JP2009236422A - Air-conditioning system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an air-conditioning system for permanently suppressing generation of slime in a drain pan. <P>SOLUTION: The air-conditioning system includes a heat exchanger 16, the drain pan 22 receiving drain water flowing down from the heat exchanger 16, and a drain pump 12 pumping up the drain water accumulated in the drain pan 22 and discharging it. An electrode type water level sensor 30 is provided for controlling actions of the drain pump 12. A silver object 50 containing silver ions having an antibacterial effect is arranged in a neighborhood of electrodes 31, 32 of the water level sensor 30. One part of a current flowing between the electrodes 31, 32 via the drain water is passed between the electrodes 31, 32 and the silver object 50, and elution of the silver ions into the drain water is promoted. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an air conditioner including a drain pan that receives drain water.

In general, an air conditioner is known that includes a heat exchanger, a drain pan that receives drain water flowing down from the heat exchanger, and a drain pump that pumps up and drains the drain water accumulated in the drain pan. In this type, semi-solid slime (hereinafter referred to as slime) may be generated in the drain water stored in the drain pan, and this slime may clog the drain pump or drain hose.
In order to eliminate this, conventionally, an arrangement in which an antibacterial unit containing an antibacterial agent that suppresses the generation of slime is arranged on the drain pan has been proposed (see, for example, Patent Document 1).
JP 2006-194491 A

  However, in the conventional configuration, the antibacterial agent is mixed with the drain water to chemically suppress the generation of slime. There is a problem that there is a difficulty in sustaining the occurrence.

  Then, the objective of this invention is providing the air conditioning apparatus which eliminates the subject which the prior art mentioned above has, and can suppress permanently that slime generate | occur | produces in drain water or a drain pan.

The present invention provides an air conditioner comprising: a heat exchanger; a drain pan that receives drain water flowing down from the heat exchanger; and a drain pump that pumps up and drains drain water accumulated in the drain pan. An electrode-type water level sensor is provided for controlling the water level, and a metal body containing a predetermined metal ion species having an antibacterial action is disposed in the vicinity of the electrode of the water level sensor, and between the electrodes via the drain water. A part of the flowing current is caused to flow between the electrode and the metal body, and the metal ion species are eluted in the drain water.
According to this configuration, by arranging a metal body containing a predetermined metal ion species having antibacterial action in the vicinity of the electrode of the water level sensor, a current flows from the electrode to the metal body via the drain water, and this metal body Since the metal ionization is promoted, the metal ions are diffused into the drain water. For this reason, it is suppressed that various bacteria propagate in drain water, and generation | occurrence | production of the slime to drain water or a drain pan can be suppressed permanently.

  In this configuration, the water level sensor includes a common electrode, a lower limit detection electrode and an upper limit lower limit electrode arranged to face the common electrode, and the metal body is disposed below the common electrode and the lower limit detection electrode. It is good also as a structure.

  Moreover, the said metal body is good also as a structure arrange | positioned in the position where the distance of this metal body and the said lower limit detection electrode becomes a distance substantially the same as the distance of the said lower limit detection electrode and the said common electrode.

  Moreover, the said metal body is good also as a structure which elutes any one of silver ion, zinc ion, or trunk | drum ion as said predetermined | prescribed metal ion seed | species.

  According to the present invention, by arranging a metal body containing a predetermined metal ion species having an antibacterial action in the vicinity of the electrode of the water level sensor, an electric current flows from the electrode to the metal body via drain water, and this metal body Since the metal ionization is promoted, the metal ions are diffused into the drain water. For this reason, it is suppressed that various bacteria propagate in the drain water, and generation | occurrence | production of the slime to drain water or a drain pan can be suppressed permanently.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a sectional view showing an air conditioner body and a decorative panel, and FIG. 2 is a bottom view showing the air conditioner body.
In these FIG.1 and FIG.2, the code | symbol 1 shows an air conditioning apparatus, This air conditioning apparatus 1 is equipped with the refrigerating cycle comprised with a compressor, an outdoor heat exchanger etc. in combination with the outdoor unit which is not shown in figure. As shown in FIG. 1, it is suspended and fixed in the ceiling space 41 of the building 40. The form in FIG.1 and FIG.2 is an example of the air conditioning apparatus 1 of a four-way ceiling cassette type, and has the air conditioning apparatus main body 2 and the decorative panel 3, and the inlet 4 is in the center of this decorative panel 3. An air outlet 5 is opened around the suction port 4 of the decorative panel 3. Four bolts 42 are set vertically downward from the building 40, and these four bolts 42 are respectively fixed to the hanging metal fittings 43 of the air conditioner main body 2.

In the air conditioner body 2, an electrical box having control devices such as a fan motor 6, an indoor fan 7 (turbo fan), a partition plate 8, a drain pump 12, a drain outlet 13, a refrigerant pipe 14, a drain pump control means, and the like. 15, a heat exchanger 16, and the like are disposed, and a drain pan 22 that receives drain water flowing down from the heat exchanger 16 is disposed below the heat exchanger 16.
The indoor fan 7 is arranged corresponding to the fan nozzle 17. The heat exchanger 16 is bent into a substantially rectangular shape and is disposed near the four air outlets 5 so as to surround the indoor fan 7. The partition plate 8 connects the tube plates 21 and 21 of the heat exchanger 16, and a drain pump 12, a drain discharge port 13, an indoor mechanical valve is provided in a space 20 outside the heat exchanger 16 partitioned by the partition plate 8. 18 etc. are accommodated. The partition plate 8 prevents air from the indoor fan 7 from leaking out during operation, and the presence of the partition plate 8 ensures that the heat exchanged air from the four outlets 5 is blown into the room R. It has become so.

FIG. 3 is a diagram of a drain pan.
In FIG. 3, a drain pan 22 is provided below the heat exchanger 16. At the bottom of the drain pan 22, a drain reservoir 22A that is lowered by one step is formed, and drain water that has flowed down to the drain pan 22 flows into the drain reservoir 22A. And the water level sensor 30 and the drain pump 12 as a water level detection means which detect the water level of drain water are arrange | positioned in 22 A of drain reservoirs. A drain pump drive means 23 such as a DC motor is connected to the drain pump 12. Further, a drain pump control means 24 that can control the start / stop and the rotation speed of the drain pump 12 is connected to the drain pump drive means 23. Is connected. The drain pump control means 24 operates the drain pump 12 based on the water level detected by the water level sensor 30.
Specifically, the water level sensor 30 includes a common electrode 31, and a lower limit detection electrode 32 and an upper limit detection electrode 33 that face the common electrode 31, and the drain pump control unit 24 determines that the drain water level is the upper limit detection electrode. The drain pump 12 is operated when it increases to the position 33, and the drain pump 12 is stopped when the water level drops below the lower end 32A of the lower limit detection electrode 32 (FIG. 5).
A voltage is applied between the common electrode 31 and the lower limit detection electrode 32 and the upper limit detection electrode 33. When there is drain water between the common electrode 31 and the lower limit detection electrode 32 or the upper limit detection electrode 33, Since a predetermined current (for example, 50 mA) flows through the water, the current is detected and it is determined that there is water. On the other hand, when the predetermined current does not flow, it is determined that there is no water.
In the present embodiment, the common electrode 31 extends to the vicinity of the bottom surface of the drain reservoir 22A, the lower limit detection electrode 32 extends to a height position substantially equal to the suction port 12A of the drain pump 12, and the upper limit detection electrode 33 performs heat exchange. It arrange | positions so that it may extend to the position lower than the bottom face 16A of the vessel 16. Thus, when the drain pump 12 is lowered to a position where it cannot be drained, the drain pump 12 is immediately stopped, and the drain pump 12 is prevented from idling and the water surface approaches the bottom surface 16A of the heat exchanger 16. By operating the drain pump 12, the heat exchanger 16 is prevented from being immersed in the drain water.

Further, the drain pump control means 24 includes an indoor fan operation stop detection means 26 (hereinafter simply referred to as fan operation detection means) for detecting whether or not the indoor fan 7 is operating, and a rotation speed for setting the rotation speed of the drain pump 12. Setting means 27.
During operation of the drain pump 12, when the rotation speed setting means 27 detects that the fan operation detection means 26 is operating the indoor fan 7, the rotation speed of the drain pump 12 is set to the maximum rotation speed. Then, after the fan operation detection means 26 detects the stop of the indoor fan 7, the minimum rotation speed that can be drained is output to the drain pump drive means 23. Then, the drain pump drive unit 23 operates the drain pump 12 at the rotation number output from the rotation number setting unit 27.

  Further, a drain hose 19 for draining drain water to the outside of the machine is connected to the drain outlet 13 of the drain pump 12. The drain hose 19 includes a rising portion 19A extending upward, and the drain water remaining in the rising portion 19A is returned to the drain pan 22 when the operation of the drain pump 12 is stopped. Yes. For this reason, since the return electrode causes the common electrode 31 and the lower limit detection electrode 32 of the water level sensor 30 to be immersed in the drain water even after the operation of the drain pump 12 is stopped, a current flows between the electrodes.

As described above, when the operation of the drain pump 12 is stopped, the drain water remaining in the rising portion 19A of the drain hose 19 is returned to the drain pan 22 by its own weight. However, the drain water on the drain pan 22 cannot be completely discharged, and the drain water is in the drain pan 22 after the cooling operation. When drain water is stored in the drain pan 22 for a long time, various bacteria in the drain water may grow and generate slime, which may clog the drain pump 12 or the drain hose 19.
In this embodiment, in order to prevent generation of slime, as shown in FIG. 3, the drain reservoir 22 </ b> A of the drain pan 22 has silver ions (as a predetermined metal ion species having an antibacterial action in the vicinity below the water level sensor 30. A silver (Ag) body 50 as a metal body containing (Ag ⁺ ) is disposed.
In general, when the silver body 50 is disposed in water, the surface of the silver body 50 is oxidized by oxygen molecules (O ₂ ) in the water to form silver ions, and the silver ions are diffused into the water. However, since silver is a metal with a relatively small tendency to ionize, simply placing it in water produces water containing silver ions at a concentration (for example, 50 ppm) sufficient to suppress slime generation in a short time. Is difficult. For this reason, by arranging in the lower vicinity of the water level sensor 30, a part of the current flowing between the electrodes of the water level sensor 30 flows into the silver body 50, and the oxidation reaction on the surface of the silver body 50 is promoted, and a large amount of Silver ions are diffused in water.
In particular, for example, during the time when the air conditioner 1 is stopped, such as at night, no new drain water is generated, so the drain pump 12 is not operated and the drain water is not discharged outside the apparatus. For this reason, since a part of the current flowing between the electrodes of the water level sensor 30 flows into the silver body 50 during this stop, a large amount of silver ions are eluted from the silver body 50 into the drain water. Water containing silver ions at a concentration sufficient to suppress the generation of water is generated.

Next, the arrangement configuration of the silver body 50 will be described.
When the common electrode 31 and the lower limit detection electrode 32 are immersed in drain water, a current flows along the current flow line 61 from the lower limit detection electrode 32 to the common electrode 31 as indicated by a broken line in FIG. In FIG. 4, reference numeral 62 is an equipotential line provided around the common electrode 31 and the lower limit detection electrode 32.
The amount of silver body 50 oxidized and silver ionized depends on the amount of current flowing through the silver body 50. For this reason, from the viewpoint of promoting a larger amount of silver ionization, the silver body 50 may be disposed at a position A where the density of the current stream lines 61 is high (for example, between the common electrode 31 and the lower limit detection electrode 32). desirable. On the other hand, the water level sensor 30 originally detects the water level of the drain water, and disposing the silver body 50 between the common electrode 31 and the lower limit detection electrode 32 hinders the function of detecting the water level. Must be avoided.
Therefore, in the present embodiment, as shown in FIG. 5, the silver body 50 is disposed between the common electrode 31 and the lower limit detection electrode 32 and in the vicinity below the common electrode 31 and the lower limit detection electrode 32. . Here, since the common electrode 31 and the lower limit detection electrode 32 are immersed in the drain water by the return water even after the operation of the drain pump 12 is stopped, the contact time with the drain water is long and the drain electrode 12 is in contact with the drain water. In the meantime, current flows between the electrodes via the drain water. Therefore, by arranging the silver body 50 between the common electrode 31 and the lower limit detection electrode 32 and in the vicinity of the lower side of the common electrode 31 and the lower limit detection electrode 32, the common electrode 31 and the lower limit detection electrode 32 are arranged. Since part of the current flowing between them flows into the silver body 50 for a long time, silver ionization can be promoted. In addition, when the water level of the drain water is lower than the lower end 32A of the lower limit detection electrode 32, current does not flow between the electrodes and the silver body 50, so silver ionization of the silver body 50 stops. According to this, when there is no water on the drain pan 22, since silver ionization is suppressed, the lifetime of the silver body 50 can be expected to be extended.

Further, the silver body 50 has a drain reservoir 22A such that the distance r1 from the lower limit detection electrode 32 to the silver body 50 is substantially the same as the distance r2 from the lower limit detection electrode 32 to the common electrode 31. It arrange | positions on the base 51 arrange | positioned at the bottom face. The pedestal 51 is provided with a recess 51A into which the silver body 50 is fitted so that the silver body 50 does not move due to the flow of drain water.
As a result, the distance from the lower limit detection electrode 32 to the silver body 50 or the common electrode 31 can be kept substantially uniform, so that a current can flow from the lower limit detection electrode 32 to the silver body 50 and the common electrode 31 substantially evenly. In addition to generating silver ions having an antibacterial action, the drain pump 12 can be operated normally.
In addition, the silver body 50 is more likely to undergo an oxidation reaction and easily become silver ionized as the contact area with water increases. For this reason, in this embodiment, it is desirable to form the silver body 50 by rolling the silver thread into a cotton shape in order to increase the contact area.

Next, the reaction mechanism generated by silver ion water will be described.
FIG. 6 is a schematic diagram for explaining the reaction between the electrode and the silver body.
When the silver body 50 is disposed between the common electrode 31 and the lower limit detection electrode 32, the surface of the silver body 50 is polarized into the anode part 50A and the cathode part 50B by the current flowing from the lower limit detection electrode 32 to the common electrode 31. To do.
Then, reaction (1) occurs in the anode portion 50A of the silver body 50, reaction (2) occurs in the cathode portion 50B, and silver ions are eluted from the anode portion 50A of the silver body 50 into the drain water.
(1) 2Ag → 2Ag ⁺ + 2e ⁻
(2) 1 / 2O ₂ + H ₂ O + 2e ⁻ → 2OH ⁻
2H ^{+ +} 2e ^- → H ₂
Thus, in the anode part 50A of the silver body 50, since the silver body 50 is silver-ionized and this silver ion is diffused into the drain water, slime is prevented from being generated on the drain water and the drain pan 22.

Next, the operation of the drain pump control means 24 will be described.
When the cooling operation of the air conditioner 1 is started, the compressor and the indoor fan 7 start the operation. When the indoor fan 7 starts operation, the fan operation detection means 26 of the drain pump control means 24 detects that the indoor fan 7 is in operation, and the rotation speed setting means 27 sets the drain pump 12 to the maximum rotation speed. To do.
The drain pump control means 24 controls the operation of the drain pump 12 based on the detection result of the water level sensor 30. That is, when the water level of the drain water rises to the position of the upper limit detection electrode 33, the drain pump control means 24 operates the drain pump 12 so that the drain pump drive means 23 reaches the maximum rotational speed. When the drain pump 12 is operated, the drain water accumulated in the drain pan 22 is pumped up and drained outside the machine via the drain hose 19.

In addition, when the cooling operation is stopped during the operation of the drain pump 12 and the compressor and the indoor fan 7 stop the operation, the fan operation detection unit 26 detects the stop of the operation of the indoor fan 7. When the indoor fan 7 is stopped, the rotation speed setting means 27 sets the rotation speed of the drain pump drive means 23 to the minimum rotation speed that can be drained, and the drain pump drive means 23 operates the drain pump 12 at this rotation speed. . In this way, by operating the drain pump 12 at the minimum number of revolutions that can be drained, noise such as the water pumping noise of the drain pump 12 is minimized, and the heat exchanger 16 and the like after the compressor and the indoor fan 7 are stopped. The drain water that adheres to and flows down and accumulates in the drain pan 22 is drained.
On the other hand, when the water level of the drain water is lowered to the position of the lower limit detection electrode 32, the drain pump 12 cannot drain, so the drain pump control means 24 stops the drain pump drive means 23 and operates the drain pump 12. To stop.

During this stop, drain water is stored on the drain pan 22, so that a part of the current flowing between the electrodes of the water level sensor 30 flows to the silver body 50, so that a large amount of silver ions from the silver body 50. Elutes in drain water. Thereby, water containing silver ions at a concentration sufficient to suppress the generation of slime is generated.
In this case, the concentration of silver ions is high around the silver body 50 and decreases as the distance from the silver body 50 increases. For this reason, it is desirable to aim at uniform silver ion concentration by moving drain water regularly.
Specifically, the drain pump control means 24 is not related to the detection result of the water level sensor 30 when the air conditioner 1 is stopped and corresponds to a midnight time zone (for example, 0:00 to 5:00). The drain pump 12 is operated and the drain water on the drain pan 22 is pumped up.
In this case, the drained water is not discharged beyond the rising portion 19 </ b> A of the drain hose 19, and the water is returned to the drain pan 22 again when the drain pump 12 is stopped. For this reason, the drain water is stirred by the return water, so that the silver ions are evenly diffused on the drain pan 22. In this embodiment, the drain pump control means 24, the drain pump drive means 23, and the drain pump 12 function as a diffusion means.

As described above, according to the present embodiment, the heat exchanger 16, the drain pan 22 that receives the drain water flowing down from the heat exchanger 16, and the drain that pumps up and drains the drain water accumulated in the drain pan 22. A water level sensor 30 of an electrode type for controlling the operation of the drain pump 12, and a silver body 50 containing silver ions having an antibacterial action is disposed in the vicinity of the electrode of the water level sensor 30. A part of the current flowing between the electrodes through the drain water flows between the electrode and the silver body 50, so that elution of silver ions into the drain water is promoted, and the silver ions are diffused into the drain water. The For this reason, with a simple configuration in which the silver body 50 is disposed in the vicinity of the electrode of the water level sensor 30, it is possible to suppress the propagation of various bacteria in the drain water, and to permanently suppress the generation of slime in the drain water or the drain pan 22. be able to. Further, drain water having an antibacterial action is discharged by the operation of the drain pump 12, and the generation of slime in the drain hose 19 can be permanently suppressed by passing the drain water through the drain hose 19. As a result, maintenance-free operation of the drain pan 22 is achieved.
Therefore, in the air conditioning apparatus of the present embodiment, not only reducing troubles in the drainage system and facilitating maintenance, but also purifying the inside of the air conditioning equipment, it contributes to more comfortable air conditioning, It is effective when installed in buildings where many unspecified people gather, such as schools, hospitals, and convenience stores.

  In the present embodiment, the common electrode 31 and the lower limit detection electrode 32 are in contact with the drain water for a long time, and while the drain electrode is in contact with the drain water, a current is passed between the electrodes via the drain water. Flowing. For this reason, by disposing the silver body 50 below the common electrode 31 and the lower limit detection electrode 32, a part of the current flowing between the common electrode 31 and the lower limit detection electrode 32 flows to the silver body 50 for a long time. Therefore, it is possible to promote silver ionization.

  Further, according to the present embodiment, the silver body 50 has a position where the distance r1 between the silver body 50 and the lower limit detection electrode 32 is substantially the same distance as the distance r2 between the lower limit detection electrode 32 and the common electrode 31. Therefore, it is possible to flow current from the lower limit detection electrode 32 to the silver body 50 and the common electrode 31 substantially uniformly, to generate silver ions having antibacterial action, and to operate the drain pump 12 normally. Is possible.

Although one embodiment of the present invention has been described above, the present invention is not limited to this. For example, in the present embodiment, the silver body 50 is disposed as the metal body, but a copper (Cu) body or a zinc (Zn) body may be disposed as long as it has an antibacterial action. Here, it is known that silver ions have an antibacterial action about 40 times that of copper ions (Cu ²⁺ ) and about 10000 times that of zinc ions (Zn ²⁺ ). For this reason, the structure which provides a silver body is more effective.
In the present embodiment, the water level detection by the water level sensor 30 is always performed. However, the water level detection may be performed every predetermined time. According to this configuration, the elution amount of silver ions can be controlled while detecting the water level, and the life of the silver body 50 can be extended.
In the present embodiment, the configuration in which the silver body 50 is arranged at a position between the common electrode 31 and the lower limit detection electrode 32, that is, at the position A where the density of the current flow lines 61 is high has been described. The silver body 50 may be arranged anywhere as long as it is within the range of the line 61.

It is sectional drawing which shows one Embodiment of the air conditioning apparatus of this invention. It is a bottom view similarly. It is a block diagram which shows the apparatus arrangement | positioning on a drain pan. It is a figure which shows the streamline of the electric current between electrodes. It is a block diagram which shows the arrangement | positioning relationship between the electrode of a water level sensor, and a silver body. It is a schematic diagram for demonstrating reaction with an electrode and a silver body.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Air conditioning apparatus 12 Drain pump 12A Suction port 13 Drain drain port 16 Heat exchanger 19 Drain hose 19A Startup part 22 Drain pan 24 Drain pump control means 30 Water level sensor 31 Common electrode 32 Lower limit detection electrode 33 Upper limit detection electrode 42 Bolt 43 Metal fittings 50 Silver body (metal body)
51 Pedestal 51A Concave part r1 distance r2 distance

Claims (4)

In an air conditioner including a heat exchanger, a drain pan that receives drain water flowing down from the heat exchanger, and a drain pump that pumps up and drains the drain water accumulated in the drain pan.
An electrode type water level sensor for controlling the operation of the drain pump;
A metal body containing a predetermined metal ion species having an antibacterial action is disposed in the vicinity of the electrode of the water level sensor, and a part of the current flowing between the electrodes through the drain water is reduced between the electrode and the metal body. The air conditioner is characterized in that the metal ion species are eluted in the drain water.   The water level sensor includes a common electrode, a lower limit detection electrode and an upper limit lower limit electrode arranged to face the common electrode, and the metal body is disposed below the common electrode and the lower limit detection electrode. The air conditioning apparatus according to claim 1.   The metal body is disposed at a position where a distance between the metal body and the lower limit detection electrode is substantially the same as a distance between the lower limit detection electrode and the common electrode. The air conditioning apparatus described.   The air conditioner according to any one of claims 1 to 3, wherein the metal body elutes silver ions, zinc ions, or body ions as the predetermined metal ion species.

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