KR900006457B1 - Airconditioner - Google Patents

Abstract

The device having functions of maintaining constant temperature and constant humidity, ventilating and air conditioning, blows air into room through fan (1) and radiator (2). The device includes humidity control passage having section area (A2) smaller than section area (A1) between radiator (2) and room for freely controlling temperature and humidity of blowing air; air cleaning water or wet filter mounted between the fan and the radiator.

Description

Indoor air purifier with constant temperature, humidity and ventilation

1 is an example of injecting outside air into the room using a fan or the like.

2 is an example of adjusting the air temperature by installing a radiator in front of the fan.

3 is a device flow diagram of the present invention.

* Explanation of symbols for main parts of the drawings

1: electric fan 2: radiator

3: humidity control passage 4: air clean water

A ₁ : Cross section area of radiator A ₂ : Cross section area of humidity control passage

The present invention relates to an indoor air purifying apparatus, by which one device can simultaneously perform cooling, heating, humidity control, ventilation, and air cleaning of a room, thereby improving work environment and protecting important facilities, as well as facility costs and energy. The purpose is to provide a device that can be saved.

Normally, a person feels "good" when in contact with the environment, depending on the season and place and the state of his or her strength, but the comfortable temperature that a healthy person can feel regardless of the season is approximately 22.8-25 ° (73). -77 ° F), and it is well known that moderate humidity is around 25-60%.

However, if the temperature is slightly higher or lower, it doesn't hurt the person's mood significantly, but if the humidity is low or high, it will not only tell you the mood, but it will also harm your health. It has been a factor in shortening lifespan.

For example, when a precision instrument and an operator who are highly sensitive to temperature, humidity, and air cleanliness simultaneously operate in an enclosed space, problems occur when operating the existing air conditioning, heating (especially cooling) system and humidity control system. . That is, 1. As fresh air is not replaced, arregic reaction occurs due to chemical reaction deterioration of the instrument contact point and dust caused by wear of parts (particularly plastic). 2. Cooling device because it ventilates a lower amount of air. In the near place will give a sense of rejection, and will cost a lot of equipment and maintenance.

In order to change the above bad working environment, a large amount of fresh air must be injected into an enclosed room. When a large amount of air is injected, the air pressure in a closed (non-airtight) workplace is slightly smaller than the external atmospheric pressure. It can be prevented from inflowing dust to the outside when the worker enters and exits.However, when using the conventional cooling, heating, and ventilation system, the cooling and heating effect decreases at every ventilation, so that it can be restored to its original level. It will bring fuel costs and waste, and will also cause problems to operate a separate humidity control device for humidity control.

The present invention created in view of the above problems will be described in detail with reference to the accompanying drawings and examples.

Example 1

Inject large quantities of fresh fresh air into a closed workplace. That is, the air is injected using a simple fan as shown in FIG. 1 or the air is sucked using the fan. However, in this case, there is a problem that the outside air that is not controlled temperature and humidity is introduced as it is.

Example 2

Let's adjust the temperature first. Consider installing a radiator in front of the fan and adjusting the temperature of the air introduced from the outside by the temperature of the radiator (for example, if the outside temperature is 28 ℃ on summer day, lower it to 18 ℃). In this case, the temperature of the air can be lowered to the desired temperature, but since the humidity of the air is nearly 100% due to passing through the radiator, it is necessary to install a dehumidifier or the like to lower the humidity again. The hassle of cooling the air to temperature and then heating it back to the desired temperature.

Here, Example 1 and Example 2 are numerically displayed.

Only use a fan

Fan and radiator use

Example 3

With this in mind, in the present invention, as shown in FIG. 3, a narrow humidity control passage 3 is installed between the radiator 2 and the room to adjust the humidity of the air according to the size of the humidity control passage 3 at will. By installing a humidity control passage,

Humid air passing through the radiator (2) as described above to pass through the humidity control passage (3) is to control the humidity.

The principle is explained in detail as follows. If the amount of air introduced per unit time by the fan 1 is V ₁ Cm ³ / sec cross-sectional area A ₁ Cm ² , the air flow rate by the fan 1

Assuming that the temperature in the radiator (2) is lowered from absolute temperature T ₁ → T ₂ , the air velocity when passing through the radiator

In other words, as the temperature decreases, the speed of v ₂ decreases slightly relative to the speed of v (but there is no significant effect). An important principle is then applied. That is, since the cross-sectional area A ₂ of the humidity control passage 3 entering the room is narrowly configured (A ₂ <A ₁ ), the flow rate of air in the humidity control passage 3 passes through the radiator (or fan). It is faster than the flow rate. In other words,

A ₁ : Cross section of fan or radiator

A ₂ : humidity control passage cross section

v ₂ : radiator passage and air velocity

v ₃ : Humidity control passage passage air speed

Therefore, depending on the ratio of the cross-sectional areas A ₁ and A ₂ , the air flow rate may be faster or slower.

Here, according to Bernoulli's principle, the head of the head is the same, so the sum of Abdu and Sokdu is always constant.

Temperature T ₂ = T ₃ ipro, density P ₂ = P ₃ . Here, if we rearrange the equation, P ₂ -P ₃ = ( v ² ₃ - v ² ₂ ).

이므로By the way

Because of

이되며 여기서

이 되므로 이를 다시 정리하면

Where is

So if you clean it up again

이 된다.

Becomes

Where P ₂ is the radiator passage air pressure P ₃ is the humidity control passage passage air pressure D is the radiator passage air velocity v ₃ is the humidity passage passage air speed P ₂ is the radiator passage air density P ₃ is the humidity passage passage air density T ₂ Is the air passing through the radiator and the absolute temperature T ₃ is the air passing through the humidity control passage and therefore the pressure difference between the radiator and the

Become. That is, the radiator 2 has a slightly higher air pressure than the humidity control passage 3. The degree of increase ΔP is determined according to the temperatures T ₁ , T ₂ and the cross-sectional areas A ₁ , A ₂ at each. However, since the humidity on the radiator 2 is 100% (when below 100%, the pressure rises until it reaches 100%, so the humidity inside the radiator will always be 100%).

The air pressure inside the radiator (2) does not increase, but instead the volume decreases, and this decrease is caused by the volume of water vapor in the air (V "': volume per mole) and foreign matter (V": volume of mole. By converting to), the shaft is equal to the volume difference (ΔV = V "'-V").

The thermodynamic equation (if 1 mole) for vaporization of liquids and condensation of gases is (V "'-V") P = 1 ₂₃ . Where 1 ₂₃ is the latent heat required to vaporize from state 2 (liquid) to state 3 (gas). (It is the same when it becomes state 2 from state 3)

n mole

이므로

Because of

Number of mole ringed into water ie n sms

이며 이 모든 값들은 라지에이터에서의 온도(T₂)값이다. 여기서 n은 물로 환원된 수증기의 mole수이다. 즉 n×18gm만큼 단위체적당 수분이 빠짐으로서 습도가 그만큼 내려가게 된다.

All these values are the temperature (T ₂ ) values in the radiator. Where n is the number of moles of water vapor reduced to water. In other words, the moisture per unit volume is lost by n × 18gm, the humidity is lowered.

In this way, the present invention can arbitrarily adjust the humidity of the room by appropriately adjusting the ratio of the cross-sectional areas A ₁ and A ₂ without using any special device.

On the other hand, when the humidity in the room is low or winter, you may need to add moisture to the air.

If the outside air is severely polluted, it is necessary to purify the air. In order to solve this problem, when the outside air is injected into the fan (or the fan), the fresh water is injected through the air clean water (4) to remove dust and soot, which are mixed in the air, and to remove carbon dioxide or sulfuric acid gas in the air. It is dissolved in water and removed, and if other neutralizer is put in the water, it can remove other harmful gas and inject clean fresh air into the room, and reference numeral 5 in the reference numeral is an air inlet pipe.

It is also possible to use a filter soaked in water instead of air fresh water. In addition, when the ground water is used for the water of the radiator 2 or the air clean water 4, the energy saving effect of 80% can be obtained.

As described above, the present invention can realize the constant temperature, humidity, ventilation, air cleaning, etc. as a device, which is a low-cost energy-saving indoor air purifier that can reduce the cost of building facilities and reduce the cost of maintaining the facility. It is a groundbreaking invention that can be supported.

Claims (3)

The air is injected into the room through the fan (l) and the radiator (2), and between the radiator (2) and the room, a humidity control passage (3) having a cross-sectional area (A ₂ ) having a smaller cross-sectional area (A ₁ ) is installed. Indoor air purifier having a constant temperature, humidity, and ventilation function characterized in that the temperature and humidity of the indoor inlet air can be arbitrarily adjusted. Injecting external air through air fresh water (4). 3. Use of a filter moistened with water for use as an alternative to air fresh water (4).

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