cap coupled to the lower end of the outer casing to prevent water leakage;
A source water inlet formed through the center of the lower surface of the outer casing cap and into which source water flows;
A block filter that has a smaller diameter than the outer casing, is provided inside the outer casing, a plurality of antibacterial balls are disposed in the inner space, and constitutes a filtration filter that filters suspended matter and sludge;
A backwashing outlet that is formed through the center of the upper surface of the outer casing and communicates with the internal space of the block filter to discharge suspended matter and sludge;
A purified water outlet that is formed through the upper surface edge of the outer casing and communicates with the space between the outer casing and the block filter to discharge purified water;
Including
The source water flowing in through the source water inlet is sterilized by the antibacterial ball, filtered while moving sideways from the inner wall surface to the outer wall surface of the block filter, and then discharged through the purified water outlet. When the washing outlet is opened, the suspended matter and sludge concentrated in the internal space of the block filter are discharged to the outside.
The sterilization washing water device according to claim 1.   The sterilizing / washing water device according to claim 2, wherein a spin structure having a spiral outer circumferential groove formed in a circular outer edge is provided in an opening of a lower surface of the internal space of the block filter. An outer casing cap coupled to the lower end of the outer casing to prevent water leakage;
A source water inlet formed through the center of the upper surface of the outer casing and into which source water flows;
It has a smaller diameter than the outer casing, is provided inside the outer casing, closes a circular edge on the upper surface by a water blocking cap, and a plurality of antibacterial balls are arranged in the inner space to filter suspended matter and sludge. A block filter constituting a filtration filter;
A backwashing outlet that is formed through the upper edge of the outer casing and communicates with the space between the outer casing and the block filter to discharge suspended matter and sludge;
A purified water outlet that is formed through the center of the lower surface of the outer casing cap and that discharges purified water in communication with the internal space of the block filter;
Including
Source water that has flowed in through the source water inlet is guided between the inner wall surface of the outer casing and the outer wall surface of the block filter by the water blocking cap, and passes through the inner wall surface from the outer wall surface of the block filter. After being filtered, it is discharged through the purified water outlet, and when the backwashing outlet is opened, concentrated suspended matter and sludge in the space between the inner wall surface of the outer casing and the outer wall surface of the block filter are removed. Discharge outside,
The sterilization washing water device according to claim 1.   The sterilizing / washing water device according to claim 4, wherein a spin structure having a spiral rotating groove is provided on a circular edge surrounding the periphery of the water blocking cap. The outer casing is formed in a cylindrical shape having a certain space inside, has a smaller diameter than the outer casing, is provided inside the outer casing, and the upper and lower circular edges of the outer casing are closed by a blocking cap. Including an antibacterial ball in the internal space, including a block filter that constitutes a filtration filter that filters suspended matter and sludge,
The block filter is formed by inserting a separation membrane having a circular shape in plan view in the horizontal direction by the thickness thereof, and connecting the other end of the separation membrane to the inner wall surface of the outer casing, Partitioning the space and communicating the internal space of the upper block filter and the internal space of the lower block filter;
The sterilization washing water device according to claim 1. The outer casing is formed in a cylindrical shape having a certain space inside, has a smaller diameter than the outer casing, is provided inside the outer casing, and a plurality of antibacterial balls are disposed in the inner space. And a block filter constituting the filtration filter for filtering sludge,
The block filter penetrates a circular separation membrane in a plan view in a horizontal direction to partition the space between the upper block filter and the lower block filter, and closes the internal space of the upper block filter and the internal space of the lower block filter And communicating the outer wall surface of the upper block filter and the outer wall surface of the lower block filter,
The sterilization washing water device according to claim 1. One or more membrane filters or ceramic filters are provided in the lower part of the lower block filter, and communicate with the inner space of the lower block filter and the outlet of the membrane filter or ceramic filter.
The sterilization washing water device according to claim 7. A case comprising a cylindrical electrode housing having a constant space therein, a housing upper cap coupled to the upper portion of the electrode housing, and a housing lower cap coupled to the lower portion of the electrode housing;
A (+) or (-) electrode electrode terminal is provided extending in a cylindrical length direction to receive power supply from the outside. A plurality of circular electrode plates arranged in order in the inner direction of the electrode housing at intervals, and functioning as (+) or (−) pole electrodes;
Including
A sterilizing / washing water device that generates sterilizing water by electrolysis while passing through the source water flowing into the space between the circular electrode plates.   The sterilization washing water device according to claim 9, wherein a spring spin structure is provided in a space between the circular electrode plates to maintain a spin phenomenon of the source water that has flowed in. A plurality of circular electrode plates formed at a lower portion of a housing upper cap, coupled to upper end surfaces of the plurality of circular electrode plates, and fixedly supporting the plurality of circular electrode plates with a predetermined distance between the circular electrode plates; An elastic seal structure for rotating the source water that is raised while electrolyzing in the space between the circular electrode plates and moving it downward;
The sterilization washing water device according to claim 9. The plurality of circular electrode plates are composed of three electrode plates, a first circular electrode plate, a second circular electrode plate, and a third circular electrode plate, and electrodes are provided on the first circular electrode plate and the third circular electrode plate. Applied,
A source water inlet through which source water flows in a lateral direction is formed on one side of the casing lower cap, and sterilized water from which the source water that has flowed in is electrolyzed and discharged as sterilizing water on the other side of the casing lower cap. An outlet is formed,
After the source water that has passed through the source water inlet has been electrolyzed from below to above through the space between the first circular electrode plate and the second circular electrode plate, the second circular electrode plate Moving while electrolyzing downward from above through the space between the third circular electrode plate and discharged from the sterilizing water discharge port,
The sterilization washing water device according to claim 9. The plurality of circular electrode plates are composed of three electrode plates, a first circular electrode plate, a second circular electrode plate, and a third circular electrode plate, and electrodes are provided on the first circular electrode plate and the third circular electrode plate. Applied,
A source water inlet through which source water flows is formed through the center of the lower housing cap, and a sterilizing water outlet through which the inflowed source water is electrolyzed and discharged as sterilizing water is formed on one side of the upper housing cap. Penetrated,
After the source water that has passed through the source water inlet has been electrolyzed from below to above through the space between the first circular electrode plate and the second circular electrode plate, the second circular electrode plate Moving while electrolyzing downward from above through the space between the third circular electrode plate and discharged from the sterilizing water discharge port,
The sterilization washing water device according to claim 9. The lower body cap has a step portion formed along a circular edge on the inner side thereof, and a spin structure having a spiral rotation groove formed on a circular outer edge to maintain the spin phenomenon of the source water that has flowed in The source water that is attached to the part and flows in through the source water inlet passes through the spin structure.
The sterilization washing water device according to claim 13. A cylindrical outer casing having a fixed space inside, and a filtration filter provided inside the outer casing for filtering floating substances and sludge that can be confirmed with the naked eye,
In the internal space of the filtration filter or in the space between the inner wall surface of the outer casing and the outer wall surface of the filtration filter, the suspended matter and sludge are concentrated, and the concentrated suspended matter and sludge are periodically exposed to the outside. A first filter that performs a back-washing function to discharge, and discharges the first source water that has passed through the filtration filter and the second source water including the concentrated suspended matter and sludge;
A second filter that removes bacteria and disease-inducing substances by filtering the first source water that has passed through the first filter;
A purified water outlet for discharging the first source water that has been purified by passing through the second filter;
A sterilizing water generator that electrolyzes the second source water that has passed through the first filter to generate sterilizing water;
Including a sterilized water outlet for discharging sterilized water that has passed through the sterilized water generator,
Sterilization washing water device. The sterilizing water generator is
A case comprising a cylindrical electrode housing having a constant space therein, a housing upper cap coupled to the upper portion of the electrode housing, and a housing lower cap coupled to the lower portion of the electrode housing;
A (+) or (-) electrode electrode terminal is provided extending in a cylindrical length direction to receive power supply from the outside. A plurality of circular electrode plates that are arranged in order in the inner direction of the electrode housing at intervals, and function as (+) or (−) pole electrodes;
Including
The source water that has flowed into the space between the respective circular electrode plates is electrolyzed while passing through to produce sterilized water,
The sterilization washing water device according to claim 15. The plurality of circular electrode plates are composed of three electrode plates, a first circular electrode plate, a second circular electrode plate, and a third circular electrode plate, and electrodes are provided on the first circular electrode plate and the third circular electrode plate. Applied,
A source water inlet through which source water flows in a lateral direction is formed on one side of the casing lower cap, and sterilized water from which the source water that has flowed in is electrolyzed and discharged as sterilizing water on the other side of the casing lower cap. An outlet is formed,
After the source water that has passed through the source water inlet has been electrolyzed from below to above through the space between the first circular electrode plate and the second circular electrode plate, the second circular electrode plate Moving while electrolyzing downward from above through the space between the third circular electrode plate and discharged from the sterilizing water discharge port,
The sterilization washing water device according to claim 16. The plurality of circular electrode plates are composed of three electrode plates, a first circular electrode plate, a second circular electrode plate, and a third circular electrode plate, and electrodes are provided on the first circular electrode plate and the third circular electrode plate. Applied,
A source water inlet through which source water flows is formed through the center of the lower housing cap, and a sterilizing water outlet through which the inflowed source water is electrolyzed and discharged as sterilizing water is formed on one side of the upper housing cap. Penetrated,
After the source water that has passed through the source water inlet has been electrolyzed from below to above through the space between the first circular electrode plate and the second circular electrode plate, the second circular electrode plate Moving while electrolyzing downward from above through the space between the third circular electrode plate and discharged from the sterilizing water discharge port,
The sterilization washing water device according to claim 16. An outer casing cap coupled to the lower end of the outer casing to prevent water leakage;
A source water inlet formed through the center of the lower surface of the outer casing cap and into which source water flows;
A block filter that has a smaller diameter than the outer casing, is provided inside the outer casing, a plurality of antibacterial balls are disposed in the inner space, and constitutes a filtration filter that filters suspended matter and sludge;
A backwashing outlet that is formed through the center of the upper surface of the outer casing and communicates with the internal space of the block filter to discharge suspended matter and sludge;
A purified water outlet that is formed through the upper surface edge of the outer casing and communicates with the space between the outer casing and the block filter to discharge purified water;
Including
The source water flowing in through the source water inlet is sterilized by the antibacterial ball, filtered while moving sideways from the inner wall surface to the outer wall surface of the block filter, and then discharged through the purified water outlet. When the washing outlet is opened, the suspended matter and sludge concentrated in the internal space of the block filter are discharged to the outside.
The sterilization washing water device according to claim 15. An outer casing cap coupled to the lower end of the outer casing to prevent water leakage;
A source water inlet formed through the center of the upper surface of the outer casing and into which source water flows;
It has a smaller diameter than the outer casing, is provided inside the outer casing, closes a circular edge on the upper surface by a water blocking cap, and a plurality of antibacterial balls are arranged in the inner space to filter suspended matter and sludge. A block filter constituting a filtration filter;
A backwashing outlet that is formed through the upper edge of the outer casing and communicates with the space between the outer casing and the block filter to discharge suspended matter and sludge;
A purified water outlet that is formed through the center of the lower surface of the outer casing cap and that discharges purified water in communication with the internal space of the block filter;
Including
Source water that has flowed in through the source water inlet is guided between the inner wall surface of the outer casing and the outer wall surface of the block filter by the water blocking cap, and passes through the inner wall surface from the outer wall surface of the block filter. After being filtered, it is discharged through the purified water outlet, and when the backwashing outlet is opened, concentrated suspended matter and sludge in the space between the inner wall surface of the outer casing and the outer wall surface of the block filter are removed. Discharge outside,
The sterilization washing water device according to claim 15. The sterilizing water outlet is
One side of the path through which the sterilizing water passes is provided with one or more fluid spin holes having a spiral rotating groove formed on the outer edge, and an air inflow port through which air flows is formed on the side surface. The microbubble device further increases the flow rate when passing the sterilizing water and mixes a large amount of air to inject the bubble water in the form of microbubbles or mist (Mist).
The sterilization washing water device according to claim 15.

Images