JP2005249367A - Air-conditioner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an air-conditioner having improved gas removing efficiency and humidifying performance to reduce the size of equipment, save energy, and require lower initial cost. <P>SOLUTION: A first heating coil, a cooling coil part and a second heating coil are arranged in a chamber having a suction port and a feed port. The cooling coil part consists of an upstream side cooling coil, a downstream side cooling coil, a first vaporizing humidifier material arranged on the upstream side of the upstream side cooling coil, and a second vaporizing humidifier material arranged on the downstream side of the downstream side cooling coil. A water tank is arranged at the lower part of the cooling coil part for supplying pure water from the upper part of the second vaporizing humidifier material and for circulating and supplying dropping water from the upper part into the upstream side cooling coil, the downstream side cooling coil and the first vaporizing humidifier material. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an air conditioner used to adjust the temperature and humidity of air to be treated and remove various molecular contaminants, and in particular, to improve gas removal efficiency, improve humidification capacity, and reduce the size of equipment. The present invention relates to an air conditioner in which the configuration of the cooling coil portion is improved in order to realize a reduction in energy and energy.

  In recent years, clean rooms for electronic industries such as semiconductor manufacturing have been required to control indoor humidification and various molecular contaminants (hereinafter referred to as AMC) and install chemical filters. Various measures have been implemented. In addition, it is required to maintain the humidity of the year constant, and humidification in winter is particularly important, and in general, precise humidification with steam has been adopted.

As one of the AMC measures as described above, water-soluble AMC (for example, NH ₃ ) such as acid gas and basic gas contained in the outside air introduced into the clean room is removed, which is represented by a washer method. There is known a wet removal system (see Patent Document 1). However, in the washer method as described above, it is necessary to increase the gas-liquid contact area in order to improve the AMC removal capability. For this purpose, it is required to increase the amount of spray water or to reduce the spray droplets, and problems such as an increase in pump power for the washer and an increase in pressure loss on the air side have been problems.

Therefore, as a method of removing AMC contained in the outside air, the present applicant installs a plurality of wet wall units and sequentially supplies the waste water from the wet wall units on the downstream side to the wet wall units on the upstream side of the air. Thus, a wet removal system having a pseudo counter flow was proposed (see Patent Document 2). This wet removal system has a large gas-liquid contact area as compared with the washer method described above, and can effectively use a very small amount of pure water to achieve high removal performance and stability. At the same time, it had sufficient performance as a vaporizing humidifier.
JP 2001-96123 A JP 2000-317248 A

  However, in the wet removal system as described above, during cooling and dehumidification in the summer, the surface of the cooling coil fin becomes a wet wall due to condensation (dehumidification) water by cooling, and AMC is absorbed by this condensation water. AMC removal rate increases. On the other hand, at the time of maximum humidification other than during dehumidification, for example, at the time of maximum humidification in winter, the cooling coil fin surface is not a wet wall, and there is a problem that the removal rate varies depending on the season, such that the AMC removal rate is lower than in summer. It was.

  In addition, the washer-type wet removal system as described above requires a space for the water spray section, and the wet-type removal system using the vaporizing humidifier material as a wet wall installs the vaporizing humidifier. Since a space (both of which is about 1000 to 1500 mm) is required, the system is increased in size and cost.

  The present invention has been proposed in order to solve the above-mentioned problems of the prior art, and its purpose is to improve gas removal efficiency, improve humidification capacity, downsize equipment and save energy, The object is to provide an air conditioner that can reduce the initial cost.

  The air conditioner according to claim 1 is an air conditioner in which a first heating coil, a cooling coil section, and a second heating coil are arranged in a chamber having an air inlet and an air inlet. The cooling coil section includes a cooling coil, a first vaporizing humidifier material disposed in contact with the upstream side thereof, and a second vaporizing type disposed in contact with the downstream side thereof. It is comprised from the humidifier raw material, A water tank is arrange | positioned under the said cooling coil part, It is comprised so that dripping water may be circulated and supplied to the said cooling coil from the upper direction.

  An air conditioner according to claim 2 is a modification of the invention according to claim 1, wherein a first heating coil, a cooling coil section, and a cooling coil section are provided in a chamber having an air inlet and an air inlet. , An air conditioner comprising a second heating coil, wherein the cooling coil portion is disposed in contact with the cooling coil and the upstream side thereof, and a first vaporizing humidifier material, A second evaporative humidifier material disposed in contact with the downstream side thereof, a water tank is disposed below the cooling coil portion, the cooling coil, the first evaporative humidifier material, and The second vaporizing humidifier material is configured such that dripping water is circulated and supplied from above them.

  An air conditioner according to claim 3 is a modification of the invention according to claim 1, wherein a first heating coil, a cooling coil section, and a cooling coil section are provided in a chamber having an air inlet and an air inlet. , An air conditioner comprising a second heating coil, wherein the cooling coil portion is disposed in contact with the cooling coil and the upstream side thereof, and a first vaporizing humidifier material, A second evaporative humidifier material disposed in contact with the downstream side thereof, a water tank is disposed below the cooling coil portion, and a pure water from above the second evaporative humidifier material. While supplying water, it is comprised so that dripping water may be circulated and supplied from the upper direction to the said cooling coil and a 1st vaporization type humidifier raw material.

  In the invention according to claims 1 to 3 having the above-described configuration, the cooling coil section is a first vaporization type arranged in contact with the cooling coil having a single-stage configuration and the upstream side thereof. By comprising the humidifier material and the second vaporization type humidifier material arranged in contact with the downstream side of the humidifier material, a water spray part and a vaporization that require a large space, which was necessary in the conventional method, Since an air humidifier can be eliminated, the air conditioner can be greatly reduced in size.

  In addition, by disposing the first vaporizing humidifier material in contact with the upstream side of the cooling coil, it is possible to prevent drying of the coil fins at the time of maximum humidification in winter and to improve the humidification saturation efficiency. Can do. Furthermore, by disposing the second vaporizing humidifier material in contact with the downstream side of the cooling coil, it is possible to prevent water droplets from being scattered from the cooling coil, and to improve the humidification saturation efficiency and chemical removal efficiency. In addition, the makeup water can be reduced by supplying pure water directly.

  The air conditioner according to claim 4 is an air conditioner in which a first heating coil, a cooling coil section, and a second heating coil are arranged in a chamber having an intake port and an air supply port. The cooling coil section has a two-stage configuration of an upstream side cooling coil disposed on the upstream side with respect to the flow of the processing air and a downstream side cooling coil, and on the upstream side of the upstream side cooling coil, The first vaporizing type humidifier material is installed in contact with the downstream cooling coil, and the second vaporizing type humidifier material is installed in contact with the downstream side of the downstream cooling coil. A water tank is disposed in the lower part of the gas tank, and pure water is supplied from above the second vaporization type humidifier material, and the upstream side cooling coil, the downstream side cooling coil, and the first vaporization type humidifier material are Further, it is characterized in that the dropped water is circulated and supplied from above.

  In the invention according to claim 4 having the above-described configuration, the upstream side cooling coil, the downstream side cooling coil, the first vaporizing humidifier material disposed on the upstream side of the upstream side cooling coil, and the downstream side By configuring the cooling coil portion with the second vaporizing humidifier material disposed on the downstream side of the side cooling coil, the water spraying portion and vaporizing humidifier that are necessary in the conventional method can be eliminated. Therefore, the air conditioner can be greatly reduced in size.

  In addition, by arranging the first vaporizing humidifier material in contact with the upstream side cooling coil, it is possible to prevent drying of the coil fins at the time of maximum humidification in winter and to improve the humidification saturation efficiency. it can. Further, by disposing the second vaporizing humidifier material in contact with the downstream side cooling coil, the efficiency of chemical removal can be increased and the makeup water can be reduced.

  The air conditioner according to claim 5 is the air conditioner according to claim 4, wherein the water tank is a first water tank located in a lower part of the first vaporizing humidifier material, and a lower part of the upstream cooling coil. Is divided into a second water tank located at the bottom and a third water tank located below the downstream cooling coil and the second vaporizing humidifier material, and the first water tank is located between the first water tank and the second water tank. The communication hole is formed, and the second communication hole is formed between the second water tank and the third water tank.

  In invention of Claim 5 which has the above structures, the dripping water supplied to an upstream cooling coil, a downstream cooling coil, and a 1st vaporization type humidifier raw material can be circulated efficiently. .

According to a sixth aspect of the present invention, in the air conditioner according to the fourth or fifth aspect, the cooling water supplied to the upstream side cooling coil and the downstream side cooling coil is opposite to the flow of the processing air. Thus, it is configured to flow from the downstream side cooling coil to the upstream side cooling coil.
In the invention according to claim 6 having the above-described configuration, the cooling water supplied to the cooling coil can be configured to be opposed to the flow of the processing air. The heat exchange efficiency can be maintained higher than that of the configuration described in Item 5.

  According to a seventh aspect of the present invention, in the air conditioner according to the sixth aspect, an amount of cooling water supplied to the downstream side cooling coil and a heating adjustment by the first heating coil are provided at an outlet of the air supply port. The dew point sensor is configured to be controlled based on the detected value.

  Further, the invention according to claim 8 is the air conditioner according to claim 6 or 7, wherein the amount of cooling water supplied to the downstream side cooling coil and the heating adjustment by the second heating coil are adjusted. It is configured to be controlled based on a detection value of a dry bulb temperature sensor provided at the outlet of the air mouth.

  In the invention according to claim 7 and claim 8 having the above-described configuration, appropriate temperature and humidity adjustment is performed based on a detection value of a dew point sensor or a dry bulb temperature sensor provided at the outlet of the air supply port. Can be implemented.

According to a ninth aspect of the present invention, in the air conditioner according to any one of the first to eighth aspects, a vaporizing humidifier material formed in a flat plate shape is disposed on the upper surface of the cooling coil. It is characterized by being.
In invention of Claim 9 which has the above structures, the dripping water supplied from the upper direction of a cooling coil can be supplied to the whole cooling coil uniformly and smoothly.

A tenth aspect of the present invention is the air conditioner according to any one of the first to ninth aspects, wherein the cooling coil is subjected to a hydrophilic treatment.
In the invention according to claim 10 having the above-described configuration, the cooling coil fin surface can be made uniformly wetted.

  According to the air conditioner of the present invention, it is possible to provide an air conditioner that can improve the gas removal efficiency, improve the humidifying capacity, reduce the size and energy of the device, and further reduce the initial cost.

  Hereinafter, an example of an embodiment (hereinafter referred to as an embodiment) according to an air conditioner of the present invention will be specifically described with reference to the drawings.

(1) Configuration (1-1) Overall Configuration FIG. 1 is a schematic diagram showing a configuration of an air conditioner according to the present invention. That is, inside the housing (not shown) of the air conditioner of this embodiment, from the air intake side, the pre-filter 1, the medium performance filter 2, the first heating coil 3, the upstream cooling coil 41, and the downstream cooling. A cooling coil unit 4 including a coil 42, a second heating coil 5, and a blower 6 for discharging the processing air to the outside of the housing are sequentially arranged. The detailed configuration of the cooling coil unit 4 will be described later.

  Further, a DP (dew point sensor) 7 and a DB (dry bulb temperature sensor) 8 are provided in the vicinity of the outlet of the processing air. And based on the detected value of DP7, the first control device 10 performs heating adjustment for controlling the humidification amount by the first heating coil 3, or cooling dehumidification adjustment by the cooling coil, and Based on the detected value of DB8, the second control device 11 is configured to perform heating adjustment by the second heating coil 5 or cooling adjustment by the cooling coil.

(1-2) Configuration of Cooling Coil Unit Subsequently, the configuration of the cooling coil unit 4 which is a characteristic member of the present invention will be described in detail. That is, as shown in FIGS. 1 and 2, the cooling coil unit 4 includes a two-stage configuration of an upstream side cooling coil 41 and a downstream side cooling coil 42 disposed on the upstream side with respect to the flow of processing air. Has been. The cooling water supplied to these cooling coils is configured to flow from the downstream cooling coil 42 to the upstream cooling coil 41 so as to be opposed to the air flow. And the 1st vaporization type humidifier raw material 43 is installed in contact with the upstream side (left side in the figure) of the upstream cooling coil 41, and the downstream side (in the figure) of the downstream cooling coil 42. , On the right side), the second vaporizing humidifier material 44 is placed in contact therewith.

  A water tank 9 is disposed below the cooling coil unit 4, and the inside of the water tank 9 includes the first water tank 91 located below the first vaporizing humidifier material 43 and the upstream side cooling. It is divided into a second water tank 92 located below the coil 41 and a third water tank 93 located below the downstream side cooling coil 42 and the second vaporizing humidifier material 44. And between the 1st water tank 91 and the 2nd water tank 92, the 1st communicating hole 94 is provided, and between the 2nd water tank 92 and the 3rd water tank 93, it is 2nd. The communication hole 95 is provided.

  Further, a pure water supply line 21 is provided above the second vaporization type humidifier material 44 so that makeup water (pure water) can be supplied to the second vaporization type humidifier material 44. Yes. In addition, a first dropped water supply line 22 is provided above the downstream cooling coil 42 from the third water tank 93, and above the upstream cooling coil 41 from the second water tank 92. The 2nd dripping water supply line 23 is provided. And by each dripping water supply line 22 and 23, dripping water is circulated and supplied to each of the downstream side cooling coil 42 and the upstream side cooling coil 41, and it is comprised so that both cooling coils can be used as a wetting wall. .

  Further, the second dripping water supply line 23 is provided with a branch line 24 so that dripping water can be supplied to the first vaporizing humidifier material 43. Further, the first water tank 91 is provided with a drain line 25 so that the water level in the first water tank 91 can be kept constant.

  In addition, vaporization type humidifier materials 45 and 46 formed in a flat plate shape are disposed on the upper surfaces of the upstream side cooling coil 41 and the downstream side cooling coil 42, and dripping water supplied to the upper part of the coil fins is supplied to the coil. It is comprised so that it can supply uniformly to the whole fin.

  Further, the upstream side cooling coil 41 and the downstream side cooling coil 42 are subjected to hydrophilic treatment. As a method for this hydrophilic treatment, a known hydrophilic paint is applied, or after manufacturing a cooling coil, a coil fin portion having a large surface area is immersed in a corrosive solution (etching solution) for a certain period of time, washed and then dried. The method can be used.

  Further, a cooling water supply line 26 connected to a cooling water supply device (not shown) such as a refrigerator is connected to the downstream cooling coil 42 so that the cooling water is supplied from the downstream side of the air. It is configured. And the cooling water discharged | emitted from the air side upstream part of the downstream side cooling coil 42 is introduce | transduced in the upstream side cooling coil 41 from the air side downstream part of the upstream side cooling coil 41, is discharged | emitted from the air side upstream part, It is configured to be sent again to the refrigerator or the like via the cooling water discharge line 27. The cooling water supply line 26 is provided with a flow rate adjusting valve 28 so that the flow rate of the cooling water supplied to the downstream side cooling coil 42 can be adjusted.

  In addition, in order to remove various molecular contaminants (AMC), it is necessary to maintain a certain level of cleanliness (= purity) on the side that absorbs this (in this embodiment, dripping water), It is necessary to continue to supply pure water as appropriate. The amount of pure water to be supplied is determined by measuring pH or conductivity or both in the middle of the first water tank 91 or the drainage line, and based on the measured value, a valve (see FIG. It is preferable to control the supply amount of pure water by adjusting the opening degree (not shown).

  In addition, for example, a method of determining the amount of makeup water for each period according to the required amount of humidification, such as L / G = 0.01 for the dehumidification period and L / G = 0.02 for the humidification period. May be used. In this case, the opening degree of a valve (not shown) provided in the pure water supply line 21 can be manually set at each time, so that the configuration becomes simple.

  In addition, as a vaporization type humidifier raw material used by this invention, the material which has a porosity of 40% or more, for example, the vaporization type humidifier raw material by Wet Master Co., Ltd. can be used.

(2) Operation The operation of the air conditioner of the present embodiment having the above configuration is shown in FIG. 3 (summer season) and FIG. 4 (winter season) with the indoor temperature and humidity set at 23 ° C. and 45%. With reference to the air diagram, description will be given separately for cooling dehumidification (mainly in summer) and heating and humidification (mainly in winter). In addition, Aw-Fw-Gw and As-Fs-Gs shown in FIG.3 and FIG.4 respond | correspond to the state of the air in the position of AG shown in FIG. 1, w shows winter season and s shows summer season. ing. Specific values such as temperature and humidity are examples, and the present invention is not limited to these numerical values. Further, the temperature rise by the fan and the relative humidity drop caused by this are not considered here for the sake of easy understanding.

(2-1) Summer season: during cooling and dehumidification (see Fig. 3)
When cooling and dehumidification of air is necessary in summer or the like, humidification is performed in the first vaporization type humidifier material 43 and the second vaporization type humidifier material 44, and the upstream side cooling coil 41 and the downstream side cooling coil. The required amount of cooling and dehumidification is performed by 42. At this time, moisture in the air is taken into the water tank.

  That is, the blower 6 is operated, and the flow rate adjustment valve 28 of the cooling water supply line 26 that supplies the cooling water to the downstream side cooling coil 42 is opened. Then, outside air (34 ° C., 60% RH) flows from the air intake port of the housing. After the dust is removed through the filters 1 and 2, the inflowing air is humidified in the first vaporizing humidifier material 43 (As to Cs) and cooled by the upstream cooling coil 41 (Cs To Ds), and further cooled by the downstream cooling coil 42 (Ds to Es). Subsequently, the second vaporizing humidifier material 44 is humidified (Es to Fs), heated by the second heating coil 5 (Fs to Gs), and supplied indoors.

  In this case, via the second communication hole 95 provided in the water tank 9, [pure water supply amount + dehumidification amount by downstream cooling coil (Ds → Es) −humidification amount by the second vaporization type humidifier material ( Es → Fs)] moves from the third water tank 93 to the second water tank 92. In addition, via the first communication hole 94, [amount of dripped water to the first vaporization type humidifier material−humidification amount by the first vaporization type humidifier material (As → Cs) −from the first water tank 91 The amount of discharged water] moves from the first water tank 91 to the second water tank 92. Furthermore, from the drainage line 25 provided in the first water tank 91, [pure water supply amount + dehumidification amount (difference between outside air and moisture content at the air conditioner outlet) (difference between As and Fs)] is discharged. Is done.

(2-2) Winter… Warming and humidification (see Fig. 4)
On the other hand, when heating and humidification of air is required as in winter, the first vaporizing humidifier material 43, the upstream cooling coil 41, the downstream cooling coil 42, and the second vaporizing humidifier material 44 All are humidified. At this time, moisture evaporates from each unit. In addition, since cooling and dehumidification are unnecessary in winter, supply of the cooling water into the cooling coil is stopped by closing the valve 28.

  That is, the blower 6 is operated and the valve 29 of the first heating coil 3 is opened. Then, outside air flows from the air intake port of the housing (−2 ° C., 30% RH). The inflowing air is heated by the first heating coil 3 (28.6 ° C.) after dust is removed through the filters 1 and 2. As a result, the dry bulb temperature changes as shown by the solid line connecting Aw and Bw in FIG.

  The air heated by the first heating coil 3 is introduced into the cooling coil unit 4 and is humidified by the first vaporizing humidifier material 43. At this time, since vaporization-type humidification is accompanied by a temperature decrease, the dry bulb temperature and the relative humidity change (Bw to Cw) as shown by the solid line connecting Bw and Cw in FIG.

  Subsequently, since the coil fin surface is wetted by the water dripped from the upper part to the upstream side cooling coil 41, it is humidified (Cw to Dw) and further humidified by the downstream side cooling coil 42 (Dw). ~ Ew). Then, it is humidified by the 2nd vaporization type humidifier raw material 44 (Ew-Fw), is heated by the 2nd heating coil 5 (Fw-Gw, 14 degreeC), and is supplied indoors.

  In this case, through the second communication hole 95 provided in the water tank 9, the [pure water supply amount−the amount of humidification by the downstream cooling coil and the second vaporizing humidifier material (Dw → Ew → Fw)] Water moves from the third water tank 93 to the second water tank 92. In addition, through the first communication hole 94, [amount of dripped water to the first vaporizing humidifier material−first vaporizing humidifier material (Bw → Cw) −amount of drainage from the first water tank 91] Water moves from the first water tank 91 to the second water tank 92. Furthermore, from the drainage line 25 provided in the first water tank 91, [pure water supply amount−humidification amount (difference between outside air and water content at air conditioner outlet) (difference between Aw and Fw)] is discharged. Is done.

(3) Effect As described above, in the air conditioner of the present embodiment, the cooling coil unit 4 has a two-stage configuration of the upstream side cooling coil 41 and the downstream side cooling coil 42, and further on the upstream side of the upstream side cooling coil 41. Since the first vaporization type humidifier material 43 is installed and the second vaporization type humidifier material 44 is installed on the downstream side of the downstream side cooling coil 42, the length of the cooling coil unit 4 is the length of the conventional cooling coil. It is longer than that (for example, it is longer by about 180 mm).

  However, since the cooling coil unit 4 of the present embodiment is configured by integrating the vaporizing humidifier material with the cooling coil, it is installed in a conventional wet removal system as shown in Patent Document 1 and Patent Document 2. In addition, an installation space for a water spray unit or a vaporizing humidifier is not required (for example, approximately 1000 to 1500 mm is not required). As a result, the air conditioner can be significantly downsized (for example, downsized by about 820 to 1320 mm).

  Further, by disposing the first vaporizing humidifier material 43 in contact with the upstream side cooling coil 41, it is possible to prevent drying of the coil fins at the time of maximum humidification in winter and to increase the humidification saturation efficiency. be able to.

  Furthermore, by arranging the second vaporizing humidifier material 44 in contact with the downstream cooling coil 42, the efficiency of chemical removal can be increased, and not only the makeup water can be reduced, but also cooling. In contrast to the problem that moisture is likely to scatter due to the narrow spacing between the coil fins, it also has the effect of preventing the water droplets from splashing downstream, thus increasing the amount of water dripping onto the coil surface and increasing the wind speed. It becomes possible.

  In addition, since the cooling coil has a two-stage configuration, even if the dripping water is circulated and dripped from the top to remove AMC, the counter flow of the cooling water and air can be maintained to some extent, so the heat exchange efficiency is high. Can be maintained at a level.

  Moreover, in the air conditioner of this embodiment, since all the cooling coil parts 4 become wet surfaces, the wet surface coefficient increases. As a result, the heat transfer coefficient on the surface of the cooling coil during cooling is increased, and the heat exchange performance is improved. On the other hand, in the conventional method, the air upstream side of the cooling coil is not a wet surface, so there are locations without a wet surface and locations with a wet surface, and the wet surface coefficient of the cooling coil is reduced. I had to.

Also, in the conventional washer method, when water having a water temperature equal to the wet bulb temperature of the inlet air is sprayed in a completely insulated space (= adiabatic humidification), the change on the air diagram is a line with a constant wet bulb temperature. Become. In other words, it is a change in isoenthalpy.
On the other hand, in the present embodiment, the first evaporative humidifier material 43 located on the most upstream side of the cooling coil unit 4 is configured such that cold water lower than the wet bulb temperature of the inlet air is dropped. Has been. Since the enthalpy of this cold water is lower than the enthalpy of the inlet air, the enthalpy of the outlet air is lowered, and energy can be saved by this enthalpy difference (see FIG. 3).

(4) Other Embodiments The present invention is not limited to the embodiment as described above, and the cooling coil constituting the cooling coil unit 4 may have a single-stage configuration. The first vaporizing humidifier material 43 and the second vaporizing humidifier material 44 are provided in contact with the upstream side and the downstream side (in other words, both sides of the cooling coil).

  Moreover, as shown in FIG. 5, you may comprise so that dripping water may be circulated and supplied from the water tank 9 provided in the lower part of the cooling coil part 4 to the upper surface of the cooling coil 50 of a 1 step | paragraph structure. In this case, since the cooling coil 50 has been subjected to hydrophilic treatment, dripped water penetrates into the first vaporizing humidifier material 43 and the second vaporizing humidifier material 44 from the cooling coil 50 having high hydrophilicity. To go.

  Moreover, as shown in FIG. 6, from the water tank 9 provided in the lower part of the cooling coil part 4, the cooling coil 50 of 1 step | paragraph structure, the 1st vaporization type humidifier material 43, and the 2nd vaporization type humidifier material You may comprise so that dripping water may be circulated and supplied to the upper surface of 44. FIG. In addition, in the modification shown in FIG.5 and FIG.6, the pure water replenished to the 2nd vaporization type humidifier raw material 44 and the dripping water circulated and supplied from the water tank 9 are not restricted to pure water, Or normal water can be used. good.

  Further, as shown in FIG. 7, a pure water supply line 21 is provided above the second vaporization type humidifier material 44 so that makeup water (pure water) can be supplied to the second vaporization type humidifier material 44. In addition, the water tank 9 provided in the lower part of the cooling coil unit 4 is configured to circulate and supply the dropped water to the upper surface of the cooling coil 50 and the first vaporizing humidifier material 43 having a one-stage configuration. Also good.

  In addition, the cooling coil may have three or more stages of the upstream side, the middle stream, and the downstream side. In this way, when the cooling coil has a plurality of stages, the cooling water introduced into the cooling coil does not necessarily have to adopt a method of flowing sequentially from the downstream side to the upstream side, and from each flow rate adjustment valve of the cooling water system, You may comprise so that it may supply in parallel with the cooling coil of a stage.

It is a schematic diagram which shows the whole structure of the air conditioner which concerns on this invention. It is a schematic diagram which shows the detailed structure of a cooling coil part. It is an air line figure explaining the effect | action in the summer of the air conditioner which concerns on this invention. It is an air line figure explaining the effect | action in the winter of the air conditioner which concerns on this invention. It is a schematic diagram which shows other embodiment of a cooling coil part. It is a schematic diagram which shows other embodiment of a cooling coil part. It is a schematic diagram which shows other embodiment of a cooling coil part.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Pre filter 2 ... Medium performance filter 3 ... 1st heating coil 4 ... Cooling coil part 5 ... 2nd heating coil 6 ... Blower 7 ... Dew point sensor 8 ... Dry bulb temperature sensor 9 ... Water tank 41 ... Upstream side cooling coil 42 ... downstream side cooling coil 43 ... first vaporization type humidifier material 44 ... second vaporization type humidifier material 50 ... cooling coil 91 ... first water tank 92 ... second water tank 93 ... third water tank 94 ... First communication hole 95 ... second communication hole

Claims (10)

An air conditioner in which a first heating coil, a cooling coil unit, and a second heating coil are disposed in a chamber having an intake port and an air supply port,
The cooling coil section includes a cooling coil, a first vaporizing humidifier material disposed in contact with the upstream side thereof, and a second vaporizing humidifier material disposed in contact with the downstream side thereof. And consists of
A water tank is disposed below the cooling coil section,
An air conditioner configured such that dripping water is circulated and supplied to the cooling coil from above. An air conditioner in which a first heating coil, a cooling coil unit, and a second heating coil are disposed in a chamber having an intake port and an air supply port,
The cooling coil section includes a cooling coil, a first vaporizing humidifier material disposed in contact with the upstream side thereof, and a second vaporizing humidifier material disposed in contact with the downstream side thereof. And consists of
A water tank is disposed below the cooling coil section,
An air conditioner characterized in that drip water is circulated and supplied from above to the cooling coil, the first vaporizing humidifier material, and the second vaporizing humidifier material. An air conditioner in which a first heating coil, a cooling coil unit, and a second heating coil are disposed in a chamber having an intake port and an air supply port,
The cooling coil section includes a cooling coil, a first vaporizing humidifier material disposed in contact with the upstream side thereof, and a second vaporizing humidifier material disposed in contact with the downstream side thereof. And consists of
A water tank is disposed below the cooling coil section,
Pure water is supplied from above the second vaporizing humidifier material, and dripping water is circulated and supplied from above to the cooling coil and the first vaporizing humidifier material. An air conditioner characterized by An air conditioner in which a first heating coil, a cooling coil unit, and a second heating coil are disposed in a chamber having an intake port and an air supply port,
The cooling coil section has a two-stage configuration of an upstream side cooling coil disposed on the upstream side with respect to the flow of processing air and a downstream side cooling coil, and the upstream side of the upstream side cooling coil includes a first stage. The vaporizer type humidifier material is installed in contact with the downstream side of the cooling coil, and a second vaporizer type humidifier material is installed in contact with the downstream side of the downstream side cooling coil, and at the bottom of the cooling coil unit. An aquarium,
Pure water is supplied from above the second vaporizing humidifier material, and dripped water is circulated and supplied from above to the upstream cooling coil, downstream cooling coil, and first vaporizing humidifier material. An air conditioner configured to be configured as described above. The said water tank is the 1st water tank located in the lower part of the 1st vaporization type humidifier raw material, the 2nd water tank located in the lower part of the said upstream cooling coil, the said downstream cooling coil, and the 2nd vaporization type It is divided into a third water tank located at the bottom of the humidifier material,
The first communication hole is formed between the first water tank and the second water tank, and the second communication hole is formed between the second water tank and the third water tank. 4. The air conditioner according to 4.   The cooling water supplied to the upstream cooling coil and the downstream cooling coil is configured to flow from the downstream cooling coil to the upstream cooling coil so as to be opposed to the flow of the processing air. The air conditioner according to claim 4 or 5.   The amount of cooling water supplied to the downstream side cooling coil and the heating adjustment by the first heating coil are configured to be controlled based on a detection value of a dew point sensor provided at the outlet of the air supply port. The air conditioner according to claim 6.   The amount of cooling water supplied to the downstream side cooling coil and the heating adjustment by the second heating coil are configured to be controlled based on a detection value of a dry bulb temperature sensor provided at the outlet of the air supply port. The air conditioner according to claim 6 or 7, wherein the air conditioner is provided.   The air conditioner according to any one of claims 1 to 8, wherein a vaporizing humidifier material formed in a flat plate shape is disposed on an upper surface of the cooling coil.   The air conditioner according to any one of claims 1 to 9, wherein the cooling coil is subjected to a hydrophilic treatment.

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