JP2008145025A - Air conditioner and its operation method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an air conditioner and its operation method capable of inhibiting growing of bacteria by diffusing silver ion in a drain pan. <P>SOLUTION: In this air conditioner comprising a heat exchanger 2, a drain pan disposed at a lower part of the heat exchanger and receiving drainage condensed in the heat exchanger 2, and a draining means 4 for discharging the drainage accumulated in the drain pan 3 to the external by pumping up the same to an upper part of the drain pan 3, an antibacterial metallic ion generator 6 is disposed inside of the draining means 4. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention provides a heat exchanger, a drain pan that is provided below the heat exchanger and receives the drain water condensed in the heat exchanger, and the drain water accumulated in the drain pan is pumped above the drain pan. The present invention relates to an air conditioner including drainage means for discharging to the outside, and an operation method thereof.

  Conventionally, in this type of air conditioner, since organic matter may be contained in the drain water, it is known that bacteria propagate in the drain pan using this organic matter as feed. Bacteria produce viscous substances such as slime when breeding, causing various problems such as blocking drainage from the drain pan to the outside by clogging a drain pump or drain hose as drainage means.

  For such problems, a drain pan is provided with a silver electrode as an anode and a metal electrode as a cathode, and a voltage is applied between the two electrodes to generate silver ions in the drain water, thereby suppressing bacterial growth of the drain water. An air conditioner (see, for example, Patent Document 1) has been proposed.

  Further, in the conventional air conditioner, in order to compensate for the lack of the pump head when the drain water is pumped above the drain pan and discharged to the outside, a drain storage portion and a drain discharge pump are provided in the middle of the drain hose. A drain up kit may be provided. In such a drain up kit, in order to suppress bacterial growth, it has been studied to dispose an antibacterial agent in the drain container (for example, see Patent Document 2).

Japanese Patent Laid-Open No. 2005-98606 JP 2006-162222 A

  However, in a conventional air conditioner in which a silver electrode is provided as an anode in a drain pan, the drain water accumulated in the drain pan stays. Therefore, even if silver ions are generated in such drain water, there is no electrical connection between the electrodes. Although migration occurred, there was no active diffusion means in the other regions, and diffusion was based only on the concentration gradient. For this reason, silver ions diffuse only in the vicinity of the electrodes, and it was difficult to spread silver ions to the drain water of the entire drain pan. Therefore, such a conventional air conditioner has not been able to sufficiently suppress the growth of bacteria in the drain water.

Further, in the vicinity of the electrodes, the reaction shown in the following chemical formula 1 proceeds at each electrode. For this reason, silver ions generated at the anode and electrophoresed toward the cathode react with hydroxide ions generated near the cathode and precipitate as silver oxide insoluble in water (Ag ₂ O). In some cases, electrons are taken in and deposited as silver at the cathode, and silver ions are not sufficiently diffused due to such factors.

[Chemical 1]
Anode: Ag → Ag ^{+ +} e ^-
_{Cathode: 1 / 4O 2 + 1 /} 2H 2 O + e - → OH - (Ag + + e - → Ag)

  In the air conditioner in which the antibacterial agent is disposed in the drain accommodating part of the drain up kit, the bacterial propagation in the drain accommodating part is suppressed, and the bacterial propagation cannot be suppressed with respect to the drain water in the drain pan. In addition, the antibacterial agent is diffused by the concentration gradient in the drain accommodating portion, and it is difficult to spread the antibacterial agent throughout the drain accommodating portion.

  The present invention has been devised in view of the above problems, and an object thereof is to provide an air conditioner that can suppress the propagation of bacteria by diffusing silver ions in a drain pan, and an operation method thereof. Is.

  A first characteristic configuration of an air conditioner according to the present invention for achieving the above object includes a heat exchanger, a drain pan provided below the heat exchanger, and receiving drain water condensed in the heat exchanger, An air conditioner comprising a drainage means for pumping the drain water accumulated in the drain pan above the drain pan and discharging the drain water to the outside, wherein an antibacterial metal ion generator is provided inside the drainage means. is there.

  Since the drainage means pumps up and drains the drain water above the drain pan, when the drainage means is stopped, the drain water corresponding to the pumping height is not drained and flows back to the drain pan. Therefore, according to this configuration, since the antibacterial metal ions can be generated inside the drainage means, the drain water inside the drainage means flows back to the drain pan with the antibacterial metal ions, and the antibacterial metal Ions can be distributed uniformly throughout the drain pan. Thereby, it is possible to efficiently suppress bacteria from breeding in the drain water of the drain pan.

  Also, if antibacterial metal ions are generated inside drainage means in which drain water is fluid, the antibacterial metal ions will diffuse immediately, so that the antibacterial metal ions react with hydroxide ions etc. It is also possible to prevent the formation of a metal salt such as an antibacterial metal from the cathode.

  According to a second characteristic configuration of the air conditioner according to the present invention, the drainage means includes a pump and a riser connected to a discharge side of the pump, and the antibacterial metal ion generator is disposed inside the riser. It is in the point provided.

  Since the antibacterial metal ion generator is installed on the discharge side of the pump, when drain water containing antibacterial metal ions flows backward, it passes through the pump and passes the antibacterial metal ions inside the pump. Can be attached to. Therefore, according to this structure, the propagation of bacteria can be suppressed even in the inside of the pump, and it is possible to prevent the discharge performance of the pump from being lowered by slime produced by the bacteria.

  According to a third characteristic configuration of the air conditioner according to the present invention, the antibacterial metal ion generator includes a plurality of electrodes and voltage applying means for applying a voltage between the electrodes, and at least an anode of the electrodes. Is that it contains an antibacterial metal.

  That is, according to this configuration, antibacterial metal ions can be easily generated by applying a voltage between the electrodes.

  A fourth characteristic configuration of the air conditioner according to the present invention is that at least a pair of electrodes containing the antibacterial metal is provided, and the voltage applying means applies a voltage between the electrodes containing the antibacterial metal. .

  That is, according to this configuration, antibacterial metal ions can be generated from either side of the electrode containing a pair of antibacterial metals by switching between the anode and the cathode when applying a voltage. Therefore, an electrode can be used effectively and the lifetime as an antibacterial metal ion generator can be lengthened.

  The characteristic means of the operation method of the air conditioner according to the present invention includes a heat exchanger, a drain pan provided below the heat exchanger, receiving drain water condensed in the heat exchanger, and the pooled in the drain pan. Air comprising a pump for pumping drain water above the drain pan and discharging it to the outside, an ascending pipe connected to the discharge side of the pump, and an antibacterial metal ion generator provided inside the ascending pipe A method of operating a conditioner, wherein the pumping pump and the antibacterial metal ion generator are driven to generate antibacterial metal ions in the drain water, and then the pump is stopped. The drain water from which the antibacterial metal ions are eluted is allowed to flow back to the drain pan.

That is, according to this means, since the antibacterial metal ions can be uniformly distributed throughout the drain pan, it is possible to prevent bacteria from breeding in the drain water of the drain pan.
In addition, since antibacterial metal ions can be attached to the inside of the pump, the growth of bacteria can be suppressed inside the pump, and the discharge performance of the pump is reduced by slime produced by the bacteria. Can be prevented.

  Hereinafter, an embodiment of an air conditioner according to the present invention will be described with reference to the drawings. Here, the case where this invention is applied to the indoor unit 1 of a ceiling cassette type air conditioner will be described as an example.

  As shown in FIG. 1, an indoor unit 1 of an air conditioner according to the present embodiment is provided below a heat exchanger 2 that cools or heats air introduced into the indoor unit 1 and a heat exchanger 2. And a drain pan 3 that receives drain water condensed and flowing down in the heat exchanger 2 during cooling operation, etc., and a drainage means 4 that pumps the drain water accumulated in the drain pan 3 above the drain pan 3 and discharges it to the outside. Configured.

  As the heat exchanger 2, a conventionally known one can be applied. Although not shown, for example, a heat exchanger 2 having a plurality of aluminum fins provided on a copper pipe through which a heat medium such as chlorofluorocarbon flows is used. The drainage means 4 includes a drain pump 41 as a pumping pump, a drain hose 42 as a riser pipe having one end connected to the discharge side of the drain pump 41 and the other end connected to the external pipe 10 above the drain pump 41. Is provided. The drain pump 41 is connected to a control device 5 that controls the driving and stopping of the drain pump 41.

  Inside the drain hose 42, there is provided a silver ion generator 6 as an antibacterial metal ion generator for generating silver ions which are a kind of antibacterial metal ions. The silver ion generator 6 includes silver electrodes 61 and 62 as electrodes containing a pair of antibacterial metals, and a DC power source 63 as voltage applying means for applying a voltage between the silver electrodes 61 and 62. In this embodiment, the silver electrodes 61 and 62 have a flat plate shape, and are arranged to face each other at a predetermined interval along the longitudinal direction of the drain hose 42. The control device 5 connected to the drain pump 41 is also connected to the DC power source 63, and controls on / off switching of energization to the silver electrodes 61, 62 in conjunction with the drive / stop control of the drain pump 41. To do. The control device 5 can also control the switching between the anode and cathode of the silver electrodes 61 and 62. By periodically switching each electrode between the anode and the cathode, silver ions are generated from only one of the electrodes. It is possible to prevent this, and to extend the life of the silver electrodes 61 and 62.

In the present embodiment, the silver ion generator 6 generates silver ions by performing constant current control so that the value of the current flowing between the silver electrodes 61 and 62 is constant.
The constant current control is control that maintains a constant current value regardless of the resistance value change between the electrodes. However, the resistance value between the electrodes always changes due to the generation of bubbles on the surface of the electrodes and the change in the distance between the electrodes due to the vibration of the electrodes, so it is difficult to make them completely constant, and some current fluctuations occur To do. Further, due to the extremely high resistance value, a constant current may not flow at a voltage within the allowable range of the circuit, and the current value may decrease. Therefore, in this embodiment, regardless of the change in the current value as described above, the voltage is changed in response to the change in the resistance value between the electrodes, that is, the voltage is increased if the resistance value is increased, and the resistance value is increased. Control that lowers the voltage and stabilizes the current value between the electrodes if lowering is referred to as constant current control.

  In the indoor unit 1 according to the present embodiment, during air conditioning operation, for example, during cooling operation, the fan (not shown) is driven to heat the indoor air taken from the suction port (not shown) and cooled by the refrigerant. Heat is exchanged in contact with the vessel 2, and sent as cold air from the outlet (not shown) to the room. In this case, condensed water droplets adhere to the heat exchanger 2, and the water droplets flow down and accumulate in the drain pan 3 as drain water. The drain pan 3 is provided with a gradient at the bottom so that the drain water is collected in the drain pump 41, and the drain water accumulated in the drain pan 3 is driven to the drain pipe 41 and discharged to the external pipe 10 through the drain hose 42. The When draining, the drain water is once pumped up above the drain pan 3 by the drain pump 41. Therefore, when the drain pump 41 stops, the drain water corresponding to the pumping height X is not discharged and flows back to the drain pan 3.

  In such an indoor unit 1, as shown in FIG. 2A, the drain pump 41 is driven and a voltage is applied between the silver electrodes 61 and 62 to generate silver ions. Thereafter, when the drain pump 41 is stopped, the drain water containing silver ions flows back to the drain pan 3 as shown in FIG. 2B, so that the silver ions are evenly distributed to the entire drain water of the drain pan 3. be able to. Thereby, it is possible to suppress bacteria from breeding in the drain water of the drain pan 3.

  In the present embodiment, the silver ion generator 6 is provided at a position higher than the level of the drain water finally remaining in the drain pan 3. Thereby, it is possible to prevent the drain water from staying in the silver ion generator 6 after the drain pump 41 is stopped and the drain water flows backward to the drain pan 3. For example, when the drain pump 41 is stopped for a long time, such as after the air conditioning operation is stopped, if the drain water stays between the silver electrodes 61 and 62 of the silver ion generator 6, There is a possibility that silver ions are deposited along with the evaporation to cause a short circuit between the silver electrodes 61 and 62. Therefore, the short circuit between the silver electrodes 61 and 62 can be prevented by providing the silver ion generator 6 so that the drain water does not stay inside.

  In the indoor unit 1 according to the present embodiment, the silver ion generator 6 is provided on the discharge side of the drain pump 41. For this reason, when drain water containing silver ions flows backward, it passes through the drain pump 41, and silver ions can be attached to the impeller of the drain pump 41. Therefore, the propagation of bacteria can also be suppressed inside the drain pump 41, and the discharge performance of the drain pump 41 can be prevented from being lowered by slime produced by the bacteria.

  In general, the drain hose 42 of the indoor unit 1 has little difference depending on the type of the indoor unit 1 in the diameter, shape, and the like. For this reason, the silver ion generator 6 of the same shape can be applied to the inside of the drain hose 42 of all types of indoor units 1 and can be manufactured at a low cost because the standard can be unified. It can also be applied to the existing indoor unit 1.

  In the indoor unit 1 according to the present embodiment, silver ions can be uniformly dispersed throughout the drain pan 3 by backflowing drain water containing silver ions. For this reason, it is only necessary to generate silver ions while the drain pump 41 is driven. However, if silver ions are generated at a stage where the drain water in the drain pan 3 is large, the silver ions are discharged together with the drain water. The silver ions are preferably generated after the drain water in the drain pan 3 is reduced. Specifically, it is preferable to generate silver ions at the stage where the drain water of about the pumping height X remains in the drain pan 3. Since the silver ions are generated while pumping, the generated silver ions can be immediately diffused into the drain water, and the drain water corresponding to the pumping height X is not discharged, so silver ions are not wasted. The electrodes 61 and 62 can be used effectively and can be long-lasting.

  The concentration of silver ions in the drain water can be controlled by the amount of electricity flowing between the silver electrodes 61 and 62, the amount of drain water, and the like. That is, the amount of elution of silver ions is approximately proportional to the amount of electricity (C) = constant current value (A) × energization time (sec). Therefore, when performing constant current control, the conduction time is controlled according to the amount of water. By doing so, drain water with a constant concentration of silver ions can be obtained. Therefore, in this embodiment, for example, the current value and the energization time so that the concentration of silver ions with respect to the drain water amount corresponding to the pumping height X (the maximum drain water amount stored in the drain pan 3 after drain water discharge) becomes a predetermined value. Is set constant, the concentration of silver ions in the drain water in the drain pan 3 can be set to a predetermined value or more.

Moreover, the silver ion generator 6 in this embodiment can control generation | occurrence | production of silver ion by the presence or absence of the application of a voltage, for example, when the amount of drain water of the drain pan 3 becomes the amount equivalent to the part of the pumping height X. Thus, it is preferable because silver ions can be generated at a desired timing.
When silver ion eluents such as silver supported zeolite, silver supported apatite, and silver-containing glass are used, silver ions are eluted when they come into contact with the drain water regardless of the amount of drain water in the drain pan 3. It may be discharged together with water to reduce efficiency.

  In addition, during the air conditioning operation, the indoor unit 1 according to the present embodiment periodically drains the drain water of the drain pan 3 by the drain pump 41, and the drain water of the drain pan 3 is replaced, so that bacteria hardly propagate. It becomes a state. In addition, when the drain pump 41 is driven, silver ions are generated each time, so that silver ions can be present in the drain water in the drain pan 3 and bacterial growth can be suppressed.

  On the other hand, when the air conditioning operation is stopped, the drain water of the drain pan 3 is discharged, and the drain pump 41 is also stopped. At this time, since the drain water of at least the pumping height X flows backward, after the air-conditioning operation is stopped, the drain water is maintained in a state where it is accumulated in the drain pan 3, and an environment in which bacteria are easy to propagate is obtained. Further, in the indoor unit 1, even if the air conditioning operation is stopped, the heat exchanger 2 is cooled, so that the flow of drain water to the drain pan 3 does not stop immediately. Even if the drain water is discharged, the drain water continues to flow into the drain pan 3 even after the drain pump 41 is stopped. For this reason, even when silver ions are generated in the drain water of the drain pan 3 when the air pump 41 is driven when the air conditioning operation is stopped, the amount of drain water in the drain pan 3 is reduced by the flow of the drain water to the drain pan 3 thereafter. Since the concentration of silver ions increases and the concentration of silver ions relatively decreases, there is a possibility that the concentration of silver ions necessary to suppress bacterial growth cannot be maintained. Therefore, a preferred example of the operation method after the air conditioning operation of the indoor unit 1 according to the present embodiment is stopped will be described below with reference to FIG.

  In the operation method of the indoor unit 1 according to the present embodiment, the flow of drain water to the drain pan 3 is completed after the fan of the indoor unit 1 is turned off and the air conditioning operation is stopped, and the amount of drain water stored in the drain pan 3 is The time (A + B) until no change occurs is measured in advance as the flow completion time, and after the flow completion time has elapsed, the drain pump 41 is turned on and driven for a predetermined time (C), and accumulated in the drain pan 3. The drain water is discharged until the drain water in the drain pan 3 is substantially eliminated. As a result, the amount of drain water stored in the drain pan 3 after the stop of the air conditioning operation is only the amount of residual drain water corresponding to the pumping height X, and can always be kept constant and minimized.

  Thereafter, when the drain pump 41 is stopped, the drain water flows backward to the drain pan 3, and therefore, for a certain time (D) after the drain pump 41 is stopped, for example, the drain water corresponding to the pumping height X is supplied to the drain pan 3. After elapse of the time until flowing out, etc., the drain pump 41 is driven again to pump the drain water of the drain pan 3, and the silver ion generator 6 is driven to generate silver ions, which are mixed in the drain water. In the operation method of the present embodiment, the silver ion generator 6 is energized by switching between the anode and the cathode of the silver electrodes 61 and 62 for a certain time. When the drain pump 41 is driven again, the drain water is only an amount corresponding to the pumping height X and is not discharged to the outside. Therefore, the drive time (E) of the drain pump 41 is the silver ion generator. 6 can be arbitrarily determined according to the driving time of the sixth embodiment. Specifically, in the operation method of the present embodiment, the driving time of the silver ion generator 6 is set to 20 seconds (reversed every 10 seconds), and the drain pump 41 The driving time (E) is 21 seconds.

  Then, by stopping the drain pump 41, the drain water corresponding to the pumping height X flows back to the drain pan 3 together with the generated silver ions. As a result, an amount of silver ions effective for inhibiting bacterial growth can be uniformly distributed throughout the drain pan 3. That is, as shown in FIG. 4, it is assumed that the pumped water height X is the highest (for example, X = 850 mm, drain water amount 510 ml). In this case, too, the silver ion concentration of drain water is effective. If the generation amount of ions (for example, current value, energization time, etc.) is set, even if the pumping height X is low, more than the necessary amount of silver ions can be present in the drain water.

  In the operation method of the indoor unit 1 according to the present embodiment, the drain pump 41 is driven for a certain period of time (A) after the air-conditioning operation is stopped. As a result, the amount of drain water accumulated in the drain pan 3 before the flow completion time (A + B) elapses can be reduced. For this reason, the propagation of bacteria can be further suppressed, and the drive time of the drain pump 41 after the elapse of the flow completion time can be shortened. The driving time (A) of the drain pump 41 after the stop of the air-conditioning operation is not particularly limited, and can be arbitrarily set, for example, 5 minutes.

  In the present embodiment, the generation of silver ions is the time (E) during which the drain pump 41 pumps up the drain water and the silver ion generator 6 and the drain water are in contact with each other. In general, when using a silver ion eluent such as silver-supported zeolite, it is required to contact with drain water for a long time (1 hour or more) in order to obtain a sufficient antibacterial effect. In particular, since the drain water of the air conditioner is derived from the concentration in the air, it contains less electrolyte than general water (tap water, well water, river water, etc.). Therefore, when silver ions are eluted by an ion exchange method as in the case of silver-supported zeolite, the elution rate of silver ions is reduced and it is necessary to make contact for a longer time. On the other hand, the silver ion generator 6 in the present embodiment is preferable because predetermined silver ions can be generated in a short time by controlling the amount of electricity. Thereby, the operation time of the drain pump 41 can be shortened, and power consumption and operation sound can be reduced.

(Example 1)
Stop the air-conditioning operation using the 5 hp ceiling cassette type indoor unit 1, setting the temperature to 27 ° C, 30 ° C, 35 ° C and setting the humidity to 40% RH, 60% RH, 80% RH. Thereafter, the amount of drain water accumulated in the drain pan 3 after the drain pump 41 was driven for 5 minutes (A) was measured. As a result, the amount of drain water is less influenced by temperature and mainly influenced by humidity. For example, at 30 ° C., as shown in FIG. 5, 230 ml at 40% RH, 310 ml at 60% RH, 80%. It was 330 ml with RH. However, in all cases, the amount of drain water did not change after 30 minutes. For this reason, it turned out that the flow of drain water is completed in 30 minutes after the lapse of time A. Therefore, in this case, the drain water amount of the drain pan 3 can be minimized by setting the flow completion time (A + B) to 35 minutes (5 minutes + 30 minutes).

(Example 2)
500 ml, 750 ml, and 1000 ml of drain water were put in the drain pan 3 of the indoor unit 1 similar to the above, and the time until the drain water was discharged by the drain pump 41 was measured. As a result, as shown in FIG. 6, it was found that even when 1000 ml of drain water was put in the drain pan 3, it could be discharged in 90 seconds. Therefore, if the drive time (C) of the drain pump 41 is 90 seconds or more, the amount of drain water in the drain pan 3 can be minimized.

(Example 3)
To 5 sterilized Erlenmeyer flasks, 100 ml of R2A liquid medium was dispensed, and 1 ml of a culture solution obtained by seed culture of drain water with R2A liquid medium (30 ° C., 1 day, shaking culture at 200 rpm) was added. And silver ion is not put in the medium of each Erlenmeyer flask, and the concentration of silver ions is 0.1 mg / L, 0.5 mg / L, 1 mg / L, 2 mg / L by the silver ion generator 6 respectively. Thus, the number of bacteria was measured over time. The reaction conditions were shaken at 30 ° C. and 180 rpm, and sampling was performed 1 ml at a time at the start of the reaction, 3 hours, 6 hours, and 24 hours later, and serial dilution was performed on the R2A agar medium. The culture was performed at 30 ° C. for 2 days, and colonies were measured.

As a result, as shown in FIG. 7, it was found that the growth can be suppressed for several hours (for example, 6 hours) by setting the silver ion concentration to 0.1 mg / L or more for the bacteria producing slime. The growth of bacteria in the drain water of the drain pan 3 is remarkable because the amount of drain water is the highest for several hours after the air conditioning operation is stopped. In addition, air conditioning operation is often resumed after several hours. If the operation is resumed, the drain water in the drain pan 3 is replaced at any time and the water temperature is lowered, so that bacteria are difficult to grow. Therefore, a sufficient effect is expected when the concentration of silver ions in the drain water of the drain pan 3 is 0.1 mg / L or more.
Further, it was found that if the silver ion concentration was 1 mg / L or more, not only the growth was suppressed but also the effect of reducing the number of bacteria. If it is this density | concentration, the growth of a microbe can be prevented more effectively and the production | generation of slime can be suppressed.

Example 4
When the pumping height X is 60 cm (drain water amount 390 ml), when 390 ml of drain water remains in the drain pan 3, the drain pump 41 is driven and at the same time, the silver electrode 61, which is the silver ion generator 6, A current of 20 mA (constant current) was applied between 62 (electrode size: width 10 mm × length 50 mm, distance between electrodes 3 mm), and the concentration of silver ions in the drain water was measured over time. The silver ion concentration was measured using a multi-item rapid water quality analyzer (HACH DR2400). The conductivity of the drain water was 25 μS / cm. As a result, as shown in FIG. 8, linearity is obtained between the silver ion concentration and the energization time. In this case, the silver ion concentration (1 mg / L) or more that has the effect of reducing bacteria is increased. In order to achieve this, it was found that it was necessary to energize for about 15 seconds or more.

(Example 5)
When the pumping height X is 60 cm (drain water amount 390 ml), when 390 ml of drain water remains in the drain pan 3, the drain pump 41 is driven and at the same time, the silver electrode 61, which is the silver ion generator 6, 62 (electrode size: width 10 mm × length 50 mm, distance between electrodes 3 mm), a current of 20 mA (constant current) was applied for 15 seconds, the drain pump 41 was stopped, and the drain pan 3 shown in FIG. The concentration of silver ions in the drain water at the position of -f was measured. Further, as a comparative example, the silver ion concentration at the positions a to f when the silver ion generator 6 was provided at the position a which is one location of the drain pan 3 to generate silver ions was also measured. As a result, as shown in Table 1, in this example, it was found that silver ions were uniformly dispersed at about 1 mg / L in the entire drain water of the drain pan 3.

  In the present embodiment, the case where the silver ion generator 6 is provided in the drain hose 42 on the discharge side of the drain pump 41 has been described. However, the present invention is not limited to this, and the inside of the drain pump 41 and the suction side of the drain pump 41 Etc. can also be provided.

  In the present embodiment, the case where the silver electrodes 61 and 62 are in the form of a flat plate has been described. However, the present invention is not particularly limited, and electrodes having other shapes such as a rod shape may be used.

In this embodiment, although the case where the silver electrodes 61 and 62 were provided as the silver ion generator 6 which is an antibacterial metal ion generator was demonstrated, the silver electrodes 61 and 62 are not restricted to pure silver, silver is used. Any electrode that contains and can elute silver ions may be used.
In addition, the antibacterial metal ion generator is not limited to the silver ion generator 6 and may be any device that generates at least one kind of antibacterial metal ions such as silver ions, copper ions, and zinc ions. Good. In such a case, an electrode containing an antibacterial metal and eluting antibacterial metal ions, such as copper, zinc, or an alloy thereof with silver, is used as the electrode. As an antibacterial metal ion, silver ion has the highest antibacterial effect and is desirable, but copper ion, zinc ion and the like also have an antibacterial effect and are inexpensive, so that they can be preferably applied.

  In this embodiment, the case where a silver electrode, which is an electrode containing an antibacterial metal, is applied to both the anode and the cathode has been described, but an electrode containing an antibacterial metal is used for the anode among a plurality of electrodes. In addition, an electrode that does not elute antibacterial metal ions, such as a titanium electrode, a platinum electrode, a carbon electrode, or a conductive plastic electrode, can be used for the cathode.

  In the present embodiment, the case where a DC power source is used as the voltage applying means has been described. However, an AC power source having a sine wave, a rectangular wave, or the like can also be used.

In the present embodiment, in the operation method, after the flow completion time (A + B) has elapsed, the drain pump 41 is driven to drain the drain water accumulated in the drain pan 3 to generate silver ions. For example, the drain pump 41 is not driven after the flow-down completion time has elapsed, and the silver ion generator 6 is driven during the time (A) for discharging the drain water before the flow-down completion time has elapsed. Silver ions can also be generated.
In addition, the drain pump 41 is also driven before the flow completion time (B), and the silver immediately before the time B passes (for example, when the amount of drain water in the drain pan 3 is about the pumping height X). The ion generator 6 can be driven to generate silver ions.
Furthermore, silver ions can be generated while the drain pump 41 is being driven after the flow-down completion time has elapsed. In this case, the silver ion generator 6 may be driven immediately before the drain pump 41 is stopped (for example, when the amount of drain water in the drain pan 3 is about the pumping height X).
In addition, about these operation methods, if silver ion is generated and then the drain pump 41 is stopped, the silver ion flows back to the drain pan 3 and diffuses together with the drain water. Therefore, the operation may be terminated at that time.

  In the present embodiment, a case has been described in which the drain pump 41 is driven for a certain period of time (A) after the air conditioning operation is stopped in the operation method, but the flow-down completion time elapses after the air conditioning operation is stopped. It is not necessary to drive the drain pump 41 before.

  In the present embodiment, in the operation method, the drain pump 41 and the silver ion generator 6 are simultaneously driven to stop the silver ion generator 6 and then the drain pump 41 is stopped. However, the present invention is limited to this. Not. For example, the drain pump 41 can be driven first, and the silver ion generator 6 can be driven to generate silver ions in the drain water while the drain water is present in the drain hose 42.

  In the present embodiment, the case where the silver ion generator 6 is driven by switching between the anode and the cathode once in the operation method has been described. However, the silver ion generator 6 may be switched a plurality of times by one drive. In addition, switching may not be performed by one driving, but may be performed at the next driving (for example, the next day) or after a plurality of driving. Note that the switching between the anode and the cathode may be periodic or random.

  In the present embodiment, the case where the silver ion generation device 6 is driven once (during E) in the operation method has been described, but it may be driven a plurality of times, and is not particularly limited.

  The air conditioner according to the present invention is not limited to the indoor unit of a ceiling cassette type air conditioner of a chlorofluorocarbon refrigerant, and is provided with a heat exchanger and a drain provided at the lower side of the heat exchanger and condensed in the heat exchanger. Various types of air conditioners, such as an air conditioner using a drain pan that receives water, and a drainage unit that pumps the drain water accumulated in the drain pan above the drain pan and discharges the drain water to the outside, such as an air conditioner using cold water, etc. It can be applied to air conditioners.

Schematic of indoor unit of ceiling cassette type air conditioner according to the present embodiment Explanatory drawing of the method of dispersing silver ions in the drain pan Explanatory drawing of the operating method of the indoor unit of the ceiling cassette type air conditioner concerning this embodiment Graph showing the relationship between residual drain amount and silver ion concentration Graph showing change in drain water over time Graph showing drain water discharge time Graph showing changes in bacterial count over time Graph showing the relationship between energization time and silver ion concentration The figure which shows the silver ion concentration measurement position of the drain pan

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Indoor unit 2 Heat exchanger 3 Drain pan 4 Drainage means 41 Drain pump (pumping pump)
42 Drain hose (rising pipe)
6 Silver ion generator (antibacterial metal ion generator)
61,62 Silver electrode (electrode containing antibacterial metal)
63 DC power supply (voltage application means)

Claims (5)

A heat exchanger, a drain pan provided below the heat exchanger and receiving drain water condensed in the heat exchanger, and the drain water accumulated in the drain pan is pumped up to the drain pan and discharged to the outside. An air conditioner comprising drainage means,
An air conditioner provided with an antibacterial metal ion generator inside the drainage means.   The air conditioner according to claim 1, wherein the drainage means includes a pump and a riser connected to a discharge side of the pump, and the antibacterial metal ion generator is provided inside the riser.   The antibacterial metal ion generator includes a plurality of electrodes and voltage applying means for applying a voltage between the electrodes, and at least an anode of the electrodes contains an antibacterial metal. Air conditioner.   The air conditioner according to claim 3, comprising at least a pair of electrodes containing the antibacterial metal, and the voltage applying unit applies a voltage between the electrodes containing the antibacterial metal. A heat exchanger, a drain pan provided below the heat exchanger and receiving drain water condensed in the heat exchanger, and the drain water accumulated in the drain pan is pumped up to the drain pan and discharged to the outside. An operating method of an air conditioner comprising a pump, a riser connected to the discharge side of the pump, and an antibacterial metal ion generator provided inside the riser,
After driving the pump and the antibacterial metal ion generator to generate antibacterial metal ions in the drain water, the pump is stopped and the antibacterial metal ions are eluted. A method for operating an air conditioner in which drain water flows backward to the drain pan.

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