JP4841471B2 - Equipment drain water purification equipment - Google Patents

Description

  The present invention relates to an apparatus for purifying drain water of equipment such as an air conditioner and a cooler having a drain pan for receiving drain water.

  In general, in a heat exchanger (cooler) that exhibits a cooling action provided in an air conditioner or a cooler, moisture contained in the circulated air condenses on the surface of the heat exchanger, and dew is generated. . The dew is stored as drain water in a drain pan provided in the heat exchanger, and discarded to the outside through a drain pipe connected to the drain pan.

  On the other hand, dust and the like in the air in the room where the equipment is installed are sucked into the heat exchanger along with the circulating air. Therefore, there is a problem that the drain water stored in the drain pan before flowing into the drain pipe stays for a long time, so that slime is generated and bacteria are propagated. The generation of this slime causes clogging of a drain pipe connected to the drain pan, and therefore there is a problem that drain water is not smoothly discharged but leaks to the outside.

Therefore, in order to suppress the generation of slime in the drain pan, conventionally, a material in which a slime generation preventing material or the like is arranged in the drain pan has been proposed (for example, see Patent Document 1). Such a slime generation preventing material is composed of a nonwoven fabric made of fibers kneaded with a drug such as an antibacterial agent. By providing the slime generation preventing material on the bottom surface of the drain pan, the drain water received in the drain pan is suppressed from generating slime due to the effect of the slime generation preventing material.
JP-A-6-159710

  However, in the method for suppressing the slime formation of the drain water by the slime generation preventing material, when the medicine such as antibiotics kneaded in the fibers constituting the preventing material disappears due to use, the effect is lost. The slime will occur. Therefore, there is a problem that slime generated in the drain water stored in the drain pan cannot be continuously suppressed, and problems such as permanent clogging of the drain pipe cannot be eliminated.

  Therefore, the present invention has been made to solve the conventional technical problems, and effectively suppresses slime generation and bacterial growth of drain water stored in the drain pan, and smoothly realizes drain drainage. Thus, a drain water purification device for equipment capable of preventing leakage of drain water to the outside is provided.

  The drain water purification apparatus of the present invention includes a purification unit that generates singlet oxygen by photosensitization or sound sensitization in an apparatus including a drain pan that receives drain water, and is stored in the drain pan by the purification unit. It is characterized in that air containing singlet oxygen is supplied into the drain water.

  According to a second aspect of the present invention, there is provided the drain water purifying device for equipment according to the present invention, wherein an air outlet of the purifying means is disposed at the deepest part of the drain pan.

  According to a third aspect of the present invention, there is provided the drain water purifying device for the apparatus according to each of the above inventions, wherein the flow rate of the air supplied from the purifying means to the drain pan and / or the flow path length of the air from the purifying means to the drain pan is determined. The time from when singlet oxygen is generated by the means until it is supplied to the drain pan is set to be 30 seconds or less.

  According to a fourth aspect of the present invention, there is provided a drain water purifying device according to the above invention, wherein the flow rate of the air supplied from the purifying means to the drain pan and / or the flow path length of the air from the purifying means to the drain pan is the purifying means. The time from generation of singlet oxygen to supply to the drain pan is set to be 10 seconds or less.

  According to a fifth aspect of the present invention, there is provided the apparatus for purifying drain water in each of the above inventions, wherein the light source for photosensitization in the purifying means is at least one selected from a fluorescent lamp, LED, incandescent lamp, or mercury lamp. And it is characterized by irradiating the sensitizer for photosensitization with visible light in the range of 400 nm or more and 700 nm or less.

  The drain water purifying device of the device of the invention of claim 6 is the above-described invention, wherein the sensitizer for photosensitization in the purifying means is methylene blue, thionine, rose bengal, erythrosin, eosin Y, fluorescein, proflavine, fluorenone , Rhodamine, porphyrin, phthalocyanine, carbon soot molecule, silicon nanocrystal, or at least one selected from these.

  The apparatus for purifying drain water of the device according to claim 7 is the invention according to claims 1 to 5, wherein the sensitizer for sound sensitization in the purifying means is a cyanine dye, phthalocyanine, porphyrin, perylenequinones, It is characterized in that it is at least one selected from xanthene dyes or these.

  According to an eighth aspect of the present invention, there is provided a drain water purifier for a device according to each of the above-mentioned inventions, comprising a control means for controlling the purification means, and the control means operates the purification means after the operation of the equipment is completed.

  The drain water purifying device for equipment of the invention of claim 9 includes a control means for controlling the purifying means in each of the above inventions, the control means having a sensor for detecting the amount of drain water stored in the drain pan, Based on the output of the sensor, the purification means is operated when the amount of drain water in the drain pan is a predetermined value or more.

  According to a tenth aspect of the present invention, there is provided a drain water purifier for a device according to the invention, further comprising a control means for controlling the purification means, wherein the control means detects the temperature of the drain water stored in the drain pan directly or indirectly. And a purifier is operated when the temperature of the drain water in the drain pan is within a predetermined range based on the output of the sensor.

  According to the present invention, in a device including a drain pan that receives drain water, the device includes a purification unit that generates singlet oxygen by photosensitization or sound sensitization, and the drain water stored in the drain pan by the purification unit. By supplying air containing singlet oxygen, drain water stored in the drain pan is brought into contact with air containing singlet oxygen having high oxidizing power, and substances and bacteria that cause slime contained in the drain water Can be disassembled.

  Thereby, the drain water stored in the drain pan can be effectively sterilized, and slime generation can be suppressed. Therefore, the inconvenience of clogging of the drain pipe or the like due to slime can be solved, and the drain water can be discharged smoothly. Therefore, it is possible to avoid the inconvenience that drain water leaks directly from the drain pan.

  In particular, according to the invention of claim 2, in addition to the above-described invention, the air blowout port of the purification means is arranged at the deepest portion of the drain pan, so that the singlet oxygen is contained in the deepest portion of the drain pan where drain water is most likely to accumulate. Since air can be supplied from the air outlet, drain water can be effectively sterilized regardless of the amount of drain water stored in the drain pan, and the singlet oxygen can be reduced. Since the contact time between the contained air and the drain water can be increased, the sterilization effect by the singlet oxygen can be improved.

  According to the invention of claim 3, in addition to each of the above inventions, the flow rate of the air supplied from the purifying means to the drain pan and / or the flow path length of the air from the purifying means to the drain pan is determined by the purifying means. By setting the time from generation of singlet oxygen to supply to the drain pan at 30 seconds or less, more preferably 10 seconds or less as in the invention of claim 4, Even singlet oxygen having a short existence time can supply air from the purification means containing the singlet oxygen to the drain pan while the singlet oxygen is present. It can demonstrate the ability to decompose substances and bacteria that cause slime due to oxygen.

  Accordingly, the drain water received in the drain pan can be effectively sterilized, and the generation of slime can be more effectively suppressed.

  According to the invention of claim 5, in addition to each of the above inventions, the light source for photosensitization in the purifying means is at least one selected from a fluorescent lamp, an LED, an incandescent lamp, or a mercury lamp. By irradiating a sensitizer for photosensitization with visible light in the range of 400 nm to 700 nm, the sensitizer can be photoexcited to form a triplet state of the sensitizer by intersystem crossing. It becomes. In particular, since visible light does not require a special light source as compared with ultraviolet light or infrared light, it is easy to handle, and the unit cost of the light source is low, so that the cost of the apparatus can be reduced.

  The triplet state of this sensitizer has an excitation energy substantially equal to the energy difference between the ground state oxygen molecules existing in the air, i.e., triplet oxygen and singlet oxygen. When the sensitizer collides with triplet oxygen, energy exchange occurs with electrons, and the sensitizer returns to the ground state, and at the same time, the triplet oxygen transitions to singlet oxygen, so that singlet oxygen is efficiently generated. Can be generated.

  According to the invention of claim 6, in addition to each of the above inventions, the sensitizer for photosensitization in the purifying means is methylene blue, thionine, rose bengal, erythrosine, eosin Y, fluorescein, proflavine, fluorenone, Since it is at least one or more selected from rhodamine, porphyrin, phthalocyanine, carbon soot molecule, silicon nanocrystal, or the like, the ground state existing in the air can be obtained by photosensitizing these sensitizers. It becomes possible to form a triplet state of a sensitizer having an excitation energy substantially equal to the energy difference between oxygen molecules, that is, triplet oxygen and singlet oxygen.

  Thereby, in the purifying means, singlet oxygen can be efficiently converted by colliding the ground state oxygen molecule in the air, that is, the triplet oxygen, with the photosensitized triplet state sensitizer. Can be generated.

  According to the invention of claim 7, in addition to the inventions of claims 1 to 5, the sensitizer for sound sensitization in the purifying means is a cyanine dye, phthalocyanine, porphyrin, perylenequinones, xanthene dye. Or, by using at least one selected from these, in the purifying means, the oxygen molecule in the ground state in the air, that is, triplet oxygen, and the sound-sensitized sensitizer are collided. Thus, singlet oxygen can be generated with high efficiency.

  According to the invention of claim 8, in addition to each of the above inventions, a control means for controlling the purification means is provided, and the control means operates the purification means after the operation of the equipment is completed, so that the drain pan cannot be drained completely. The remaining drain water can be sterilized by singlet oxygen supplied from the purification means.

  Thereby, by operating the purification means according to the timing when the drain water is supplied to the drain pan, it is possible to effectively sterilize the drain water stored in the drain pan, and to effectively suppress the generation of slime. It can be realized.

  According to the invention of claim 9, in addition to the above-mentioned inventions, there is provided control means for controlling the purification means, the control means having a sensor for detecting the amount of drain water stored in the drain pan, Based on the output, when the amount of drain water in the drain pan is greater than or equal to a predetermined value, by operating the purification means, the drain water in the drain pan cannot be evaporated in a relatively short time by natural evaporation. In this case, since the drain water is sterilized by the purifying means, the purifying means can be operated as necessary, and it is possible to effectively suppress the generation of slime.

  According to the invention of claim 10, in addition to each of the above inventions, a control means for controlling the purifying means is provided, and the control means detects the temperature of the drain water stored in the drain pan directly or indirectly. And purifying means when the temperature of the drain water in the drain pan is within a predetermined range based on the output of the sensor, so that the purifying means Can be operated, and the operation of the purification means can be realized as necessary. Therefore, it is possible to realize effective suppression of slime generation.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In this embodiment, an air conditioner will be described as an apparatus to which the present invention is applied. FIG. 1 is a cross-sectional view of a use side unit (indoor unit) 1 of the air conditioner, and FIG. 2 is a plan view of the use side unit 1.

  The utilization side unit 1 is configured by incorporating a utilization side heat exchanger (indoor heat exchanger) 3 and a blower 4 driven by a fan motor 5 in a sheet metal main body 2. It is fitted inside the ceiling so as to close the ceiling surface 8. A suction port 9 is formed at the center of the lower surface of the main body 2 that is substantially flush with the ceiling surface 8, and air outlets 11 are formed on the sides (four sides) thereof. A filter 10 is attached to the suction port 9.

  The blower 4 is disposed corresponding to the suction port 9, and the use side heat exchanger 3 is formed in a rectangular shape so as to surround the blower 4, and is disposed in the vicinity of each outlet 11. The The tube plates 12 of the heat exchanger 3 are connected by a partition plate 13, and a drain pump 14, a valve device 15, etc. are provided in the space outside the heat exchanger 3 partitioned by the partition plate 13. Is housed. The partition plate 13 prevents the air from the blower 4 from leaking out during the operation of the air conditioner, whereby the air heat-exchanged inside from the four air outlets 11 is effectively conditioned. It is set as the structure discharged in R. In FIG. 1, reference numeral 17 denotes an electrical box that houses a control device C and the like to be described later.

  Further, the use side unit 1 attached to the room and set to the ceiling fitting side constitutes an air conditioner together with a heat source side unit (outdoor unit) installed outdoors, and these are connected by a refrigerant pipe 16. ing. In the heat source unit, a compressor, a four-way switching valve for switching the refrigerant flow during cooling / heating operation, a heat source side heat exchanger (outdoor heat exchanger), an electric expansion valve, etc. are installed. Yes.

  Thereby, when the blower 4 is operated, the air in the conditioned room R is sucked from the suction port 9 and flows into the use side heat exchanger 3. The conditioned air that has flowed into the use-side heat exchanger 3 and exchanged heat is accelerated by the blower 4 and blown into the conditioned room R from the blowout port 11.

  At this time, when the cooling operation is performed, the use-side heat exchanger 3 exhibits a cooling action, so the air sucked into the main body 2 is cooled by the use-side heat exchanger 3 and blown by the blower 4. Blow out from the outlet 11 to the conditioned room R. Here, moisture contained in the air sucked from the conditioned room R by the use side heat exchanger 3 condenses on the surface of the heat exchanger 3 due to a temperature difference, and condensation, so-called drain water D is generated. Therefore, the drain water D is stored in the drain pan 20 installed below the heat exchanger 3.

  Next, the drain water purification device 18 will be described with reference to FIGS. 3 to 5. 3 is a schematic configuration diagram of the drain water purification device 18, FIG. 4 is a partially enlarged view of FIG. 3, and FIG. 5 is a schematic configuration diagram of the purification unit 23.

  As described above, a dish-shaped drain pan 20 having an opening on the upper side and capable of storing a predetermined volume of drain water D is disposed below the heat exchanger 3. In the drain pan 20, the drain pump 14 having the suction port 14 </ b> A is disposed in the vicinity of the bottom surface 20 </ b> A for storing the drain water D, and becomes lower toward a position where the suction port 14 </ b> A of the drain pump 14 is disposed. In this way, the entire bottom surface 20A is inclined. The position where the suction port 14 </ b> A of the drain pump 14 is disposed is the deepest portion 20 </ b> B of the drain pan 20. A drain pipe 21 having one end opened to the outside is connected to the discharge port of the drain pump 14.

  A sensor (water level sensor) 22 for detecting the amount of drain water stored in the drain pan 20 is provided at a position corresponding to the deepest portion 20B of the drain pan 20 or in the vicinity of the deepest portion 20B. Similarly, at a position corresponding to the deepest portion 20B of the drain pan 20 or in the vicinity of the deepest portion 20B, an air discharge portion (air outlet) 31 for discharging air sent from the purification portion (purification means) 23. Is arranged.

  Here, the structure of the purification | cleaning part 23 is demonstrated with reference to FIG. The purifier 23 forms an air flow path 24 therein, and a sensitizer 26 that houses the sensitizer carrier 25 and light that irradiates light to the sensitizer carrier 25 in the sensitizer 26. And a light source 27 for sensitization.

  The sensitizing member 26 is positioned upstream of the air flow path 24 and has an air inlet 26A. A pump (air supply means) 28 for sucking in air from the outside is connected to the air inlet 26A. The connected pipe 29 is connected. On the other hand, an air outlet 26B is formed on the downstream side of the air flow path 24, and air that has been processed in the sensitizing member 26 is supplied into the drain pan 20 to the air outlet 26B. For this purpose, a pipe 30 is connected. The air discharge part 31 arrange | positioned at the deepest part 20B of the drain pan 20 is connected to the edge part of the said piping 30 as mentioned above. It is desirable that the air release part 31 is constituted by a member that can release air such as an air stone as fine bubbles.

  The sensitizing member 26 is made of at least a translucent material, and is configured to irradiate the sensitizer carrying body 25 accommodated therein with irradiation light from the light source 27.

  The sensitizer carrier 25 is carried, for example, by impregnating or applying a sensitizer to a mesh-like air-permeable member. The sensitizer in this example is a photosensitizer that can generate singlet oxygen from oxygen in the air by photosensitization. For example, methylene blue, thionine, rose bengal, erythrosine, eosin Y, fluorescein , Proflavine, fluorenone, rhodamine, porphyrin, phthalocyanine, carbon soot molecule (a carbon molecule containing a fullerene-like molecule or a part thereof), silicon nanocrystal, etc., and those containing at least one of these.

  On the other hand, the light source 27 for photosensitization is configured to be capable of photosensitizing the sensitizer carried on the sensitizer carrier 25, such as a fluorescent lamp, LED, incandescent lamp, mercury lamp, and the like. The The light source 27 is composed of at least one selected from these fluorescent lamps and the like, and makes it possible to irradiate the sensitizer carrier 25 with visible light in the range of 400 nm to 700 nm. The excitation wavelength is not necessarily limited to the wavelength range of visible light, and may be the wavelength range of ultraviolet light or infrared light. However, when visible light is used as in this embodiment, a special light source is not required as compared with ultraviolet light or infrared light, so that handling is easy and the unit price of the light source is low. Cost reduction is possible.

  With this configuration, the sensitizer carried on the sensitizer carrier 25 is irradiated with the visible light by irradiating the sensitizer carrier 25 of the sensitizer 26 with visible light from the light source 27. The triplet state of the sensitizer is formed by intersystem crossing.

  In this state, by sending outside air from the pump 28 to the air flow path 24 in the sensitizing member 26 via the pipe 29, the triplet state sensitizer in the air flow path 24 exists in the air. Since it has excitation energy almost equal to the energy difference between the ground state oxygen molecule, that is, triplet oxygen and singlet oxygen, the triplet state sensitizer collides with triplet oxygen to exchange energy with electrons. Occurs, and at the same time the sensitizer returns to the ground state, the triplet oxygen transitions to singlet oxygen to generate singlet oxygen.

  The air containing the singlet oxygen is led out from the air outlet 26 </ b> B into the pipe 30 by the pump 28, and is discharged from the air release part 31 connected to the end of the pipe 30. In the present embodiment, the pump 28 used as the air supply means is a pump that suppresses noise and vibration with an indoor noise level of 60 dB or less, and more preferably 50 dB or less.

  Next, with reference to the electric block diagram of FIG. 6, the control apparatus C of the drain water purification apparatus provided in the air conditioner of the present embodiment will be described. The control device C is configured by a general-purpose microcomputer, and a control unit 33 that controls at least each device provided in the air conditioner 1 and a water level sensor 22 disposed in the drain pan 20 are connected to the input side. At the same time, a power source 35, a pump 28 constituting the purification unit 23, and a light source 27 are connected to the output side via a relay switch 34. A drain pump 14 is connected to the output side (not shown).

  With the above configuration, the operation of the drain water purifying device 18 of the air conditioner of this embodiment will be described. When the air conditioner performs a cooling operation, a dehumidifying operation, or the like, the use-side heat exchanger 3 exhibits a cooling action, so that the air sucked into the main body 2 is cooled, and moisture contained in the air Is condensed on the surface of the heat exchanger 3 due to a temperature difference, and is stored as drain water D in a drain pan installed below the heat exchanger 3. The control unit 33 of the air conditioner may forcibly perform the defrosting operation of the use side heat exchanger 3 to melt the frost on the surface of the heat exchanger 3. Further, in a state where the cooling operation or the like is performed, the drain water in the drain pan 20 is discharged to the outside by the drain pump 14 when a predetermined water level is detected, so that the drain water is always replaced.

  When it is output from the control unit 33 of the air conditioner that the cooling operation, the dehumidifying operation, or the defrosting operation has been stopped, the control device C operates the drain water purification device 18. Hereinafter, a description will be given with reference to the flowchart of FIG.

  First, the control device C starts drain water purification control based on an output (step S1) indicating that the operation has been stopped by the control unit 33 of the air conditioner. In step S2, the control device C outputs the water level sensor 22 output. Based on this, it is determined whether or not a predetermined amount of drain water D is stored in the drain pan 20. Here, the drain water D stored in the drain pan 20 is drained to the outside by the drain pump 14 that is operation-controlled based on the output of the water level sensor 22. Therefore, when the drain level by the drain pump 14 detects that the water level in the drain pan 20 satisfies a predetermined water level, for example, the deepest portion 20B of the drain pan 20, the control device C performs step S3. Then, the pump 28 and the light source 27 constituting the purification unit 23 are energized to start sterilization.

  At this time, in step S4, the control device C determines whether or not a predetermined minimum amount of drain water D is stored in the drain pan 20 based on the output of the water level sensor 22, and becomes equal to or less than the predetermined minimum amount. If YES, the process proceeds to step S6, and energization of the pump 28 and the light source 27 is stopped. In step S4, when it is determined that the amount of drain water D in the drain pan 20 is equal to or greater than a predetermined minimum amount, the process proceeds to step S5, and the time after starting energization of the pump 28 and the like is predetermined. It is determined whether or not a time that can reliably sterilize the drain water D in the drain pan 20 such as 1 to 2 hours has elapsed. If not, the process returns to step S4. Then, power is continuously supplied to the pump 28 and the like. On the other hand, if the predetermined time has elapsed, the process proceeds to step S6, and energization of the pump 28 and the light source 27 is stopped.

  The sensitizer carried on the sensitizer carrier 25 is irradiated with visible light from the light source 27 to the sensitizer carrier 25 of the sensitizer 26 by the operation of the drain water purification device 18. It is excited by visible light to be in a triplet state. In this state, by sending outside air to the air flow path 24 in the sensitizing member 26 by the pump 28 through the pipe 29, the triplet state sensitizer in the air flow path 24 exists in the air. Singlet oxygen is generated by collision with a ground state oxygen molecule, that is, triplet oxygen.

  The air containing the singlet oxygen is led out from the air outlet 26 </ b> B into the pipe 30 by the pump 28, and is discharged from the air release portion 31 connected to the end of the pipe 30. Therefore, in the drain water D stored in the drain pan 20, air containing singlet oxygen is released from the ventilating unit 31, thereby coming into contact with the air due to high oxidizing power of singlet oxygen. Substances and bacteria that cause slime contained in the drain water D are decomposed.

  As a result, the drain water D stored in the drain pan 20 can be effectively sterilized, and slime generation can be suppressed. Therefore, inconveniences such as clogging of the drain pipe 21 and the pump 14 due to slime can be eliminated, and smooth drain water can be discharged. Therefore, it is possible to avoid the disadvantage that the drain water D leaks directly from the drain pan 20.

  Moreover, in this embodiment, since the sterilization treatment of the drain water D can be realized without using any special electrolysis means, the apparatus itself can be simplified and the production cost can be reduced. Is possible. In addition, since the drain water D is not sterilized by a strong odorous substance such as ozone, it is possible to avoid discomfort due to a bad odor drifting around the drain water purification device 18. Become.

  In particular, in the present embodiment, air containing singlet oxygen supplied from the purification unit 23 is configured to be discharged from the ventilating unit 31 disposed in the deepest part 20B of the drain pan 20, and therefore the most drain water. It is possible to supply air containing singlet oxygen to the deepest portion 20B of the drain pan 20 where water tends to accumulate, and effectively sterilize the drain water regardless of the amount of drain water D stored in the drain pan 20. Is possible. In addition, since the contact time between the air containing singlet oxygen and the drain water D can be increased, it is possible to improve the sterilizing effect due to the oxidizing power of the singlet oxygen.

  Further, in this embodiment, since the drain water purification device 18 is operated by the control device C after the operation of the air conditioner, for example, the cooling operation, the dehumidifying operation, or the defrosting operation, the drain pan 20 cannot drain completely. It is possible to sterilize the drain water that is left until the next operation with the singlet oxygen supplied from the purifying unit 23.

  Thereby, by operating the purification | cleaning part 23 according to the timing with which drain water is supplied to the drain pan 20, the sterilization process of the drain water stored in the drain pan 20 can be performed effectively, and effective slime of It is possible to realize generation suppression.

  Furthermore, the control device C does not start the operation of the air conditioner after a predetermined time, for example, 12 hours from the end of the previous operation of the drain water purification device 18, and the drain stored in the drain pan 20. When the water is not replaced, the drain water purifier 18 may be operated again according to the amount of drain water in the same manner as described above.

  Thus, by leaving the drain water D in the drain pan 20 for a long time while being stored, it avoids the disadvantage that slime is generated in the drain water D and the disadvantage that bacteria are propagated. It becomes possible.

  In this case, the pump 28 is operated when the drain water purifier 18 is operated. As described above, the pump 28 has a noise level reduced to a predetermined value or less as described above. Since it is used, noise and vibration in the room can be suppressed.

  Furthermore, in addition to the above, the control device C, based on the output of the water level sensor 22, operates the drain water purification device 18 when the drain water amount in the drain pan 20 is equal to or greater than a predetermined value. When there is drain water in the drain pan 20 that cannot evaporate the drain water in a relatively short time, the purification unit 23 performs the sterilization process of the drain water. Therefore, it is possible to effectively suppress the generation of slime.

  On the other hand, since singlet oxygen generated in the purification unit 23 is an unstable substance, the lifetime is said to be 45 minutes in vacuum and 3.3 μs in water. Since the lifetime in air varies depending on conditions, it is generally recognized that the lifetime is very short, and there is a problem that the oxidizing power cannot be maintained for a long time. Therefore, an experiment was conducted on the bactericidal effect with respect to the time from the purification unit 23 to the delivery to the drain pan 20. FIG. 8 is a diagram showing the experimental results.

In this experiment, the purification unit 23, which is a singlet oxygen generation source, uses glass beads (φ2 cm × 20 cm) carrying rose bengal as a sensitizer as a sensitizer and a fluorescent lamp as the light source 27. used. The air flow rate is 100 ml / min. The flow path length of the pipe 30 from the pump 28 so that the time from the purification unit 23, which is a source of singlet oxygen, to 15 seconds, 25 seconds, 35 seconds until it is sent to the drain pan 20 as the action unit, The channel diameter is set. A 10 ^5-6 CFU / ml E. coli solution is prepared in the drain pan 20 in advance, and the number of E. coli after 60 minutes and 90 minutes after the start of energization of the pump 28 and the light source 27 for each setting. Compare

According to this, before the air containing singlet oxygen from the purification unit 23 was supplied, the number of viable bacteria was 10 ^5-6 CFU / ml, but when the delivery time is 15 seconds, The viable cell count was 0 at 60 minutes and 90 minutes, respectively. When the delivery time was 25 seconds, the viable cell count was 0-10 CFU / ml after 60 minutes, but it was 0 after 90 minutes. Furthermore, even when the delivery time was 35 seconds, the viable cell count became 0 after 60 minutes and 90 minutes, respectively. In addition, although the delivery time was 25 seconds and the viable count after 60 minutes was 0 to 10 CFU / ml, it is considered to be an error level.

  From the above results, singlet oxygen is an unstable substance. However, even if the time (sending time) from generation in the purification unit 23 to delivery to the drain pan 20 is 35 seconds, it is sufficient. It can be seen that the ability to decompose singlet oxygen can be obtained, and the drain water D stored in the drain pan 20 can be effectively sterilized.

  Therefore, also from the above results, conditions such as the flow rate of air supplied from the purification unit 23 to the drain pan 20 and / or the flow path length of air from the purification unit 23 to the drain pan 20 are singlet in the purification unit 23. By setting the time from when oxygen is generated to when it is supplied to the drain pan 20 to 30 seconds or less, more preferably 10 seconds or less, the singlet is present while singlet oxygen is present. Since it becomes possible to supply the air from the purification | cleaning part 23 containing oxygen to the drain pan 20, the decomposition | disassembly capability of the substance and bacteria which cause the slime by singlet oxygen can be exhibited reliably.

  Therefore, the drain water D stored in the drain pan 20 can be sterilized quickly and effectively, and the generation of slime can be more effectively suppressed.

  In addition, the purification | cleaning part 23 is not limited to the said structure, For example, it is good also as a structure as shown in FIG. 9, FIG. FIG. 9 is a perspective view of a sensitizing member 37 as another embodiment, and FIG. 10 is a cross-sectional view of the sensitizing member 37 of FIG. The sensitizing member 37 is a cylindrical member having an air flow path 36 formed therein, and has a sensitizer carrying structure similar to that of the sensitizer carrying body 25 of the above embodiment along the inner wall surface. A body 38 is provided. Inside the sensitizing member 37, a light source 39 for photosensitization extending in the longitudinal direction and surrounded by a sensitizer carrier 38 is disposed. The light source 39 is configured in the same manner as the light source 27 of the above embodiment.

  Similarly to the above embodiment, the sensitizing member 37 is located upstream of the air flow path 36, and an air inlet 36A is formed. The air inlet 36A is a pump that sucks air from outside. A pipe 40 to which (air supply means) 28 is connected is connected. On the other hand, an air outlet 36B is formed on the downstream side of the air flow path 36, and air that has been processed in the sensitizing member 37 is supplied into the drain pan 20 to the air outlet 36B. For this purpose, a pipe 41 is connected. The air discharge part 31 arrange | positioned at the deepest part 20B of the drain pan 20 is connected to the edge part of the said piping 41 as mentioned above.

  By adopting such a configuration, it is not necessary to configure the sensitizing member 37 with a light-transmitting material, and it is possible to uniformly irradiate the sensitizer carrying member 38 with the irradiation light from the light source 39 uniformly. Thus, singlet oxygen can be effectively generated.

  Further, as shown in FIG. 11, the deepest portion 20 </ b> B is configured so that the air discharge portion 31 is the lowest in the drain pan 20 in the pipe 30 or 41 that sends out air containing singlet oxygen from the purification portion 23. You may arrange | position so that a predetermined | prescribed inclination | tilt angle may be comprised between a bottom face. Thereby, it becomes possible to form a water flow in the drain water D stored in the drain pan 20 by jetting the air supplied from the purification unit 23. Therefore, the stirring effect of the drain water D can be exhibited, and the sterilization effect by singlet oxygen can be improved.

  In each of the above embodiments, singlet oxygen is generated by photosensitization. However, the present invention is not limited to this, and singlet oxygen may be generated by sound sensitization. In that case, the purifying unit 23 uses a sensitizer carried on the sensitizer carrying body 44 as a cyanine dye, phthalocyanine, porphyrin, perylenequinone, xanthene dye, or one containing at least one of these. To do. Further, instead of the light source 27 for photosensitization, an ultrasonic generator 43 for sound sensitization is used. The ultrasonic generator 43 generates a sound wave having a frequency at which the sensitizer can be sensitized, for example, a sound wave having a frequency of 0.01 to 10 MHz, preferably 0.01 to 2 MHz.

  With such a configuration, the sensitizer carried on the sensitizer carrier 44 by irradiating the sensitizer carrier 44 of the sensitizer 26 or 37 with sound waves of a predetermined frequency from the ultrasonic generator 43 is as follows. The sound is excited to form a triplet state of the sensitizer by intersystem crossing.

  In this state, by sending the outside air from the pump 28 via the pipe 29 to the air flow path 24 or 36 in the sensitizing member 26 or 37, the triplet state sensitizer in the air flow path 24 or 36 becomes The ground state oxygen molecules existing in the air, that is, having an excitation energy substantially equal to the energy difference between triplet oxygen and singlet oxygen, the triplet state sensitizer collides with triplet oxygen. As a result, energy exchange with electrons occurs, and the sensitizer returns to the ground state, and at the same time, triplet oxygen transitions to singlet oxygen to generate singlet oxygen.

  Then, the air containing the singlet oxygen is led out into the pipe 30 or 41 by the pump 28 and is discharged from the air release part 31 connected to the pipe end. Therefore, in the drain water D stored in the drain pan 20, air containing singlet oxygen is released from the ventilating unit 31, thereby coming into contact with the air due to high oxidizing power of singlet oxygen. Substances and bacteria that cause slime contained in the drain water D are decomposed.

  As a result, the drain water D stored in the drain pan 20 can be effectively sterilized, and slime generation can be suppressed. Therefore, inconveniences such as clogging of the drain pipe 21 and the pump 14 due to slime can be eliminated, and smooth drain water can be discharged. Therefore, it is possible to avoid the disadvantage that the drain water D leaks directly from the drain pan 20.

  In such a case, since the sensitizer is not a photosensitization but a sound sensitization, it is not necessary to have a configuration in which direct light is irradiated. Accordingly, it is not necessary to configure the sensitizing member 26 with a translucent material, and the singlet is more effectively achieved by causing the sound wave to reach the core of the sensitizer carrier 44 where light cannot reach. Oxygen can be generated. Therefore, without providing the sensitizer carrier 44 as shown in FIG. 5 so as to face the ultrasonic generator 43, the position where the sound wave can reach, for example, as shown in FIG. Even when it is provided on the bottom surface of the air flow path 24, singlet oxygen can be effectively generated.

  In addition, the propagation of bacteria that generate slime in the drain water is mainly at a temperature of 25 ° C to 38 ° C. Therefore, in addition to the above embodiments, the deepest part 20B of the drain pan 20 is provided with a temperature sensor 46 as shown in FIG. 4, and the detected temperature directly detected by the temperature sensor 46 is a temperature range suitable for bacterial growth. In such a case, the drain water purification device 18 may be operated. Note that the temperature-based control is not limited to this. For example, the temperature in the drain pan 20 is suitable for bacterial growth based on the temperature indirectly detected by another temperature sensor provided in the device. When it is determined that the drain water purification device 18 has been obtained, the drain water purification device 18 may be configured to operate.

  As a result, when the drain water D stored in the drain pan 20 is in a temperature range suitable for the propagation of bacteria, the drain water purification device 18 is operated to realize purification control as required. Therefore, it is possible to realize effective suppression of slime generation.

  In this embodiment, an air conditioner is cited as an apparatus to which the drain water purification device 18 is applied. However, the apparatus is not limited to this, and has a configuration in which drain water is stored in a drain pan. It may be a device such as a low temperature showcase, a refrigerator, a car air conditioner, or the like.

It is sectional drawing of the utilization side unit of an air conditioner. It is a top view of the utilization side unit of FIG. It is a schematic block diagram of a drain water purification apparatus. FIG. 4 is a partially enlarged view of FIG. 3. It is a schematic block diagram of a purification | cleaning part. It is a block diagram of a control apparatus. It is a flowchart of drain water purification control. It is a figure which shows an experimental result. It is a perspective view of the sensitizing member as another Example. It is sectional drawing of the sensitizing member of FIG. It is the elements on larger scale of the drain water purification apparatus as another Example. It is a schematic block diagram of the sensitizing member as another Example.

Explanation of symbols

C Control device D Drain water R Room to be conditioned 1 User side unit (air conditioner as equipment)
2 Main body 3 Use side heat exchanger (indoor heat exchanger)
4 Blower 5 Fan Motor 14 Drain Pump 14A Suction Port 16 Refrigerant Piping 18 Drain Water Purifier 20 Drain Pan 20A Bottom 20B Deepest Portion 21 Drain Pipe 22 Water Level Sensor 23 Purifier (Purification Unit)
24, 36 Air flow path 25, 38, 44 Sensitizer carrier 26, 37 Sensitizing member 27, 39 Light source 28 Pump (air supply means)
29, 30, 40, 41 Piping 31 Air vent (air outlet)
33 Control unit (air conditioner side)
43 Ultrasonic generator

Claims (10)

In equipment with a drain pan that receives drain water,
An apparatus comprising a purification means for generating singlet oxygen by photosensitization or sound sensitization, wherein air containing singlet oxygen is supplied to the drain water stored in the drain pan from the purification means. Drain water purification device.   The apparatus for drain water purification of equipment according to claim 1, wherein an air outlet of the purification means is disposed at the deepest part of the drain pan.   The flow rate of the air supplied from the purification unit to the drain pan and / or the flow path length of the air from the purification unit to the drain pan is supplied to the drain pan after singlet oxygen is generated by the purification unit. The apparatus for drain water purification of equipment according to claim 1 or 2, wherein the time until the operation is performed is set to be 30 seconds or less.   The flow rate of the air supplied from the purification unit to the drain pan and / or the flow path length of the air from the purification unit to the drain pan is supplied to the drain pan after singlet oxygen is generated by the purification unit. The drain water purification device for equipment according to claim 3, wherein the time until the operation is performed is set to be 10 seconds or less.   The light source for photosensitization in the purification means is at least one selected from a fluorescent lamp, an LED, an incandescent lamp, or a mercury lamp, and visible light in the range of 400 nm to 700 nm is used for photosensitization. The apparatus for irrigating drainage of water according to any one of claims 1 to 4, wherein the sensitizer is irradiated.   Sensitizers for photosensitization in the purification means are methylene blue, thionine, rose bengal, erythrosine, eosin Y, fluorescein, proflavine, fluorenone, rhodamine, porphyrin, phthalocyanine, carbon soot molecule, silicon nanocrystal, or these The drain water purification apparatus for equipment according to any one of claims 1 to 5, wherein at least one selected from the group consisting of:   The sensitizer for sound sensitization in the purification means is a cyanine dye, phthalocyanine, porphyrin, perylenequinones, xanthene dye, or at least one selected from these. The drain water purification apparatus of the apparatus in any one of Claim 5 thru | or 5.   8. The drain water purification of equipment according to claim 1, further comprising a control means for controlling the purification means, wherein the control means operates the purification means after the operation of the equipment is completed. apparatus.   And a control means for controlling the purifying means, the control means having a sensor for detecting the amount of drain water stored in the drain pan, and based on the output of the sensor, the amount of drain water in the drain pan is not less than a predetermined value. The apparatus for purifying drain water according to any one of claims 1 to 8, wherein the purification means is operated in the case of   Control means for controlling the purification means, the control means has a sensor for directly or indirectly detecting the temperature of the drain water stored in the drain pan, and based on the output of the sensor, The apparatus for purifying drain water according to any one of claims 1 to 9, wherein the purifying means is operated when the temperature of the drain water is within a predetermined range.

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