KR20200108815A - Hybrid cooling system and method for preventing dew condensation - Google Patents

Abstract

The present invention relates to a condensation prevention complex cooling system and a complex cooling method, in which a ventilation device and a dehumidifying device can be omitted, and radiant cooling and convective cooling are combined and operated indoors. To this end, the condensation prevention complex cooling system includes: a cooling unit that cools a cooling medium; a fan coil unit that performs convective cooling according to a movement of the cooling medium, including a fan coil and a blowing fan; a floor coil that performs radiant cooling according to the movement of the cooling medium; a supply passage that forms a path through which the cooling medium cooled in the cooling unit is supplied to at least one of the fan coil and the floor coil; a supply valve that selects whether to supply the cooling medium in the supply passage; a recovery passage that forms a path through which the cooling medium that has passed through at least one of the fan coil and the floor coil is recovered to the cooling unit; an indoor temperature sensor that measures the indoor air temperature; a floor temperature sensor that measures the temperature of a surface on which the floor coil is installed; a humidity sensor that measures indoor water vapor or indoor humidity; and a control unit that calculates the condensation constant and the condensation point temperature based on the measured value of the indoor temperature sensor and the measured value of the humidity sensor, compares the condensation point temperature and the measured value of the floor temperature sensor, and controls the cooling unit, the supply valve, and the blowing fan so that the cooling medium is supplied to at least one of the fan coil and the floor coil.

Description

Hybrid cooling system and method for preventing condensation {HYBRID COOLING SYSTEM AND METHOD FOR PREVENTING DEW CONDENSATION}

The present invention relates to a complex cooling system for preventing condensation and a complex cooling method, and more specifically, a ventilation device and a dehumidifying device can be omitted, and a combined cooling system for preventing condensation for operating in combination with radiant cooling and convection cooling indoors It relates to the system and the combined cooling method.

With the recent rise in industry and living standards, everyone's interests and demands are gradually moving toward improving the quality of life. In order not only to emphasize financial economics, but also to protect health that cannot be converted into money and to improve the quality of life, many people yearn for a more comfortable and comfortable system. Unlike general convection cooling, radiant cooling has no discomfort caused by cold wind, so large companies also sell airless air conditioners developed by advocating radiant cooling.

Radiant heating and cooling is an energy supply method that can meet the above-described trends and demands, and is recognized as the most ideal energy supply system for the human body without a simple economical comparison, and is widely spread around the world.

For this reason, in Korea, which uses radiant heating, there is a great advantage that it can perform wet radiant cooling by using the radiant heating equipment as it is, and various institutions are developing and researching it. However, there are several problems to be solved in order to actually apply radiant cooling to general homes.

First, there is a problem of insufficient supply unit calories. In more detail, even if both the ceiling and the floor are equipped with radiant cooling facilities and cold water is supplied, the maximum cooling load that can be supplied per unit area is insufficient, so it is difficult to handle the required load by radiant cooling alone.

Second, there is a problem that the load response time is delayed. In more detail, radiant cooling takes a relatively long time to cool because the air is cooled by radiation after the ceiling or floor is cooled, unlike convection cooling that supplies cool air by rapid cooling operation.

Third, there is a problem that condensation occurs on the ceiling or the floor. In more detail, condensation can be said to be the biggest problem in radiant cooling. In particular, in Korea, when the cooling water is circulated from the ceiling or the floor due to the hot and humid summer weather, the problem of condensation on the surface is inevitable. In particular, in the case of circulating coolant with a low temperature of less than 10 degrees to solve the first or second problem, it is very difficult to solve the condensation problem, and even if the coolant is circulated at about 15 degrees, the condensation problem still occurs. Ventilation and dehumidification devices must be installed in order to build a radiant cooling system. However, in installing various sensors, ventilation devices, and dehumidifying devices for radiant cooling in ordinary houses or apartments, it is difficult to apply them to ordinary houses due to high facility costs even if there is insufficient space and installation space. .

Korean Registered Patent Publication No. 10-0510774 (Name of invention: Combined dehumidification cooling system, 2005. 08. 30. Announcement)

An object of the present invention is to solve the problems of the prior art, and a ventilation device and a dehumidifying device can be omitted, and a combined cooling system for preventing condensation and a combined cooling method for operating in combination with radiant cooling and convective cooling indoors. In the offering.

According to a preferred embodiment for achieving the object of the present invention described above, the condensation prevention complex cooling system according to the present invention comprises: a cooling unit for cooling a cooling medium for cooling indoors; A fan coil unit configured to perform convective cooling according to the movement of the cooling medium, including a fan coil forming a moving path of the cooling medium and a blowing fan for passing indoor air through the fan coil; A floor coil that performs radiant cooling according to the movement of the cooling medium; A supply passage defining a path through which the cooling medium cooled by the cooling unit is supplied to at least one of the fan coil and the bottom coil; A supply valve for selecting whether to supply the cooling medium in the supply passage; A recovery passage for forming a path through which the cooling medium passing through at least one of the fan coil and the bottom coil is recovered to the cooling unit; An indoor temperature sensor measuring indoor air temperature; A floor temperature sensor measuring the temperature of the surface on which the floor coil is installed; A humidity sensor that measures the amount of water vapor in the room or humidity in the room; And calculating a condensation constant and a condensation point temperature based on the measured value of the indoor temperature sensor and the measured value of the humidity sensor, and comparing the measured value of the condensing point temperature and the floor temperature sensor to compare the fan coil and the floor coil. And a control unit for controlling the cooling unit, the supply valve, and the blowing fan so that the cooling medium is supplied to at least one of them.

Here, the control unit includes: a condensation constant calculating unit for calculating the condensation constant based on the measured value of the indoor temperature sensor and the measured value of the humidity sensor; A condensation point calculator for calculating the condensation point temperature based on the condensation constant; A condensation comparison unit comparing the condensation point temperature and a measured value of the floor temperature sensor; And a driving control unit for controlling the cooling unit, the supply valve, and the blowing fan so that the cooling medium is supplied to at least one of the fan coil and the bottom coil according to a comparison result of the condensation comparing unit.

Here, the drive control unit, when the comparison result of the condensation comparison unit, when the measured value of the floor temperature sensor is equal to or less than the dew point temperature, the cooling unit and the supply valve so that the cooling medium is supplied only to the fan coil. A first control unit for controlling the blowing fan; As a result of the comparison of the condensation comparison unit, when the measured value of the floor temperature sensor is greater than the condensation point temperature and less than the sum of the condensation point temperature and the adjustment variable, the cooling medium is supplied to both the fan coil and the bottom coil. A second control unit controlling the cooling unit, the supply valve, and the blowing fan; And when a comparison result of the condensation comparison unit, when the measured value of the floor temperature sensor is equal to or greater than the sum of the condensation point temperature and the adjustment variable, the cooling unit and the supply valve are controlled so that the cooling medium is supplied only to the floor coil. It includes; a third control unit.

Here, the control unit includes a condensation variable setting unit for setting a condensation variable for an error range of the condensation point temperature; And a relative humidity calculator configured to calculate a relative humidity of the room based on the amount of water vapor in the room among the measured values of the humidity sensor and the measured value of the room temperature sensor. It further includes at least any one of.

인 관계식이 성립하고, 상기 결로점 온도 DP에 대해

인 관계식이 성립한다.Here, the first control constant is a, the second control constant is b, the third control constant is c, the indoor relative humidity is RH, and the measured value (degrees Celsius) of the room temperature sensor is If T, for the condensation constant DH

The phosphorus relation is established, and for the dew point temperature DP

The relational expression is established.

The condensation prevention complex cooling method according to the present invention is a condensation prevention complex cooling method for controlling a condensation prevention complex cooling system, an indoor temperature sensing step of measuring the indoor air temperature through the indoor temperature sensor, and the humidity sensor. An indoor environment sensing step including a humidity sensing step of measuring an indoor water vapor amount or indoor humidity, and a floor temperature sensing step of measuring a temperature of a surface on which the floor coil is installed through the floor temperature sensor; A condensation constant calculating step of calculating the condensation constant based on the measured value of the indoor temperature sensor and the measured value of the humidity sensor; A condensation point calculation step of calculating the condensation point temperature based on the condensation constant; A condensation comparison step of comparing the condensation point temperature and a measured value of the floor temperature sensor; And a driving control step of controlling the cooling unit, the supply valve, and the blowing fan so that the cooling medium is supplied to at least one of the fan coil and the bottom coil according to a comparison result of the condensation comparing step.

Here, in the driving control step, when the measured value of the floor temperature sensor is equal to or less than the dew point temperature as a result of the comparison of the condensation comparing step, the cooling unit and the supply are supplied so that the cooling medium is supplied only to the fan coil. A first control step of controlling a valve and the blowing fan; As a result of the comparison of the condensation comparing step, when the measured value of the floor temperature sensor is greater than the condensation point temperature and less than the sum of the condensation point temperature and the adjustment variable, the cooling medium is supplied to both the fan coil and the floor coil. A second control step of controlling the cooling unit, the supply valve, and the blowing fan to be possible; And a comparison result of the condensation comparing step, when the measured value of the floor temperature sensor is equal to or greater than the sum of the condensation point temperature and the adjustment variable, the cooling unit and the supply valve are configured so that the cooling medium is supplied only to the floor coil. And a third control step of controlling.

The condensation prevention complex cooling method according to the present invention comprises a condensation variable setting step of setting a condensation variable for an error range of the condensation point temperature; And calculating a relative humidity of the room based on the amount of water vapor in the room and the measured value of the room temperature sensor among the measured values of the humidity sensor. It further includes at least any one of.

인 관계식이 성립하고, 상기 결로점 온도 DP에 대해

인 관계식이 성립한다.Here, the first control constant is a, the second control constant is b, the third control constant is c, the indoor relative humidity is RH, and the measured value (degrees Celsius) of the room temperature sensor is If T, for the condensation constant DH

The phosphorus relation is established, and for the dew point temperature DP

The relational expression is established.

According to the complex cooling system for preventing condensation and the complex cooling method according to the present invention, a ventilation device and a dehumidifying device can be omitted, and radiant cooling and convective cooling can be combined and operated indoors.

In addition, the present invention is controlled by convective cooling, combined cooling of convective and radiant cooling, and radiant cooling to solve the problem of shortage of heat in the supply unit and the problem of delay in load response time, while the surface on which the floor coil is installed (indoor floor or ceiling or wall surface) Radiation cooling can be performed while preventing condensation from occurring.

In addition, according to the present invention, the installation cost can be reduced while the installation is simple, and discomfort and rejection of radiant cooling for users who are adapted to convection cooling can be prevented.

In addition, the present invention can prevent condensation from occurring on the surface on which the floor coil is installed in response to the calculated dew point temperature.

In addition, according to the present invention, it is possible to compare and analyze whether the temperature of the surface on which the floor coil is installed is approaching or moving away from the dew point temperature, and the indoor air temperature can be easily adjusted.

In addition, the present invention can prevent an error in controlling the indoor air temperature and maintain a comfortable room.

In addition, the present invention can improve the calculation basis and accuracy for the dew point temperature, and it is possible to clarify the comparison of the measured value of the dew point temperature and the floor temperature sensor.

In addition, the present invention prevents condensation from occurring indoors even if the indoor environment changes rapidly due to opening and closing of doors or windows through the condensation variable.

In addition, the present invention can prevent the occurrence of condensation indoors by adjusting the condensation variable in consideration of regional climate characteristics.

In addition, the present invention facilitates switching between convective cooling and radiant cooling through an adjustment variable, as well as enabling complex cooling.

1 is a view showing a combined cooling system for preventing condensation according to an embodiment of the present invention.
2 is a view showing a control unit in the condensation prevention complex cooling system according to an embodiment of the present invention.
3 is a view showing a condensation prevention complex cooling method according to an embodiment of the present invention.
4 is a view showing an operating state of the complex cooling system according to the first control step in the complex cooling method for preventing condensation according to an embodiment of the present invention.
5 is a view showing an operating state of a combined cooling system according to a second control step in the combined cooling method for preventing condensation according to an embodiment of the present invention.
6 is a view showing the operating state of the complex cooling system according to the third control step in the complex cooling method for preventing condensation according to an embodiment of the present invention.

Hereinafter, an embodiment of a complex cooling system for preventing condensation and a complex cooling method according to the present invention will be described with reference to the accompanying drawings. At this time, the present invention is not limited or limited by the examples. In addition, in describing the present invention, detailed descriptions of known functions or configurations may be omitted to clarify the gist of the present invention.

Hereinafter, a condensation prevention complex cooling system according to an embodiment of the present invention will be described with reference to FIGS. 1 and 2.

In the combined cooling system for preventing condensation according to an embodiment of the present invention, a ventilation device and a dehumidifying device may be omitted, and radiant cooling and convective cooling may be combined and operated in parallel in the room (H).

The complex cooling system for preventing condensation according to an embodiment of the present invention includes a cooling unit 10, a fan coil unit 60, a bottom coil 70, a supply passage 20, a supply valve 30, and A recovery passage 40, an indoor temperature sensor 100, a floor temperature sensor 200, a humidity sensor 300, and a control unit 80 may be included.

The cooling unit 10 cools a cooling medium for cooling the room H. Here, cooling water or refrigerant may be used as the cooling medium. The cooling unit 10 may cool the cooling medium to a preset temperature.

The fan coil unit 60 performs convective cooling according to the movement of the cooling medium. The fan coil unit 60 includes a fan coil 62 that forms a moving path of the cooling medium in the room (H), and a blower fan (61) that passes air in the room (H) through the fan coil (62). I can. Here, the fan coil 62 prevents direct contact with the floor, ceiling, and sidewalls in the room (H), and the blower fan 61 adjusts the intensity of the blowing in stages to pass through the fan coil 62 per hour ( H) air can be adjusted.

The floor coil 70 performs radiant cooling according to the movement of the cooling medium. The floor coil 70 may directly contact or be embedded in at least one of a floor, a ceiling, and a side wall of the room H, thereby increasing the efficiency of radiant cooling. As an example, the floor coil 70 may utilize a heating pipe embedded in the floor of the room H.

The supply passage 20 forms a path through which the cooling medium cooled in the cooling unit 10 is supplied to at least one of the fan coil 62 and the bottom coil 70. The supply passage 20 connects the cooling unit 10 and the fan coil 62, connects the cooling unit 10 and the floor coil 70, or connects the cooling unit 10 with the fan coil 62 and the floor coil. (70) can be connected.

For example, the supply passage 20 includes a first supply line 21 connecting the cooling unit 10 and the fan coil 62, and a second supply line connecting the cooling unit 10 and the bottom coil 70. It can be divided into (22).

As another example, the supply passage 20 includes a fan supply line connected to the inlet of the fan coil 62, as in the detailed configuration of the recovery passage 40 to be described later, and a bottom supply line connected to the inlet of the floor coil 70. , It can be divided into a cooling supply line connected to the outlet of the cooling unit 10 and the fan supply line and the bottom supply line.

The supply valve 30 selects whether or not the cooling medium is supplied from the supply passage 20. As the supply valve 30 is opened, the cooling medium of the supply passage 20 may be supplied to at least one of the fan coil 62 and the bottom coil 70.

For example, in response to the supply passage 20 divided into the first supply line 21 and the second supply line 22, the supply valve 30 is provided in the first supply line 21 to supply the cooling medium. It can be divided into a first supply valve 31 for selecting a and a second supply valve 32 provided in the second supply line 22 to select whether to supply the cooling medium. Then, when only the first supply valve 31 is opened, the cooling medium is supplied to the fan coil 62, and when only the second supply valve 32 is opened, the cooling medium is supplied to the bottom coil 70, and the first supply When both the valve 31 and the second supply valve 32 are opened, a cooling medium can be supplied to both the fan coil 62 and the bottom coil 70.

As another example, in response to the supply passage 20 divided into a fan supply line, a bottom supply line and a cooling supply line, the supply valve 30 has a cooling supply line connected to the inlet, and a fan supply line connected to the first outlet. , It may be made of a three-way valve to which the bottom supply line is connected to the second outlet. Then, the cooling medium is supplied only to the fan coil 62, the cooling medium is supplied only to the bottom coil 70, or the cooling medium is supplied to both the fan coil 62 and the bottom coil 70 according to the opening and closing operation of the three-way valve. Can be.

The recovery passage 40 forms a path through which the cooling medium passing through at least one of the fan coil 62 and the bottom coil 70 is recovered to the cooling unit 10. The recovery passage 40 connects the cooling unit 10 and the fan coil 62, or connects the cooling unit 10 and the floor coil 70, or both the fan coil 62 and the floor coil 70 are cooled. It can be connected to the unit 10.

As an example, the recovery passage 40 includes a fan recovery line 41 connected to the outlet of the fan coil 62, a bottom recovery line 42 connected to the outlet of the bottom coil 70, and a cooling unit 10. It can be divided into a cooling recovery line 43 connected to the inlet of the fan recovery line 41 and the bottom recovery line 42 is connected.

As another example, the recovery passage 40 includes a first recovery line connecting the fan coil 62 and the cooling unit 10, as in the detailed configuration of the supply passage 20 described above, and the bottom coil 70 and the cooling unit ( It can be divided into a second recovery line connecting 10).

Here, the combined cooling system for preventing condensation according to an embodiment of the present invention may further include a recovery valve 50. The recovery valve 50 selects whether to recover the cooling medium from the recovery passage 40. As the recovery valve 50 is opened, the cooling medium passing through at least one of the fan coil 62 and the bottom coil 70 may be recovered to the cooling unit 10 through the recovery passage 40.

For example, in response to the recovery flow path 40 divided into the fan recovery line 41, the bottom recovery line 42 and the cooling recovery line 43, the recovery valve 50 is a fan recovery line 41 at the first inlet. This is connected, the bottom recovery line 42 is connected to the second inlet, and the cooling recovery line 43 is connected to the outlet. Then, according to the opening and closing operation of the three-way valve, only the cooling medium of the fan coil 62 is recovered to the cooling unit 10, only the cooling medium of the bottom coil 70 is recovered to the cooling unit 10, or the fan coil 62 Both the cooling medium of the bottom coil 70 and the bottom coil 70 may be recovered in the cooling unit 10.

As another example, the recovery valve 50 is provided in the first recovery line in response to the supply passage 20 divided into a first recovery line and a second recovery line, and a first recovery valve that selects whether to recover the cooling medium; It can be divided into a second recovery valve that is provided in the second recovery line and selects whether to recover the cooling medium. Then, when only the first recovery valve is opened, the cooling medium of the fan coil 62 is recovered to the cooling unit 10, and when only the second recovery valve is opened, the cooling medium of the bottom coil 70 is transferred to the cooling unit 10. When both the first recovery valve and the second recovery valve are opened, both the cooling medium of the fan coil 62 and the cooling medium of the bottom coil 70 can be recovered to the cooling unit 10.

The room temperature sensor 100 measures the air temperature in the room (H).

The floor temperature sensor 200 measures the temperature of the surface on which the floor coil 70 is installed. The floor temperature sensor 200 may measure the temperature of the surface on which the floor coil 70 is installed in a contact or non-contact method.

The humidity sensor 300 measures the amount of water vapor in the room (H) or the humidity in the room (H). When the humidity sensor 300 measures the amount of water vapor in the room H, the relative humidity must be calculated based on the amount of saturated water vapor for each temperature. In addition, when the humidity sensor 300 measures the humidity of the room (H), the measured humidity of the room (H) may be used as the relative humidity of the room (H).

The control unit 80 calculates the condensation constant and the condensation point temperature based on the measured value of the indoor temperature sensor 100 and the measured value of the humidity sensor 300, and the measured value of the condensation point temperature and the floor temperature sensor 200 In comparison, the cooling unit 10, the supply valve 30, and the blowing fan 61 are controlled so that the cooling medium is supplied to at least one of the fan coil 62 and the bottom coil 70. The control unit 80 also controls the recovery valve 50 according to the addition of the recovery valve 50.

Here, the condensation constant and the condensation point temperature can be calculated by the following relationship.

인 관계식이 성립한다.The first control constant is a, the second control constant is b, the third control constant is c, the relative humidity of the room (H) is RH, and the measured value of the room temperature sensor 100 (Celsius Temperature) is T, for the condensation constant DH

The relational expression is established.

인 관계식이 성립한다.Also, for the dew point temperature DP

The relational expression is established.

Therefore, the condensation constant and the condensation point temperature are calculated using the corresponding relational expression. At this time, the first control constant, the second control constant, and the third control constant are constants necessary for deriving the corresponding relational expression, and in an embodiment of the present invention, the first control constant is 17.62, the second control constant is 243.12, and the second control constant is 3 The control constant can be defined as 0.4343.

The control unit 80 includes a condensation constant calculating unit 92 that calculates a condensation constant based on the measured value of the indoor temperature sensor 100 and the measured value of the humidity sensor 300, and the condensation point temperature based on the condensation constant. The fan coil 62 according to the comparison result of the calculated condensation point calculation unit 93, the condensation comparison unit 96 for comparing the measured values of the condensation point temperature and the floor temperature sensor 200, and the condensation comparison unit 96. ) And the bottom coil 70 to supply the cooling medium to at least one of the cooling units 10, the supply valve 30, and the drive control unit 97 for controlling the blowing fan 61. The drive control unit 97 may also control the recovery valve 50 according to the addition of the recovery valve 50.

In addition, the control unit 80 includes a condensation variable setting unit 84 for setting a condensation variable for an error range of the condensation point temperature, and the amount of water vapor in the room (H) and a room temperature sensor ( It may further include at least any one of the relative humidity calculation unit 92 for calculating the relative humidity of the room (H) based on the measured value of 100). Here, the condensation variable setting unit 84 may store the set condensation variable. In addition, the condensation variable setting unit 84 may also set an adjustment variable to be described later, and the set adjustment variable may be stored. In addition, the relative humidity calculation unit 92 may store the calculated relative humidity of the room H.

In addition, the control unit 80 includes an indoor temperature storage unit 81 that stores the measured values of the indoor temperature sensor 100, a floor temperature storage unit 82 that stores the measured values of the floor temperature sensor 200, It may further include a humidity storage unit 83 for storing the measured value of the humidity sensor 300.

In addition, the control unit 80 may further include a saturated water vapor amount storage unit 85 for storing the amount of saturated water vapor for each temperature. The amount of saturated water vapor by temperature is used to calculate the relative humidity of the room (H) based on the amount of water vapor in the room (H) and the measured value of the room temperature sensor (100).

In addition, the control unit 80 includes a condensation constant storage unit 94 for storing the condensation constant calculated by the condensation constant calculation unit 92 and a condensation point for storing the condensation point temperature calculated by the condensation point calculation unit 93. It may further include a storage unit (95).

Here, the driving control unit 97 may include a first control unit 971, a second control unit 972, and a third control unit 973.

As a result of the comparison of the condensation comparing unit 96, the first control unit 971 determines that a condensation generation section is determined when the measured value of the floor temperature sensor 200 is equal to or less than the condensation point temperature, and the cooling medium is the fan coil 62 The cooling unit 10, the supply valve 30, and the blowing fan 61 are controlled to be supplied only to ).

At this time, the dew point temperature can be expressed as a temperature range by applying a dew point variable. For example, when the measured value of the floor temperature sensor 200 is 20 degrees Celsius and the dew point temperature is 20 degrees Celsius, condensation occurs because the measured value of the floor temperature sensor 200 is the same as the dew point temperature. However, due to the error range of the floor temperature sensor 200, the measured value of the floor temperature sensor 200 is actually 20 degrees Celsius but measured at 21 degrees Celsius, or if the dew point temperature is 20 degrees Celsius and 19 degrees Celsius, the system error As a result, an error in which the first control unit 971 is not operated may occur. Accordingly, by applying the condensation variable to the temperature of the condensation point, an error in which the first control unit 971 is not operated is prevented, and the first control unit 971 can be stably operated for an actual condensation generation section.

In addition, when the indoor environment changes rapidly, for example, when outdoor air flows into the room (H) due to the user's access and humidity increases rapidly, condensation may occur on the surface where the floor coil 70 is installed. By applying the variable, the error range for the operation of the first control unit 971 is widened so that condensation does not occur in the room H even if the indoor environment changes rapidly.

The operation of the first control unit 971 will be described in more detail through a first control step S81 to be described later.

As a result of the comparison of the condensation comparison unit 96, the second control unit 972 determines as a condensation caution section when the measured value of the floor temperature sensor 200 is greater than the condensation point temperature and less than the sum of the condensation point temperature and the adjustment variable. And, the cooling unit 10, the supply valve 30, and the blowing fan 61 are controlled so that the cooling medium is supplied to both the fan coil 62 and the bottom coil 70.

As the adjustment variable is applied to the condensation point temperature, no condensation occurs, but since it is a section close to the condensation occurrence section, it can be defined as a condensation caution section.

The operation of the second control unit 972 will be described in more detail through a second control step (S82) to be described later.

As a result of the comparison of the condensation comparison unit, the third control unit 973 determines that a condensation-free section is determined when the measured value of the floor temperature sensor 200 is equal to or greater than the sum of the condensation point temperature and the adjustment variable, and the cooling medium is The cooling unit 10 and the supply valve 30 are controlled so as to be supplied only to the 70. In addition, the third control unit 973 includes stopping the blowing fan 61.

Since the adjustment variable is applied to the temperature of the condensation point, since condensation does not occur indoors, it can be defined as a non-condensing section.

The operation of the third control unit 973 will be described in more detail through a third control step S83 to be described later.

From now on, with reference to FIGS. 1 and 2 and 3 to 6, a description will be given of a condensation prevention complex cooling method according to an embodiment of the present invention.

The complex cooling method for preventing condensation according to an embodiment of the present invention is to control the complex cooling system for preventing condensation according to an embodiment of the present invention, the indoor environment sensing step (S1), the condensation constant calculation step (S5), It may include a condensation point calculation step (S6), a condensation comparison step (S7), and a drive control step (S8).

The indoor environment sensing step (S1) is an indoor temperature sensing step (S11) measuring the air temperature in the room (H) through the indoor temperature sensor 100, and the amount of water vapor in the room (H) through the humidity sensor (300) or A humidity sensing step (S12) of measuring the humidity of (H), and a floor temperature sensing step (S13) of measuring the temperature of the surface on which the floor coil 70 is installed through the floor temperature sensor 200.

In this case, the combined cooling method for preventing condensation according to an embodiment of the present invention may further include an indoor environment storage step (S2) in which a value measured through the indoor environment detection step (S1) is stored.

The indoor environment storage step (S2) includes an indoor temperature storage step (S21) in which the measured values of the indoor temperature sensor 100 are stored, a humidity storage step (S22) in which the measured values of the humidity sensor 300 are stored, and the floor temperature. A floor temperature storage step (S23) in which the measured value of the sensor 200 is stored may be included.

The condensation constant calculation step (S5) calculates the condensation constant based on the measured value of the indoor temperature sensor 100 and the measured value of the humidity sensor 300. The condensation constant calculated in the condensation constant calculation step (S5) may be stored in the condensation constant storage unit 94.

The dew point calculation step (S6) calculates the dew point temperature based on the dew point constant. The dew point temperature calculated in the dew point calculation step S6 may be stored in the dew point storage unit 95.

Here, the condensation constant and the condensation point temperature can be calculated by the following relationship.

인 관계식이 성립한다.The first control constant is a, the second control constant is b, the third control constant is c, the relative humidity of the room (H) is RH, and the measured value of the room temperature sensor 100 (Celsius Temperature) is T, for the condensation constant DH

The relational expression is established.

인 관계식이 성립한다.Also, for the dew point temperature DP

The relational expression is established.

Therefore, the condensation constant and the condensation point temperature are calculated using the corresponding relational expression. At this time, the first control constant, the second control constant, and the third control constant are constants necessary for deriving the corresponding relational expression, and in an embodiment of the present invention, the first control constant is 17.62, the second control constant is 243.12, and the second control constant is 3 The control constant can be defined as 0.4343.

In the condensation comparison step (S7), the condensation point temperature and the measured value of the floor temperature sensor 200 are compared.

The driving control step (S8) includes the cooling unit 10 and the supply valve 30 so that the cooling medium is supplied to at least one of the fan coil 62 and the bottom coil 70 according to the comparison result of the condensation comparison step (S7). And control the blowing fan (61).

In the condensation prevention complex cooling method according to an embodiment of the present invention, the condensation variable setting step (S3) of setting a condensation variable for an error range of the condensation point temperature, and the indoor (H) of the measured values of the humidity sensor 300 It may further include at least one of the relative humidity calculation step (S4) of calculating the relative humidity of the room H based on the amount of water vapor and the measured value of the room temperature sensor 100. Here, the condensation variable set in the condensation variable setting step S3 may be stored in the condensation variable setting unit 84. In addition, the condensation variable setting step (S3) may also set the adjustment variable, and the set adjustment variable may be stored in the condensation variable setting unit 84. In addition, the relative humidity of the room (H) calculated in the relative humidity calculation step (S4) may be stored in the relative humidity calculation unit 92.

Here, the driving control step S8 may include a first control step S81, a second control step S82, and a third control step S83.

In the first control step (S81), as a result of the comparison of the condensation comparison step (S7), when the measured value of the floor temperature sensor 200 is equal to or less than the condensation point temperature, it is determined as a condensation generation section, and the cooling medium is a fan coil ( The cooling unit 10, the supply valve 30, and the blowing fan 61 are controlled so as to be supplied only to 62). At this time, the dew point temperature can be expressed as a temperature range by applying a dew point variable.

In addition, the first control step S81 allows the cooling medium of the cooling unit 10 to be moved only to the fan coil 62 as shown in FIG. 4. For example, by opening the first supply valve 31, the cooling medium is moved to the first supply line 21 connecting the cooling unit 10 and the fan coil 62, and the second supply valve 32 is closed. By blocking, the cooling medium is blocked from moving to the second supply line 22 connecting the cooling unit 10 and the bottom coil 70. As another example, by adjusting the three-way valve so that the cooling supply line and the fan supply line communicate with each other, the cooling medium of the cooling unit 10 may be moved only to the fan coil 62. At this time, in the first control step (S81), by controlling the blower fan 61 to a strong wind having the maximum intensity, convective cooling is performed to quickly lower the air temperature in the room H and the humidity in the room H. In addition, the first control step (S81) controls the recovery valve 50 so that the cooling medium of the fan coil 62 is recovered to the cooling unit.

In the second control step (S82), as a result of the comparison of the condensation comparison step (S7), when the measured value of the floor temperature sensor 200 is greater than the condensation point temperature and less than the sum of the condensation point temperature and the adjustment variable, the condensation occurrence caution section is performed. It determines and controls the cooling unit 10, the supply valve 30, and the blowing fan 61 so that the cooling medium is supplied to both the fan coil 62 and the bottom coil 70.

As the adjustment variable is applied to the condensation point temperature, no condensation occurs, but since it is a section close to the condensation occurrence section, it can be defined as a condensation caution section.

In addition, in the second control step S82, the cooling medium of the cooling unit 10 moves to both the fan coil 62 and the bottom coil 70 as shown in FIG. 5. For example, by opening the first supply valve 31, the cooling medium is moved to the first supply line 21 connecting the cooling unit 10 and the fan coil 62, and the second supply valve 32 is closed. Open to allow the cooling medium to be moved to the second supply line 22 connecting the cooling unit 10 and the bottom coil 70. As another example, by adjusting the three-way valve so that the cooling supply line, the fan supply line, and the bottom supply line are in communication with each other, the cooling medium of the cooling unit 10 can be moved to both the fan coil 62 and the floor coil 70. . At this time, the second control step (S82) is to prevent condensation in the room (H) by controlling the blowing fan 61 to a medium-intensity medium wind or a weak-intensity weak wind, thereby simultaneously performing convective cooling and radiant cooling. Cooling can be operated.

In the third control step (S83), when the comparison result of the condensation comparison step (S7), when the measured value of the floor temperature sensor 200 is equal to or greater than the sum of the condensation point temperature and the adjustment variable, it is determined as a condensation-free section, The cooling unit 10 and the supply valve 30 are controlled so that the cooling medium is supplied only to the bottom coil 70. The third control step (S83) includes stopping the blowing fan (61).

Since the adjustment variable is applied to the temperature of the condensation point, since condensation does not occur in the room (H), it can be defined as a non-condensation section.

In addition, the third control step S83 allows the cooling medium of the cooling unit 10 to be moved only to the bottom coil 70 as shown in FIG. 6. For example, by blocking the first supply valve 31, the first supply line 21 connecting the cooling unit 10 and the fan coil 62 is blocked, and the second supply valve 32 is opened to The cooling medium is moved to the second supply line 22 connecting the 10 and the bottom coil 70. As another example, the cooling medium of the cooling unit 10 may be moved to the bottom coil 70 by adjusting the three-way valve so that the cooling supply line and the bottom supply line communicate with each other. At this time, in the third control step (S83), by stopping the blowing fan 61, convective cooling is not performed, only radiant cooling is performed, and comfortable cooling can be performed without circulating air in the room (H). .

According to the above-described condensation prevention complex cooling system and complex cooling method, a ventilation device and a dehumidifying device can be omitted, and radiant cooling and convective cooling can be combinedly operated in the room (H).

In addition, convective cooling, combined cooling of convective and radiant cooling, and radiant cooling are controlled to solve the problem of shortage of heat in the supply unit and delay in load response time, while Alternatively, radiant cooling can be performed while preventing condensation from occurring on the wall.

In addition, the installation cost can be reduced while the facility is simple, and discomfort and rejection of radiant cooling for users who are adapted to convection cooling can be prevented.

In addition, it is possible to prevent condensation from occurring on the surface on which the floor coil 70 is installed in response to the calculated dew point temperature.

In addition, it is possible to compare and analyze whether the temperature of the surface on which the floor coil 70 is installed is approaching or moving away from the dew point temperature, and the air temperature in the room (H) can be easily adjusted.

In addition, it is possible to prevent an error in adjusting the air temperature in the room (H) and maintain a comfortable room (H).

In addition, it is possible to improve the calculation basis and precision for the dew point temperature, and to clearly compare the measured value of the dew point temperature and the floor temperature sensor 200.

In addition, condensation is prevented from occurring in the room (H) even if the indoor environment changes rapidly due to the opening and closing of doors or windows through the condensation variable.

In addition, it is possible to prevent the occurrence of condensation indoors (H) by adjusting the condensation variable in consideration of regional climate characteristics.

In addition, it facilitates switching between convective cooling and radiant cooling through adjustment variables, as well as enabling complex cooling.

As described above, preferred embodiments of the present invention have been described with reference to the drawings, but those skilled in the art will variously modify the present invention within the scope not departing from the spirit and scope of the present invention described in the following claims. Can be modified or changed.

10: cooling unit 20: supply passage 21: first supply line
22: second supply line 30: supply valve 31: first supply valve
32: second supply valve 40: recovery passage 41: fan recovery line
42: bottom recovery line 43: cooling recovery line 50: recovery valve
60: fan coil unit 61: blowing fan 62: fan coil
70: floor coil 80: control unit 81: indoor temperature storage unit
82: floor temperature storage unit 83: humidity storage unit 84: condensation variable setting unit
85: saturated water vapor amount storage unit 91: relative humidity calculation unit 92: condensation constant water calculation unit
93: condensation point calculation unit 94: condensation constant storage unit 95: condensation point storage unit
96: condensation comparison unit 97: drive control unit 971: first control unit
972: second control unit 973: third control unit H: indoor
S1: Indoor environment detection step S11: Indoor temperature detection step S12: Humidity detection step
S13: Floor temperature detection step S2: Indoor environment storage step S21: Indoor temperature storage step
S22: humidity storage step S23: floor temperature storage step S3: condensation variable setting step
S4: Relative humidity calculation step S5: Condensation constant calculation step S6: Condensation point calculation step
S7: condensation comparison step S8: drive control step S81: first control step
S82: second control step S83: third control step

Claims (7)

A cooling unit for cooling a cooling medium for cooling indoors;
A fan coil unit configured to perform convective cooling according to the movement of the cooling medium, including a fan coil forming a moving path of the cooling medium and a blowing fan for passing indoor air through the fan coil;
A floor coil that performs radiant cooling according to the movement of the cooling medium;
A supply passage defining a path through which the cooling medium cooled by the cooling unit is supplied to at least one of the fan coil and the bottom coil;
A supply valve for selecting whether to supply the cooling medium in the supply passage;
A recovery passage for forming a path through which the cooling medium passing through at least one of the fan coil and the bottom coil is recovered to the cooling unit;
An indoor temperature sensor measuring indoor air temperature;
A floor temperature sensor measuring the temperature of the surface on which the floor coil is installed;
A humidity sensor that measures the amount of water vapor in the room or humidity in the room; And
A condensation constant and a condensation point temperature are calculated based on the measured value of the indoor temperature sensor and the measured value of the humidity sensor, and the temperature of the condensation point and the measured value of the floor temperature sensor are compared to one of the fan coil and the floor coil. And a control unit for controlling the cooling unit, the supply valve, and the blowing fan so that the cooling medium is supplied to at least one of them. The method of claim 1,
The control unit,
A condensation constant calculating unit for calculating the condensation constant based on the measured value of the indoor temperature sensor and the measured value of the humidity sensor;
A condensation point calculation unit that calculates the condensation point temperature based on the condensation constant;
A condensation comparison unit comparing the condensation point temperature and a measured value of the floor temperature sensor; And
And a drive control unit for controlling the cooling unit, the supply valve, and the blowing fan so that the cooling medium is supplied to at least one of the fan coil and the bottom coil according to a comparison result of the condensation comparison unit. Complex cooling system for preventing condensation. The method of claim 2,
The drive control unit,
As a result of the comparison of the condensation comparator, when the measured value of the floor temperature sensor is equal to or less than the condensation point temperature, the cooling unit, the supply valve, and the blowing fan are controlled so that the cooling medium is supplied only to the fan coil. 1 control unit;
As a result of the comparison of the condensation comparison unit, when the measured value of the floor temperature sensor is greater than the condensation point temperature and less than the sum of the condensation point temperature and the adjustment variable, the cooling medium is supplied to both the fan coil and the bottom coil. A second control unit controlling the cooling unit, the supply valve, and the blowing fan; And
As a result of the comparison of the condensation comparison unit, when the measured value of the floor temperature sensor is equal to or greater than the sum of the dew point temperature and the adjustment variable, the cooling unit and the supply valve are controlled so that the cooling medium is supplied only to the floor coil. A complex cooling system for preventing condensation, comprising: a third control unit. The method of claim 2,
The control unit,
A condensation variable setting unit for setting a condensation variable for an error range of the condensation point temperature; And
A relative humidity calculator configured to calculate a relative humidity of the room based on the amount of water vapor in the room among the measured values of the humidity sensor and the measured value of the room temperature sensor;
Condensation prevention complex cooling system, characterized in that it further comprises at least one of. The method according to any one of claims 1 to 4,
Let the first control constant a,
The second control constant is called b,
Let the third control constant be c,
The relative humidity in the room is called RH,
If the measured value (degrees Celsius) of the room temperature sensor is T,
For the condensation constant DH above

The relationship is established,
For the dew point temperature DP

Complex cooling system for preventing condensation, characterized in that the relationship is established. It is a condensation prevention complex cooling method for controlling the condensation prevention complex cooling system according to claim 1,
An indoor temperature sensing step of measuring indoor air temperature through the indoor temperature sensor, a humidity sensing step of measuring indoor water vapor amount or indoor humidity through the humidity sensor, and the floor coil installed through the floor temperature sensor. Indoor environment sensing step including a floor temperature sensing step of measuring the temperature of the surface;
A condensation constant calculating step of calculating the condensation constant based on the measured value of the indoor temperature sensor and the measured value of the humidity sensor;
A condensation point calculation step of calculating the condensation point temperature based on the condensation constant;
A condensation comparison step of comparing the condensation point temperature and a measured value of the floor temperature sensor; And
And a driving control step of controlling the cooling unit, the supply valve, and the blowing fan so that the cooling medium is supplied to at least one of the fan coil and the bottom coil according to a comparison result of the condensation comparison step. Complex cooling method for preventing condensation. The method of claim 6,
The driving control step,
As a result of the comparison of the condensation comparing step, when the measured value of the floor temperature sensor is equal to or less than the condensation point temperature, controlling the cooling unit, the supply valve, and the blowing fan so that the cooling medium is supplied only to the fan coil. A first control step;
As a result of the comparison of the condensation comparing step, when the measured value of the floor temperature sensor is greater than the condensation point temperature and less than the sum of the condensation point temperature and the adjustment variable, the cooling medium is supplied to both the fan coil and the floor coil. A second control step of controlling the cooling unit, the supply valve, and the blowing fan to be possible; And
When the comparison result of the condensation comparison step, when the measured value of the floor temperature sensor is equal to or greater than the sum of the dew point temperature and the adjustment variable, the cooling unit and the supply valve are controlled so that the cooling medium is supplied only to the floor coil. Condensation prevention complex cooling method comprising a; a third control step to.

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