KR102602290B1 - A convergence system consisting of a ventilation system and an air conditioner - Google Patents

Abstract

The present invention discloses a fusion system in which a ventilation device and an EHP (Electric Heat Pump) system air conditioner are fused together. The present invention can save energy by recirculating indoor air that is discarded to the outside air during ventilation operation to the outdoor unit of the EHP system air conditioner, and comparing the amount of heat discarded through indoor air with the COP performance coefficient of the complex ventilation device to perform forced ventilation operation. By implementing this, an energy saving effect is achieved.

Description

A convergence system consisting of a ventilation system and an air conditioner}

The present invention relates to a technology for saving energy by fusing a ventilation device and an EHP (Electric Heat Pump) system air conditioner. More specifically, the indoor air that is discarded to the outside during ventilation operation is recirculated to the outdoor unit of the EHP system air conditioner to save energy. It is about a convergence system consisting of a ventilation device and an air conditioner that saves energy.

Recently, as interest in quality of life has increased, interest in indoor air quality, where most of the time is spent during work, has also increased. The Ministry of Environment has enacted the Indoor Air Quality Management Act for multi-use facilities, etc. and presented indoor air quality standards. Installation of ventilation equipment is mandatory as a way to maintain air quality, so multi-use facilities must also be provided with the required amount of ventilation according to their use.

Polluted indoor air can be said to be the main culprit in harming health. Moreover, since pollutants are constantly generated due to living indoors most of the time, and indoor polluted air can harm one's health, ventilation facilities to improve indoor air quality are urgently needed.

In particular, recently newly built buildings have excellent airtightness, which can reduce heat loss by about 30 to 40%, but the natural ventilation rate is decreasing. Therefore, these buildings require ventilation devices that supply fresh air from the outside and exhaust the polluted air inside to the outside.

However, in general, ventilation reduces the cooling and heating effect, but if ventilation is not done, indoor air becomes polluted, so ventilation is unavoidable. When ventilation is done, the indoor temperature is lost to the outside air, causing sudden temperature changes that make you feel cold or hot, making you feel uncomfortable. At the same time, the load on the air conditioner increases, causing excessive loss of valuable energy. This causes a temperature difference between indoor air and outdoor air. It circulates the air to supply fresh outdoor air indoors and purifies indoor air by discharging indoor polluted air to the outdoors.

In air conditioners, air source heat pumps have the disadvantage that production and performance decrease rapidly when the outside temperature drops in the winter. Generally, when the outside temperature is below 5℃, condensation occurs in the condenser (outdoor unit), and if operation continues, condensation occurs. Freezing (implantation) phenomenon occurs. Therefore, the air source heat pump requires a defrost operation to remove frost when operating in the winter, and not only is it unable to supply heating during this time, but it also consumes unnecessary power for the defrost operation. To solve this shortcoming, when the outside temperature is below a certain temperature, the heating operation of the heat pump is stopped and heating heat is supplied using the electric heater attached to the indoor unit. At this time, excessive energy costs due to the use of additional heating devices such as heaters are incurred. There are problems that arise.

In particular, as energy prices are rising day by day in recent years, efficient energy use is required to protect natural resources and preserve a clean environment. In addition, technology linking heating, cooling and ventilation devices is being developed to reduce the energy consumption of ventilation and air conditioning devices as much as possible and use them efficiently. However, while simultaneously performing the combined functions of heating and cooling, ventilation and air purification, it is possible to adjust the outdoor and indoor temperature usage conditions according to each season. An optimal ventilation/cooling/heating device that can operate efficiently has not yet been developed.

The purpose of the present invention is to provide a convergence system consisting of a ventilation device and an air conditioner that can save energy by recirculating indoor air, which is discarded to the outside air during ventilation operation, to the condenser of the EHP system air conditioner.

Another object of the present invention is to provide a convergence system consisting of a ventilation device and an air conditioner that can perform cooling/heating or ventilation operation by monitoring indoor humidity and temperature, air quality, and temperature difference between the temperature of the ceiling and the floor, etc. I'm doing it.

A fusion system consisting of a ventilation device and an air conditioner according to the present invention to achieve the above object includes a complex ventilation device that performs a cooling and heating operation using an evaporator and performs an indoor ventilation operation using an air supply fan and an exhaust fan; A condenser connected to the condenser through a refrigerant pipe; and an exhaust duct that supplies indoor air discarded while the complex ventilation device performs a cooling or heating operation to the condenser, thereby reducing energy consumption in the condenser.

In addition, the condenser is installed integrally with the complex ventilation device.

Additionally, a sensor unit including one or more of an air quality sensor, a temperature sensor, a humidity sensor, a ceiling temperature sensor, and a floor temperature sensor; and a control unit that controls the operation of the combined ventilation device and the condenser according to the detection results of the sensor unit.

In addition, the control unit compares the heat content of indoor air discarded from the combined ventilation device while performing a cooling operation or heating operation with the COP performance coefficient of the combined ventilation device, and determines the amount of heat obtained by supplying indoor air to the condenser to the indoor air. When it is determined that the amount of heat discarded through the air is greater than that, forced ventilation operation is performed.

In addition, during the cooling/heating operation, the control unit compares the indoor temperature measured through the temperature sensor and the indoor humidity measured through the humidity sensor with the outdoor temperature and humidity to start the cooling/heating operation by introducing outside air, but when the inflow of outside air is If it is judged to be more unfavorable, it is characterized by starting cooling and heating operation while blocking the inflow of external air.

In addition, the control unit compares the temperature around the indoor ceiling detected through the ceiling temperature sensor with the temperature around the indoor floor surface detected through the floor temperature sensor, and when the difference exceeds a certain value, drives the diffuser blower fan. It is characterized by carrying out air flow operation.

In addition, the control unit measures indoor air quality through the air quality sensor and performs an indoor air purification operation or ventilation operation when the sensed air quality exceeds a preset standard value.

In addition, the air quality sensor detects one or more of fine dust, carbon monoxide, carbon dioxide, nitrogen, and radon and purifies the detected substances.

The fusion system consisting of a ventilation device and an air conditioner according to the present invention has the following effects.

First, there is an effect of saving energy by recirculating indoor air, which is discarded as outdoor air during ventilation operation, to the condenser.

Second, by eliminating the difference between the upper and lower indoor temperatures through airflow operation, the indoor temperature can be maintained evenly, which has the effect of improving energy efficiency.

Third, energy savings can be achieved by comparing the amount of heat discarded through indoor air and the COP performance coefficient of the combined ventilation device and performing forced ventilation operation.

Fourth, by comparing the indoor temperature measured through the temperature sensor and the indoor humidity measured through the humidity sensor with the outdoor temperature and humidity, if it is judged that the cooling and heating operation with outside air is more disadvantageous, the inflow of outside air is blocked. It has the preventive effect of preventing unnecessary inflow of air.

Figure 1 is an overall schematic diagram of a fusion system consisting of a ventilation device and an air conditioner according to an embodiment of the present invention.
Figures 2 (a) and (b) are exemplary diagrams of an outdoor unit.
Figure 3 is a detailed block diagram of the main controller.

Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings. First, it should be noted that when adding reference numerals to components in each drawing, the same components are given the same reference numerals as much as possible even if they are shown in different drawings. Additionally, in describing the present invention, if a detailed description of a related known configuration or function is determined to be obvious to those skilled in the art or may obscure the gist of the present invention, the detailed description will be omitted.

Figure 1 is an overall schematic diagram of a fusion system consisting of a ventilation device and an air conditioner according to an embodiment of the present invention, Figures 2 (a) and (b) are exemplary diagrams of the outdoor unit, and Figure 3 is a detailed block of the main controller. It's a degree.

Referring to Figure 1, the fusion system consisting of a ventilation device and an air conditioner according to the present invention includes a complex ventilation device 100, a plurality of air supply devices 140, a plurality of ventilation devices 150, a main controller 160, and an exhaust system. Includes a duct 220 and a condenser 300.

The complex ventilation device 100 includes an evaporator 110, a total heat exchanger 120, a pre-filter 131, a HEPA filter 132, an air supply fan (FAN1), and an exhaust fan (FAN2).

The evaporator 110, which is a heat exchanger, performs cooling and heating operations under the control of the main controller 160. The evaporator 110 may be connected to the condenser 300 and the refrigerant pipe 210. The condenser 300 may be installed integrally with the complex ventilation device 100, or may be installed separately.

Figures 2 (a) and (b) show an example of installation of the condenser 300. That is, Figure 2 (a) shows an example in which the condenser 300 is installed separately from the complex ventilation device 100. In this case, the condenser 300 is included in the outdoor unit, and is connected to the evaporator through the refrigerant pipe 210. It can be connected to (110). Figure 2 (b) shows an example in which the condenser 300 is installed integrally with the complex ventilation device 100. In this case, it can be directly connected to the evaporator 110.

The evaporator 110 and condenser 300 can perform cooling or heating operation under the control of the main controller 160.

In the cooling operation mode, the refrigerant is compressed by a compressor (not shown in the drawing), and in the condenser 300, the high-temperature, high-pressure gas meets air sucked in from the outside and cools down to become a liquid, at which time heat is released. The high-temperature, high-pressure liquid passing through the condenser 300 is changed into a low-temperature, low-pressure liquid through an expansion valve (not shown in the drawing). The low-temperature, low-pressure liquid generated in this way evaporates through the evaporator 110 and absorbs surrounding heat, causing the surrounding temperature to cool. The cold air thus generated is supplied to the air supply fan (FAN1) and a plurality of air supply devices installed on the ceiling ( 140) is supplied indoors.

In the heating operation mode, the condenser 300 and the evaporator 110 operate in the opposite manner to those in the cooling operation mode. At this time, the condensed refrigerant radiates heat as it passes through the evaporator 110, and the warm air generated by this is supplied into the room through the air supply fan (FAN1) and a plurality of air supply devices 140 installed on the ceiling.

In the ventilation operation mode, the control unit 162 of the main controller 160 opens the damper of the exhaust duct 220 and drives the exhaust fan (FAN2). Accordingly, indoor air is supplied to the condenser 300 through the exhaust duct 220.

There may be two types of indoor air supplied to the condenser 300 through the exhaust duct 220. First, as an example, in the cooling operation mode, cold indoor air may be supplied to the condenser 300 through the exhaust duct 220. As another example, in the heating operation mode, warm indoor air may be supplied to the condenser 300 through the exhaust duct 220. The energy efficiency of the condenser 300 is improved by supplying indoor air in this way.

For example, in the cooling operation mode, the temperature around the outdoor condenser 300 is 35 degrees, and the temperature of the indoor air discharged from the exhaust fan (FAN2) may be much lower than 35 degrees (e.g., 30 degrees). there is. Accordingly, the surrounding temperature can be lowered to about 30 degrees without using additional energy in the condenser 300. Accordingly, the energy efficiency of the condenser 300 is improved.

As another example, in the heating operation mode, the ambient temperature of the outdoor condenser 300 is -15 degrees, and the temperature of the indoor air discharged from the exhaust fan (FAN2) is much higher than -15 degrees (e.g., 18 degrees). It can be. Accordingly, the surrounding temperature can be increased to about 18 degrees without using additional energy in the condenser 300. Accordingly, the energy efficiency of the condenser 300 is improved.

The forced ventilation operation mode can be performed according to the determination result of the COP (Coefficient Of Performance) performance coefficient in the main controller 160 even if ventilation operation is not necessary. For example, the control unit 162 of the main controller 160 compares the amount of heat discarded through indoor air with the COP performance coefficient of the complex ventilation device 100, and performs a cooling or heating operation to control indoor air as described above. When it is determined that the amount of heat obtained by supplying to the condenser 300 is greater than the amount of heat discarded through indoor air, the indoor air discarded as above can be supplied to the condenser 300 while forcibly performing a cooling or heating operation. .

The control unit 162 of the main controller 160 compares the indoor temperature measured through the temperature sensor 161B and the indoor humidity measured through the humidity sensor 161C with the outdoor temperature and humidity to allow more outside air to be introduced. If it is deemed unfavorable, do not allow outside air (OA) into the room. The reason for doing this is to prevent the adverse effect of the indoor air being raised by the outside air when outside air is introduced without detecting latent heat during cooling operation during the summer rainy season.

The control unit 162 of the main controller 160 compares the temperature around the indoor ceiling detected through the ceiling temperature sensor 161D with the temperature around the indoor floor detected through the floor temperature sensor 161E, and the difference is greater than a certain value. When flying, the diffuser blower fan is driven to perform airflow operation.

Accordingly, air stagnation due to convection phenomenon is resolved and driving time can be reduced. In particular, during heating operation in the winter, high-temperature indoor air stagnates in the upper part due to convection, making it difficult to heat the lower part. However, by performing indoor airflow operation as described above, operation efficiency is maximized and heating maintenance costs can be reduced.

The control unit 162 of the main controller 160 measures indoor air quality through the air quality sensor 161A of the sensor unit 161, and can perform cooling or heating operation or ventilation operation when the sensed air quality exceeds a preset standard value. there is. Here, the air quality sensor 161A can measure one or more of fine dust, carbon monoxide, carbon dioxide, nitrogen, and radon.

Although the preferred embodiments have been described and illustrated above to illustrate the technical idea of the present invention, the present invention is not limited to the configuration and operation as shown and described, and does not depart from the scope of the technical idea. Those skilled in the art will appreciate that many changes and modifications are possible to the present invention. Accordingly, all such appropriate changes, modifications and equivalents shall be considered to fall within the scope of the present invention.

100: Complex ventilation device 110: Evaporator
120: total heat exchanger 131: pre-filter
132: HEPA filter 140: Air supply device
150: recovery device 160: main controller
161A: Air quality sensor 161B: Temperature sensor
161C: Humidity sensor 161D: Ceiling temperature sensor
161E: Floor temperature sensor 162: Control unit
210: Refrigerant piping 220: Exhaust duct
300: Condenser

Claims (8)

A complex ventilation device equipped with an evaporator to perform cooling and heating operation, and indoor ventilation operation using an air supply fan and an exhaust fan;
A condenser connected to the evaporator through a refrigerant pipe;
an exhaust duct that supplies indoor air discarded while the complex ventilation device performs a cooling or heating operation to the condenser to reduce energy consumption in the condenser; and
A main controller consisting of a sensor unit equipped with one or more of an air quality sensor, a temperature sensor, a humidity sensor, a ceiling temperature sensor, and a floor temperature sensor, and a control unit that controls the operation of the complex ventilation device and the condenser according to the detection results of the sensor unit. Contains,
The control unit
By comparing the amount of heat in indoor air discarded from the combined ventilation device during cooling or heating operation and the COP performance coefficient of the combined ventilation device, the amount of heat obtained by supplying indoor air to the condenser is discarded through the indoor air. A fusion system consisting of a ventilation device and an air conditioner, characterized in that forced ventilation operation is performed when it is determined that the heat quantity is greater than the heat quantity. According to paragraph 1,
The condenser is characterized in that it is installed integrally with the complex ventilation device.
A fusion system consisting of ventilation and air conditioning. delete delete According to paragraph 1,
During the cooling/heating operation, the control unit compares the indoor temperature measured through the temperature sensor and the indoor humidity measured through the humidity sensor with the outdoor temperature and humidity to start the cooling/heating operation by introducing outside air, but the inflow of outside air is more disadvantageous. A fusion system consisting of a ventilation device and an air conditioner that starts cooling and heating operation while blocking the inflow of external air when it is determined that it is. According to paragraph 1,
The control unit compares the temperature around the indoor ceiling detected through the ceiling temperature sensor with the temperature around the indoor floor detected through the floor temperature sensor, and when the difference exceeds a certain value, operates the diffuser blower fan to operate the airflow. A fusion system consisting of a ventilation device and an air conditioner, characterized in that. According to paragraph 1,
The control unit measures indoor air quality through the air quality sensor and performs cooling/heating or ventilation operation when the sensed air quality exceeds a preset standard value. A fusion system consisting of a ventilation device and an air conditioner. In clause 7,
The air quality sensor is a fusion system consisting of a ventilation device and an air conditioner, characterized in that it detects one or more of fine dust, carbon monoxide, carbon dioxide, nitrogen, and radon and purifies the detected substances.

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