JP5916346B2 - Air conditioning equipment - Google Patents

Description

The present invention relates to an air conditioning facility that performs indoor ventilation and temperature cooling by a temperature control panel.

While installation of a temperature control panel for floor heating is progressing in general households, facilities that can perform floor cooling using a temperature control panel for floor heating can be seen, and a specific example is disclosed in Patent Document 1. It is described in. Patent Document 1 describes that floor heating is performed by heating a heat medium supplied to a temperature control panel (floor temperature control panel), and floor cooling is performed by cooling the heat medium supplied to the temperature control panel. Yes.
In a room where floor cooling is performed, there arises a problem that when the dew point temperature rises, the floor cooled by the temperature control panel condenses.

Therefore, in Patent Document 1, when the temperature of the heat medium sent out from the temperature control panel is lower than the dew point temperature estimated value, supply of the heat medium to the temperature control panel is stopped to prevent condensation on the floor. ing.
The temperature control panel may be arranged not in the floor but in the indoor space. In this case, the temperature control panel directly cools or warms the indoor air.
In addition, due to the revision of the Building Standards Law, as a countermeasure against sick house, it is obliged to install a ventilator that ventilates 0.5 times / h or more in ordinary households. Ventilation as described in Patent Document 2 The device is now installed in the house.

JP 2001-336804 A JP 2002-39579 A

However, since Patent Document 1 calculates the dew point temperature estimated value from the humidity detected by the indoor humidity sensor provided in the indoor unit and the outdoor humidity sensor provided in the outdoor unit, the indoor unit provided with the indoor humidity sensor is There is a problem that the room where the room is not installed is not controlled to prevent condensation.
Then, if an indoor unit provided with indoor humidity sensors is installed in all the rooms of the house, there is a problem that the required indoor humidity sensors increase and the wiring for connecting the indoor humidity sensors becomes complicated.
This invention is made in view of this situation, and it aims at providing the air-conditioning equipment which suppresses that the number of sensors which measure the value input into the arithmetic expression of dew point temperature increases with the increase in the number of rooms. And

The air conditioning equipment according to the present invention that meets the above-mentioned object is taken into a suction duct via a plurality of temperature control panels that respectively cool a plurality of rooms, a control means that determines the cooling temperature of the temperature control panel, and a suction port. In an air conditioning system having a ventilator for ventilating the room by discharging the indoor air to the outside, temperature and humidity for measuring the temperature and humidity of the indoor air taken in and mixed with the suction duct A detection means, and the control means calculates a determination target temperature based on a measured temperature of the temperature / humidity detection means and a dew point temperature obtained from the measured humidity, and performs cooling at a set temperature determined by the control means. When it is detected that the cooling temperature of the temperature control panel is equal to or lower than the determination target temperature, the cooling temperature of the temperature control panel is changed from the set temperature to a dew condensation prevention temperature higher than the determination target temperature.

In the air conditioner according to the present invention, when the control means calculates the determination target temperature lower than the set temperature of the temperature control panel in a state where the temperature control panel performs cooling at the dew condensation prevention temperature. It is preferable to return the cooling temperature of the temperature control panel to the set temperature.

In the air conditioning equipment according to the present invention, it is preferable that the control means displays on the display means signal-connected to the control means that the temperature control panel performs cooling at the condensation prevention temperature.

In the air conditioning equipment according to the present invention, it is preferable that the ventilation device has a casing to which the suction duct is connected, and the temperature and humidity detection means is provided in the casing.

In the air conditioning equipment according to the present invention, it is preferable that the temperature control panel is disposed on a floor to perform floor cooling.

In the air conditioning equipment according to the present invention, it is preferable that the control means calculates the determination target temperature by adding a predetermined temperature to a dew point temperature obtained from the measured temperature and the measured humidity of the temperature and humidity detection means.

In the air conditioning equipment according to the present invention, it is preferable that the predetermined temperature added to the dew point temperature in calculating the determination target temperature can be changed by setting.

The air conditioning equipment according to the present invention includes temperature and humidity detection means for measuring the temperature and humidity of the indoor air taken in and mixed with the suction duct via the suction port, and the control means measures the temperature measured by the temperature and humidity detection means. And a determination target temperature based on the dew point temperature obtained from the measured humidity. Therefore, there is no need to install temperature / humidity detection means in the room for preventing condensation, and the number of temperature / humidity detection means can be suppressed from increasing as the number of rooms increases.

In the air conditioning equipment according to the present invention, when the control means calculates a determination target temperature lower than the set temperature of the temperature control panel in a state where the temperature control panel performs cooling at the dew condensation prevention temperature, the temperature control panel is cooled. When returning the temperature to the set temperature, the temperature control panel can perform cooling at the set temperature required by the occupant within a range in which the floor can be prevented from dewing.

In the air conditioning equipment according to the present invention, when the control means displays on the display means that the temperature control panel is cooling at the dew condensation prevention temperature, the resident can easily know the cooling state by the temperature control panel. Can do.

In the air conditioning equipment according to the present invention, when the ventilation device has a casing to which a suction duct is connected and the temperature / humidity detection means is provided in the casing, the temperature / humidity detection means is attached on the production line of the factory. It is possible to shorten the installation work of the air conditioning equipment in the house. If the temperature / humidity detection means is attached to the suction duct, the suction duct generally needs to be adjusted depending on the house at the installation site. Therefore, the temperature / humidity detection means is also installed in the house. The installation process will increase.

In the air conditioning equipment according to the present invention, when the temperature control panel is disposed on the floor and performs floor cooling, the temperature control panel can provide a comfortable temperature environment to the occupant.

In the air conditioning equipment according to the present invention, when the control means calculates the determination target temperature by adding a predetermined temperature to the dew point temperature obtained from the measurement temperature and the measurement humidity of the temperature / humidity detection means, the determination target temperature is measured by the temperature / humidity detection means. It can be higher than the dew point temperature obtained from the temperature and the measured humidity, and it is possible to stably prevent condensation due to cooling of the temperature control panel.

In the air conditioning equipment according to the present invention, when the predetermined temperature added to the dew point temperature can be changed in calculating the judgment target temperature, the optimum judgment target temperature can be used depending on the house where the air conditioning equipment is installed.

It is explanatory drawing of the air-conditioning equipment which concerns on one embodiment of this invention. It is explanatory drawing which shows the connection of the temperature control panel with which the air conditioning equipment is equipped, and an outdoor unit. It is explanatory drawing which shows the signal connection of the control means of the air conditioning equipment. It is explanatory drawing of the ventilation apparatus of the air-conditioning equipment.

Next, embodiments of the present invention will be described with reference to the accompanying drawings for understanding of the present invention.
As shown in FIGS. 1-4, the air-conditioning equipment 10 which concerns on one embodiment of this invention is the temperature control panels 14-16 which cool the indoors 11-13, respectively, and the cooling temperature of the temperature control panels 14-16. It has the control means 17 to determine, and the ventilator 21 which ventilates the room | chamber interior by discharging the air of the rooms 11-13 taken into the suction duct 20 via the several suction inlets 18 and 19 outside. This will be described in detail below.

As shown in FIG. 1, the house 22 in which the air conditioning equipment 10 is installed includes rooms 11 to 13 in which floor cooling is performed by temperature control panels 14 to 16, respectively. In the present embodiment, the room 11 is a living dining kitchen, the rooms 12 and 13 are bedrooms, and the temperature control panels 14 to 16 can also perform floor heating in addition to floor cooling.
The indoor units 11 and 12 are provided with indoor units 23 and 24, respectively, and the indoors 11 and 12 are cooled and heated by the indoor units 23 and 24, respectively. No indoor unit is installed in the room 13, and the room 13 is only cooled and heated by the temperature control panel 16.

An outdoor unit 25 connected to the indoor unit 23 via a circulation circuit 27 is provided outside the house 22, and the indoor unit 23 and the outdoor unit 25 together with the temperature control panels 14 to 16 and the ventilation device 21 are air conditioning equipment 10. The main part of
On the other hand, the outdoor unit 26 and the indoor unit 24 connected to the indoor unit 24 via the circulation circuit 28 do not belong to the air conditioning facility 10, and cool and heat the room 12 independently of the air conditioning facility 10. .
Also, the indoor air inlets 18 and 19 of the ventilator 21 are respectively provided in the indoors 11 to 13, and the indoor air in the indoors 11 to 13 is replaced with the outside air by the ventilator 21.
Although the outdoor unit 25 and the temperature control panels 14 to 16 are connected, FIG. 1 is drawn with the connection between the outdoor unit 25 and the temperature control panels 14 to 16 omitted. The ventilator 21 performs 24-hour ventilation as defined by the Building Standards Law, and in principle ventilates living rooms.

As shown in FIG. 2, the indoor unit 23 and the outdoor unit 25 are connected by a circulation circuit 27 in which the refrigerant H1 (in the present embodiment, chlorofluorocarbon R410A) circulates.
The circulation circuit 27 connects the compressor 29, the heat exchanger 30 and the expansion valve 31 provided in the outdoor unit 25 and the heat exchanger 32 provided in the indoor unit 23 to form a heat pump cycle, and this heat pump cycle Thus, the room 11 is cooled and heated.
When the compressor 29 starts operation, the refrigerant H <b> 1 in the circulation circuit 27 circulates through the circulation circuit 27. The expansion valve 31 adjusts the flow rate of the refrigerant H1 that circulates in the circulation circuit 27 so that the room 11 can be efficiently cooled and heated.

When air conditioning by the indoor unit 23 or floor air conditioning by the temperature control panels 14 to 16 is performed, one of the heat exchangers 30 and 32 functions as an evaporator and the other functions as a condenser. Which of the heat exchangers 30 and 32 is an evaporator and which is a condenser is determined by the flow direction of the refrigerant H1 that circulates in the circulation circuit 27, and the circulation circuit 27 includes a refrigerant that circulates in the circulation circuit 27. A four-way valve 33 that switches the direction in which H1 flows is provided.
Therefore, in the heat exchangers 30 and 32, the one functioning as the condenser becomes the evaporator and the one functioning as the evaporator becomes the condenser by switching the direction in which the refrigerant H <b> 1 flows by the four-way valve 33. .

During the cooling operation by the indoor unit 23, the heat exchangers 30 and 32 function as a condenser and an evaporator, respectively. The gaseous refrigerant H1 compressed by the compressor 29 is radiated by the heat exchanger 30 and condensed to become a liquid, and then expanded by the expansion valve 31. When passing through the heat exchanger 32, the gaseous refrigerant H1 receives heat from the room air. It absorbs and evaporates and cools the room 11.
During the heating operation by the indoor unit 23, the heat exchangers 30 and 32 function as an evaporator and a condenser, respectively, and the refrigerant H1 circulating in the circulation circuit 27 absorbs heat absorbed from outside air when passing through the heat exchanger 30. The room 11 is warmed by dissipating heat to the room 11 when passing through the heat exchanger 32.

The indoor unit 23 includes a cross flow fan 35 that takes in indoor air into a casing provided with a heat exchanger 32 and discharges the air into the room. The indoor air is taken into the housing of the indoor unit 23 by the operation of the cross flow fan 35, and after the heat is exchanged with the refrigerant H1 flowing in the heat exchanger 32 and cooled (or after being warmed), To be released.

As shown in FIG. 3, the compressor 29, the expansion valve 31, the four-way valve 33, and the cross flow fan 35 are signal-connected to the control means 17 comprising a microcomputer, and the compressor 29, the expansion valve 31, the four-way valve 33, and the like. The cross flow fan 35 operates according to a command signal transmitted from the control means 17.
A controller 36 is signal-connected to the control means 17, and the cooling temperature (the same applies to the heating temperature) input from the controller 36 is stored in the control means 17 as a set temperature.
The control means 17 adjusts the rotation speed of the compressor 29 according to the stored set temperature of the cooling / heating temperature, and adjusts the amount of the refrigerant H1 discharged from the compressor 29 per unit time.

As shown in FIG. 2, the outdoor unit 25 is provided with a propeller fan 37 that promotes heat exchange of the heat exchanger 30, and the casing of the outdoor unit 25 has two on-off valves provided in the circulation circuit 27. 38 is attached. The on-off valve 38 is normally open and is closed during maintenance. The propeller fan 37 is signal-connected to the control means 17 as shown in FIG.
As shown in FIGS. 2 and 3, the circulation circuit 27 is provided with temperature sensors 39, 40 and 41 connected to the control means 17. The temperature sensor 39 measures the temperature of the refrigerant H1 discharged from the compressor 29, and the temperature sensor 40 measures the temperature of the refrigerant H1 flowing in the heat exchanger 32. The temperature sensor 41 is disposed between the heat exchanger 32 and the compressor 29, measures the temperature of the refrigerant H1 sent from the heat exchanger 32 during the cooling operation, and refrigerant H1 before flowing into the heat exchanger 32 during the heating operation. Measure the temperature.
The control means 17 adjusts the rotation speed of the compressor 29 and the opening degree of the expansion valve 31 based on the measured values of the temperature sensors 39, 40, 41. In the present embodiment, the thermistors are used for the temperature sensors 39, 40, and 41.

As shown in FIG. 2, the circulation circuit 27 branches from the circulation circuit 27 between the heat exchanger 30 and the expansion valve 31 and joins the circulation circuit 27 between the heat exchanger 32 and the compressor 29. Are connected.
In the branch path 42, a water heat exchanger that cools or warms the expansion valve 43 that depressurizes the refrigerant H1 flowing in the branch path 42 and the heat medium H2 (antifreeze liquid in the present embodiment) supplied to the temperature control panels 14-16. 44 is provided.

The expansion valve 43 is a fully-closed electronic expansion valve, and is signal-connected to the control means 17 (see FIG. 3), and adjusts the flow rate of the refrigerant H1 flowing through the branch path 42 by a command signal transmitted from the control means 17, or The refrigerant H1 is prevented from being supplied to the branch path 42.
A circulation circuit 45 in which the heat medium H2 circulates is connected to the water heat exchanger 44, and the water heat exchanger 44 heats between the refrigerant H1 that circulates in the circulation circuit 27 and the heat medium H2 that circulates in the circulation circuit 45. Exchange. A circulation pump 46 attached to the circulation circuit 45 and signal-connected to the control means 17 circulates the heat medium H2 to the circulation circuit 45 and supplies the water heat exchanger to the temperature control panels 14 to 16 connected to the circulation circuit 45. The heat medium H2 heat-exchanged at 44 is supplied.
The circulation circuit 45 is provided with a water supply tank 47 for storing the heat medium H2.

The temperature control panel 14 includes an in-panel circuit 14a into which the heat medium H2 that has passed through the water heat exchanger 44 flows, and the room 11 is floor-cooled or heated by the heat medium H2 that flows through the in-panel circuit 14a. The temperature control panels 15 and 16 are also provided with in-panel circuits 15a and 16a that perform the same operation as the in-panel circuit 14a, respectively.
The temperature control panels 14 to 16 are connected in parallel by a circulation circuit 45. On the downstream side of the temperature control panel 14 along the flow direction of the heat medium H2 circulating in the circulation circuit 45, there is provided an on-off valve 49 and a temperature sensor 50 that are connected to the control means 17 as shown in FIG. ing.

The control means 17 stores a floor cooling temperature (cooling temperature) that serves as a reference when controlling the floor cooling of the temperature control panel 14, and the floor cooling temperature of the temperature control panel 14 is determined during the floor cooling operation. The temperature of the heat medium H2 measured by the temperature sensor 50 is compared, and the on-off valve 49 is opened and closed as necessary.
Specifically, when the temperature corrected by the temperature sensor 50 becomes lower than the floor cooling temperature of the temperature control panel 14, the on-off valve 49 is closed to lower the floor cooling level by the temperature control panel 14, and the on-off valve 49 The open / close valve 49 is opened after the closed state continues for a predetermined time. Here, the temperature corrected by the temperature measured by the temperature sensor 50 is used to correct the difference between the temperature measured by the temperature sensor 50 and the temperature of the floor cooled by the temperature control panel 14.

As shown in FIG. 2, the on-off valve 51 and the temperature sensor 52 are also provided on the downstream side of the temperature control panel 15, and the on-off valve 53 and the temperature sensor 54 are provided on the downstream side of the temperature control panel 16. And the control means 17 has memorize | stored each floor cooling temperature of the temperature control panels 15 and 16, and controls the floor cooling by the temperature control panels 15 and 16 on the basis of each floor cooling temperature. Since the on-off valves 51 and 53 and the temperature sensors 52 and 54 have the same configuration and function as the on-off valve 49 and the temperature sensor 50, respectively, detailed description thereof is omitted. As the on-off valves 49, 51 and 53, proportional valves capable of adjusting the opening degree can be used.
The arrangement of the temperature sensor provided for adjusting the floor cooling is not limited to the arrangement of the temperature sensors 50, 52, and 54 of the present embodiment, and for example, along the flow of the heat medium H2 during the floor cooling. In addition, a temperature sensor may be provided on the upstream side of the point where the circulation circuit 45 on the upstream side of the temperature control panels 14 to 16 branches.
Moreover, the control means 17 has memorize | stored floor heating temperature in addition to floor cooling temperature about each of the temperature control panels 14-16.

When the floor cooling operation by the temperature control panels 14 to 16 is performed simultaneously, the control means 17 uses the lowest floor cooling temperature among the floor cooling temperatures of the temperature control panels 14 to 16 as a reference. The number of revolutions of 29 is determined. Accordingly, the heat medium H2 circulating in the circulation circuit 45 passes through the water heat exchanger 44 and is sent to the temperature control panels 14 to 16 at a temperature corresponding to the lowest floor cooling temperature.
The water heat exchanger 44 is provided with temperature sensors 55 and 55a for measuring the temperature of the heat medium H2 on the inlet side and the outlet side of the heat medium H2, respectively. The temperature sensors 55 and 55a are as shown in FIG. The signal is connected to the control means 17. The control means 17 detects the temperature of the heat medium H2 circulating through the circulation circuit 45 from the measured temperatures of the temperature sensors 55 and 55a, and adjusts the rotational speed of the compressor 29 and the opening degree of the expansion valve 43.

The set temperature of the floor cooling temperature (the same applies to the floor heating temperature) of the temperature control panels 14 to 16 is changed by an input operation from the controller 36. In addition, in this Embodiment, although the controller is one, you may provide a separate controller with respect to each of the temperature control panels 14-16.
Two open / close valves 56 provided in the circulation circuit 45 are attached to the casing of the outdoor unit 25. The on-off valve 56 is normally open and is closed during maintenance.

Moreover, the ventilation apparatus 21 which ventilates the rooms 11-13 has the suction duct 20 in which the several suction inlets 18 and 19 were formed and it connected with the housing | casing 58, as shown in FIG. 1, FIG. .
An exhaust path 59 for discharging the air taken into the housing 58 through the suction duct 20 to the outside of the housing 58 is formed in the housing 58. The suction duct 20 is connected to one side of the exhaust path 59, and the exhaust duct 60 that sends the air that has passed through the exhaust path 59 to the outside is connected to the other side of the exhaust path 59. As shown in FIGS. 3 and 4, a fan 61 that is signal-connected to the control means 17 is installed in the exhaust path 59. The fan 61 draws air in the rooms 11 to 13 from the suction ports 18 and 19. 20, and is discharged to the outside through the exhaust passage 59 and the exhaust duct 60.
The suction duct 20 has a branch path in which the suction port 18 is formed and a branch path in which the suction port 19 is formed, and downstream of the point where the two branch paths merge along the air flow of the suction duct 20. Since the air is taken into the suction duct 20 from the suction ports 18 and 19, the air is mixed in the suction duct 20 and then flows into the exhaust passage 59. The air taken in from the suction ports 18 and 19 and mixed in the suction duct 20 is hereinafter also referred to as “collected air”.

In addition, as shown in FIGS. 1 and 4, an air intake duct 63 that connects an air supply path 62 formed in the housing 58 and the outside is connected to the housing 58. The air intake duct 63 is connected to one side of the air supply path 62, and the other side of the air supply path 62 is a blowout for sending outside air taken into the air supply path 62 through the air intake duct 63 to the rooms 11 to 13. A duct 64 is connected.
As shown in FIG. 1, the outlet duct 64 has an upstream end connected to the housing 58 along the air flow in the outlet duct 64, and is branched into a plurality (two in this embodiment) on the downstream side. doing. An air outlet 64a that supplies outside air to the room 11 is formed on one side of the branch path, and an air outlet 64b that supplies outside air to the room 12 and an air outlet 64c that supplies outside air to the room 13 are on the other side of the branch path. Is formed. As shown in FIGS. 3 and 4, the air supply passage 62 is provided with a fan 65 that is signal-connected to the control means 17.
The fan 65 operates in response to a command signal from the control means 17 and supplies outside air to the rooms 11 to 13 through the intake duct 63, the air supply path 62, and the blowout duct 64.

In the present embodiment, since the air outlet 64a is on the living side of the room 11 and the suction port 18 is arranged on the kitchen side of the room 11, the outside air sent from the outside is supplied to the living room, and from the room 11 to the outside The air exhausted is sucked by the kitchen and sent to the outdoors.
Moreover, the blower outlets 64b and 64c are each provided in the room | chambers 12 and 13, and the suction inlet 19 is arrange | positioned in the corridor 73 of the 2nd floor in which the room | chambers 12 and 13 are located. And the room 12 (the same applies to the room 13) and the hallway 73 are in a state in which air flows back and forth through the opening formed in the lower part of the door even if the door that partitions the room 12 and the hallway 73 is closed. is there. Accordingly, outside air from the outside is supplied to the rooms 12 and 13, and the air staying in the rooms 12 and 13 moves to the corridor 73 and passes through the suction port 19, the suction duct 20, the exhaust path 59 and the exhaust duct 60. Are discharged outdoors.
The reason for this air flow is to supply fresh outdoor air taken from the outdoors to a space where residents spend a lot of time, and residents spend a lot of time staying indoors. It is based on the design philosophy of moving to an empty space and discharging it outdoors.

As shown in FIG. 4, the ventilation device 21 includes a desiccant rotor 66 that adjusts humidity and a sensible heat exchange rotor 67 that adjusts temperature in a housing 58.
The desiccant rotor 66 is formed of a laminated body such as a corrugated plate or a honeycomb so that the air flowing through the exhaust passage 59 and the air supply passage 62 flows therethrough, and the surface is covered with a hygroscopic material. It arrange | positions so that the path | route 59 may be interrupted | blocked. The desiccant rotor 66 rotates by receiving a driving force from a well-known electric motor, and moves moisture from the high relative humidity side of the air supply path 62 and the exhaust path 59 to the low side.
In the present embodiment, a polymeric absorbent material is used as the hygroscopic material, but it is also possible to use silica gel or zeolite.

Two heat exchangers 68 and 69 are provided in the exhaust path 59, and two heat exchangers 70 and 71 are also provided in the air supply path 62. The heat exchangers 68 and 70 are provided with a compressor and are connected by a circulation circuit (not shown) through which the refrigerant circulates. One of the heat exchangers 68 and 70 functions as an evaporator, and the other functions as a condenser. Which of the heat exchangers 68 and 70 is the evaporator and which is the condenser is determined by the flow direction of the refrigerant circulating in the circulation circuit.
The heat exchangers 69 and 71 also have the same relationship as that of the heat exchangers 68 and 70, one functioning as a condenser and the other functioning as an evaporator.

The moisture absorbent adhering to the surface of the desiccant rotor 66 is heated to release moisture adsorbed on the moisture absorbent, and can be repeatedly used to regenerate moisture.
When the heat exchangers 68 and 69 function as a condenser, the heat exchanger 68 heats the moisture absorbent of the desiccant rotor 66 that is adsorbing moisture so that the moisture can be adsorbed. The heat exchanger 69 is provided to reliably condense the refrigerant circulating in the circulation circuit provided with the heat exchangers 69 and 71.
And when the heat exchanger 71 is functioning as a condenser, it heats the hygroscopic material of the desiccant rotor 66 so that it can adsorb moisture.
The heat exchanger 70 is provided for warming or cooling the outside air flowing through the air supply path 62 and is not used for regenerating the hygroscopic material of the desiccant rotor 66.

Similarly to the desiccant rotor 66, the sensible heat exchange rotor 67 is made of a laminated body such as a corrugated plate or a honeycomb so that the air flowing through the exhaust passage 59 and the air supply passage 62 flows through the air supply passage. 62 is arranged on the downstream side of the desiccant rotor 66 so as to block the air supply passage 62 and the exhaust passage 59 along the flow of outside air traveling from the outside toward the rooms 11 to 13.
The sensible heat exchange rotor 67 rotates using a known electric motor as a power source, absorbs heat from the higher temperature side in the outside air flowing in the air supply path 62 and the indoor air flowing in the exhaust path 59, and moves to the lower temperature side. Dissipate heat.

Thus, since the desiccant rotor 66, the sensible heat exchange rotor 67, and the heat exchangers 68 to 71 are provided in the ventilation device 21 in addition to the fans 61 and 65, the ventilation device 21 includes the indoors 11 to 13. At the same time as ventilation, dehumidifying cooling and moisturizing warming can be performed.
When performing dehumidification cooling with ventilation with respect to the rooms 11-13, the heat exchangers 68 and 69 function as a condenser, and the heat exchangers 70 and 71 function as an evaporator. The outside air taken into the air supply path 62 through the intake duct 63 is cooled by the heat exchanger 71 and dehumidified by the desiccant rotor 66, and then passes through the sensible heat exchange rotor 67 and the heat exchanger 70 in order. It is further cooled and flows into the rooms 11 to 13 through the blowout duct 64.

The room air taken into the exhaust passage 59 via the suction duct 20 passes through the sensible heat exchange rotor 67 and the heat exchanger 68 in order and then rises in temperature, and then passes through the desiccant rotor 66 and the heat exchanger 69. It passes through and is discharged to the outside through the exhaust duct 60.
When indoor air flows in the exhaust passage 59, the sensible heat exchange rotor 67 dissipates heat absorbed in the air supply passage 62 to the indoor air flowing in the exhaust passage 59, and the desiccant rotor 66 absorbs in the air supply passage 62. The released moisture is released to the indoor air flowing in the exhaust passage 59.

On the other hand, when performing humidification warming with ventilation with respect to the rooms 11-13, the heat exchangers 68 and 69 function as an evaporator, and the heat exchangers 70 and 71 function as a condenser.
The outside air taken into the air supply passage 62 via the intake duct 63 is warmed by the heat exchanger 71, the sensible heat exchange rotor 67 and the heat exchanger 70, is humidified by the desiccant rotor 66, and passes through the blowout duct 64. It flows into the rooms 11-13.
The indoor air taken into the exhaust passage 59 via the suction duct 20 is absorbed by the sensible heat exchange rotor 67, further absorbed by the heat exchangers 68 and 69, and absorbed by the desiccant rotor 66, and then the exhaust duct. It is discharged to the outside through 60.

The casing 58 of the ventilation device 21 is provided with a temperature / humidity sensor 72, which is an example of temperature / humidity detection means, in the exhaust path 59. Since the temperature / humidity sensor 72 is arranged on the upstream side of the sensible heat exchange rotor 67 along the air flow in the exhaust passage 59, the temperature / humidity sensor 72 is taken in from the plurality of suction ports 18, 19 and in the suction duct 20. The temperature and humidity of the mixed air that has been mixed are measured by the temperature and humidity sensor 72 before the temperature and humidity change in the exhaust path 59.

As shown in FIG. 3, the control means 17 is signal-connected to the temperature / humidity sensor 72, and can acquire the temperature and humidity of the collective air measured by the temperature / humidity sensor 72 from the temperature / humidity sensor 72.
The control means 17 is provided with an arithmetic circuit that outputs a dew point temperature when temperature and humidity are inputted. The control means 17 obtains the dew point temperature from the measured temperature and the measured humidity of the temperature / humidity sensor 72 using this arithmetic circuit, and cools the floor cooling by the temperature control panels 14 to 16 based on the obtained dew point temperature as necessary. Adjust the level (cooling strength). The adjustment of the cooling level of the floor cooling is performed in order to prevent condensation on the floors of the rooms 11 to 13 that are cooled by the temperature control panels 14 to 16.

The control means 17 obtains the dew point temperature from the measured temperature and the measured humidity of the temperature / humidity sensor 72 at a predetermined time interval when at least one of the temperature control panels 14 to 16 is performing the floor cooling. The determination target temperature is calculated based on the temperature. And whenever the determination means temperature is calculated, the control means 17 compares floor cooling temperature with the calculated determination object temperature about the temperature control panels 14-16 which are performing floor cooling.
And as a result of the comparison, when it is detected that the floor cooling temperature is higher than the determination target temperature for all of the temperature control panels 14 to 16 performing the floor cooling, the control means 17 sets the floor at the preset temperature. About the temperature control panels 14-16 which are cooling, the state, ie, the state which is performing the floor cooling temperature by preset temperature, is maintained.

On the other hand, as a result of comparing the determination target temperature and the floor cooling temperature for the temperature control panels 14 to 16 performing the floor cooling, the floor cooling temperature is included in the temperature control panels 14 to 16 performing the floor cooling according to the set temperature. When it is detected that there is a temperature below the determination target temperature, the corresponding temperature control panels 14 to 16 (that is, the temperature control panels 14 to 16 that perform the floor cooling at the floor cooling temperature equal to or lower than the determination target temperature). The cooling temperature is changed from the set temperature to a dew condensation prevention temperature that is higher than the determination target temperature.
The temperature control panels 14 to 16 having the cooling temperature set to the dew condensation prevention temperature are controlled by the control means 17 to control the floor cooling based on the dew condensation prevention temperature.
Therefore, the temperature control panels 14 to 16 normally perform the cooling operation by setting the set temperature determined by the control means 17 to the floor cooling temperature, and when the set temperature becomes lower than the determination target temperature, the cooling by the dew condensation prevention temperature is performed. It will be switched to driving.

Here, the temperature to be judged is calculated by adding or subtracting the predetermined temperature to the dew point temperature (hereinafter also referred to as “dew point temperature of the collective air”) obtained from the measured temperature and measured humidity of the temperature / humidity sensor 72. The dew point temperature of the collective air can be used as the target temperature for determination, and which method is used to derive the target temperature is determined by the location of the inlet and the temperature control panel. It can be selected depending on whether an indoor unit is provided in the room.

In a house where some or all of the air inlets are arranged in a space where the cooling by the indoor unit is not performed (in this embodiment, the corridor 73), and the temperature control panel and the indoor unit are provided in all the rooms, When cooling is performed by an indoor unit, the gathered air is usually at a higher temperature than the room in which the temperature control panel and the indoor unit are provided.
For this reason, the temperature lower than the dew point temperature of the collective air can be set as the determination target temperature, that is, the temperature obtained by subtracting the predetermined temperature from the dew point temperature of the collective air can be set as the determination target temperature.
However, when the indoor unit is not cooled in all the rooms where the temperature control panel is provided, there is no difference between the temperature of the collective air and the room where the temperature control panel is provided. However, it is necessary to give priority to not generating condensation rather than performing floor cooling at the set temperature by the temperature control panel, and it is preferable to set a temperature obtained by adding a predetermined temperature to the dew point temperature of the collective air as the determination target temperature.

A room in which all the air inlets are arranged in a space (in this embodiment, the room 11) where the cooling is performed by the indoor unit, and only the temperature control panel is provided (in this embodiment, the room 13 corresponds to this). In some houses, the gathered air is usually cooler than the room where only the temperature control panel is provided due to the cooling effect of the indoor unit.
For this reason, in order not to cause dew condensation, it is necessary to set a temperature higher than the dew point temperature of the collective air as the determination target temperature, that is, a temperature obtained by adding a predetermined temperature to the dew point temperature of the collective air as the determination target temperature. It is.

In houses other than the above, i.e., where the temperature of the collective air is higher or lower than the temperature of the room where the temperature control panel is provided, the dew point of the collective air is determined by the cooling condition of the indoor unit. By setting the temperature higher than the temperature as the determination target temperature, that is, by setting the temperature obtained by adding a predetermined temperature to the dew point temperature of the collective air as the determination target temperature, it is possible to stably prevent dew condensation.
From the above, it can be said that it is desirable to set the temperature obtained by adding a predetermined temperature to the dew point temperature of the collective air as the determination target temperature from the viewpoint of reliably preventing condensation.

The predetermined temperature that is added to or subtracted from the dew point temperature of the collective air in calculating the determination target temperature can be changed by setting by an input operation from the controller 36, and when the predetermined temperature is α, In the present embodiment, α is 0 ° C. <α ≦ 9 ° C.
Further, the dew condensation prevention temperature is a temperature obtained by adding β ° C. to the determination target temperature, and β can be set by an input operation from the controller 36 in a range of 0 ° C. or more and 5 ° C. or less.
Thus, the maintenance person can change α and β by an operation from the controller 36 while actually confirming whether or not condensation occurs on the floor during floor cooling.

The control means 17 acquires the temperature and humidity of the collective air measured by the temperature / humidity sensor 72 even when at least one of the temperature control panels 14 to 16 is performing the floor cooling at the dew condensation prevention temperature, A calculation process for calculating the determination target temperature from the acquired value is performed at predetermined time intervals.
Then, each time the control unit 17 calculates the determination target temperature, the control unit 17 compares the calculated determination target temperature with the set temperature of the temperature control panels 14 to 16 that perform floor cooling at the dew condensation prevention temperature. When it is detected that the temperature is lower than the set temperature, the cooling temperature of the temperature control panels 14 to 16 is returned from the dew condensation preventing temperature to the set temperature.
By performing such control, the control means 17 can prevent the floor from condensing even in the room 12 that is cooled by the indoor unit 24 that does not belong to the air conditioning facility 10.

Further, when at least one of the temperature control panels 14 to 16 is performing floor cooling at the dew condensation prevention temperature, the control means 17 causes the temperature control panel (temperature control panels 14 to 16) to prevent dew condensation. Display that floor cooling is performed at temperature.
The controller 36 includes a display, and displays the temperature control panels 14 to 16 that perform floor cooling at the dew condensation prevention temperature.
In the present embodiment, the controller 36 is a display means for displaying that the floor cooling is performed at the dew condensation prevention temperature. However, an electric lamp (for example, an LED) connected to the control means 17 as a signal is provided in the rooms 11 to 13. The electric lamp may be a display means for displaying that the floor cooling is performed at the dew condensation prevention temperature.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and all changes in conditions and the like that do not depart from the gist are within the scope of the present invention.
For example, the temperature control panel may be installed not in the floor but in an indoor space to directly cool or warm the indoor space. Moreover, what has only the ventilation function which cannot perform dehumidification cooling and moisturizing warming can be used for a ventilator. Then, the temperature and humidity of the collective air may be measured using two types of sensors, a temperature sensor and a humidity sensor, instead of the temperature and humidity sensor. In addition, the temperature / humidity sensor can be arranged at a position where the test shows the same effect or at a more severe condition (for example, in the vicinity of a washroom or piping).

10: Air conditioning equipment, 11-13: Indoor, 14: Temperature control panel, 14a: Circuit in panel, 15: Temperature control panel, 15a: Circuit in panel, 16: Temperature control panel, 16a: Circuit in panel, 17: Control Means, 18, 19: Suction port, 20: Suction duct, 21: Ventilator, 22: House, 23, 24: Indoor unit, 25, 26: Outdoor unit, 27, 28: Circulation circuit, 29: Compressor, 30 : Heat exchanger, 31: Expansion valve, 32: Heat exchanger, 33: Four-way valve, 35: Cross flow fan, 36: Controller, 37: Propeller fan, 38: Open / close valve, 39-41: Temperature sensor, 42: Branch path, 43: expansion valve, 44: water heat exchanger, 45: circulation circuit, 46: circulation pump, 47: water supply tank, 49: on-off valve, 50: temperature sensor, 51: on-off valve, 52: temperature sensor, 53: On-off valve, 54: Temperature sensor 55, 55a: temperature sensor, 56: on-off valve, 58: housing, 59: exhaust path, 60: exhaust duct, 61: fan, 62: air supply path, 63: intake duct, 64: outlet duct, 64a 64b, 64c: outlet, 65: fan, 66: desiccant rotor, 67: sensible heat exchange rotor, 68-71: heat exchanger, 72: temperature and humidity sensor, 73: corridor

Claims (7)

A plurality of temperature control panel for cooling a plurality of indoor respectively, said control means defining the cooling temperature of the temperature control panel, said plurality of indoor air it ipecac to the suction duct through a suction port is discharged to the outdoor In an air conditioning system having a ventilation device for indoor ventilation,
A temperature / humidity detection means for measuring the temperature and humidity of the plurality of indoor air taken in and mixed with the suction duct, and the control means has a dew point determined from the measurement temperature and the measurement humidity of the temperature / humidity detection means; The temperature to be judged is calculated based on the temperature, and when it is detected that the cooling temperature of the temperature control panel that is performing cooling at the set temperature determined by the control means is equal to or lower than the temperature to be judged, the temperature An air conditioning system characterized in that the cooling temperature of the control panel is changed from the set temperature to a dew condensation prevention temperature higher than the determination target temperature. 2. The air conditioning system according to claim 1, wherein the control means calculates the determination target temperature lower than the set temperature of the temperature control panel in a state where the temperature control panel performs cooling at the dew condensation prevention temperature. The air conditioner characterized in that the cooling temperature of the temperature control panel is returned to the set temperature. 3. The air conditioning equipment according to claim 1, wherein the control means displays on the display means signal-connected to the control means that the temperature control panel performs cooling at the condensation prevention temperature. Air conditioning equipment. The air-conditioning equipment according to any one of claims 1 to 3, wherein the ventilation device has a casing to which the suction duct is connected, and the temperature and humidity detection means is provided in the casing. Characteristic air conditioning equipment. The air conditioning equipment according to any one of claims 1 to 4, wherein the temperature control panel is disposed on a floor and performs floor cooling. 6. The air conditioning equipment according to claim 1, wherein the control unit calculates the determination target temperature by adding a predetermined temperature to a dew point temperature obtained from the measured temperature and the measured humidity of the temperature / humidity detecting unit. Air conditioning equipment characterized by The air conditioning equipment according to claim 6, wherein the predetermined temperature added to the dew point temperature in calculating the determination target temperature can be changed by setting.

Images