JP3245418U - Control device - Google Patents

Abstract

An object of the present invention is to provide a control device that can maintain the aesthetic appearance of a living room without requiring the labor and effort of extending a signal line cable for transmitting a predetermined mode setting based on the presence/absence state of a living room to a load device. [Solution] A control device includes a detection means that detects the presence or absence of a user in a living room, and receives a detection signal from the detection means and sets a usage mode or non-use mode of the living room for load equipment based on the detection signal. a processing means 11 having a control section 13 for setting a mode to a mode, a wireless transmission section 19 for wirelessly transmitting a mode setting signal of any mode set by the control section 13 using radio waves; and a living room separated from the processing means 11. wireless receiving sections 21 and 31 that are provided at predetermined locations in the interior of the device and receive mode setting signals; and a switch section 27 that supplies or cuts off power to predetermined load devices based on the mode setting signals received by the wireless receiving sections 21 and 31. , 37a to 37c. [Selection diagram] Figure 3

Description

The present invention relates to a control device that can control load equipment for each room based on a mode that is appropriately set.

The conventional control device determines the presence or absence of a user in the living room by detecting the insertion/removal state of the opening/closing door key for entering/exiting the living room into the key unit, and the control unit: Based on this determination, the load equipment is set to a predetermined mode (see, for example, Patent Document 1).

Japanese Patent Application Publication No. 2009-74742 (Page 10, Figure 6)

However, in Patent Document 1, since the control unit needs to set a predetermined mode based on the presence/absence state for each load device installed at various places in the living room, the control unit and the individual Not only does it take time and effort to extend a signal line cable to transmit the settings of a predetermined mode between the load device and the device, but there is a risk that the aesthetics of the living room may be spoiled.

The present invention was developed with a focus on these problems, and requires the labor and effort of extending a signal line cable to transmit the setting of a predetermined mode based on the presence/absence of a room to the load equipment. First, the purpose is to provide a control device that can maintain the aesthetic appearance of a living room.

In order to solve the above problems, the control device of the present invention has the following features:
A control device capable of controlling load equipment for each room based on an appropriately set mode,
Detection means for detecting the presence or absence of a user in the living room;
a control unit that receives a detection signal from the detection means and sets the load equipment to a use mode or a non-use mode of the room based on the detection signal; and a mode setting signal for any of the modes set by the control unit. a wireless transmitter that wirelessly transmits the information using radio waves;
a wireless receiving section that is provided at a predetermined location in the living room separated from the processing means and receives the mode setting signal; and supplying or cutting off power to a predetermined load device based on the mode setting signal received by the wireless receiving section. a remote tap having a switch portion configured to
It is characterized by being composed of.
According to this feature, in order to transmit and receive a mode setting signal for use/non-use mode of the room between the processing means and the remote tap separated from the processing means, there is a separate connection between the processing means and the remote tap. Not only does it not require the trouble of wiring signal line cables and improves the appearance of the living room, but if the detection means and processing means are already installed, simply adding a wireless transmitter and remote tap without using wires, The control device can be easily configured. Further, since the processing means and the remote tap communicate wirelessly using radio waves, the remote tap can be placed in a place where it is not exposed, such as behind a shield such as a headboard or a desk in the living room.

The radio waves are characterized by being extremely short waves having a frequency of 300 MHz to 3 GHz.
According to this feature, it is possible to suppress attenuation of radio waves due to shielding objects such as headboards and desks in the living room.

The wireless receiving section is paired with the wireless transmitting section provided in the same room as the wireless receiving section, and receives the mode setting signal transmitted from the paired wireless transmitting section. It is said that
According to this feature, since the wireless receiving section is paired with the wireless transmitting section in the same room, it is possible to prevent the wireless receiving section from accidentally receiving a mode setting signal transmitted from the wireless transmitting section in the next room. can.

The remote tap is connected to an external power source, and the external power source obtains standby power for the wireless receiving unit to receive a mode setting signal and supply power to be supplied to the predetermined load device. It is said that
According to this feature, both the standby power that the wireless receiving section of the remote tap requires at all times to receive mode setting signals and the power supplied to the load equipment are obtained from the external power supply, so wiring cords can be bundled together. Can be easily extended.

The processing means is configured to cause the detection means to detect the presence state of the user after the wireless transmission section transmits a mode setting signal for the non-use mode of the room based on the detection signal in which the detection means detects the presence state of the user. A predetermined non-use mode continuation signal is transmitted to continue the non-use mode of the room until the wireless transmitter transmits a mode setting signal for the use mode of the room based on the detected detection signal,
When the remote tap continues to receive the non-use mode continuation signal transmitted from the processing means, the switch section continues to cut off power to the predetermined load equipment, and the remote tap continues to receive the non-use mode continuation signal transmitted from the processing means. The present invention is characterized in that when reception of the non-use mode continuation signal is interrupted, the switch section supplies power to the predetermined load device.
According to this feature, when the reception of the unused mode continuation signal from the processing means is interrupted, it is assumed that an unexpected malfunction has occurred in the processing means, and in this case, a switch is made to supply power to a predetermined load device. By switching the parts, control can be performed with greater safety in mind.

The detection means is characterized in that it is a door sensor that detects movement of an opening/closing door for entering and exiting the living room, and/or a human sensor that detects the presence or absence of a user in the living room. .
According to this feature, by employing a highly versatile door sensor and/or human sensor as the detection means, the control device can be configured at low cost and easily.

The wireless receiver is attached to the outside of a metal chassis, and the wireless receiver and the outside of the chassis are covered with a resin case.
According to this feature, the radio receiving section can be stably attached to a high-strength chassis, and the outside of the radio receiving section can be protected by the resin case. Since the resin case transmits radio waves, it does not affect communication between the wireless receiving section and the wireless transmitting section.

1 is a configuration diagram showing a control device in Example 1 of the present invention; FIG. FIG. 3 is a schematic diagram showing the state of wiring of a power supply unit. FIG. 2 is a schematic diagram showing the configuration of a remote tap. FIG. 2 is a perspective view showing the configuration of a remote tap. This is a timing chart when a customer enters the room. This is a timing chart when a customer leaves the room. It is a block diagram which shows the control apparatus in Example 2 of this invention.

Embodiments for implementing the control device according to the present invention will be described below based on examples.

A control device according to a first embodiment will be described with reference to FIGS. 1 to 6.

First, FIG. 1 shows the overall configuration of an indoor air conditioning system for a hotel or the like as a first embodiment of the present invention. A hotel guest room 1, which is the living room of the present invention, can be entered and exited through an opening/closing door 5 that can be unlocked with a card key. The interior of the guest room 1 is mainly divided into a main room 10 in which a desk 3 and a twin bed 4 are arranged, and a bathroom 2.The bathroom lighting 6, the bed lighting 7, and the entrance lighting 8 are each connected to a power cable. It is connected to the power supply unit 11 as the processing means of the present invention via the main room lights 9A, 9B and 9C, and electrical equipment as load equipment such as a television, respectively, are connected to an external power supply. Furthermore, remote taps 20 and 30 connected to an external power source are provided at appropriate locations in the main room 10.

As shown in FIGS. 1 and 3, the remote tap 20 mainly uses a wireless receiving section 21 that receives radio waves as a mode setting signal (to be described later), and an external power supply based on the information of the radio waves received by the radio receiving section 21. It is comprised of a switching section 26 and a switch section 27 that cut off or supply external power by opening and closing a power cable to a power socket 28 connected to the power supply socket 28 . This wireless receiving section 21 is paired with an individual identification number of a wireless transmitting section 19 in the same guest room 1, which will be described later, and receives radio waves only from the paired wireless transmitting section 19. There is.

The structure of the remote tap 20 will be described in detail with reference to FIGS. 3 and 4. A control section 23, a switching section 26, a switch section 27, and the power cable are installed inside a metal chassis 24, and a wireless reception A section 21 is attached to the outside of the chassis 24. These control unit 23, switching unit 26, switch unit 27, wireless receiving unit 21, and chassis 24 are housed in a housing 22 as a resin case, and are protected from dust, impact, and the like. The casing 22 is an openable and closable box-like body consisting of a lid 22a and a case 22b.

This housing 22 is provided with a power socket 28 on the outer panel facing the users of the guest room 1, and is located in a relatively inconspicuous location away from the power supply unit 11 of the guest room 1 (for example, behind the nightstand). Ru. Further, the remote tap 20 obtains standby power for the wireless receiving unit 21 to receive radio waves and power to be supplied to the power socket 28 from an external power source. The chassis 24 may have a U-shaped cross section, or may be a box-like body that can be opened and closed and includes a lid and a case.

Next, another remote tap 30 includes a wireless receiving section 31 similar to the above-described remote tap 20, and each main room lighting 9A connected to an external power source, based on the radio wave information received by the wireless receiving section 31. It is composed of a switching section 36 that cuts off or supplies power by uniformly opening and closing the power cables to 9B and 9C, and switch sections 37a, 37b, and 37c. This wireless receiving section 21 is paired with an individual identification number of a wireless transmitting section 19 in the same guest room 1, which will be described later, and receives radio waves only from the paired wireless transmitting section 19. There is.

The structure of the remote tap 30 will be described in detail with reference to FIGS. 3 and 4. The control section 33, the switching section 36, the switch sections 37a, 37b, 37c, and the power cable are attached to the inside of a metal chassis 34. At the same time, a wireless receiving section 31 is attached to the outside of the chassis 34. The control section 33, the switching section 36, the switch sections 37a, 37b, 37c, the wireless receiving section 31, and the chassis 34 are housed in a housing 32 as a resin case, and are protected from dust, impact, and the like. The casing 32 is an openable and closable box-like body consisting of a lid 32a and a case 32b.

This housing 32 is disposed on the back side of the desk 3 in the guest room 1 where it is relatively inconspicuous. Further, the remote tap 30 obtains standby power for the wireless receiving section 31 to receive radio waves and power to be supplied to each of the main room lights 9A, 9B, and 9C from an external power source. Incidentally, the chassis 34 may have a U-shaped cross section or the like, or may be a box-like body that can be opened and closed and includes a lid and a case.

Next, as shown in FIG. 1, the opening/closing door 5 is provided with a door sensor 42 such as a well-known magnetic type that detects the movement of the opening/closing door 5, that is, the open state or the closed state. is connected to the power supply unit 11 via a signal cable.

A human sensor 40 such as a well-known infrared type that detects the presence of a person in the main room 10 based on the slight movement of a person is installed on the ceiling surface in the approximate center of the main room 10, and on the ceiling surface of the bathroom 2. A similar human sensor 41 is provided, and these human sensors 40, 41 are connected to the power supply unit 11 via a signal cable. That is, the door sensor 42 and the human sensors 40 and 41 constitute a detection means of the present invention that detects the presence or absence of a user in the guest room 1.

In addition, the human sensors 40 and 41 can sense almost the entire area inside the main room 10 and the bathroom 2, respectively, but the human sensor 40 in the main room 10 detects the area near the opening/closing door 5 in the guest room 1. It is assumed that the area around the entrance portion 1a cannot be sensed.

As shown in FIGS. 1 and 2, 12 is a so-called package type and fan coil type indoor air conditioner as a load device installed individually in each guest room 1, which detects the room temperature of the guest room 1. It has a room temperature sensor (not shown) that allows the user to set the desired temperature, a room temperature operation panel 18 as an operation unit that allows the user to set and input the desired set temperature, and a control unit to which these are connected. The air conditioner operates based on the temperature detected by the above-mentioned room temperature sensor relative to the desired set temperature, and blows air at an appropriately set air volume and temperature into the cabin 1. Although the internal structure of the indoor air conditioner 12 is not shown in detail, it has various parts such as a fluid pipe forming a circulation path, a pump that circulates heat exchange fluid inside the fluid pipe, and a fan for blowing air. Each of these parts operates under the control of the control section.

To explain the mode set by the power supply unit 11, after the opening/closing door 5 is opened/closed, that is, when there is a user in the guest room 1, the mode set by the user of the guest room 1 as described later. The indoor air conditioner 12 is operated based on the set temperature, and power is supplied to the power socket 28 and the main room lights 9A, 9B, and 9C in a usage mode or temporary usage mode. In addition, when the user is leaving the guest room 1, the guest room 1 where the user is not present is air-conditioned as described below, and the power to the power socket 28 and the main room lights 9A, 9B, and 9C is cut off. It is set to non-use mode.

As shown in FIG. 2, the power supply unit 11 includes terminals d1 to d10, terminals e1 to e7, terminals f1 to f8, and terminals g1 to g2, and the control unit 13 of the present invention to which these terminals are connected. have. Further, the control unit 13 is connected to a timer 15, which will be described later, and a switch unit 14 as a temperature setting means, and is also connected to a room temperature sensor (not shown) via a signal line, and is also connected to the indoor air conditioner 12 via a signal line. It is further connected to a wireless transmitter 19 that transmits predetermined radio waves based on a setting mode to be described later. Note that the wireless transmitter 19 is disposed at a predetermined location where it can easily transmit radio waves to the wireless receivers 21, 31 of all the remote taps 20, 30 via a signal line extending from the power supply unit 11.

Note that the radio waves of the present invention refer to electromagnetic waves having a frequency of 3 THz (3×10 ¹² Hz) or less, and as described later, in this embodiment, a frequency of 2.4 GHz band is used. There is.

External power is input to the power supply unit 11 through terminals d9 to d10. Terminal d9 is directly connected to terminals d1, d3, d5, and d7, respectively, and terminal d10 is connected to terminals d2, d4, d6, and d8 via switches 17a, 17b, 17c and 17d, respectively. An entrance light 8 equipped with an operating switch 8a is connected to the terminals d1 and d2 via a power cable, an outlet 43 is similarly connected to the terminals d3 and d4, and an operating switch 6a is attached to the terminals d5 and d6. A bathroom lighting 6 is connected to the terminals d7 and d8, and a bed lighting 7 equipped with an operation switch 7a is connected to the terminals d7 and d8. Each of the switches 17a to 17d can be turned on and off by a control section 13 connected via switching sections 16a to 16d, respectively.

An external power supply for the indoor air conditioner 12 is connected to the terminals e1 to e3, and an output line to the indoor air conditioner 12 is connected to the terminals e4 to e7.

A door sensor 42 is connected to the terminals f1 and f2, and they are also connected to the control section 13 within the power supply unit 11. The control unit 13 controls whether the door 5 is in the open state or not by controlling the circuit between f1 and f2 to be closed when the door 5 is closed, or by opening the circuit when the door 5 is open. Detects closed state.

The human sensor 40 of the main room 10 is connected to the terminals f3 to f5, and they are also connected to the control section 13 within the power supply unit 11. The control unit 13 operates such that the circuit between f3 and f4 is closed when the human sensor 40 is in a sensing state, or the circuit between f3 and f5 is closed when the human sensor 40 is in a non-sensing state. , the presence or absence of the user in the main room 10 is detected.

A human sensor 41 in the bathroom 2 is connected to the terminals f6 to f8, and they are also connected to the control section 13 within the power supply unit 11. The control unit 13 operates such that the circuit between f6 and f7 is closed when the human sensor 41 is in the sensing state, or the circuit between f6 and f8 is closed when the human sensor 41 is in the non-sensing state. , the presence or absence of the user in the bathroom 2 is detected.

Further, a communication line can be connected to the terminals g1 and g2, and the mode setting status by the control unit 13 can be transmitted to, for example, a hotel reception desk or a control room connected via this communication line.

Each of the lights 6 to 8, the main room lights 9A, 9B, and 9C, the power socket 28, the indoor air conditioner 12, etc. as load devices in the guest room 1 described above are set to the usage mode, provisional usage mode, or temporary usage mode by the control unit 13. The setting is controlled to one of the non-use modes. Here, the usage mode is a mode in which a user exists in guest room 1, and the provisional usage mode is a mode in which a user temporarily exists in guest room 1, and is a mode in which a user is temporarily present in guest room 1. The mode is a mode in which no user is present in the guest room 1. The control unit 13 sets the above-mentioned use mode, provisional use mode, or non-use mode based on the detection by the door sensor 42 and the human sensors 40 and 41.

As shown in FIG. 2, in the use mode and provisional use mode, each of the lights 6 to 8 is connected to an external power source by turning on each switch 17a, 17c, and 17d. The lighting 8, the bathroom lighting 6, and the bed lighting 7 can be turned on/off based on the on/off operation of the respective operation switches 8a, 6a, and 7a. Furthermore, in the non-use mode, each of the lights 6 to 8 is turned off by turning off the switches 17a, 17c, and 17d, thereby cutting off the connection to the external power source.

Similarly, in the use mode and temporary use mode, the main room lights 9A, 9B, and 9C are connected to the external power source by uniformly turning on the switch parts 37a, 37b, and 37c by the switching part 36. The main room lights 9A, 9B and 9C can be turned on and off based on the on/off operation using the operation switches 9a, 9b and 9c, respectively. In addition, in the non-use mode, the main room lights 9A, 9B, and 9C are all turned off because the switches 37a, 37b, and 37c are uniformly turned off, cutting off the connection to the external power source. It is supposed to be done.

Further, in the use mode and the temporary use mode, the power socket 28 is connected to an external power source when the switch section 27 is turned on by the switching section 26, and supplies power to electrical load devices such as a television and a personal computer. Furthermore, when the power socket 28 is in the non-use mode, the switch section 27 is turned off, thereby cutting off the connection to the external power source, and power is no longer supplied to the electrical load equipment.

Next, in the usage mode and the temporary usage mode, the indoor air conditioner 12 can arbitrarily control the room temperature by pressing the room temperature operation panel 18 by the user of the guest room 1.

The room temperature operation panel 18 is disposed on a wall or the like in the main room 10 so that it can be operated by a guest room user, and includes an ON switch that operates the indoor air conditioner 12 so that the air volume can be set, and a desired The indoor air conditioner 12 includes a temperature setting switch that can set the indoor temperature, a set temperature display section that displays the set temperature, and an OFF switch that stops the operation of the indoor air conditioner 12. Furthermore, the ON switch consists of three types of switches: an LO switch, a HI switch, and an AUTO switch. In the use mode and temporary use mode, if any switch is pressed, the device will start up at the predetermined set temperature and air volume. Further, if the OFF switch is pressed, the operation of the indoor air conditioner 12 is stopped.

In the non-use mode, the indoor air conditioner 12 automatically and repeatedly performs on/off control on the indoor air conditioner 12 in accordance with conditions to be described later. For example, in the cooling season, the indoor air conditioner 12 is automatically turned on using the above-mentioned room temperature sensor, etc. to maintain the temperature in the guest room 1 lower than a preset upper limit temperature (for example, 30 degrees or 27 degrees). /off control. The upper limit temperature in the cooling season is set higher than the desired setting temperature (24 degrees in this example) under the state of use of the guest room, and lower than the outside temperature. Even when the room is in use, the temperature of the guest room 1 is kept low to a certain degree to ensure comfort when entering the room. Furthermore, during the heating season, the indoor air conditioner 12 is controlled to maintain the temperature in the guest room 1 higher than a preset lower limit temperature (for example, 17 degrees or 20 degrees). The lower limit temperature in the heating season is set lower than the normally desired set temperature when the guest room is in use, and higher than the outside temperature. The temperature is kept high to a certain degree to ensure comfort when entering the room.

Note that, in the non-use mode, the indoor air conditioner is not necessarily limited to repeatedly performing the above-described on/off control; for example, in the non-use mode, the air conditioner may be controlled to always turn off.

Setting switching of each mode will be described in detail with reference to the timing charts of FIGS. 5 and 6.

First, setting switching from non-use mode to use mode will be explained.

As shown in FIG. 5, when a user enters the guest room, the user enters the guest room 1 in the non-use mode L from t0 to t1, that is, the room is empty, at t1, that is, the opening/closing door 5 By temporarily opening and then closing again, the door sensor 42 detects the open and closed states of the opening/closing door 5, and a detection signal of the open and closed states is transmitted to the control unit 13. The control unit 13, which has received the open state and closed state detection signals, switches the load devices such as the lights 6 to 8, 9A, 9B and 9C, the power socket 28, and the air conditioner 12 from the non-use mode L to the provisional use mode. M is set, and time measurement by the timer 15 is started.

Further, the control unit 13 transmits radio waves corresponding to the provisional usage mode M via the wireless transmission unit 19 while setting the provisional usage mode M described above. The control unit 23 of the remote tap 20 that has received the radio wave via the wireless reception unit 21 closes the switch unit 27 via the switching unit 26 to supply power to a load device such as a television via the power socket 28. Similarly, the control unit 33 of the remote tap 30 that has received the radio waves via the wireless reception unit 31 closes the switch units 37a, 37b, and 37c via the switching unit 36, thereby controlling each of the main room lights 9A, 9B, and 9C. to supply power.

The frequency of the radio waves in this embodiment uses the 2.4 GHz band, which can easily reach the back side of shields such as desks and walls. Note that the radio waves may be ultrashort waves having a frequency of 300 MHz to 3 GHz.

As a result, the remote taps 20 and 30 equipped with the wireless receiving sections 21 and 31 can be placed in a place where they are not exposed in the guest room 1, for example, the remote tap 20 can be placed on the back side of the night table, and the remote tap 30 can be placed on the back side of the desk 3. .

Furthermore, the wireless receiving sections 21 and 31 are paired in association with the individual identification numbers of the wireless transmitting sections 19 in the same guest room 1, and can only receive radio waves from the paired wireless transmitting sections 19. Therefore, if the control devices according to the present invention are used in adjacent guest rooms, the wireless transmitter 19 and the wireless receivers 21, 31 that are paired with each other can be used for each control device. Only the remote tap under control can be activated, and it is possible to prevent a problem in which an adjacent remote tap that is not under control (for example, a remote tap in an adjacent cabin) is erroneously activated.

To explain in detail the timing in the provisional usage mode M, the control unit 13 controls the timing when a predetermined initial time A (3 minutes in this embodiment) measured by the timer 15 has elapsed from the time t1 when the provisional usage mode M was set. Until t2, the detection signals from the human sensors 40 and 41 are ignored, and from t2 when the initial time A has elapsed, a predetermined room occupancy confirmation time B (30 minutes in this embodiment) measured by the timer 15 from t1 is set. ) until the elapsed time t3 (27 minutes in this embodiment), it waits to see if the human sensor 40 or the human sensor 41 detects a person. In other words, if the human sensor 40 or the human sensor 41 detects a person during the time from t2 to t3, the control unit 13 immediately sets the usage mode to N. If the human sensors 40 and 41 do not detect any person, the non-use mode L is set after t3 (see FIG. 5).

Note that the initial time A and the room occupancy confirmation time B are not necessarily limited to 3 minutes and 30 minutes, respectively, in this embodiment, and can be arbitrarily changed by a setting section (not shown) connected to the control section 13. do. For example, the initial time A may be set in units of 1 minute in the range of 1 to 7 minutes, and the occupancy confirmation time B may be set in units of 5 minutes in the range of 5 to 75 minutes.

A user who enters the guest room 1 by changing the opening/closing door 5 from the open state to the closed state is activated by the motion sensor 40 installed in the main room 10 or the motion sensor 41 installed in the bathroom 2 between t2 and t3. Therefore, as shown in FIG. 5, after the sensing, the usage mode N is set.

Next, setting switching from use mode to non-use mode will be explained.

As shown in FIG. 6, to explain the case where only one guest leaves the guest room, from t20 to t21, from usage mode N, that is, guest room 1, where the room is occupied, at t21, only one guest leaves the guest room. leaves the room, that is, temporarily opens the door 5 and closes it again, the door sensor 42 detects the open and closed states of the door 5, and the open and closed state detection signals are sent to the control unit. It will be sent on 13th. The control unit 13, which has received the open state and closed state detection signals, switches the load devices such as the lights 6 to 8, the main room lights 9A, 9B, and 9C, the power socket 28, and the indoor air conditioner 12 to the usage mode. From then on, the temporary use mode M is set, and the timer 15 starts measuring time.

Similarly to the above, the control unit 13 controls the detection signals from the human sensors 40 and 41 from the time t21 when the provisional usage mode M is set until the elapse of the predetermined initial time A measured by the timer 15 t22. It is ignored and waits for whether or not the human sensor 40 or the human sensor 41 detects a person during the period from time t22 when the initial time A has elapsed to time t23 when the room occupancy confirmation time B has elapsed.

Since the guest room 1 in which only one guest has left the room by changing the opening/closing door 5 from the open state to the closed state is not detected by the human sensor 40 or the human sensor 41 during the time from t22 to t23, As shown in FIG. 6, the non-use mode L is set after t23.

The control unit 13 sets the above-described non-use mode L and transmits radio waves corresponding to the non-use mode L via the wireless transmitter 19. The control unit 23 of the remote tap 20 that has received the radio wave via the wireless reception unit 21 opens the switch unit 27 via the switching unit 26 to cut off the power supply to the load device. Similarly, the control unit 33 of the remote tap 30 that has received the radio waves via the wireless reception unit 31 opens the switch units 37a, 37b, and 37c via the switching unit 36, thereby controlling each of the main room lights 9A, 9B, and 9C. Cut off the power supply to.

Further, while the non-use mode L continues, the control unit 13 transmits radio waves corresponding to the above-described non-use mode L via the wireless transmitter 19 at predetermined intervals (one minute in this embodiment). The radio waves at the interval indicate that the power supply unit 11 is functioning normally without any malfunctions such as breakdowns, and are a signal to continue the non-use mode L, and are used to control each remote tap 20, 30. While the units 23 and 33 are receiving the radio waves via the wireless receiving units 21 and 31, the non-use mode L is continued, and each switch unit 27, 37a, 37b, and 37c does not operate and the power is turned off. maintain the cut-off state. If the control units 23 and 33 of the remote taps 20 and 30 do not receive the radio waves described above, they determine that the power supply unit 11 that is the source of the transmission is in an emergency state due to a failure or other malfunction, and takes greater safety precautions. Then, by closing each switch section 27, 37a, 37b, and 37c via each switch section 26, 36, the main room lights 9A, 9B, and 9C, which are predetermined load devices, and a personal computer etc. connected to the power socket 28 are connected. Supply electricity.

As explained above, according to the control device according to the first embodiment, the use/non-use mode of the guest room 1 is controlled between the power supply unit 11 as a processing means and the remote tap 20 separated from the power supply unit 11. Since the mode setting signal is transmitted and received using radio waves, which are wireless signals, there is no need to wire a separate signal line cable between the power supply unit 11 and the remote tap 20. If the door sensor 42, human sensor 40, 41, and power supply unit 11 that are the means are already installed, the control device can be installed simply by adding the wireless transmitter 19 and the remote tap 20 that are the wireless transmitter without using wires. Easy to configure.

In addition, since it uses radio waves in the 2.4 GHz band that can easily reach the back side of shields, remote taps 20 and 30 equipped with wireless receiving sections 21 and 31, switch sections 27, 37a, 37b, 37c, and the like are used. The wiring cords that are turned on and off by the switch parts 27, 37a, 37b, and 37c can be hidden by being placed in a place where they are not exposed in the cabin 1, and the aesthetic appearance of the cabin 1 is improved.

In addition, since both the standby power that the wireless receiving units 21 and 31 of the remote taps 20 and 30 constantly require to receive mode setting signals and the power supplied to the load equipment are obtained from an external power source, the wiring cords are Can be easily extended in bulk.

In addition, the case where the reception of the non-use mode continuation signal from the power supply unit 11 is interrupted is considered to be a case where an unexpected malfunction occurs such as the power supply to the power supply unit 11 being cut off. By switching the switch sections 27, 37a, 37b, and 37c to supply power to the power socket 28 and the main room lights 9A, 9B, and 9C, control can be performed with greater safety in mind.

Further, by employing the highly versatile door sensor 42 and human sensors 40 and 41 as the detection means, the control device can be constructed easily and inexpensively.

Further, the wireless receiving units 21 and 31 can be stably attached to the outside of the strong metal chassis 24 and 34. Furthermore, since the resin casings 22 and 32 that cover the outside of the wireless receivers 21 and 31 and the chassis 24 and 34 are resin cases that can transmit radio waves, the wireless receivers 21 and 31 and the wireless transmitter The wireless receiving sections 21 and 31 can be protected without affecting communication with the section 19.

Next, a control device according to a second embodiment will be described with reference to FIG. 7. Note that the configuration is the same as that of the first embodiment, and redundant explanation will be omitted.

In the guest room 1 in Embodiment 2, a well-known device is installed on the ceiling surface of the guest room 1 near the door 5 to detect its presence based on the slight movement of a person outside the guest room 1 near the door 5. A human sensor 52 such as an infrared type is provided, and this human sensor 52 is connected to the power supply unit 11 via a signal cable. That is, the human sensor 52 constitutes a detection means of the present invention that detects the presence or absence of a user near the opening/closing door 5 outside the guest room 1.

To explain the case where a guest enters the guest room 1, a user enters the guest room 1 where there is no one in the room.In other words, by being located near the door 5 outside the guest room 1 in order to open the door 5, the user enters the guest room 1 which is empty. The sensor 52 detects the presence state of the user near the opening/closing door 5, and a detection signal of the presence state of the user is transmitted to the control unit 13. The control unit 13 that receives the open state and closed state detection signals sets the load devices such as the lights 6 to 8, the main room lights 9A, 9B, and 9C, the power socket 28, and the indoor air conditioner 12 to a non-use mode. The temporary use mode is set from then on, and time measurement by the timer 15 is started.

In this way, the human sensor 52 serving as a detection means detects the presence state of the user near the opening/closing door 5 outside the guest room 1, so that when the user immediately opens the opening/closing door 5 and enters the guest room 1. At this time, the load devices such as the lights 6 to 8, the main room lights 9A, 9B, and 9C, the power socket 28, and the indoor air conditioner 12 are operating in a temporary usage mode.

Based on the detection signal from the human sensor 52, which is a detection means that detects the presence of a user near the opening/closing door 5 outside the guest room 1 at the time of entering the room, the control unit 13 controls each of the lighting devices 6 to 8, which are load devices, and the main room. In order to set the main room lights 9A, 9B, and 9C, the power socket 28, the indoor air conditioner 12, etc. to temporary usage mode M, each of the lights 6 to 8 and the main room light 9A are turned on for users who enter the room through the opening/closing door 5. , 9B and 9C, the power socket 28, the indoor air conditioner 12, etc., not only can provide comfort, but also the detection of the human sensor 52 after detecting the presence of a user near the opening/closing door 5 outside the guest room 1. Based on the signal, if there is a user in the guest room 1, each of the lights 6 to 8, the main room lights 9A, 9B, and 9C, the power socket 28, the indoor air conditioner 12, etc. are set to usage mode N, or the user is absent. In this case, the non-use mode L is set, so it is not necessary to set a mode based on a separate operation such as locking/unlocking with a door key.

Similarly to the first embodiment described above, the control unit 13 ignores the detection signal in the provisional usage mode M until the initial time A has elapsed, and then indicates that no one is present in the guest room 1 until the occupancy confirmation time B elapses. The detection means can set the load devices such as each of the lights 6 to 8, the main room lights 9A, 9B, and 9C, the power socket 28, and the indoor air conditioner 12 to non-use mode L, on the condition that the state is It is possible to avoid the possibility of a malfunction in which the human sensors 40 and 41 detect a user who is still in the guest room 1 immediately after opening the opening/closing door 5 when leaving the room as the presence of the user.

Although the embodiments of the present invention have been described above using the drawings, the specific configuration is not limited to these embodiments, and any changes or additions that do not depart from the gist of the present invention are included in the present invention. It will be done.

For example, in the first embodiment, the door sensor 42 and the human sensors 40 and 41 are provided as detection means for detecting the presence or absence of a user in the guest room 1. As shown in 2, it may be composed of only the human sensor 52 or only the door sensor, or instead of or in addition to the above-mentioned sensor, a card key used to lock and unlock the entrance door of the living room may be used. It may be an entry key such as the above, and the case where the room is locked with the entry key may be taken as the state where the user is absent, and the case where the room is unlocked may be taken as the state where the user is present.

Further, in the embodiment described above, the remote taps 20 and 30 each having a wireless reception section that wirelessly receives a mode setting signal from the power supply unit 11 are connected to the power socket 28 and the main room lights 9A, 9B, and 9C as predetermined load devices. The predetermined load equipment to which power is supplied or cut off by the remote tap may be, for example, an indoor air conditioner or an entrance light.

Further, in the above embodiment, the mode indicating the use/non-use status of the guest room 1 is set to one of the three modes: non-use mode L, provisional use mode M, and use mode N. It may be set to either one of only two modes: mode and usage mode.

1 Guest room 5 Doors 6 to 8 Lighting 9A, 9B, 9C Main room lighting (load equipment)
11 Power supply unit (processing means)
12 Indoor air conditioner 13 Control unit 19 Wireless transmitter 20 Remote tap 21 Wireless receiver 27 Switch unit 28 Power socket (load equipment)
30 Remote tap 31 Wireless receiving section 37a, 37b, 37c Switch section 40, 41 Human sensor (detection means)
42 Door sensor (detection means)
52 Human sensor (detection means)

Claims (7)

A control device capable of controlling load equipment for each room based on an appropriately set mode,
Detection means for detecting the presence or absence of a user in the living room;
a control unit that receives a detection signal from the detection means and sets the load equipment to a use mode or a non-use mode of the room based on the detection signal; and a mode setting signal for any of the modes set by the control unit. a wireless transmitter that wirelessly transmits the information using radio waves;
a wireless receiving section that is provided at a predetermined location in the living room separated from the processing means and receives the mode setting signal; and supplying or cutting off power to a predetermined load device based on the mode setting signal received by the wireless receiving section. a remote tap having a switch portion configured to
A control device comprising: The control device according to claim 1, wherein the radio wave is an extremely high frequency wave having a frequency of 300 MHz to 3 GHz. The wireless receiving section is paired with the wireless transmitting section provided in the same room as the wireless receiving section, and receives the mode setting signal transmitted from the paired wireless transmitting section. The control device according to claim 1. The remote tap is connected to an external power source, and the external power source obtains standby power for the wireless receiving unit to receive a mode setting signal and supply power to be supplied to the predetermined load device. The control device according to claim 1. The processing means is configured to cause the detection means to detect the presence state of the user after the wireless transmission section transmits a mode setting signal for the non-use mode of the room based on the detection signal in which the detection means detects the presence state of the user. A predetermined non-use mode continuation signal is transmitted to continue the non-use mode of the room until the wireless transmitter transmits a mode setting signal for the use mode of the room based on the detected detection signal,
When the remote tap continues to receive the non-use mode continuation signal transmitted from the processing means, the switch section continues to cut off power to the predetermined load equipment, and the remote tap continues to receive the non-use mode continuation signal transmitted from the processing means. 2. The control device according to claim 1, wherein the switch unit supplies power to the predetermined load device when reception of the non-use mode continuation signal is interrupted. The detection means is characterized in that it is a door sensor that detects movement of an opening/closing door for entering and leaving the living room, and/or a human sensor that detects the presence or absence of a user in the living room. The control device according to claim 1. 2. The control device according to claim 1, wherein the wireless receiving section is attached to the outside of a metal chassis, and the wireless receiving section and the outside of the chassis are covered with a resin case.

Images