JP4917506B2 - Indoor air conditioning system - Google Patents

Description

  The present invention relates to an indoor air conditioning system capable of controlling the room temperature for each living room by operating an indoor air conditioner based on an appropriately set mode.

  Conventionally, for example, when a room is used, the temperature in a room such as a hotel guest room is controlled based on a predetermined set temperature set by an operation panel provided in each room. It is common (patent document 1).

Japanese Patent Laid-Open No. 10-141749 (page 3, FIG. 2)

  However, in Patent Document 1, when the user does not use the living room, the indoor air conditioner is not operating and the living room is close to the outside temperature, so the user returns to the living room. There was a problem that the room was extremely cold or hot when it arrived, and the comfort of using the room was difficult.

  The present invention has been made paying attention to such problems, and provides comfort when the user enters the room by maintaining a predetermined temperature even when the user does not use the room. An object of the present invention is to provide an indoor air-conditioning system that can be used.

In order to solve the above-described problem, an indoor air conditioning system according to claim 1 of the present invention includes:
An indoor air conditioning system capable of controlling the room temperature for each living room by operating an indoor air conditioner based on an appropriately set mode,
A first room temperature sensor for detecting a room temperature; and an operation unit capable of setting and inputting a first set temperature, wherein the first room temperature sensor and the operation unit are powered on. An indoor air conditioner that operates based on a temperature detected by the first room temperature sensor with respect to a set temperature of
A discriminating means for discriminating whether the room is in use or non-use;
A power on / off unit for turning on or off the first room temperature sensor and the operation unit power of the indoor air conditioner;
A second room temperature sensor for detecting room temperature;
Temperature setting means capable of setting a second set temperature consisting of a predetermined upper limit temperature and / or lower limit temperature;
A control unit to which the determination unit, the power on / off unit, the second room temperature sensor, and the temperature setting unit are connected;
With
The power on / off unit is based on control by the control unit,
At the time when the use state of the living room is determined by the determining means,
Turn on the first room temperature sensor of the indoor air conditioner that operates based on the temperature detected by the first room temperature sensor with respect to the first set temperature and the power supply for the operation unit ,
At the time when the non-use state of the living room is determined by the determining means,
When the temperature detected by the second room temperature sensor is lower than the upper limit temperature set by the temperature setting means, or when the temperature is higher than the lower limit temperature, the first temperature relative to the first set temperature is set. The first room temperature sensor of the indoor air conditioner that operates based on the temperature detected by the room temperature sensor and the power source for the operation unit are turned off, and the temperature detected by the second room temperature sensor is the temperature setting means. If exceeds the set upper limit temperature by, or if you are below the lower limit temperature, the indoor air conditioner that operates on the basis of the first said relative set temperature first temperature sensed by the temperature sensor The first room temperature sensor and the operation unit power supply are turned on.
According to this feature, even when the living room is not used, which is determined by the determining means, the power on / off unit is connected to the air conditioner by the relationship between the temperature detected by the second room temperature sensor and the second set temperature. Since the power can be turned on or off and the room temperature can be maintained in the vicinity of the second set temperature, comfort can be provided when the user enters the room. Further, in the non-use state, the second function is performed by using the function of the indoor air conditioner that operates based on the room temperature detected by the first room temperature sensor with respect to the first set temperature that is set when the user is in the room. By turning on and off the power to the indoor air conditioner based on the room temperature sensor, the air conditioning can be performed to a second set temperature that is higher or lower than the first set temperature.

The indoor air conditioning system according to claim 2 of the present invention is the indoor air conditioning system according to claim 1,
The indoor air conditioner having a switching unit capable of switching the first room temperature sensor and the operation unit power supply to an on state or a off state;
The control unit,
The indoor air conditioner and the control unit are connected via a signal line.
According to this feature, the control unit is connected to the control unit via the signal line by turning the power on / off unit on or off based on the determination unit, the second room temperature sensor, and the temperature setting unit. Thus, the switching unit of the indoor air conditioner can be switched, and the indoor air conditioner can be easily and reliably controlled from the outside with a simple structure.

The indoor air conditioning system according to claim 3 of the present invention is the indoor air conditioning system according to claim 2,
A timer that continues to turn off the first room temperature sensor of the indoor air conditioner and the operation unit is connected to the control unit ,
The controller is
At the time when the non-use state of the living room is determined by the determining means,
Prior to the second room temperature sensor, the first room temperature sensor of the indoor air conditioner and the time when the set time set by the timer elapses from the time when the power supply for the operation unit is turned off . One of the room temperature sensors and the operation unit power supply is turned off, and after the set time has elapsed, a cut-off state continuation control is performed in which control is performed based on the second room temperature sensor.
According to this feature, in the non-use state of the living room, the control unit performs the cut-off state continuation control in which the power-off state for the indoor air conditioner is continued for at least a set time by the timer. The frequency of switching to the on state can be reduced, and the load applied to the indoor air conditioner by switching the power source can be suppressed.

The indoor air conditioning system according to claim 4 of the present invention is the indoor air conditioning system according to claim 2,
The controller is connected to a timer that continues to turn on the first room temperature sensor and the operation unit power of the indoor air conditioner,
The controller is
At the time when the non-use state of the living room is determined by the determining means,
Prior to the second room temperature sensor, the first room temperature sensor of the indoor air conditioner and the power source for the operation unit are turned on until the set time set by the timer elapses . The on-state continuation control is performed in which the on-state of the first room temperature sensor and the operation unit power supply is continued, and control is performed based on the second room temperature sensor after the set time has elapsed.
According to this feature, in the non-use state of the living room, the control unit performs the on-state continuation control for continuing the power-on state of the indoor air conditioner for at least a set time by the timer. The frequency of switching to the cut-off state can be reduced, and the load applied to the indoor air conditioner by switching the power supply can be suppressed.

The indoor air conditioning system according to claim 5 of the present invention is the indoor air conditioning system according to claim 2,
The controller is connected to a timer that continues the on / off state of the first room temperature sensor of the indoor air conditioner and the operation unit power supply,
The controller is
At the time when the non-use state of the living room is determined by the determining means,
Prior to the second room temperature sensor, the first room temperature sensor of the indoor air conditioner and the time when the set time set by the timer elapses from the time when the power supply for the operation unit is turned off . A switch-off state continuation control in which the switch-off state of the first room temperature sensor and the operation unit power supply is continued, and control is performed based on the second room temperature sensor after the set time has elapsed;
Prior to the second room temperature sensor, the first room temperature sensor of the indoor air conditioner and the power source for the operation unit are turned on until the set time set by the timer elapses . On- state continuation control for continuing the on-state of the room temperature sensor of 1 and the operation unit power supply and controlling based on the second room temperature sensor after elapse of the set time;
It is characterized by repeatedly performing.
According to this feature, in the non-use state of the living room, the control unit repeatedly performs the cut-off state continuation control and the turn-on state continuation control so that the power-on state and the cut-off state of the indoor air conditioner are changed. The switching frequency can be further reduced, and the load applied to the indoor air conditioner can be suppressed as much as possible.

An indoor air conditioning system according to claim 6 of the present invention is the indoor air conditioning system according to any one of claims 1 to 5,
The discriminating means is an entrance / exit sensor for discriminating entrance / exit into the living room,
The second room temperature sensor is provided in the entrance / exit room sensor.
According to this feature, since the second room temperature sensor is provided in the entrance / exit sensor that determines whether the room is entered / exited, the components of the indoor air conditioning system arranged in the room can be consolidated. In addition, it is easy to wire and arrange the entrance / exit sensors.

The indoor air conditioning system according to claim 7 of the present invention is the indoor air conditioning system according to claim 6,
The entrance / exit sensor is installed in the vicinity of the entrance in the living room.
According to this feature, the second room temperature sensor is provided in the entrance / exit sensor installed in the vicinity of the entrance of the living room, and the room can be air-conditioned based on the temperature in the vicinity of the entrance. Therefore, the room has entered the unused room. In other words, it is possible to spend comfortably in the vicinity of the entrance when shifting from the non-use state to the use state.

The indoor air conditioning system according to claim 8 of the present invention is the indoor air conditioning system according to any one of claims 1 to 7,
A room temperature sensor for confirmation to detect the room temperature,
A detection unit for detecting a temperature difference between the room temperature detected by the confirmation room temperature sensor and the room temperature detected by the second room temperature sensor;
When the temperature difference is less than a predetermined value, the second room temperature sensor is in a normal state, and when the temperature difference exceeds a predetermined value, the second room temperature sensor is in an error state. It is characterized in that the error state is notified as being.
According to this feature, the temperature difference between the room temperature detected by the confirmation room temperature sensor and the room temperature detected by the second room temperature sensor is detected by the detection unit, and the temperature difference is 0 or slightly different. By confirming the above, it is possible to improve the reliability of the room temperature detected by the second room temperature sensor.

  Examples of the present invention will be described below.

  An embodiment of the present invention will be described with reference to the drawings. First, FIG. 1 (a) is a configuration diagram showing an indoor air conditioning system in an embodiment of the present invention, and (b) is a room temperature operation panel of an indoor air conditioner. FIG. FIG. 2 is a schematic diagram illustrating a wiring state of the power supply unit. FIG. 3 is a front view showing the key unit. FIG. 4 is a front view showing the switch unit. FIG. 5 is a timing chart showing ON / OFF of the card key and the indoor air conditioner. FIG. 6A is a configuration diagram showing the operation of the indoor air conditioner when the card key is inserted, and FIG. 6B shows the operation of the indoor air conditioner when the card key is extracted. It is a block diagram. FIG. 7 is a flowchart showing each control mode of the indoor air conditioner. FIG. 8 is a flowchart of the non-use state mode of the indoor air conditioner.

  First, FIG. 1A shows the overall configuration of an indoor air conditioning system for a hotel or the like as an embodiment of the present invention. The hotel guest room 1 which is the room of the present invention can be entered / exited by an opening / closing door 5 which can be unlocked by a card key. In the guest room 1, a bus 2, a desk 3, and a bed 4 are arranged, and electric devices such as a bus lighting 6, a bed lighting 7, a desk lighting 8, and a television 9 each have a power cable. Via the power supply unit 11.

  As shown in FIG. 1B, 12 is a so-called package type indoor air conditioner that is individually arranged in each cabin 1, and includes a first room temperature sensor 14 that detects the room temperature of the cabin 1. And a room temperature operation panel 22 as an operation unit capable of setting and inputting a first set temperature desired by the user, and a control unit 34 to which these are connected. It operates on the basis of the temperature detected by the first room temperature sensor 14 with respect to the temperature, and air having an air volume and temperature set appropriately is blown into the cabin 1. Although not shown in detail about the internal structure of the indoor air conditioner 12, it has various parts such as a fluid pipe that forms a circulation path, a pump that circulates a heat exchange fluid inside the fluid pipe, and a fan for blowing air. Each of these components operates based on the control of the control unit 34.

  In addition, as shown in FIGS. 1A, 1B, and 2, the indoor air conditioner 12 is not connected to the power supply unit 11 and is connected to an external power source independently of other electrical devices. The indoor air conditioner 12 has a switching unit 33 that can be switched between the on state and the off state, and operates the main power switch 12b of the indoor air conditioner 12 or connects the signal line to the switching unit 33 via the contact 12a. The switching unit 33 can be turned on and off by the power on / off unit 15 connected at L. Specifically, a card key is inserted into the key unit 10, that is, in a usage state where a user is present in the cabin 1, and at a first set temperature set by the user of the cabin 1 as described later. A case where the indoor air conditioner 12 is actuated based on this is set as a use state mode. Further, a case where the card key is extracted from the key unit 10, that is, in a non-use state where the user leaves the guest room 1 and the guest room 1 where the user is absent is air-conditioned as described later, is set as a non-use state mode. Yes. That is, the use state mode or the non-use state mode of the indoor air conditioner 12 is selectively set based on the insertion / removal of the card key to / from the key unit 10.

  As shown in FIG. 3, the key unit 10 is an entrance / exit sensor that determines entrance / exit into the guest room 1 as a determination unit that determines whether the guest room 1 is in a use state or a non-use state. The room 1 is disposed on the wall surface of the entrance 1a, has a display unit 10a and a key insertion unit 10b on the front surface, and a second room temperature sensor 19 is provided. Further, a slide switch 30 used for cleaning the cabin 1 is installed on the lower surface of the key unit 10. In this way, by providing the second room temperature sensor 19 in the key unit 10, it is possible to consolidate the components of the indoor air conditioning system disposed in the cabin 1, so that the wiring of the second room temperature sensor 19 and the key unit 10 Easy to arrange.

  As illustrated in FIG. 2, the power supply unit 11 includes terminals d1 to d6, terminals e1 to e8, and terminals f1 to f4, and includes a control unit 13 to which these terminals are connected. The control unit 13 is connected to a timer 21 and a confirmation room temperature sensor 29 described later, and a switch unit 20 as temperature setting means, and is connected to the key unit 10 and the second room temperature sensor 19 through signal lines. In addition, it is connected to the indoor air conditioner 12 through a signal line L that can be opened and closed by a power on / off unit 15.

  External power is input to the power supply unit 11 via terminals d1 to d4, and a normal power cable is connected to terminals d5 and d6 and terminals e3 and e4 that are directly connected to the terminals d1 to d4, respectively. It is wired and appropriately connected to an outlet (not shown) in the guest room 1, and power is always supplied regardless of whether the guest room 1 is used or not used. In addition, terminals e2 and e6 are connected to terminals d2 and d4 via switches 16 and 17, respectively, and an energy-saving power cable is appropriately wired in the cabin 1 to terminals e1 and e2 and terminals e5 and e6. When a card key is inserted into the key unit 10, the control unit 13 connected to the key unit 10 closes the switch 16 and the switch 17, and the power is supplied to the power cable for energy saving. . 1 are connected to the power supply unit 11 via the power-saving power cable, and the card key is the guest room 1. The bus lighting 6, the bed lighting 7, the desk lighting 8, and the television 9 shown in FIG. When it is inserted into the key unit 10 installed on the wall surface of the inlet portion 1 a, power is supplied through the power supply unit 11. Further, in these electric devices, when the card key is extracted from the key unit 10, the power supply is stopped in the power supply unit 11. Further, by turning on / off the entrance lamp switch 31 connected to the terminals f1 and f2, the entrance lamp 32 connected to the terminals e7 and e8 via the control unit 13 is turned on or off. ing.

  Next, regarding the air conditioning of the guest room 1, the use state mode will be described. First, the use state of the guest room 1 is a state in which a card key is inserted in the key unit 10, that is, a user is present in the guest room 1. I mean. The usage state mode set in this usage state refers to a mode in which the room temperature can be controlled by the user of the cabin 1 pressing the room temperature operation panel 22.

  The room temperature operation panel 22 is mainly arranged on the wall surface of the cabin 1 so as to be operable by the cabin user, and the air volume can be set on the front surface thereof as shown in FIG. An ON switch 24 for operating the indoor air conditioner 12, a temperature setting switch 25 capable of setting a desired indoor temperature as a first set temperature, and a first set temperature set by the temperature setting switch 25 are displayed. A set temperature display unit 26 and an OFF switch 27 for stopping the operation of the indoor air conditioner 12 are provided. Further, the ON switch 24 includes three types of switches: a LO switch 24a, a HI switch 24b, and an AUTO switch 24c. When one of the switches 24a to 24c is pressed in the usage state of the passenger compartment 1 in which the card key is inserted into the key unit 10, it is activated in the pressed predetermined mode. An operation display lamp 28 displays whether the indoor air conditioner 12 is in an operating state. If the OFF switch 27 is pressed, the operation of the indoor air conditioner 12 is stopped.

  Further, the main body of the indoor air conditioner 12 is provided with a first room temperature sensor 14 for detecting the temperature in the cabin 1, and when the AUTO switch 24c is pressed, the first temperature set by the temperature setting switch 25 is set. The set temperature of 1 is compared with the temperature in the passenger compartment 1 detected by the first room temperature sensor 14, and air is blown so that the air volume can be changed as appropriate.

  Next, the non-use state mode will be described. First, the non-use state of the guest room 1 means a state in which the card key has been extracted from the key unit 10, that is, the user has left the guest room 1. . The non-use state mode set in the non-use state is control for turning on the indoor air conditioner 12 or turning off the power to the indoor air conditioner 12 in accordance with conditions described later. Is repeated and repeated.

  In the cooling season of the present embodiment, the indoor air conditioner 12 is controlled so as to keep the temperature in the cabin 1 lower than 30 degrees or 27 degrees as the upper limit temperature that is the second preset temperature. is there. The second set temperature in the cooling season is set higher than the first set temperature (24 degrees in this embodiment) that is normally set in the use state of the guest room and lower than the outside temperature. Even when the guest room 1 is not in use, the temperature of the guest room 1 is lowered to a certain extent to pursue comfort when entering the room.

  In the heating season, the indoor air conditioner 12 is controlled so as to maintain the temperature in the cabin 1 higher than 17 degrees or 20 degrees as the lower limit temperature that is a second preset temperature set in advance. The second set temperature in the heating season is set to be lower than the first set temperature normally set in the use state of the guest room and higher than the outside air temperature, and in the non-use state of the guest room 1 However, the temperature of the guest room 1 is raised to a certain degree in order to pursue comfort when entering the room.

  Hereinafter, it is assumed that the present embodiment is in the cooling season, and in the use state mode, the set air volume “strong wind” is set on the room temperature operation panel 22 and “24 ° C.” is set as the first set temperature. In the description, it is assumed that “30 ° C.” is set as the upper limit temperature that is the second set temperature.

  As shown in FIG. 4, regarding the setting of the non-use state mode, the non-use state mode in the cooling season can be set by turning on the first switch in the switch unit 20 provided in the power supply unit 11. In this case, the second set temperature can be set to 30 ° C by turning on the second switch, or the second set temperature can be set to 27 ° C by turning off the second switch. it can. Similarly, the non-use state mode in the heating season can be set by turning on the third switch, and in this case, the second set temperature is set to 17 ° C. by turning on the fourth switch. The second set temperature can be set to 20 ° C. by setting the No. 4 switch to the OFF state.

  It is also possible to select not to implement the non-use state mode by turning off both the second switch and the fourth switch. For example, the non-use state mode is often not implemented in the spring and autumn when neither air conditioning nor heating is required. In addition, the switch part 20 is normally arrange | positioned in the location which cannot be operated by the user of a hotel, and it is comprised so that the hotel manager may operate it suitably.

  Next, the operation of the indoor air conditioner 12 in the use state mode and the non-use state mode of the cabin 1 will be described with reference to the timing chart shown in FIG.

  First, in the use state mode between t0 and t1 when the card key is inserted into the key unit 10, the indoor air conditioner 12 is operated based on the first set temperature “24 ° C.” set on the room temperature operation panel 22. Air conditioning. At t1, the card key is removed from the key unit 10 to shift to the non-use state mode. In the non-use state mode between t1 and t6, the indoor air conditioner 12 alternately repeats the power-on state or the off-state according to the room temperature in the guest room 1 detected by the second room temperature sensor 19, Air conditioning is performed so that the temperature in 1 falls below the upper limit temperature “30 ° C.” that is the second set temperature.

  More specifically, regarding the control of the indoor air conditioner 12 between t1 and t6, the operation of the indoor air conditioner 12 stops at t1 to t2 after shifting to the non-use state mode at t1 where air conditioning has been performed until then. However, the temperature of the guest room 1 approaches the outside air temperature and becomes high. Then, at t2, the temperature of the cabin 1 detected by the second room temperature sensor 19 exceeds the upper limit temperature “30 ° C.” that is the second set temperature, and the indoor air conditioner 12 starts operating.

  At t2, the indoor air conditioner 12 that has once started operation has been operated for 5 minutes, which is the set time set by the timer 21, in preference to the second room temperature sensor 19, and when 5 minutes have passed ( After t2 ′), the operation stops at the time (t3) when the temperature of the cabin 1 falls below the upper limit temperature “30 ° C.”. Control for continuously operating the indoor air conditioner 12 at t2 to t3 in preference to the second room temperature sensor 19 is referred to as on-state continuation control in the non-use state mode.

  At time t3, the indoor air conditioner 12 that has been temporarily stopped is prior to the second room temperature sensor 19 and is continuously stopped for 5 minutes, which is the set time set by the timer 21, and when 5 minutes have passed ( After t3 ′), the operation starts again at the time (t4) when the temperature of the passenger compartment 1 exceeds the upper limit temperature “30 ° C.”. The control for continuously stopping the indoor air conditioner 12 at t3 to t4 in preference to the second room temperature sensor 19 is referred to as cut-off state continuation control in the non-use state mode.

  Thereafter, the on-state continuation control (t4 to t5) and the cut-off state continuation control (t5 to t6) are repeatedly performed in the non-use state mode. And in a present Example, in the middle of this cut-off state continuation control (t6), a user enters into the guest room 1 and the guest room 1 becomes a use state again.

  In this way, even when the cabin 1 is not in use, the power on / off unit 15 controlled by the control unit 13 is in the room according to the relationship between the temperature detected by the second room temperature sensor 19 and the second set temperature. Since the air conditioner 12 can be turned on or off and the room temperature can be maintained in the vicinity of the upper limit temperature “30 ° C.” that is the second set temperature, the user can comfortably enter the room at t6. Can give

  In the heating season, the indoor air conditioner 12 is turned on or off, and the room temperature can be maintained in the vicinity of the lower limit temperature “20 ° C.” or “17 ° C.” that is the second set temperature.

  Furthermore, since the temperature of the guest room in the non-use state can be maintained below the second set temperature “30 ° C.” and can be brought close to the first set temperature “24 ° C.” in advance, the user enters the guest room 1 at t6. Later, in the use state mode shown between t6 and t7, the temperature of the cabin 1 can be quickly reached to the desired first set temperature “24 ° C.”.

  Further, in this way, in the non-use state of the cabin 1, the control unit 13 performs the cut-off state continuation control in which the power-off state for the indoor air conditioner 12 is continued for at least the set time (5 minutes) by the timer 21. The frequency of switching from the power-off state to the on-state to the machine 12 can be reduced, and the load applied to the indoor air conditioner 12 by switching the power supply can be suppressed.

  Further, in the non-use state of the cabin 1, the control unit 13 performs the on-state continuation control for continuing the power-on state of the indoor air conditioner 12 at least for a set time (5 minutes) by the timer 21, The frequency of switching from the on state to the off state can be reduced, and the load applied to the indoor air conditioner 12 by switching the power source can be suppressed.

  Furthermore, in the non-use state of the cabin 1, the control unit 13 repeatedly switches between the on state and the off state of the indoor air conditioner 12 by repeatedly performing the off state continuation control and the on state continuation control. By reducing the frequency further, the load applied to the indoor air conditioner 12 can be suppressed as much as possible.

  In addition, since the second room temperature sensor 19 is provided in the key unit 10 installed in the entrance 1a that is in the vicinity of the entrance in the cabin 1, and the cabin 1 can be air-conditioned based on the temperature in the entrance 1a, it is not used. When entering the guest room 1 (t6), that is, at the entrance 1a when shifting from the non-use state to the use state, it can be comfortably spent.

  As shown in FIGS. 6A to 6C, the mode setting described above will be specifically described. The power supply unit 11 and the indoor air conditioner 12 are connected via a signal line, that is, the key unit 10. And the indoor air conditioner 12 are connected via a control unit 13 as mode setting means. From terminals f3 and f4 to which signal lines are connected, wirings extend to c contact and a contact, respectively, and a power on / off unit 15 for selectively switching between c contact and a contact or b contact is provided.

  Then, as illustrated in FIG. 6A, when the card key K is inserted into the key unit 10, the control unit 13 sets the usage state mode. That is, since the control unit 13 connects the power on / off unit 15 to the contact a to close the signal line, the switching unit 33 is closed and the indoor air conditioner 12 is turned on. The indoor air conditioner 12 can be operated based on the room temperature operation panel 22.

  Further, when the card key K is extracted from the key unit 10, the control unit 13 sets the non-use state mode as shown in FIG. 6B. That is, as described above, based on the timer 21 and the second room temperature sensor 19, the control unit 13 connects the power on / off unit 15 to the b contact and opens the signal line, thereby switching the unit 33. Is opened, and the power to the indoor air conditioner 12 is turned off, so that the operation control of the indoor air conditioner 12 becomes impossible. Alternatively, as shown by the dotted line in FIG. 6B, based on the timer 21 and the second room temperature sensor 19, the control unit 13 connects the power on / off unit 15 to the contact a and closes the signal line. As a result, the switching unit 33 is closed and the indoor air conditioner 12 is turned on, so that the indoor air conditioner 12 can be operated based on the room temperature operation panel 22.

  Thus, in the non-use state, the function of the indoor air conditioner 12 that operates based on the room temperature detected by the first room temperature sensor 14 with respect to the first set temperature that is set when the user is in the cabin 1. Utilizing and turning on / off the power to the indoor air conditioner 12 based on the second room temperature sensor 19 makes it possible to air-condition to a second set temperature higher than the first set temperature in the cooling season.

  Further, as described above, the control unit 13 turns the power on / off unit 15 on or off based on the key unit 10, the second room temperature sensor 19, and the switch unit 20. The switching unit 33 of the indoor air conditioner 12 connected via L can be switched, and the indoor air conditioner 12 can be easily and reliably controlled from the outside with a simple structure.

  Next, as shown in FIG. 7, the air conditioning control in each mode will be described in detail with reference to a flowchart. First, when a card key is inserted into the key unit in S1, the process proceeds to S2 and the use state mode is selected. The In this use state mode, when the user of the cabin 1 presses the ON switch 24 of the room temperature operation panel 22 (S3), the process proceeds to S4, where the indoor air conditioner 12 can be controlled in accordance with the set condition, and the air volume By selecting and appropriately pressing the ON switch 24 and the temperature setting switch 25, desired air conditioning can be performed. Naturally, the indoor air conditioner 12 can also be stopped by pressing the OFF switch 27.

  Next, when the card key is extracted from the key unit in S1, the process proceeds to S5 to determine the ON / OFF state of the cooling season (heating season) use switch of the switch unit 20 to use the cooling season (heating season). When the switch is in the ON state, the non-use state mode is selected. At this time, regardless of the state in which the indoor air conditioner 12 is activated at the predetermined first set temperature or the desired air volume, or the state in which the indoor air conditioner 12 has been deactivated, in the use state mode described above, When the card key is extracted from the key unit, the mode is forcibly shifted from the use state mode to the non-use state mode.

  As shown in FIG. 8, in the non-use state mode, first, the current room temperature of the cabin 1 is detected by the second room temperature sensor 19 near the entrance 1a of the cabin 1 at T1. Next, the indoor air conditioner 12 is activated when the current room temperature detected at T2 reaches a preset second preset temperature (T3). More specifically, for example, when the current room temperature is higher than the upper limit temperature “30 ° C.” as the second set temperature in the cooling season, the indoor air conditioner 12 is activated. Further, when the current room temperature detected by the second room temperature sensor 19 at T2 is lower than the second set temperature “30 ° C.”, the indoor air conditioner 12 does not start and proceeds to T1 and continues. The second room temperature sensor 19 detects the current room temperature. Generally, immediately after shifting from the use state mode appropriately air-conditioned to the non-use state mode, the current room temperature does not exceed the upper limit temperature “30 ° C.” that is the second set temperature, but the passage of time At the same time, as the current room temperature approaches the outside air temperature, the current room temperature exceeds the second set temperature “30 ° C.”.

  The timer starts simultaneously with the activation of the indoor air conditioner 12 (T3), proceeds to T4, and the indoor air conditioner 12 continues to operate until a preset time (5 minutes) elapses. . Then, with the elapse of 5 minutes, the timer is reset (T5), the process proceeds to T6, and the second room temperature sensor 19 detects the current room temperature of the cabin 1. Next, when the detected current room temperature falls below the upper limit temperature “30 ° C.” that is the second set temperature (T7), the process proceeds to T8 and the indoor air conditioner 12 is stopped. That is, the indoor air conditioner 12 continues until the set time (5 minutes) has elapsed and the current room temperature detected by the second room temperature sensor 19 falls below the second set temperature “30 ° C.”. It is configured to operate. Control related to the continuation of the operation of the indoor air conditioner 12 described above is referred to as on-state continuation control in the non-use state mode.

  The air emitted from the indoor air conditioner 12 in the non-use state mode is the air volume and the air temperature set last in the use state mode immediately before the non-use state mode. For example, if the user has set the set air volume “strong wind” and the first set air temperature “24 ° C.” on the room temperature operation panel 22 immediately before leaving the guest room 1, the non-use after the user leaves the room 1 In the state mode, air having the set air volume “strong wind” and the set air temperature “24 ° C.” is emitted for the time described above.

  Subsequently, at T8, the timer starts simultaneously with the stop of the indoor air conditioner 12, and the indoor air conditioner 12 continues to stop until a preset time (5 minutes) elapses (T9). As the set time elapses, the process proceeds to T10, the timer is reset, and the process proceeds to T1 again to detect the current room temperature of the cabin 1 by the second room temperature sensor 19. Next, when the detected current room temperature exceeds the upper limit temperature “30 ° C.” that is the second set temperature (T2), the process proceeds to T3 and the indoor air conditioner 12 is activated again. That is, the indoor air conditioner 12 has passed the set time (5 minutes) and until the time (T2) when the current room temperature detected by the second room temperature sensor 19 again exceeds the second set temperature “30 ° C.”. Has been made to stop continuously. The control related to the continuation of the stop of the indoor air conditioner 12 is referred to as a cut-off state continuation control in the non-use state mode.

  Hereinafter, similarly, the on-state continuation control and the off-state continuation control described above are repeatedly performed in the non-use state mode. In the non-use state mode described above, it is not used when the card key is inserted into the key unit regardless of the state in which the on-state continuation control is being performed or the state in which the cut-off state continuation control is being performed. The mode is forcibly shifted to the usage mode.

  In the heating season, contrary to the above, when the temperature is lower than the lower limit temperature “20 ° C.” or “17 ° C.” which is the second set temperature, the indoor air conditioner 12 is turned on. When the lower limit temperature is exceeded, the indoor air conditioner 12 is turned off.

  Next, the use state of the guest room 1 determined by the card key being inserted into the key unit 10 or the non-use state of the guest room 1 determined by the card key being removed from the key unit 10 is determined. The identification information is displayed on the display unit provided at the front of the hotel, and the use / non-use state of the guest room 1 can be grasped collectively at the front. Further, when the interior of the cabin 1 is to be cleaned, the card key is inserted into the key unit 10 and the slide switch 30 provided on the lower surface of the key unit 10 is switched, whereby the above-described usage state of the cabin 1 or non-use. In addition to the state, the cleaning state of the cabin 1 can be identified and displayed.

  In addition, a confirmation room temperature sensor 29 having the same specifications as the second room temperature sensor 19 provided in the key unit 10 is disposed inside the power supply unit 11 and is detected by the second room temperature sensor 19. The difference between the current room temperature detected and the current room temperature detected by the confirmation room temperature sensor 29 is calculated by the control unit 13 serving as a detection unit. When the difference is less than a predetermined value set in advance, the second room temperature sensor 19 is assumed to be in a normal state, and normal control is performed, and the difference exceeds the predetermined value. Furthermore, it is preferable that the second room temperature sensor 19 is in an error state due to a failure or the like so that the error state can be notified. Thus, the temperature difference between the temperature detected by the confirmation room temperature sensor 29 and the temperature detected by the second room temperature sensor 19 is detected by the control unit 13, and this temperature difference is 0 or a slight difference. By confirming this, the reliability of the temperature detected by the second room temperature sensor 19 can be enhanced.

  Although the embodiments of the present invention have been described with reference to the drawings, the specific configuration is not limited to these embodiments, and modifications and additions within the scope of the present invention are included in the present invention. It is.

  For example, in the above embodiment, the upper limit temperature “27 ° C.” or “30 ° C.” as the second set temperature can be alternatively selected in the cooling season, but the upper limit temperature is generally set in the cooling season. As long as the temperature is higher than the first set temperature, the temperature is not limited to the above-described temperature. For example, the temperature may be set steplessly. Similarly, in the heating season, the lower limit temperature “17 ° C.” or “20 ° C.” can be alternatively selected as the second set temperature, but the lower limit temperature is generally set in the heating season. As long as the temperature is lower than the first set temperature, the temperature is not limited to the above-described temperature. For example, the temperature may be set steplessly.

  Further, for example, in the above embodiment, the set time is 5 minutes, but is not necessarily limited to this time, and may be, for example, 3 minutes or 10 minutes, or may be set in a stepless manner. Furthermore, the set time for continuing the activation of the indoor air conditioner and the set time for continuing the stop are not limited to the same time but may be different times.

  Further, for example, in the above-described embodiment, the indoor air conditioner 12 is a so-called individual type package type air conditioner arranged for each guest room. It may be a package type air conditioner of the type, or may be a fan coil type air conditioner.

  In addition, for example, a plurality of second room temperature sensors are provided at appropriate positions in the cabin, and an average value of room temperatures detected by the plurality of second room temperature sensors is calculated, and air conditioning is performed based on the average value. It may be.

  Further, for example, when a plurality of indoor air conditioners are installed at appropriate positions in the guest room, a plurality of second room temperature sensors may be provided to individually correspond to these indoor air conditioners. Only one may be provided so as to correspond to all the machines.

(A) is a block diagram which shows the indoor air conditioning system in the Example of this invention, (b) is a front view which shows the room temperature operation panel of an indoor air conditioner. It is the schematic which shows the condition of the wiring of a power supply unit. It is a front view which shows a key unit. It is a front view which shows a switch part. It is a timing chart which shows ON / OFF of a card key and an indoor air conditioner. (A) is a block diagram which shows the action | operation of the indoor air conditioner in case the card key is inserted, (b) is a block diagram which shows the action | operation of the indoor air conditioner in case the card key is extracted. It is. It is a flowchart which shows each control mode of an indoor air conditioner. It is a flowchart about the non-use state mode of an indoor air conditioner.

Explanation of symbols

1 Guest room 1a Entrance 10 Key unit (discriminating means, entrance / exit sensor)
11 Power supply unit 12 Indoor air conditioner 13 Control unit (detection unit)
14 First room temperature sensor 15 Power on / off section 19 Second room temperature sensor 20 Switch section (temperature setting means)
21 Timer 22 Room temperature operation panel (operation unit)
25 Temperature setting switch 29 Room temperature sensor 33 for confirmation

Claims (8)

An indoor air conditioning system capable of controlling the room temperature for each living room by operating an indoor air conditioner based on an appropriately set mode,
A first room temperature sensor for detecting a room temperature; and an operation unit capable of setting and inputting a first set temperature, wherein the first room temperature sensor and the operation unit are powered on. An indoor air conditioner that operates based on a temperature detected by the first room temperature sensor with respect to a set temperature of
A discriminating means for discriminating whether the room is in use or non-use;
A power on / off unit for turning on or off the first room temperature sensor and the operation unit power of the indoor air conditioner;
A second room temperature sensor for detecting room temperature;
Temperature setting means capable of setting a second set temperature consisting of a predetermined upper limit temperature and / or lower limit temperature;
A control unit to which the determination unit, the power on / off unit, the second room temperature sensor, and the temperature setting unit are connected;
With
The power on / off unit is based on control by the control unit,
At the time when the use state of the living room is determined by the determining means,
Turn on the first room temperature sensor of the indoor air conditioner that operates based on the temperature detected by the first room temperature sensor with respect to the first set temperature and the power supply for the operation unit ,
At the time when the non-use state of the living room is determined by the determining means,
When the temperature detected by the second room temperature sensor is lower than the upper limit temperature set by the temperature setting means, or when the temperature is higher than the lower limit temperature, the first temperature relative to the first set temperature is set. The first room temperature sensor of the indoor air conditioner that operates based on the temperature detected by the room temperature sensor and the power source for the operation unit are turned off, and the temperature detected by the second room temperature sensor is the temperature setting means. If exceeds the set upper limit temperature by, or if you are below the lower limit temperature, the indoor air conditioner that operates on the basis of the first said relative set temperature first temperature sensed by the temperature sensor An indoor air conditioning system in which a first room temperature sensor and the operation unit power supply are turned on. The indoor air conditioner having a switching unit capable of switching the first room temperature sensor and the operation unit power supply to an on state or a off state;
The control unit,
The indoor air conditioning system according to claim 1, wherein the indoor air conditioner and the control unit are connected via a signal line. A timer that continues to turn off the first room temperature sensor of the indoor air conditioner and the operation unit is connected to the control unit ,
The controller is
At the time when the non-use state of the living room is determined by the determining means,
Prior to the second room temperature sensor, the first room temperature sensor of the indoor air conditioner and the time when the set time set by the timer elapses from the time when the power supply for the operation unit is turned off . 3. The switch-off state continuation control is performed in which the switch-off state of the first room temperature sensor and the operation unit power supply is continued, and control is performed based on the second room temperature sensor after the set time has elapsed. The indoor air conditioning system described. The controller is connected to a timer that continues to turn on the first room temperature sensor and the operation unit power of the indoor air conditioner,
The controller is
At the time when the non-use state of the living room is determined by the determining means,
Prior to the second room temperature sensor, the first room temperature sensor of the indoor air conditioner and the power source for the operation unit are turned on until the set time set by the timer elapses . 3. The on-state continuation control is performed in which the on-state of the first room temperature sensor and the operation unit power supply is continued, and control is performed based on the second room temperature sensor after the set time has elapsed. The indoor air conditioning system described. The controller is connected to a timer that continues the on / off state of the first room temperature sensor of the indoor air conditioner and the operation unit power supply,
The controller is
At the time when the non-use state of the living room is determined by the determining means,
Prior to the second room temperature sensor, the first room temperature sensor of the indoor air conditioner and the time when the set time set by the timer elapses from the time when the power supply for the operation unit is turned off . A switch-off state continuation control in which the switch-off state of the first room temperature sensor and the operation unit power supply is continued, and control is performed based on the second room temperature sensor after the set time has elapsed;
Prior to the second room temperature sensor, the first room temperature sensor of the indoor air conditioner and the power source for the operation unit are turned on until the set time set by the timer elapses . On- state continuation control for continuing the on-state of the room temperature sensor of 1 and the operation unit power supply and controlling based on the second room temperature sensor after elapse of the set time;
The indoor air conditioning system according to claim 2, wherein the step is repeatedly and repeatedly performed. The discriminating means is an entrance / exit sensor for discriminating entrance / exit into the living room,
The indoor air conditioning system according to any one of claims 1 to 5, wherein the second room temperature sensor is provided in the entrance / exit sensor.   The indoor air conditioning system according to claim 6, wherein the entrance / exit sensor is installed in the vicinity of an entrance in a living room. A room temperature sensor for confirmation to detect the room temperature,
A detection unit for detecting a temperature difference between the room temperature detected by the confirmation room temperature sensor and the room temperature detected by the second room temperature sensor;
When the temperature difference is less than a predetermined value, the second room temperature sensor is in a normal state, and when the temperature difference exceeds a predetermined value, the second room temperature sensor is in an error state. The indoor air conditioning system according to any one of claims 1 to 7, wherein the error state is notified as being .

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