KR20110121561A - Method for improving performance of heating and cooling system and heating and cooling system using the method - Google Patents

Abstract

PURPOSE: A performance advancing method of a heating and cooling facility and a heating and cooling facility using the same are provided to improve the indoor temperature control effect of heating and cooling facility by providing the air controlled by the temperature in which the heating and cooling efficiency is good. CONSTITUTION: A heating and cooling facility comprises a chiller, an air conditioner(200) and a duct for transferring the air. The chiller generates the cold water or the warm water required for heating and cooling. The air conditioner comprises a heat exchanger and a blower. The heat exchanger heat-exchanges the air and the cold or warm water generated in the chiller. The blower transfers the heat-exchanged air. The outlet discharging the air heat-exchanged in the air conditioner to the indoor is formed in the end of the duct for the air transfer.

Description

Method for Improving Performance Of Heating And Cooling System And Heating and Cooling System Using The Method}

The present invention relates to a method for improving the performance of a cooling and heating facility already installed in a building and a plastic house, and a newly installed heating and cooling facility, and a cooling and heating facility using the method.

More specifically, air conditioning and heating, such as buildings and plastic houses, can dramatically improve the performance of air-conditioning and heating facilities by adjusting the air movement speed appropriately by improving air-conditioning facilities installed or installed in large buildings to ensure sufficient heat exchange. It relates to a method of improving the performance of the equipment and its equipment.

Furthermore, the present invention relates to a technology applicable to an air conditioner or a heater that is operated alone.

Large buildings are equipped with air conditioning and heating equipment for heating and cooling the buildings. Figure 1 is a schematic diagram of the heating and cooling equipment currently installed in a large building. As shown in FIG. 1, the air conditioning equipment currently installed in a large building includes a cold and hot water heater 100, an air conditioner 200, and a duct 300.

The cold and hot water heater 100 serves to produce cold water or hot water required for cooling and heating, and the air conditioner 200 is a heat exchanger 210 for exchanging cold water or hot water and air produced in the cold and hot water heater, and a blower for transporting the air. And 220.

Duct 300 is a tube for transferring the temperature controlled air from the air conditioner 200 to the room, the discharge port 310 is formed at the end of the duct, the discharge port 310 is typically on the ceiling or wall of the room Is installed.

Operation of the cooling and heating equipment installed in such a building produces cold water or hot water in the cold and hot water heater 100 and sends it to the heat exchanger 210, in the heat exchanger 210 by the cold water or hot water and the blower 220 flowing therein The temperature of the air is adjusted to a desired temperature by heat exchange of the air to be transported, and the air whose temperature is controlled in the air conditioner 200 is supplied to the room 400 through the discharge port 310 and thus the temperature of the room 400. Will be adjusted.

In general, in order to maintain the proper temperature for the indoor space controlled by the heating and cooling facilities to maintain the proper temperature, it is necessary to supply the heat required for heating and cooling, the relationship between the maintenance temperature and the supply heat of the indoor space is quite complex. For example, the volume of the indoor space, the height of the ceiling, the arrangement and number of the air outlets, the air temperature and speed at the outlets, the humidity in the room, the furniture placed in the room, the heating element, the number of people, the size and number of the windows, the doors. The interrelationship with factors to be considered such as the frequency of opening and closing of the door is too many to be calculated by the formula, and it is more complicated considering the convection caused by the temperature and density difference of the air, thermal conduction of furniture, radiant heat of the heating element, etc. . As a result, it is difficult to calculate the correlation between the supply calories and room temperature in consideration of these general requirements, so that the capacity of each facility is usually calculated under the general design conditions, and the equipment that is commonly used in the market closest to the heating and cooling facility capacity calculated at the time of design. Choose the capacity value of the equipment will be installed.

Therefore, it is common that the capacity is larger than the proper air-conditioning and heating equipment required for the building, and the capacity is excessively installed by 20 to 30% in consideration of the peak value of midsummer and midwinter.

In addition, the air-conditioning equipment installed in the building is designed to transfer heat of the heat exchanged air very quickly in order to quickly adjust the indoor temperature to the desired temperature, thereby providing sufficient time for the air to heat exchange in the heat exchanger. As a result, the air passing through the heat exchanger is supplied to the room without reaching the most suitable temperature for heating and cooling.

Due to the above reason, the air-conditioning air supplying from the discharge port 310 of the duct 300 does not spread evenly throughout the room 400, and the air-conditioning efficiency is low while air is circulated, resulting in excessive consumption of air-conditioning fuel and electricity. There is a problem of environmental pollution such as cost increase and carbon dioxide emission.

The present invention has been invented to solve the above problems, the present invention is to adjust the air movement speed to suit the heating and cooling of the building through a simple modification of the air-conditioning equipment and newly installed air-conditioning equipment that is already installed in the building By supplying air with sufficient heat exchange in the heat exchanger, it is possible to drastically improve the heating and cooling efficiency, and to apply it to the heating of the plastic house that needs heating, and to increase the heating efficiency. It is also applied to heating facilities to save energy and reduce environmental pollution.

The method and apparatus for increasing the efficiency of the heating and cooling facilities according to the present invention was derived in the process of finding the most efficient air-conditioning operation method while substantially operating for the designed and heating facilities without considering all the requirements for the heating and cooling facilities. It is applied to existing and new air-conditioning facilities to improve existing air-conditioning facilities and to new air-conditioning facilities.

The technical idea of the present invention is to reduce the air moving speed in the air conditioner and the discharge port, so that the heat is exchanged sufficiently in the heat exchanger to supply air at a lower temperature when cooling, and when the air is supplied at a higher temperature during heating, the heating and cooling efficiency is increased and energy consumption is reduced. Technology.

In general, in order to obtain the desired room temperature by operating the cooling equipment in summer, the room temperature of 24 ℃ can be obtained after 2 hours after the cooling equipment is operated. Cold water of 7 ℃ can be obtained only when operating for 30 minutes to 2 hours, and the desired room temperature can be obtained only when air is circulated for 30 minutes by exchanging heat in a heat exchanger for cold water circulating. In this case, the air discharge rate of the air conditioner is high in the heat exchanger of the air conditioner. As a result, the temperature of the air that is not sufficiently exchanged and the temperature of the air supplied to the discharge port is excessively heated by the air speed of the air supplied rapidly. As a result, the temperature of the discharge port stays at 14 ℃ ~ 15 ℃ and the temperature of the circulating cold water rises to about 12 ℃, and the cold / hot water machine keeps running, but the indoor temperature does not drop much. As a result, the indoor cooling efficiency is reduced.

However, by reducing the blower speed in the air conditioner, the heat exchanged air is sufficiently exchanged to lower the air supply temperature of the heat exchanger during normal cooling by 1.5 to 2 ° C. In the process of circulating air through the heat exchanger continuously, the heat exchange efficiency was increased in series, reducing the operating time of the chilled water, resulting in a 20 ~ 30% reduction in energy consumption.

In other words, since the heat is exchanged sufficiently in the heat exchanger, the cold water temperature is maintained at about 12 ℃ and the air supply temperature is maintained at 12 ℃ ~ 13 ℃ even if air supply is started after only 30 minutes of operation without dropping the cold water temperature of the cold / hot water machine to about 7 ℃. It is possible to supply air at a temperature of 1.5 to 2 ℃ lower than the existing method. At this time, the circulating cold water of the cold / hot water heater reduces the air movement speed in the heat exchanger, so that less heat is taken away, thereby saving energy, and the chain reaction can reduce the operating time of the cold / hot water machine and increase the indoor cooling effect.

This phenomenon is applied even if the air supply temperature is raised in the same way as in the case of heating.

In order to reduce the discharge rate of air as described above, the heat is sufficiently exchanged in the heat exchanger to obtain the cooling and heating effect as in the present invention.

The method and the device for improving the performance of the air conditioning and heating equipment installed in the most preferred building according to the present invention has a height from the floor to the ceiling H (m), the discharge rate of air at the discharge port V (m / sec) is the following equation (1) It is characterized in that it comprises a step of improving the air-conditioning equipment so as to satisfy the lowering the air supply temperature during cooling, the air supply temperature higher when heating.

0.45 * H ≤ V ≤ 0.75 * H ----------- (1)

When the V value calculated by Equation (1) is out of a maximum of 3 m / s and a minimum of 1.8 m / s, it is preferable to adopt the maximum or minimum value. If the discharge port is far away or close to the installation condition, the air velocity can be reduced within 10%.

Equation (1) is the most preferred embodiment for controlling the air speed of the discharge port in the normal heating and cooling equipment, and the discharge speed of the air outlet in accordance with the building structure and the air conditioner capacity, etc. blower installed on the heat exchanger side of the air conditioner Since it is associated with and can be determined by the air discharge rate of the discharge port obtained by adjusting the speed of the blower so that heat can be properly exchanged in the heat exchanger. At this time, the air discharge speed of the discharge port may be increased from the above-defined or maximum value according to the conditions.

According to another preferred feature of the present invention, the air supply temperature discharged from the discharge port is characterized in that the air supply is lowered by at least 1.5 degrees at the time of cooling and at least 1.5 degrees at the time of heating than the standard temperature of the existing heating and cooling equipment normally designed and operated. .

According to another preferred feature of the invention the air temperature is heat exchanged in the heat exchanger and the air temperature supplied to the discharge port by the blower is a heat exchange in the range of the same or less than 1.5 degrees maximum or less than the hot and cold water temperature circulated due to the reduced air discharge rate It is characterized by.

According to another preferred feature of the present invention, it is preferable that the discharge speed V of the air at the discharge port is kept constant during the operation of the air-conditioning equipment.

According to a preferred feature of the present invention, the improvement of the cooling and heating equipment is characterized in that the heat exchange in the heat exchanger is sufficiently performed by adjusting the rotational speed of the blower associated with the air speed of the discharge port to lower the discharge rate from the blower.

According to another preferred feature of the invention, the blower is composed of a motor and a fan mechanically connected thereto, the rotational speed of the blower by the adjustment of the inverter or by a pulley that the diameter of the motor shaft satisfies the above-mentioned To be controlled at a desired rate.

According to another preferred feature of the invention, the blower is provided at the front and rear ends of the heat exchanger, respectively, characterized in that the air discharge speed and the temperature of the discharged air at the discharge port side is adjusted in accordance with the rotation speed of the blower It is done.

According to another preferred feature of the present invention is applied as it is to the heating equipment of the vinyl house for cultivating horticultural crops, etc., it is characterized by reducing the energy by increasing the heating efficiency.

According to another preferred feature of the invention, it is characterized by saving energy by applying to the individual air-conditioner, heating equipment supplied to the apartment as it is.

The air conditioning equipment having improved performance according to the present invention has a sufficient heat exchange between air and cold water / hot water in the heat exchanger, so that the air is controlled at an efficient temperature for air conditioning. Can save energy.

In addition, this performance improvement can be achieved by a relatively simple method such as adjusting the rotational speed by an inverter connected to the blower motor or replacing the blower motor, and furthermore, by simply adjusting the speed by simply replacing the blower motor side pulley. As the construction period is considerably shorter and the facility investment cost is small, the improvement effect of the air conditioning and heating facilities is remarkable. Therefore, it is expected to reduce the payback period, save energy, and reduce carbon emissions.

In addition, by reducing the rotation speed of the blower fan, the electricity consumption is reduced, the usable life of the device is increased, there is little effect in the room.

The present invention does not simply reduce the moving speed of the air, but provides a method for driving the optimum air supply temperature and the moving speed, thereby maximizing the performance improvement effect.

When applying the present invention is expected to reduce carbon dioxide emissions by energy savings, such as carbon credits.

1 is a schematic diagram of a heating and heating facility currently installed in a large building,
2 is a schematic diagram of a blower installed in a current building,
3 is a schematic diagram of a blower in which only the motor side pulley is replaced according to the present invention.
4 is a block diagram of a heating facility in a plastic house according to the present invention;
5 is a layout view of the duct in the plastic house according to the present invention.

The inventors of the present invention have led to the present invention by studying a method and apparatus for improving the performance of the air-conditioning equipment installed or installed in a building or the like. The most important part of the present invention in the present invention is to improve the performance of the air-conditioning equipment to be installed in buildings and vinyl houses, etc., in order to minimize the investment cost and construction period, air-conditioning equipment installed in buildings and plastic houses and newly installed air-conditioning equipment Minimize the renovation.

Therefore, in the present invention, in order to minimize the investment cost and construction period required to improve the performance, it is necessary to exclude a method that requires a large investment cost such as changing the capacity of the cold / hot water heater and the heat exchanger, or replacing the duct or the outlet with a different diameter. desirable.

From this point of view, the inventors are currently analyzing the problems of the heating and cooling facilities installed in buildings and plastic houses, and the currently installed heating and cooling facilities are designed to have a very high air transfer speed in order to quickly adjust the temperature of the room. It has been found that the air passing through the heat exchanger is often supplied indoors without suitable temperature for heating and cooling without sufficient time for sufficient heat exchange in the heat exchanger.

In the present invention, the performance of the air conditioning system is improved by a method of providing an air moving speed at which air can stay sufficiently in the heat exchanger so that the air passing through the heat exchanger is suitable for air conditioning and reaches an efficient temperature.

To this end, in the present invention, the feed rate of air is controlled to give a time allowance for sufficient heat exchange in the heat exchanger 210. On the other hand, the present invention controls the conveying speed of the air on the basis of the conveying speed of the air in the discharge port 310 installed in the room which is most convenient for the measurement of the conveying speed of the air and the rotation speed of the blower in the air conditioner associated with it.

In the air-conditioning and heating facilities installed in the current building, the discharge speed of the air at the discharge port 310 is 5 ~ 16m / s, the most preferred embodiment in the present invention based on the discharge speed that is commonly operated as described above While reducing the discharge rate (V) of air at the discharge port 310, it is adjusted to the extent that the following equation (1) can be satisfied.

0.45 * H ≤ V ≤ 0.75 * H ----------- (1)

Here, H is the height from the floor to the ceiling of the room in which the discharge port is installed, and the calculated unit of V is m / s.

For example, if the height of the room is 4 m, it is most preferable to operate the air conditioning system so that the discharge speed V of the air at the discharge port may be 1.8 m / s to 3 m / s.

However, when the V value calculated by Equation (1) is out of a maximum of 3 m / s and a minimum of 1.8 m / s, it is most preferable to operate by adopting the maximum or minimum value. If less than 1.8m / s, the flow of air is too small to take too much time to control the temperature of the room, if it exceeds 3m / s there is a problem that the efficiency of the heat exchanger is not enough because the heat exchange is not made.

Equation (1) is the most preferred embodiment for controlling the air speed of the discharge port in the air-conditioning equipment that is commonly operated, the discharge speed at the discharge port of the air is connected to the blower installed on the heat exchanger side of the air conditioner It can be determined by the air discharge rate of the discharge port obtained on the basis of the speed of the blower to the extent that heat is properly exchanged to increase the heating and cooling effect. Therefore, depending on the structure of the building and the capacity of the heating and cooling facilities, the air discharge speed of the discharge port may be increased more than the speed and the maximum value according to the above formula.

In addition, in the present invention, it is preferable that the discharge speed V of the air at the discharge port 310 is kept constant from the initial operation to the stop. In other words, by keeping the air moving speed constant in an optimal state, sufficient heat exchange occurs in the heat exchanger at all times, thereby allowing the air regulated to a desired temperature to be continuously supplied to the room.

In the present invention, in order to adjust the discharge speed of the air from the discharge port 310 to suit the present invention, the rotational speed of the blower 220 installed in the air conditioner 200 is adjusted.

In the present invention, in order to adjust the discharge speed of the air in the discharge port 310 to the discharge speed calculated by the above formula (1), the rotational speed of the blower 220 installed in the air conditioner 200 is adjusted.

That is, by adjusting the rotational speed in the blower 220 is to control the feed rate of air

The method of controlling the rotational speed in the blower 220 may include 1) replacing a blower motor or 2) replacing at least one of the fan side and motor side pulleys 3) installing an inverter controlling the blower motor, and adjusting the same. There is this.

The method of replacing the blower motor is to replace the motor of the blower so that the blower of the heating and heating installation currently installed in the building can maintain the air discharge rate calculated by the method. Even in this case, the electricity consumption and fuel consumption are reduced, the usable time of the equipment is increased, and there is no noise.

Next, the least costly investment method is to adjust the rotational speed of the blower to a desired speed by replacing the pulleys with different diameters on the rotation shaft of the motor and fan. In this case, either or both of the rotation shafts of the motor and the fan may be replaced, but preferably, a pulley having a small diameter capable of adjusting the rotation speed on the blower motor side is replaced.

2 is a schematic diagram of a blower installed in a current building, and FIG. 3 is a schematic diagram of a blower in which the motor side pulley according to the present invention is replaced with a small fleece.

As shown in FIG. 2, the blower is a belt 227 connecting the motor 224, the motor side pulley 226, the fan 223, the fan side pulley 225, the motor side pulley 226 and the fan side pulley 225. In one embodiment of the present invention, the motor-side pulley 230 is replaced with a smaller diameter. In this case, since the motor is not replaced, there is no change in the electricity consumption, but the fuel consumption is reduced while the investment cost is low.

Furthermore, the above-described methods may be used in combination. Specifically, a method of replacing a pulley while replacing a motor may be used. For example, if the motor capacity and the pulley diameter are cut in half, T∝P / N (where T is the torque, P is the motor pole, and N is the rotation speed), the motor-side pulley 230 is halved. If it is reduced, the air volume is reduced by 1/2, and the motor capacity is also reduced by 1/2, which satisfies the torque required to start the blower, and can reduce electric consumption and fuel consumption.

You can install an inverter that controls the blower motor or use a pre-installed inverter. For example, if you control the frequency from the output of the inverter, the speed of the motor of the blower is proportional to the square of the frequency, and the power is proportional to the quadratic. Reducing to 30Hz can reduce the rotational speed to one quarter and the power to one quarter. By controlling the speed of the blower in this way, the air feed rate in the heat exchanger is adjusted according to the blower speed, and the power supplied is adjusted.

By the way, the control method of the inverter is preferable to operate in consideration of the harmonics generated in the operation process may affect other equipment control.

In consideration of this, the inverter output frequency is adjusted up to 50Hz in consideration of this point, but there has been no case of reducing the purpose of improving heating and cooling efficiency.

The reason why the energy consumption in the present invention is reduced can be explained by the following equation.

* Output calories converted from air volume into energy

Gas volume (CMH) * Specific gravity Kg / ㎥ * Conversion temperature difference = heat consumption

Air flow rate m ³ / sec * Air specific heat * Specific gravity * Conversion temperature difference = kcal 1 kwh = 760 kcal

In other words, when the gas volume (wind volume) is reduced, the energy consumed is also saved in proportion to the wind volume.

When the number of revolutions of the blower is reduced, the amount of air conveyed by the blower decreases in proportion to the number of revolutions, and the air velocity (strength) conveyed decreases in proportion to the square of the number of revolutions. This reduces the amount of energy consumed through the heat exchanger. However, the heat exchange is sufficiently made so that the temperature of the air discharged by the blower through the heat exchanger, the cold and hot water circulated from the cold or hot water heater or the freezer / boiler is lowered during the cooling and higher when heating. As a result, the speed of air discharged during cooling and heating is reduced, but the cooling and heating efficiency is increased because the temperature of the air supplied from the heat exchanger is sufficiently lowered or raised. In other words, if you reduce the air speed and supply air with sufficient heat exchange, you can obtain the desired air conditioner temperature even if you reduce the operating time of the hot / cold water heater or the freezing turbine / boiler, and improve the air-conditioning cycle by improving the chain heating and cooling cycle. Will be increased.

On the other hand, the blower in the heating and cooling facilities currently installed in the building may be installed at the front and rear ends of the heat exchanger respectively. In FIG. 1, reference numeral 221 denotes a blower installed at the rear end of the heat exchanger 210, and reference numeral 222 denotes a blower installed at the front of the heat exchanger 210. Here, if there is no window in the room and does not have a separate flue gas facility, the blower 222 installed in front of the heat exchanger should be used as a flue gas facility in case of emergency, in this case, the rotation speed adjustment method described above is a heat exchanger. It is not applicable to the blower 222 installed at the front end. In this case, of course, this can also be applied to the blower installed in front of the heat exchanger. In case of fire, the blower 221 installed at the rear of the heat exchanger is automatically stopped, and the blower 222 installed at the front of the heat exchanger plays a role of exhausting. This is because they do not perform their roles properly.

It looks at the experimental process and the effect of the improvement of the heating and cooling equipment according to the present invention.

The inventors conducted experiments over two years on the same large building. That is, in the first year, the air conditioner and inverter installed in the current building were operated as usual, and in the second year, the optimum air movement speed was derived by the present invention, and the inverter was able to move air at the air movement speed. The air conditioning system was operated at the optimum air movement speed by controlling the constant frequency and adjusting the fan motor speed accordingly. In the first year, the air discharge rate at the outlet of the air-conditioning equipment installed in the current building was measured to be 8 ~ 16m / s. Since the ceiling height of this building was 3.6 m, the optimal air discharge rate was calculated by equation (1). As a result, the air movement speed of the discharge port became 2.7 m / s, and the air conditioning equipment was operated by adjusting the air speed at the discharge port to the speed of 2.7 m / s.

As a result, it was possible to reduce the operating time of cold water heater before going to work to 30 minutes in 2 time zones, and the temperature of cold water circulated after operating for 30 minutes with air supply from the air conditioner was 12 degrees and the temperature supplied from the air conditioners was heat exchanged within 12 degrees. Maintained 13 degrees. Since the room temperature was easily reached at 24 degrees and no heat exchange occurred in the air conditioner during 24 degrees, the hot and cold water was operated without any heat loss. When the room temperature exceeds 24 degrees Celsius, air supplied from the air conditioner is exchanged with cold water through a heat exchanger to lower the air supply temperature.The air supply is supplied at a temperature lower than 1.5 degrees below the normal air supply temperature before the change. This operation was repeated to save energy.

As a result of the test operation comparing the electricity consumption and fuel consumption is shown in Table 1 below.

Comparison of electricity and fuel consumption (inverter installation operation; proper wind speed fixed operation) division Electricity (Kwh) Fuel (gas, m3) First year Second year increase First year Second year increase In May 597,388 559,913 -37,475 9,399 3,781 -5,618 June 715,870 671,360 -44,510 22,867 20,973 -1,894 In July 765,746 694,596 -44,682 44,682 31,075 -13,607 August 836,684 807,527 -54,980 54,980 41,011 -13,969

As shown in Table 1 above, it can be seen that the use of electricity and fuel is reduced by improving the operating method of the air conditioning equipment installed in the current building.

Electric saving is a pure amount of power supplied to the blower according to the speed control of the blower, and the cooling method is a gas method, so the gas reduction is mainly made during cooling.

The present invention is characterized by optimizing the moving speed of air supplied during heat exchange in an air conditioner so that sufficient heat can be exchanged in the heat exchanger so as to efficiently use energy. Its characteristics are minimized.

In addition, the present invention can be equally applicable to a case in which air conditioning and air conditioning facilities are newly installed in a building that is newly constructed as well as already equipped with air conditioning and air conditioning facilities.

In addition, in order to control the rotational speed of the blower motor for controlling the movement speed of the air in the air conditioner, not only the existing inverter but also the newly installed inverter can increase the heating and cooling efficiency of the building using the method of the present invention.

On the other hand, the present invention can be applied to the air-conditioning equipment, heating equipment that operates alone, such as offices, restaurants, homes alone, for example, when the air discharge speed is calculated inefficiently, and the air discharge speed is reduced when it is unnecessarily large. Thus, the effect can be achieved by allowing sufficient heat exchange. At this time, the air discharge rate is determined according to the method defined in the present invention.

The present invention is also applicable to a vinyl house heating facility.

In order to grow flowers, vegetables, trees, horticultural crops, etc. in a plastic house, the plant must be heated to a certain temperature necessary for cultivation. The air discharge rate of the heating equipment installed in the plastic house reaches an average of 20 m / sec. It is supplied to the outlet of the duct in the vinyl house at a temperature of about 40 ℃ without sufficient exchange, and the heating efficiency is greatly reduced.

By reducing the speed of the air discharged from the heat exchanger according to the method according to the invention it is possible to efficiently raise the air temperature in the plastic house by the warm air is discharged to the duct 50 ℃ or more heat exchanged sufficiently in the heat exchanger. In order to adjust the moving speed of the discharged air by installing an inverter in the blower or by using a motor replacement and pulley it can achieve the purpose of power saving and the present invention.

Specific embodiments,

4 is a block diagram of a heating facility in a plastic house according to the present invention.

As shown in Figure 4, the vinyl house heating facility of the present invention is an air conditioner for discharging the air sucked into the boiler 100 to produce hot water necessary for heating and the air drawn into the vinyl house to the duct (300) ( 200 and a duct 300 for transferring the temperature-controlled air into the room.

The boiler 100 generates hot water for heating required for growth of crops in the plastic house.

The air conditioner 200 includes a heat exchanger 210 for exchanging hot water and air produced by the boiler and a blower 220 for transferring the air.

The heat exchanger 210 is a heat exchange between the boiler 100 and the air sucked from the inside of the vinyl house.

The rear side of the blower 220 sucks air from the interior of the vinyl house 400, heat-exchanges the heat exchanger 210 in the air conditioner 200, and discharges the air to the duct 300 of the front side of the blower 220. .

Therefore, the feed rate of the air is controlled by the rotational output of the blower 220 so that the heat exchanger 210 has a sufficient time for air generation at a set temperature.

The duct 300 is connected to the end of the air conditioner 200 can withstand the resistance of the air in order to transfer the temperature controlled air in the heat exchanger 210 to the vinyl house interior 400, but the person is a specific tool Without being made of a material such as vinyl that can easily make a plurality of discharge ports 310 in the desired position, it consists of two tubes containing a plurality of discharge ports (310).

5 is a layout view of the duct in the plastic house according to the present invention.

As shown in FIG. 5, the two ducts 300 are located at a length equal to one from the left and a length equal to one from the right by dividing the length of the left and right sides of the vinyl house into four equal parts. It is preferable to double the length equal to 1, and to place the duct 300 on the upper and lower sides where the position of the duct 300 is 1/2 of the height of the vinyl house, so that the temperature-controlled air can be spread evenly throughout the vinyl house. .

Unlike the building, the air discharge rate in the vinyl house duct is low, the insulation effect is low, and the large space must be heated by a single duct, so the air discharge rate is designed and operated faster than the building about 10 ~ 20m / sec.

Therefore, it is most preferable to set the air discharge speed condition twice as the building heating condition.

That is, 0.9 * H ≤ V ≤ 1.5 * H. (H: height from floor to ceiling [m])

When the air discharge speed is out of the maximum 6m / s, minimum 1.8m / s, the blower speed is adjusted to be the maximum or minimum determined here.

However, the air discharge rate may be determined by the air discharge rate of the discharge port obtained by adjusting the speed of the blower so that heat exchange can be properly performed in the heat exchanger. At this time, the air discharge rate of the discharge port may be less than the lower limit or greater than the upper limit.

Another desirable feature of the present greenhouse heating facility is that the heat exchange is sufficient during heat exchange, so that the temperature of the hot water circulated and the discharged air are about the same or within a range of 10 to 15 degrees.

The discharge port 310 is formed on the upper, lower, left and right sides of the duct 300 made of vinyl to be easily removed by a perforation line at regular intervals, and when the transfer speed of air and the temperature of the room are required, Can be removed to control the position and number of outlets on the vinyl duct.

As a result of the heating test of the vinyl house by the method according to the present invention, the electricity consumption and the fuel consumption were compared as follows.

The frequency of the inverter supplied to the blower was raised to 60 Hz to raise the ambient temperature 19 ℃ to 23 ℃, and the air moving speed was measured at 21m / sec. Run for minutes.

As a result of reducing the speed of the blower by setting the frequency of the inverter to 25Hz, the moving speed of air decreased to 3.5m / sec, and it operated for 2 minutes for 2 minutes for 2 minutes in the full operation of the boiler. The temperature rose and the residual heat remaining in the boiler lasted for 5 minutes after the boiler was shut down. Blower electricity consumption was also reduced to about one quarter.

The heating method and equipment of the vinyl house as described above is equally applied to the heating concept of the building described above. However, there is only a difference in applied temperature due to structural differences and differences in heating capacity.

In the present specification, a preferred embodiment of an existing building, an air conditioner and a heater, and a heating facility of a vinyl house, which are operated independently of a cooling and heating facility of a newly constructed building, is not limited thereto.

The invention can be practiced in a variety of modifications within the scope of the claims and the accompanying drawings, which also belong to the scope of the invention.

100: air conditioners
200: air conditioner
210: heat exchanger
220: blower
221 blower installed at the rear end of the heat exchanger
222: blower installed in front of heat exchanger
223 blower fan
224; motor
230: motor side pulley
300: Duct
310: discharge outlet
400: indoor

Claims (17)

A cold and hot water machine for producing cold or hot water required for heating and cooling;
An air conditioner including a heat exchanger for heat exchange between cold water or hot water produced in the cold and hot water heater, and a blower for transferring the heat exchanged air; And
In the performance improvement method of the heating and cooling equipment comprising an air transfer duct is formed at the end of the discharge port for discharging the heat exchanged air from the air conditioner to the room,
And improving the air conditioning equipment such that the air discharge rate (V) at the discharge port satisfies Equation (1) below.

0.45 * H ≤ V ≤ 0.75 * H ----------- (1)
Here, H is the height from the floor to the ceiling of the room in which the discharge port is installed, and the calculated unit of V is m / s.
However, when the V value calculated by Equation (1) is outside the maximum of 3 m / s and the minimum of 1.8 m / s, the maximum or minimum value is adopted.
A cold and hot water machine for producing cold or hot water required for heating and cooling;
An air conditioner including a heat exchanger for heat exchange between cold water or hot water produced in the cold and hot water heater, and a blower for transferring the heat exchanged air; And
In the performance improvement method of the heating and cooling equipment comprising an air transfer duct is formed at the end of the discharge port for discharging the heat exchanged air from the air conditioner to the room,
The air supply temperature which is sufficiently exchanged with the heat in the heat exchanger and discharged to the discharge port may be supplied at a minimum of 1.5 ° C. or lower at cooling and at least 1.5 ° C. or higher at heating than a standard air supply temperature which is normally designed or operated under the same conditions. Improved performance of the heating and cooling equipment, characterized in that for reducing the blower speed of the air conditioner.
The method of claim 1 or 2, wherein the discharge speed (V) of the air at the discharge port is kept constant during operation of the air conditioning equipment.
The method of claim 1 or 2, wherein the improvement of the air conditioning system is performed by adjusting a rotation speed of the blower.
The air conditioner of claim 4, wherein the blower comprises a motor and a fan mechanically connected thereto, and the rotation speed of the blower is controlled by replacing a pulley having a diameter different from each other on the rotation shaft of the motor and the fan. How to improve facility performance.
The method of claim 4, wherein the blower is installed at the front end and the rear end of the heat exchanger, and the adjustment of the rotation speed of the blower is applied only to the blower installed at the rear end of the heat exchanger. .
A cold and hot water machine for producing cold or hot water required for heating and cooling;
An air conditioner including a heat exchanger for heat exchange between cold water or hot water produced in the cold and hot water heater, and a blower for transferring the heat exchanged air; And
In the air-conditioning facility comprising an air transfer duct is formed at the end of the discharge port for discharging the heat exchanged air from the air conditioner to the room,
And the rotational speed of the blower is determined so that the air discharge rate (V) at the discharge port satisfies Equation (1) below.
0.45 * H ≤ V ≤ 0.75 * H ----------- (1)
Here, H is the height from the floor to the ceiling of the room in which the discharge port is installed, and the calculated unit of V is m / s.
However, when the V value calculated by Equation (1) is outside the maximum of 3 m / s and the minimum of 1.8 m / s, the maximum or minimum value is adopted.
A cold and hot water machine for producing cold or hot water required for heating and cooling;
An air conditioner including a heat exchanger for heat exchange between cold water or hot water produced in the cold and hot water heater, and a blower for transferring the heat exchanged air; And
In the air-conditioning facility comprising an air transfer duct is formed at the end of the discharge port for discharging the heat exchanged air from the air conditioner to the room,
The heat is exchanged sufficiently in the heat exchanger so that the air supply temperature discharged to the discharge port is at least 2 ° C. or lower when cooled and at least 2 ° C. or higher when the air is cooled. Heating and cooling equipment, characterized in that the rotation speed is determined.
The cooling and heating equipment according to claim 7 or 8, wherein the discharge rate (V) of air at the discharge port is kept constant during operation of the cooling and heating equipment.
The air conditioning system according to claim 7 or 8, wherein the improvement of the air conditioning unit is made by adjusting a rotational speed of the blower.
The method of claim 7 or 8, wherein the blower is composed of a motor and a fan mechanically connected thereto, and the rotation speed of the blower is adjusted by replacing a pulley having a diameter different from each other on the rotation shaft of the motor and the fan. Heating and cooling equipment characterized by the above-mentioned.
The air conditioner according to claim 7 or 8, wherein the blower is installed at the front end and the rear end of the heat exchanger, and the rotation speed of the blower is applied only to the blower installed at the rear end of the heat exchanger. .
Water heaters for producing hot water for heating;
An air conditioner including a heat exchanger for exchanging heat between the hot water produced in the water heater and the air and a blower for transferring the heat-exchanged air; And
In the performance improvement method of the vinyl house heating facility comprising a duct is formed with a discharge port for discharging the heat exchanged air from the air conditioner into the vinyl house,
The heating device of the plastic house, characterized in that to reduce the blower speed of the heat exchanger so that the air temperature discharged from the heat exchanger and supplied to the duct discharge port can be supplied in a state at least 10 ℃ higher than the air supply temperature that is normally designed or operated How to improve performance.
Water heaters for producing hot water for heating;
An air conditioner including a heat exchanger for exchanging heat between the hot water produced in the water heater and the air and a blower for transferring the heat-exchanged air; And
In the method of improving the heating facility performance of a vinyl house comprising a duct is formed with a discharge port for discharging the air heat exchanged in the air conditioner into the vinyl house,
The rotational output of the blower in the air conditioner is a feed rate (V) of the air at the discharge port is made of 0.2 * H ≤ V ≤ 1.5 * H, if the feed speed is out of the maximum 6m / s, minimum 1.8m / s Vinyl house heating facility performance improvement method characterized in that for controlling the rotational output of the blower to be the maximum or minimum value.
(Where H is the height from the floor to the ceiling of the interior of the vinyl house where the outlet is installed, and the unit of calculated V is m / s.)
Water heaters for producing hot water for heating;
An air conditioner including a heat exchanger for exchanging heat between the hot water produced in the water heater and the air and a blower for transferring the heat-exchanged air; And
In a vinyl house heating facility comprising a duct is formed with a discharge port for discharging the air heat exchanged in the air conditioner into the vinyl house,
The heating device of the plastic house, characterized in that for reducing the blower speed of the heat exchanger so that the air temperature discharged from the heat exchanger and supplied to the duct discharge port can be supplied at least 10 ℃ higher than the air supply temperature that is normally designed or operated .
Water heaters for producing hot water for heating;
An air conditioner including a heat exchanger for exchanging heat between the hot water produced in the water heater and the air and a blower for transferring the heat-exchanged air; And
In the heating facility of the plastic house comprising a duct is formed for the discharge port for discharging the air heat exchanged in the air conditioner into the plastic house,
The rotational output of the blower in the air conditioner is a feed rate (V) of the air at the discharge port is made of 0.2 * H ≤ V ≤ 1.5 * H, if the feed speed is out of the maximum 6m / s, minimum 1.8m / s Vinyl house heating equipment characterized in that for controlling the rotational output of the blower to be the maximum or minimum value.
(Where H is the height from the floor to the ceiling of the interior of the vinyl house where the outlet is installed, and the unit of calculated V is m / s.)
The method according to claim 15 or 16,
The air discharge pipe is a heating facility of the plastic house, characterized in that a plurality of discharge ports are formed to be easily removed by the cutting line at regular intervals on the upper, lower, left and right sides.

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