KR102524281B1 - Up-and-down heating operation type fan coil cooling and heating system with refrigerant flow interlocking inverter turbofan - Google Patents

Abstract

The present invention provides a fan coil cooling and heating system with vertical air current heating operation having a refrigerant flow-linked inverter turbofan, which can reduce electric energy required for heating operation. The fan coil cooling and heating system with vertical air current heating operation having a refrigerant flow-linked inverter turbofan comprises: a fan coil unit driving an inverter turbofan to suck indoor air to perform cooling and heating operation while circulating the indoor air indoors after the indoor air passes through a heat exchanger; a supply flow path supplying a refrigerant or flow to the heat exchanger, and having a supply water temperature sensor; a discharge flow path circulating the refrigerant discharged from the heat exchanger, and having a return water temperature sensor and a return water valve; an inverter pump installed on the supply flow path to adjust a supply amount of flow and a refrigerant amount supplied to the fan coil unit; and a control part calculating the temperature difference between the supply water temperature and the return water temperature of the refrigerant and flow in accordance with temperature data transmitted from the supply water temperature sensor and the return water temperature sensor, transmitting a driving signal to the return water valve and the inverter pump in accordance with the calculated temperature difference between the supply water temperature and the return water temperature to adjust the refrigerant supply flow, calculating the temperature difference between a target temperature and the indoor temperature when the cooling and heating operation is started, and transmitting a driving signal to the inverter turbofan to adjust an air volume.

Description

Up-and-down heating operation type fan coil cooling and heating system with refrigerant flow interlocking inverter turbofan}

The present invention relates to a fan coil cooling and heating system having a refrigerant or flow rate-linked inverter turbo fan, and more particularly, a difference between a refrigerant or flow rate supply water temperature and a return water temperature after a cooling and heating operation is started. It detects and controls the supply of refrigerant or flow rate according to the temperature difference, and effectively supplies the refrigerant and flow rate according to the change in the load amount according to the temperature difference between the supply water temperature and the return water temperature. By controlling the fan, the indoor temperature can be quickly reached to the target temperature, and when the load is small, the refrigerant supply flow rate and the inverter turbo fan can be controlled to prevent excessive consumption of heating and cooling energy and electric energy. During operation, when there is a difference between the upper temperature and the lower temperature inside the room, air flow operation starts and the high-temperature air flow from the upper part is circulated to the lower floor. It shortens the heating operation time and saves heating energy and electric energy.

It relates to a fan coil air-conditioning system having a refrigerant and a flow rate-linked inverter turbo fan.

In general, a fan coil unit system equipped with a fan coil unit (FCU) is installed and used to lower or increase the temperature inside a building.

Specifically, when cooling the inside of a building, cold water is sent to the coil inside the fan coil unit to cool the air, and the fan rotates to circulate the cooled air to lower the temperature. When heating the inside of the building, hot water is sent to the coil to cool the air. The temperature is raised by heating and turning the fan to circulate the heated air.

The fan coil unit is disclosed in, for example, Korean Utility Model Registration No. 312184, and its configuration is a heat exchanger (coil unit) provided between a casing constituting an external enclosure, a frame inside the casing to exchange heat with indoor air, It includes an inverter turbo fan provided on the lower side of the heat exchanger to suck in external air and then blows it upward, and a fan panel fixed to the frame on the upper side of the inverter turbo fan so that the inverter turbo fan can be attached to the heat exchanger. In order to receive condensate generated during heat exchange from the fan panel and discharge it to the outside, a drain groove formed in a long horizontal direction on one side of the fan panel, a discharge hole formed on one or both sides of the drain groove, and a drain hole formed on one or both sides of the fan panel It includes a drain member provided with a discharge portion formed on the lower surface and a discharge hose connected to the discharge portion below the drain member.

Conventionally, an ON/OFF valve, which is a valve that only opens/closes, is used to control the amount of cold and hot water flowing through the fan coil, and the supply of cold and hot water for cooling or heating supplied by household or zone is turned on/off. Cooling and heating were performed using the OFF valve.

Since the ON/OFF valve is cheaper than the variable complex constant flow valve used in the present invention, the valve is controlled only by a relay, and the construction of the valve is common compared to the variable complex constant flow valve, conventional FCUs are generally used. (Fan Coil Unit) A simple valve that only turns ON/OFF was used for the flow rate.

However, while the fan coil unit is operating, the ON/OFF valve continues to remain open 100%, resulting in unnecessary energy being wasted.

As the need to improve energy waste and reduce consumer spending on heating and cooling has emerged, a variable complex constant flow valve that controls the amount of valve opening has been introduced. ), it is possible to supply the required amount of hot and cold water for cooling or heating through fine control.

In the existing FCU board, there are limitations in installing a driving power transformer for variable complex valves on the PCB and difficulties in program development. The process of installing the drive power transformer for complex valves and the variable complex constant flow valve control device is difficult, requires a lot of fixed costs, and has difficulties in initial operation and maintenance.

Conventionally, as the variable complex constant flow valve control device is installed outside the FCU board, an AC 220 OUTLET must be installed separately, and a communication line must be connected between the FCU board and the variable complex constant flow valve control device.

This configuration causes additional installation process costs, and construction and operating costs are added by separately setting and installing the variable complex constant flow valve control device.

In addition, the conventional FCU control system causes a lot of inconvenience in terms of initial operation and maintenance.

First, in order to install a conventional FCU control system, it is necessary to construct an FCU board, construct a communication line, and conduct a trial run. There are separate communication line construction companies and commissioning companies that construct the lines.

Complex valve construction companies install variable complex constant flow valves on pipes and construct them with only the lines drawn out. When the variable complex constant flow valve is installed by the complex valve construction company, the line communication contractor installs the variable complex constant flow valve control device and connects the complex valve line and the FCU line.

In this way, when the variable complex constant flow valve is installed in the pipe and the variable complex constant flow valve control device is installed, the communication line is connected and the commissioning team conducts a test run of the FCU system.

However, if a variable complex constant flow valve-related problem occurs when the commissioning team conducts a commissioning test, it is very difficult to analyze the cause. of the control device

Whether it is a problem, an FCU controller problem, or a communication line wiring problem,

It's hard to figure out.

To explain in more detail the reason why it is difficult to find the cause and solve the problem related to the variable complex constant flow valve in the field, it is necessary to find the part where the problem occurred, but the line is complicated, so there is a limit to finding it with a tester.

In addition, since the place where the variable complex constant flow valve and the variable complex constant flow valve control device are installed is in the ceiling, it is difficult to find the location where the variable complex constant flow valve is installed because the space is narrow and dark.

In addition, when a problem occurs, there are several elements that can cause a problem, so if a problem occurs in multiple parts instead of one part, it is necessary to check each part one by one. Afterwards, if a defect occurs in the operating state, it is very difficult to find a solution, and since it is not possible to know which part the problem occurred, it is not even clear which company to contact, so it takes a lot of time to solve the problem.

If cooling or heating is not actually performed, the user first requests service to the FCU company. When an FCU company receives a service request for problem solving, the FCU company visits the FCU controller and inspects the FCU controller. If there is no problem with the FCU controller, it explains the contents to the customer and terminates the service.

Then, when the user requests service from the variable complex constant flow valve company again, the complex valve company visits and checks only the variable complex constant flow valve.

When the user receives service again to the communication company, the communication company visits the line and checks the line. If there is no problem with the line, it explains the contents to the consumer and terminates the service.

It is a reality that only consumers suffer from great inconvenience when checking the parts constituting the FCU system one by one in this state.

In order to solve the above problems, a delta temperature control valve device and a fan coil unit with a built-in transformer have been developed, and the fan coil unit according to the prior art uses room temperature information received from a temperature sensor to generate a variable complex constant flow valve. determine the rate of opening,

A fan coil drive unit that outputs an opening rate control signal corresponding to the opening rate with a voltage according to the set flow rate value, a power supply unit that supplies power to the fan coil drive unit with 220V AC power as an input, and an opening rate control signal from the fan coil driver An opening rate voltage generating unit that receives and outputs a valve opening rate voltage corresponding to the opening rate of the variable complex constant flow valve to control and output the set flow rate, and a variable complex that generates 24V AC voltage with 220V AC voltage as input Includes a constant flow transformer.

The background art of the present invention is Republic of Korea Utility Model Publication No. 20-2021-0001353 (published on June 17, 2021, title of design: control device for variable complex constant flow valve and fan coil inlet control device with built-in transformer) is disclosed in

The fan coil unit according to the prior art detects the room temperature and adjusts the opening rate of the flow control valve according to the room temperature to perform cooling and heating. When the opening rate of the flow control valve is low, the fan coil unit is driven more than necessary regardless of the user's target temperature, making it difficult to save electric energy.

In addition, in the fan coil unit according to the prior art, since most of the air passing through the heat exchanger is discharged to the upper side of the room, during the heating operation in winter, the indoor air does not circulate smoothly, and the temperature difference between the upper part and the lower part of the room There is a problem in that it is difficult to reduce electric energy required for heating operation as the fan coil unit is controlled to increase the temperature of the lower part of the room to the set temperature as it becomes remarkably large.

Therefore, there is a need to improve this.

The present invention detects the difference between the supply water temperature and return water temperature of the refrigerant after the cooling and heating operation is started, adjusts the refrigerant or supply flow rate according to the temperature difference (delta), and adjusts the load amount according to the temperature difference between the supply water temperature and return water temperature. The flow rate can be supplied, so when the load is higher than the set value, the refrigerant amount or supply flow rate and the inverter turbo fan can be controlled to quickly reach the indoor temperature to the target temperature. A refrigerant or a refrigerant that can prevent excessive consumption of electric energy by controlling and can reduce electric energy required for heating operation by controlling the temperature difference between the upper temperature and the lower temperature of the room within a set value during heating operation. It is an object of the present invention to provide a fan coil air conditioning system for up-and-down flow heating operation having a flow rate-linked inverter turbo fan.

The present invention includes a fan coil unit that drives an inverter turbo fan to suck in indoor air, pass it through a heat exchanger, and then circulate it into the room to perform cooling and heating operations; a supply passage supplying a refrigerant or flow rate to the heat exchanger and equipped with a water supply temperature sensor; a discharge passage for circulating the refrigerant or flow rate discharged from the heat exchanger and having a return water temperature sensor and a return valve; an inverter pump installed in the supply passage to adjust the supply amount of the refrigerant and the flow rate supplied to the fan coil unit; And according to the temperature data transmitted from the supply water temperature detection sensor and the return water temperature detection sensor, the temperature difference between the supply water temperature of the refrigerant or supply flow rate and the return water temperature is calculated, and the temperature difference (delta) between the calculated supply water temperature and the return water temperature is calculated. A drive signal is sent to the water return valve and the inverter pump to adjust the refrigerant or supply flow rate, and when the cooling/heating operation starts, the temperature difference between the target temperature and the room temperature is calculated, and the set temperature difference (delta) sends a drive signal to the inverter turbo fan. It is characterized in that it includes a control unit for transmitting and adjusting the amount of air flow.

It is characterized by calculating the temperature difference between the water supply temperature sensor and the return water temperature sensor, and supplying a certain amount of heat to the room by accurately adjusting the temperature difference by reducing or increasing the refrigerant or supply flow rate so that the set temperature difference (delta) can be precisely controlled.

In addition, the refrigerant or supply flow rate calculated by the controller of the present invention is determined by the supply heat amount calculated to be supplied to the heat exchanger, and the supply heat amount (Q) is, Q = A V ΔT A: cross-sectional area of the passage V: refrigerant supply speed ΔT: characterized in that it consists of a temperature difference (delta) between the target temperature and the room temperature.

In addition, in the present invention, when the temperature difference between the upper temperature and the lower temperature of the room is greater than a set value during heating operation, the fan coil unit discharges the air that has passed through the heat exchanger of the fan coil unit to the lower part of the room to the floor of the room. It is characterized in that it further comprises a diffuser damper installed to extend to the side.

In addition, the diffuser damper of the present invention is characterized in that a louver member for adjusting the blowing direction is provided.

In addition, the fan coil unit of the present invention is installed in each of a plurality of households, and the cooling and heating operation is performed by the refrigerant or flow rate supplied from the central control room, and a flow meter is installed in the discharge passage installed in each household. to be

In addition, it is characterized in that a fine dust sensor, a fine dust filter or a deodorizing filter is provided at the outlet of the fan coil unit of the present invention to remove fine dust contained in indoor air.

In addition, the inlet or outlet of the fan coil unit of the present invention is provided with a photoplasma generator, photocatalytic filter, UV-LED or volatility sensor to remove volatile substances contained in indoor air and remove microorganisms or fungi characterized by being

In the fan coil cooling and heating system having a refrigerant or flow rate-linked inverter turbo fan according to the present invention, when the cooling and heating operation starts, the cooling operation is performed through the temperature difference (delta) between the supply temperature of the refrigerant or flow rate and the return water temperature. Alternatively, calculate the amount of heat required for heating operation, determine the load amount based on the amount of heat required for operation, and adjust the refrigerant and flow rate supplied to the fan coil unit according to the amount of load. It is possible to supply the refrigerant and flow rate suitable for the load and adjust the driving amount of the inverter turbo fan to perform the cooling and heating operation according to the load, thereby reducing the electric energy required for the cooling and heating operation of the fan coil unit.

In addition, in the up-down flow heating operation type fan coil air conditioning system having a refrigerant or flow rate interlocked inverter turbo fan according to the present invention, when the temperature difference between the supply water temperature and the return water temperature is large after the cooling and heating operation is started, the supply amount of the refrigerant and the flow rate is reduced. It is possible to provide a comfortable indoor environment to the user by increasing the indoor temperature to reach the target temperature in a short time, and when the temperature difference between the supply temperature of the refrigerant or flow rate and the return temperature is relatively small, the refrigerant supply flow rate required for cooling and heating operation At the same time, there is an advantage in that it is possible to more effectively prevent electric energy required for heating and cooling operation from being consumed more than necessary by reducing the driving amount of the inverter turbo fan.

In addition, in the up-and-down flow heating operation type fan coil air conditioning system having a refrigerant or flow rate-linked inverter turbo fan according to the present invention, when the temperature difference (delta difference) between the upper temperature and the lower temperature of the room during heating operation is greater than a set value A diffuser damper extending from the fan coil unit to the indoor floor is provided so that the air passing through the heat exchanger is discharged to the indoor floor, so if the temperature difference between the upper and lower temperatures of the room measured by the room temperature sensor is greater than the set value, the control unit transmits The outlet of the fan coil unit is closed according to the driving signal, and the air passing through the heat exchanger is discharged to the indoor floor through the diffuser damper, raising the temperature of the lower part of the room and heating the entire room evenly. As the indoor temperature rises as a whole, there is an advantage in that electric energy can be remarkably reduced by reducing the heating energy and operation time required for heating operation.

1 is a configuration diagram showing a fan coil air-conditioning system for up-and-down flow heating operation having a refrigerant or flow rate-linked inverter turbo fan according to an embodiment of the present invention.
2 is a cross-sectional view showing a fan coil unit of a vertical flow heating operation type fan coil air conditioning system having a refrigerant or flow rate-linked inverter turbo fan according to an embodiment of the present invention.
3 is a cross-sectional view showing a fan coil unit of a vertical flow heating operation type fan coil air conditioning system having a refrigerant or flow rate-linked inverter turbo fan according to another embodiment of the present invention.
4 is a cross-sectional view showing a diffuser damper of a fan coil unit of a vertical flow heating operation type fan coil air conditioning system having a refrigerant or flow rate interlocked inverter turbo fan according to another embodiment of the present invention.
FIG. 5 is a view showing insertion of a delta valve into a fan coil unit and main board control of a fan coil air-conditioning system having an up-and-down flow heating operation type having a refrigerant or flow rate-linked inverter turbo fan according to another embodiment of the present invention.

Hereinafter, an embodiment of a vertical flow heating operation type fan coil air conditioning system having a refrigerant or flow rate-linked inverter turbo fan according to the present invention will be described with reference to the accompanying drawings.

In this process, the thickness of lines or the size of components shown in the drawings may be exaggerated for clarity and convenience of explanation.

In addition, the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of a user or operator.

Therefore, definitions of these terms will have to be made based on the content throughout this specification.

1 is a configuration diagram showing a fan coil air conditioning system for up-and-down flow heating operation having a refrigerant or interlocking type inverter turbo fan according to an embodiment of the present invention, and FIG. A cross-sectional view of a fan coil unit of an up-and-down flow heating operation type fan coil air conditioning system having a flow rate-linked inverter turbo fan.

In addition, FIG. 3 is a cross-sectional view showing a fan coil unit of a vertical flow heating operation type fan coil air conditioning system having a refrigerant or flow rate-linked inverter turbo fan according to another embodiment of the present invention, and FIG. 4 is another cross-sectional view of the present invention. A diffuser damper of a fan coil unit of an up-and-down flow heating operation type fan coil air conditioning system having a refrigerant or a flow-linked inverter turbo fan according to an embodiment is shown, and FIG. It is a drawing showing a delta valve insertion and main board control in a fan coil unit of an up-and-down flow heating operation type fan coil cooling/heating system having a flow rate-linked inverter turbo fan.

Referring to FIGS. 1 to 5, an up-down flow heating operation type fan coil air conditioning system having a refrigerant or flow rate-linked inverter turbo fan according to an embodiment of the present invention drives an inverter turbo fan 12 to clean indoor air. refrigerant is supplied to the fan coil unit 10 and the heat exchanger 14, which perform cooling and heating operations while circulating the air through the heat exchanger 14 and circulating it into the room, and a water supply temperature sensor 50 is provided. The supply passage 30 and the refrigerant discharged from the heat exchanger 14 are circulated, and the discharge passage 40 provided with the return water temperature sensor 60 and the return valve 90 and the fan coil unit 10 According to the temperature data transmitted from the inverter pump 104 installed in the supply passage 30 to adjust the supply amount of the refrigerant, the water supply temperature sensor 50, and the return water temperature sensor 60, the supply temperature of the refrigerant and The temperature difference between the returned water temperature is calculated, and a drive signal is sent to the return valve 90 and the inverter pump 104 according to the calculated temperature difference between the supplied water temperature and the returned water temperature to adjust the refrigerant supply flow rate, and when the cooling/heating operation starts, the target temperature and a control unit 17 that calculates a temperature difference between the indoor temperature and the indoor temperature, and transmits a drive signal to the inverter turbo fan 12 to adjust the airflow amount.

Therefore, the temperature signal measured from the water supply temperature sensor 50 and the temperature signal measured from the water return temperature sensor 60 are transmitted to the control unit 17, and the heat exchanger 14 ), and the inverter pump 104 and the return valve 90 according to the drive signal transmitted from the control unit 17 to provide the target heat amount determined by the formula described in Equation 1 to be described later. It is driven and the supply of refrigerant to provide the amount of heat required by the heat exchanger 14 is made.

As described above, the refrigerant is supplied to the heat exchanger 14 of the fan coil unit 10

In this state, when the inverter turbo fan 12 provided in the fan coil unit 10 is driven, the indoor air introduced along the inlet 10a of the fan coil unit 10 passes through the heat exchanger 14 and absorbs or absorbs heat. After being discharged, it is circulated into the room through the discharge port 10b, and a heating or cooling operation is performed.

In addition, the control unit 17 according to the present embodiment controls the driving amount of the inverter turbo fan 12 according to the refrigerant supplied to the heat exchanger 14 or the supply flow rate to control the amount of air supplied to the heat exchanger 14 while performing a cooling/heating operation. It is possible to prevent the electrical energy required for the above from being consumed more than necessary.

For example, when the driving amount of the inverter pump 104 increases and the opening amount of the return valve 90 increases and the refrigerant supply flow rate increases, the driving amount of the inverter turbo fan 12 is increased and supplied to the heat exchanger 14. The heat exchange efficiency between the refrigerant supplied to the heat exchanger 14 and the indoor air is improved while increasing the amount of blown air.

In addition, when the refrigerant and the supply flow rate are reduced, the driving amount of the inverter turbo fan (12) is reduced to prevent more indoor air from being supplied to the heat exchanger (14), thereby preventing electrical energy from being consumed more than necessary. be able to

Here, the refrigerant or supply flow rate calculated by the controller 17 of the present embodiment is determined by the amount of heat supplied calculated to be supplied to the heat exchanger 14, and the amount of heat supplied (Q) is determined by the calculation formula described in Equation 1 do.

[Equation 1]

Q = A V △T

Here, A in Equation 1 is the cross-sectional area of the passage, V is the supply speed of the refrigerant, and ΔT is

It means the temperature difference (delta) between the target temperature and the room temperature.

In addition, in the fan coil unit of another embodiment of the present invention, as shown in FIGS. 3 and 4 , when the temperature difference between the upper temperature and the lower temperature of the room is greater than a set value during heating operation, the heat exchanger of the fan coil unit 10 A diffuser damper 100 extending from the fan coil unit 10 to the floor of the room is further included to discharge the air passing through 14 to the lower part of the room.

Therefore, when heating operation is in progress during the winter season, the temperature sensor installed inside the room measures the temperature at the top and bottom of the room. The first louver member 101 installed at the discharge port 10b of (10) is driven to close the discharge port 10b, and the diffuser damper 100 extending from the cabinet constituting the fan coil unit 10 to the indoor floor side Indoor air that has been opened and passed through the heat exchanger 14 is directly injected toward the indoor floor, thereby effectively increasing the temperature of the lower part of the indoor space and evenly increasing the temperature of the entire indoor space.

As described above, when the warm air is directly injected toward the indoor floor, the temperature of the lower part of the indoor air rises, and the high-temperature air rises to the upper indoor air due to the cooling effect of the indoor air, and the temperature of the entire indoor air evenly rises, enabling effective heating operation. be able to proceed.

In addition, since the diffuser damper 100 of this embodiment is provided with the second louver member 102 for adjusting the blowing direction, the discharge direction can be adjusted so that the warm air discharged toward the indoor floor does not come into direct contact with the user's body.

A plurality of second louver members 102 of this embodiment are installed so that the plurality of second louver members 102 can be rotated individually, dispersing the discharge direction of the air discharged through the diffuser damper 100 in both directions and can eject it.

In addition, the fan coil unit 10 of this embodiment is installed in each of a plurality of households, and the cooling and heating operation is performed by the refrigerant supplied from the central control room or the supplied flow rate, and the discharge passage 40 installed in each household has a flow meter. 70 is installed to measure the refrigerant and the supply flow rate that vary according to the opening amount of the return valve 90, and the flow rate of the refrigerant measured by the flow meter 70 is fed back to the control unit 17 so that the return valve 90 ) can be precisely controlled.

In addition, in the discharge port 10b of the fan coil unit 10 of this embodiment, a first filtering unit 106 composed of a fine dust sensor, a fine dust filter or a deodorizing filter to remove fine dust contained in indoor air Since it is provided, it is possible to keep the indoor air pleasant by collecting fine dust and odor particles included in the indoor air.

In addition, the inlet 10a of the fan coil unit 10 of this embodiment has a photoplasma generator, photocatalytic filter, UV-LED or volatility detection to remove volatile substances contained in indoor air and remove microorganisms or fungi. A second filtering unit 108 made of a sensor is provided, and since the second filtering unit 108 may be provided in the discharge port 10b of this embodiment, volatile substances, microorganisms or fungi contained in the indoor air can be removed. there will be

In this way, after the cooling/heating operation starts, the difference between the supply temperature of the refrigerant and the return temperature of the refrigerant is sensed, and the supply amount of the refrigerant and the flow rate are adjusted according to the temperature difference, and the refrigerant supply can be effectively supplied according to the load change according to the temperature difference between the supply water temperature and the return water temperature. When the load is greater than the set value, the refrigerant quantity or supply flow rate and the inverter turbo fan are controlled to quickly reach the indoor temperature to the target temperature. Inverter turbo fan linked to refrigerant flow that can prevent electric energy from being consumed, and can reduce electric energy required for heating operation by adjusting the temperature difference between the upper and lower temperature inside the room to within the set value during heating operation. It is possible to provide an up-and-down flow heating operation type fan coil air conditioning system having a.

Although the present invention has been described with reference to an embodiment shown in the drawings, this is merely exemplary, and those skilled in the art can make various modifications and equivalent other embodiments therefrom. will understand

In addition, although a fan coil cooling and heating system equipped with a refrigerant or flow rate-linked inverter turbo fan has been described as an example, this is only an example, and a vertical flow heating operation type having a refrigerant flow-linked inverter turbo fan. The fan coil cooling and heating system of the present invention can be used for other products other than the fan coil cooling and heating system.

Therefore, the true technical protection scope of the present invention should be determined by the claims below.

10: fan coil unit 12: inverter turbo fan
14: heat exchanger 17: control unit
18: controller 30: supply passage
40: discharge flow path 50: water supply temperature sensor
60: water return temperature sensor 70: flow meter
90: return valve 101: first louver member
102: second louver member 104: inverter pump

Claims (7)

A fan coil unit that drives an inverter turbo fan to suck indoor air, pass it through a heat exchanger, and then circulate it to the room to perform cooling and heating operations;
a supply passage supplying a refrigerant or a flow rate to the heat exchanger and equipped with a water supply temperature sensor;
a discharge passage for circulating the refrigerant or flow rate discharged from the heat exchanger and having a return water temperature sensor and a return valve;
an inverter pump installed in the supply passage to adjust the supply amount of the refrigerant and flow rate supplied to the fan coil unit; and
The temperature difference (delta) between the supply water temperature of the refrigerant and the return water temperature is calculated according to the temperature data transmitted from the water supply temperature sensor and the return water temperature sensor, and the return valve and the A control unit that transmits a drive signal to the inverter pump to adjust the amount of refrigerant or supply flow, calculates the temperature difference between the target temperature and the room temperature when heating and cooling operation starts, and transmits a drive signal to the inverter turbo fan to adjust the air flow rate ,
When the temperature difference (delta) between the upper temperature and the lower temperature of the room during heating operation is more than a set value, the fan coil unit extends from the fan coil unit to the floor side of the room to discharge the air that has passed through the heat exchanger to the lower part of the room. Further comprising a diffuser damper installed to be,
When heating operation is in progress in the winter, the upper and lower temperatures of the room are measured by a temperature sensor installed in the room, and when the temperature difference between the upper and lower temperatures of the room becomes greater than the set value, the fan coil unit The diffuser damper ( 100) is opened, and the indoor air that has passed through the heat exchanger 14 is directly injected toward the indoor floor, thereby increasing the temperature of the lower part of the indoor space and evenly increasing the temperature of the entire indoor space. Up and down flow heating operation type fan coil air conditioning system having an inverter turbo fan.
According to claim 1,
The refrigerant or supply flow rate calculated by the controller is determined by the amount of heat supplied calculated to be supplied to the heat exchanger,
The heat supply (Q) is,
Q = A V △T
A: cross-sectional area of flow path
V: supply speed of refrigerant
△T: temperature difference between target temperature and room temperature
Up and down flow heating operation type fan coil air conditioning system having a refrigerant or flow rate-linked inverter turbo fan, characterized in that consisting of.
delete delete According to claim 1,
The fan coil unit is installed in each of a plurality of households, and the cooling and heating operation is performed by the refrigerant and the flow rate supplied from the central control room, and the refrigerant or flow rate, characterized in that the flow meter is installed in the discharge passage installed in each household Up-and-down flow heating operation type fan coil air conditioning system having an interlocking type inverter turbo fan.
According to claim 1,
A refrigerant or flow-linked inverter turbo fan, characterized in that a fine dust sensor, a fine dust filter or a deodorizing filter is provided in the discharge port of the fan coil unit to remove fine dust contained in the indoor air Up and down flow heating operation type fan coil air conditioning system.
According to claim 1,
A photoplasma generator, a photocatalyst filter, or a volatility sensor is provided at the inlet or the outlet of the fan coil unit to remove volatile substances contained in the indoor air and to remove microorganisms or fungi. Refrigerant or flow rate, characterized in that Up and down flow heating operation type fan coil cooling and heating system having an interlocking type inverter turbo fan.

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