JP2016103716A - Electrical machine and linkage system including the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electrical machine capable of establishing communication with an opposite machine while suppressing product cost.SOLUTION: A first machine (10) includes a control part (11) for controlling an infrared transmission part (13) and a rotation drive part (14a) so that, when a linkage mode is selected, the infrared transmission part (13) rotates while transmitting an operation signal for operating a second machine (20).SELECTED DRAWING: Figure 1

Description

  The present invention relates to an interlocking system in which a plurality of devices operate in cooperation.

  For example, it becomes possible to provide a comfortable space to the user by linking a heating device and a humidifier in the same space. In this case, if the interlocking system is established by operating the humidifier according to the operation signal from the heating device, the user does not need to operate the humidifier, which is convenient for the user. In such an interlocking system between devices, when a communication medium having directivity such as infrared rays is used for communication of operation signals, the devices face each other so that the transmitting element and the receiving element can reliably communicate with each other. Need to be placed.

  In preparation for a case where devices cannot be arranged so that the transmitting element and the receiving element face each other, for example, it is conceivable to mount a plurality of transmitting elements on a device on the side that transmits an operation signal. Alternatively, for example, it is conceivable that the transmitting element and the receiving element face each other by using a technique in which a monitor device is mounted on the laser radar device disclosed in Patent Document 1 and directed toward the target object.

  On the other hand, for example, in Patent Document 2, when a device detects infrared rays, a system that determines that the user is in the direction in which the infrared rays are detected, specifies the user position, and provides a comfortable air conditioning service to the user. It is disclosed.

JP 2002-162466 A (published June 7, 2002) Patent 5383727 (Registered October 11, 2013)

  However, providing a plurality of transmission elements in the transmission-side device leads to an increase in product cost. In addition, when the technique disclosed in Patent Document 1 is used, the equipment becomes large, leading to an increase in cost, which is not realistic. In addition, the system disclosed in Patent Document 2 relates to processing after the device receives infrared rays. If the infrared rays cannot be received in the first place, the service cannot be provided.

  Therefore, the present invention has been made in view of the above-described problems, and an object of the present invention is to control the product cost and establish the communication with the counterpart device and the interlock provided with the same. To provide a system.

  In order to solve the above problems, an electrical device according to one embodiment of the present invention has an interlock mode in which a communicable counterpart device is interlocked with the operation of the own device, and directs an operation signal for operating the counterpart device. When the communication mode is selected, the rotation unit that changes the transmission direction of the operation signal by rotating the signal transmission unit, and the interlock mode is selected, the signal transmission unit And a control unit for controlling the signal sending unit and the rotation driving unit so as to rotate while sending an operation signal.

  According to the configuration of the electrical device according to one aspect of the present invention, when the interlock mode is selected, the signal transmission unit rotates while transmitting an operation signal for operating the counterpart device. Therefore, even if only one signal transmission unit is provided, operation signals in a plurality of directions can be transmitted by rotation, and the operation signal transmission range can be expanded. Therefore, when the transmission range of the operation signal and the range of the receivable direction of the counterpart device overlap in any of the transmission directions during rotation, the counterpart device can receive the operation signal. Thus, according to the said structure, the electric equipment which can suppress communication with a partner apparatus and can suppress a product cost can be provided.

It is a figure which shows schematic structure of the interlocking | linkage system of Embodiment 1 of this invention. It is a perspective view of the 1st apparatus and Embodiment 2 of Embodiment 1 of the present invention. It is a figure which shows the structure of the infrared receiving part of the 2nd apparatus of Embodiment 1 of this invention. It is a figure which shows the flow of a process of the 1st apparatus of Embodiment 1 of this invention. It is a figure which shows the flow of a process of the 2nd apparatus of Embodiment 1 of this invention. It is a figure which shows schematic structure of the interlocking | linkage system of Embodiment 2 of this invention. It is a figure which shows the flow of a process of the 1st apparatus of Embodiment 2 of this invention. It is a figure which shows the flow of a process of the 2nd apparatus of Embodiment 2 of this invention. It is a figure which shows schematic structure of the interlocking | linkage system of Embodiment 3 of this invention.

[Embodiment 1]
An embodiment of the present invention will be described below with reference to FIGS.

(Configuration of interlocking system)
FIG. 1 is a diagram showing a configuration of an interlocking system 100 according to the present embodiment. The interlocking system 100 includes a first device (electrical device) 10 and a second device (partner device) 20, and the infrared rays from the first device 10 are used so that the second device 20 is interlocked with the operation of the first device 10. In this system, the second device 20 is operated by an operation signal. In the present embodiment, the operation performed by the operation signal from one device in the other device, and the operation linked to the operation of the one device is referred to as interlocking.

  In the present embodiment, the operation signal from the first device 10 is communicated by infrared, that is, the operation signal is an infrared signal, but the medium for communicating the operation signal is not limited to infrared, and directivity is set. Any communication medium may be used.

  In the following description, the first device 10 will be described by taking a heater as an example, and an air cleaner having a humidifying function as the second device 20 as an example. However, the 1st apparatus 10 and the 2nd apparatus 20 are not limited to this, For example, the 1st apparatus 10 may be a cleaner and the 2nd apparatus 20 may be an air conditioner. Further, for example, the first device 10 may be an air conditioner and the second device 20 may be a blower. Of course, these are examples and are not limited to the devices described here. In the interlocking system 100, the first device 10 may be configured to interlock not only the second device 20 but also a plurality of devices. The number of devices to be linked is not limited.

(First device)
The configuration of the first device 10 will be described. The first device 10 is a device having an interlock mode in which a communicable counterpart device is interlocked with the operation of the own device. In the present embodiment, the counterpart device is the second device 20. The first device 10 executes an operation when receiving an operation from an operation unit (not shown) provided in the first device 10 or when receiving an operation signal from a remote controller (not shown). To do. The first device 10 operates alone, but when the interlocking mode is selected, the interlocking with the second device 20 is executed.

  As shown in FIG. 1, the first device 10 includes a control unit 11, a data storage unit 12, an infrared transmission unit (signal transmission unit) 13, an operation unit 14, a power supply unit 15, and a temperature / humidity detection unit 16 (humidity sensor). Have

  The control unit 11 is a block that controls the operation of each unit of the first device 10. For example, the control unit 11 includes a computer device including an arithmetic processing unit such as a CPU (Central Processing Unit) or a dedicated processor. The control unit 11 comprehensively controls the operation of each unit of the first device 10 by reading and executing a program for executing various controls in the first device 10 stored in the data storage unit 12.

  The data storage unit 12 includes a RAM (Random Access Memory), a ROM (Read Only Memory), a HDD (Hard Disk Drive), and the like, and is a block that stores various information (data) used in the first device 10. Further, the mode related to the operation state currently set in the first device 10 is stored. In the present embodiment, there are a single operation mode and an interlocking mode as modes related to the operation state set in the first device 10 (which the first device 10 has). The independent operation mode is a mode for independent operation, and the interlocking mode is a mode for instructing operation by transmitting an operation signal by infrared rays to the second device 20 in the same space where communication is possible. In addition, for example, the mode may be subdivided according to the heating intensity by the first device 10 such as a single operation with a medium heating intensity. These are examples, and the first device 10 may have modes other than these. Furthermore, the data storage unit 12 stores a mode (swing mode) relating to the rotation of the main body of the first device 10 currently set in the first device 10. In the present embodiment, the swing mode includes a mode in which the main body is not rotated, a mode in which the main body is rotated in a large range (for example, 90 degrees left and right with respect to the front of the first device 10), and a main body is in a small range (for example, , And a mode of rotating 45 degrees left and right with respect to the front of the first device 10. The data storage unit 12 stores information for setting the operation state of the first device 10 for each mode.

  The infrared transmitter 13 is a block that transmits an operation signal for operating the second device 20 by infrared rays. The operation signal indicates an operation (including stop) command to the second device 20. In the present embodiment, since the operation signal for operating the second device 20 is transmitted by infrared rays, the infrared transmission unit 13 is provided, but the operation signal for operating the 20th device is communication having directivity. It is only necessary to have a means that can send out by a medium. In the present embodiment, the infrared transmitter 13 is installed in front of the first device 10 as shown in FIG. 2, but the installation location is not limited.

  The operation unit 14 is a block that executes various operations of the first device 10 under the control of the control unit 11. In the present embodiment, since the first device 10 is a heater, one operation of the first device 10 is a heating operation. Moreover, the operation | movement part 14 is provided with the rotation drive part 14a which rotates the 1st apparatus 10 main body. The 1st apparatus 10 can heat space effectively by rotating at the time of a heating. Hereinafter, the rotation of the main body of the first device 10 may be referred to as swinging. In the present embodiment, when the rotation driving unit 14a rotates the main body, the infrared transmission unit 13 installed in the main body rotates accordingly. Thus, since the 1st apparatus 10 has the function to rotate a main body, it can implement | achieve rotation of the infrared rays transmission part 13 reasonably. However, a configuration in which a rotation driving unit that rotates the infrared transmission unit 13 is separately provided may be employed.

  The power supply unit 15 is a block that applies a current to the first device 10 in order to operate the first device 10.

  The temperature / humidity detection unit 16 is a sensor device that detects the temperature and humidity around the first device 10. In addition, the apparatus which can detect only humidity may be sufficient.

  As shown in FIG. 2, when the interlock mode is selected in the first device 10, the control unit 11 sends an operation signal for operating the second device 20 by the infrared transmission unit 13, and the main body of the first device 10. The infrared transmission unit 13 and the rotation driving unit 14a are controlled so that the rotation is performed. Therefore, the infrared transmitter 13 rotates while sending the operation signal. In the present embodiment, this rotation is 180 degrees left and right with respect to the front surface of the first device 10. This is merely an example, and for example, it may be rotated 150 degrees to the left or right, or 360 degrees in one direction. The rotation while sending the operation signal by the infrared transmission unit 13 can also be referred to as rotation for causing the second device 20 to receive the operation signal or rotation for searching for the second device 20.

  As described above, since the infrared transmission unit 13 rotates while sending an operation signal for operating the second device 20, even if only one infrared transmission unit 13 is provided, operation signals in a plurality of directions are obtained by the rotation. Can be transmitted, and the transmission range of the operation signal can be expanded. Therefore, when the transmission range of the operation signal and the range of the receivable direction of the second device 20 overlap in any of the transmission directions during rotation, the second device 20 can receive the operation signal. Thus, according to the 1st apparatus 10, product cost can be suppressed and communication with the 2nd apparatus 20 can be established.

  Here, in the 1st apparatus 10, the control part 11 controls the rotation drive part 14a so that 90 degree may be rotated over 36 seconds so that the operation signal by infrared rays may be received by the 2nd apparatus 20 at the time of rotation. . The numerical values here are not limited. In the normal rotation of the first device 10, for example, the control unit 11 may control the rotation driving unit 14 a to rotate 90 degrees over 18 seconds.

  In the present embodiment, the infrared transmitter 13 rotates in the horizontal direction, so that the range in which the operation signal reaches can be expanded with a small amount of movement. However, it is not limited to rotation in the horizontal direction, and the infrared transmitter 13 may be configured to rotate with a change in elevation angle. For example, when the first device 10 is provided with a louver that moves in the vertical direction, the elevation angle can be changed by installing the infrared transmitter 13 in the louver. Therefore, by installing the infrared transmission unit 13 in the louver and further rotating the first device body in the horizontal direction, the infrared transmission unit 13 can be rotated in the horizontal direction with a change in elevation angle. By rotating with a change in elevation angle, an operation signal can be emitted in any direction, and the range in which the operation signal reaches can be expanded.

  Note that after the infrared transmission unit 13 rotates while transmitting an operation signal at a predetermined angle, a predetermined time, or a predetermined number of rotations, the control unit 11 operates the first device 10 to operate the first device 10. If it returns before rotating while sending a signal, it can return without requiring a user's operation, and it can be used according to the convenience of the user.

  As described above, in the first device 10, when the interlock mode is selected, the infrared transmission unit 13 rotates while sending an operation signal for operating the second device 20. Therefore, even if only one infrared transmission unit 13 is provided, it is possible to transmit operation signals in a plurality of directions by rotation, and the operation signal transmission range can be expanded. Therefore, when the transmission range of the operation signal and the range of the receivable direction of the second device 20 overlap in any of the transmission directions during rotation, the second device 20 can receive the operation signal. Thus, according to the 1st apparatus 10, product cost can be suppressed and communication with the 2nd apparatus 20 can be established.

  Here, the selection of the interlocking mode is executed by an operation from an operation unit provided in the main body of the first device 10 or an operation from a remote controller. The first device 10 may be connected via a communication network (not shown), and the interlock mode may be selected by an operation signal from an external device connected to the communication network. For example, the Internet can be used as this communication network. Further, a telephone line network, a mobile communication network, a CATV (CAble TeleVision) communication network, a satellite communication network, or the like can be used. The external device may be, for example, a mobile phone, a smartphone, a tablet terminal, a personal computer, or the like.

  By linking a heater and an air cleaner with a humidifying function as in the present embodiment, it is possible to automatically perform comfortable and efficient heating and humidification control according to the temperature and humidity in the room. . As can be seen from the above, the interlocking system 100 includes a first device 10 that is a heater having a rotation drive unit 14a, and a second device 20 that is an air cleaner with a humidification function without mounting a plurality of infrared transmission units 13. Since it can be linked, a system that can provide a comfortable space with low temperature and temperature and humidity can be constructed.

  Here, in order to make effective use of the function of the air cleaner, the air cleaner is generally installed along the wall so that the back surface faces the wall. Therefore, when the 2nd apparatus 20 is an air cleaner, it arrange | positions the infrared receiving part 23 in the front as it mentions later so that the infrared receiving part 23 may face the side opposite to a wall (space inside). And it becomes easier to receive an operation signal from the first device 10. Therefore, a system that can be interlocked can be constructed by rotating the infrared transmitter 13 of the first device 10 without rotating or moving the second device.

  In addition, by linking the vacuum cleaner as the first device 10 and the air conditioner as the second device 20, the air of the air conditioner is prevented from being sent out to the floor surface during cleaning, thereby cleaning dust and the like. It is possible to provide an easy-to-clean environment without raising up. In this case, when the vacuum cleaner is a self-propelled cleaner, the self-propelled cleaner has a rotating function for self-propelling, so the infrared transmitter that sends an operation signal is rotated by this rotating function. Therefore, it is preferable because an interlocking system can be constructed without newly providing a part for rotating the infrared transmission unit. Moreover, if it is a self-propelled cleaner, it can wrap around in any direction, such as the front and back sides of the counterpart device, and send an operation signal in any direction. Even if it is provided, an operation signal can be received, which is preferable.

  In addition, by linking the air conditioner as the first device 10 and the blower as the second device 20, during the heating operation of the air conditioner, the air current in the entire space is secured by the blower, and the entire space is effectively Can be heated. In this case, for example, a fan may be used as the blower, or when the heater has a blowing function, the blowing function may be used.

(Secondary equipment)
The second device 20 is an electric device that executes an operation in response to an infrared operation signal from the first device 10. The second device 20 receives an operation from an operation unit (not shown) provided in the second device 20, or receives an infrared operation signal from a remote controller (not shown). Execute the operation. In the present embodiment, the second device 20 is an air cleaner with a humidifying function, and therefore performs a humidifying operation, an air cleaning operation, and the like.

  As illustrated in FIG. 1, the second device 20 includes a control unit 21, a data storage unit 22, an infrared reception unit (operation reception unit) 23, an operation unit 24, and a power supply unit 25.

  The control unit 21 is a block that controls the operation of each unit of the second device 20. Similar to the control unit 11, the control unit 21 includes a computer device configured by an arithmetic processing unit such as a CPU or a dedicated processor, for example. The control unit 21 reads out and executes a program for performing various controls in the second device 20 stored in the data storage unit 22, thereby comprehensively controlling the operations of the respective units of the second device 20.

  The data storage unit 22 includes a RAM (Random Access Memory), a ROM (Read Only Memory), an HDD (Hard Disk Drive), and the like, and is a block that stores various information (data) used in the first device 10. Further, the data storage unit 22 stores the mode currently set in the second device 20. As a mode set in the second device 20 (which the second device 20 has), in the present embodiment, a mode for stopping humidification (only air cleaning operation), a mode for performing strong humidification, a mode for performing weak humidification, Has a mode of moderate humidification. In addition, you may have modes other than these. The data storage unit 22 stores information for setting the operation state of the second device 20 for each mode.

  The infrared receiving unit 23 is a block that receives an infrared operation signal transmitted from the first device 10 and transmits the operation signal to the control unit 21. Further, it receives an infrared operation signal transmitted from the remote controller and transmits it to the control unit 21. As shown in FIG. 2, the infrared receiving unit 23 is disposed in front of the second device 20 in the present embodiment. In the present embodiment, since the operation signal from the first device is based on infrared rays, the infrared receiving unit 23 is provided. However, it is only necessary to include means capable of receiving the operation signal from the first device.

  The operation unit 24 is a block that executes various operations of the second device 20 under the control of the control unit 21. The power supply unit 25 is a block that applies a current to the second device 20 in order to operate the second device 20.

  The infrared receiver 23 will be described in more detail. As shown in FIG. 3, the infrared receiving unit 23 includes a sensor unit S and a lens L. The sensor unit S receives infrared rays and outputs an operation signal included in the infrared rays to the control unit 21. The sensor unit S is installed on the control board B in this embodiment.

  The lens L is an optical member for causing infrared rays to enter the sensor unit S. The lens L is disposed to face the sensor unit S. The lens L may be separated from the sensor unit S by an appropriate distance or may be in contact with the sensor unit S. The lens L has a truncated cone shape, an optical axis that is perpendicular to the center of the sensor unit S and passes through the center of the sensor unit S, and an optical axis of the lens L that passes through the center of the entrance surface and the exit surface of the lens L described later. The lens L is arranged with respect to the sensor unit S so as to match.

  As the material of the lens L, for example, a transparent material having excellent light transmittance such as polycarbonate can be used. The material of the lens L is not limited to polycarbonate, but optical plastics such as PMMA (methacrylic resin), SAN (styrene / acrylonitrile copolymer resin), PS (polystyrene resin), crown type, flint type, etc. Optical glass or the like may be used.

  The infrared rays that have entered the entrance surface of the lens L pass through the inside of the lens L, exit from the exit surface, and enter the sensor unit S. The surface opposite to the surface facing the sensor portion S of the lens L is an infrared incident surface, and the surface facing the sensor portion S is an exit surface. The entrance surface and the exit surface face each other so that a perpendicular passing through the center of the entrance surface is in a positional relationship perpendicular to the center of the exit surface. The lens L includes a peripheral side portion whose diameter is increased in a tapered shape from the entrance surface to the exit surface on the side surface. The cross-sectional shape of the lens L is not limited to a circle, but may be an ellipse or a square such as a hexagon, but a circle is most preferable for obtaining a desired infrared ray from the emission surface.

  Since the peripheral side portion of the lens L is tapered as described above, even when infrared rays having a large incident angle (for example, more than 30 °) are incident on the incident surface of the lens L, the circumference of the infrared rays incident on the lens L is reduced. The incident angle on the inner surface of the side portion can be made larger than when there is no taper, and the infrared light incident on the lens L can be totally reflected on the peripheral side portion. That is, it is possible to prevent infrared rays from being emitted (leaked) from the peripheral side portion. The infrared rays totally reflected at the peripheral side portion pass through the exit surface of the lens L and enter the sensor portion S. Thereby, even when an infrared ray having a large incident angle is incident, it can be guided to the sensor unit S. Therefore, in the conventional case, when the incident angle exceeds 30 °, the sensor unit S cannot receive the infrared ray in an amount that can receive the operation signal. Even if the angle is large, the sensor unit S can emit an infrared ray that can receive the operation signal from the emission surface, so that the operation signal can be received.

  Furthermore, in the present embodiment, the entrance surface of the lens L is formed as a concave surface. The concave surface is, for example, a shape whose depth increases toward the center along the radial direction of the circular incident surface. Specifically, the concave surface is formed so as to form a part of a spherical surface having a curvature. Further, the shape of the concave surface is not limited to a part of the spherical surface, and may be another shape in which the center of the incident surface is depressed, such as a cylindrical shape, an aspherical surface (free curved surface), a Fresnel shape, or a cone. The incident surface may be a flat surface.

  By making the incident surface of the lens L concave, even when the incident angle is around 45 °, the infrared light incident on the incident surface is guided to the peripheral side portion and totally reflected on the peripheral side portion and incident on the sensor portion S. Can do. Further, by making the incident surface concave, it is possible to suppress an increase in reflectance at the incident surface of the lens due to Fresnel reflection compared to a case where the incident surface is a flat surface, and as a result, the sensor unit S is reached. The amount of infrared rays can be increased. Further, since the incident surface is concave, the direction in which infrared light incident on the incident surface of the lens is emitted from the exit surface of the lens can be expanded. For example, the optical axis shift between the lens L and the sensor unit S or the lens Even when an attachment error such as an attachment interval between L and the sensor unit S occurs, infrared rays emitted from the lens can be incident on the sensor unit S. Therefore, the tolerance with respect to the above-mentioned attachment error becomes high, and the mechanical design of the 2nd apparatus 20 becomes easy.

  The taper angle and the concave shape of the lens L are appropriately designed according to the characteristics of the received infrared rays, the distance from the sensor unit S, the sensitivity of the sensor unit S, and the like.

  Since the lens L having the above-described configuration is provided in the infrared receiving unit 23, the angle that can be received by the infrared receiving unit 23 of the second device is increased without changing the intensity of infrared rays transmitted from the first device 10. Can do. Therefore, the interlocking system 100 can be a system with good communication sensitivity.

  Further, the second device 20 is provided with an illuminance sensor (not shown). And the control part 21 is illuminating devices, such as LED provided in the operation part provided in order to operate the 2nd apparatus 20 directly according to the detection value of an illumination intensity sensor, the display part etc. which show the driving | running state of the 2nd apparatus 20, etc. Adjust the brightness (not shown). For example, when the space where the second device 20 is installed is dark, adjustment is performed such that the intensity of the lighting device is reduced when the detection value of the illuminance sensor is lower than a predetermined value.

  In the present embodiment, the second device 20 is an air cleaner, but the illuminance sensor of the air cleaner is often mounted toward the ceiling, and directly enters the brightness of the facing ceiling or the illuminance sensor. Brightness is easy to detect by illumination light or external light. Therefore, depending on the installation location of the second device 20, there may be a difference between the user's perceived brightness and the detection value of the illuminance sensor. Furthermore, the illuminance sensor of an air cleaner is often mounted on an operation board, and since there are operation switches, LEDs, etc., the distance from the window that takes light into the illuminance sensor to the illuminance sensor becomes large. As a result, the sensitivity of the illuminance sensor may decrease.

  Therefore, in the present embodiment, the illuminance sensor of the second device 20 is opposed to the illuminance sensor and is directed from the incident surface to the emission surface, as shown in FIG. 3, similarly to the sensor unit S of the infrared receiver 23. A lens having a peripheral portion that has a tapered diameter and a concave incident surface is disposed. What is necessary is just to arrange | position a lens in the window which takes in light to an illumination intensity sensor.

  The taper angle and concave shape of the lens arranged opposite to the illuminance sensor are appropriately designed according to the characteristics of visible light, the distance to the illuminance sensor, the sensitivity of the illuminance sensor, and the like.

  Thus, by arranging the lens having the tapered peripheral edge and the concave incident surface facing the illuminance sensor, incident light having a large incident angle reaches the illuminance sensor, and the second device 20 is installed. Therefore, the brightness can be detected with light from various angles in the space, and the deviation between the user's perceived brightness and the detection value of the illuminance sensor can be reduced. Moreover, even if there is a distance between the illuminance sensor and the window through which light is guided by guiding light through the lens, more light can reach the illuminance sensor, and the sensitivity of the illuminance sensor can be increased.

(Processing flow of each device in linked mode)
First, the process flow of the first device 10 will be described. As shown in FIG. 4, the first device 10 determines whether the operation has started (step S1, hereinafter abbreviated as S1), and determines whether the interlock mode is selected (S2). If the operation is not started (NO in S1), the start is waited. If the interlock mode is not selected (NO in S2), the selection of the interlock mode is waited while driving. The operation may be started by determining whether or not the current from the power supply unit 15 is applied. The selection of the interlock mode may be performed by determining whether an operation for instructing the interlock mode is accepted.

  When the interlock mode is selected during operation (YES in S1 and YES in S2), the humidification mode is determined based on the detection value (temperature / humidity sensor detection value) by the temperature / humidity detection unit 16 (S3). The humidification mode is a mode for setting the second device. In the present embodiment, as described above, the mode for stopping humidification (only the air cleaning operation), the mode for performing strong humidification, the mode for performing weak humidification, There is a mode for moderate humidification.

  Next, the current swing mode of the first device 10 is stored in the data storage unit 12 (swing Buff) (S4). Note that the swing mode is set or changed at the start of S1 operation or during operation. Then, rotation (swinging) of the first device 10 main body is started (S5), and the infrared transmitter 13 transmits an infrared code (S6). The infrared code to be transmitted is a signal for instructing the humidification mode determined in S3. In S5 and S6, the infrared transmitter 13 rotates while transmitting the infrared code.

  Thereafter, it is determined whether the head swing has made one reciprocation, specifically, whether the infrared ray transmitting unit 13 has returned to the front of the first device 10 by rotating 180 degrees in the left-right direction (S7). If the head swing has not made one reciprocation (NO in S7), the process returns to S5, and the infrared transmitter 13 continues to rotate while transmitting the infrared code. When the head swings once (YES in S7), the head swing for rotation while transmitting the infrared code is stopped, and the current head swing mode of the first device 10 is stored in the head swing Buff. Return to the swing mode (S8). Furthermore, the humidification mode determined in S3 (humidification mode set in the second device 20) is stored in the data storage unit 12 (humidification mode Buff) (S9).

Thereafter, the temperature / humidity detection unit 16 detects the temperature / humidity in a timely manner, and determines the humidification mode based on the detection value (temperature / humidity sensor detection value) (S10). Then, it is determined whether the humidification mode stored in S9 is the same as the humidification mode determined in S10 (S11).
When the humidification mode stored in the humidification mode Buff is the same as the determined humidification mode (YES in S11), the process returns to S10. When the humidification mode stored in the humidification mode Buff is not the same as the determined humidification mode (NO in S11), the process returns to S4 and is repeated.

  Next, the process flow of the second device 20 will be described. As shown in FIG. 5, the second device 20 determines whether the operation has started (S21), and determines whether an infrared ray (infrared signal) has been received (S2). If the operation has not been started (NO in S1), the process waits for the start, and if the infrared ray is not received (NO in S22), the operation waits for the reception of the infrared ray. The operation may be started by determining whether or not a current from the power supply unit 25 is applied.

  When infrared rays are received during operation (YES in S21 and YES in S22), the humidification mode is determined by the infrared code (operation signal). That is, the humidification mode indicated by the infrared code is determined as the humidification mode of the second device 20 (S23). And it is determined whether the humidification mode of the present 2nd apparatus memorize | stored in the data storage part 22 and the humidification mode which the received infrared code shows are the same (S24). If the current humidification mode of the second device is the same as the humidification mode indicated by the received infrared code (YES at 24), the process returns to S22 and the operation is continued (no mode change).

  If the current humidification mode of the second device is different from the humidification mode indicated by the received infrared code (NO at 24), the received infrared code is stored in the data storage unit 22 as the current humidification mode of the second device. Is stored (S25), the operation is changed to the operation in the humidification mode indicated by the infrared code that received the humidification operation (S26), and the operation returns to S22 and the operation is continued (mode change is present).

  As described above, in the interlocking system 100, when the interlocking mode is selected, the first device 10 rotates while sending the operation signal for operating the second device 20, so that the product cost is suppressed, It is possible to construct an interlocking system that can establish communication.

[Embodiment 2]
Another embodiment of the present invention will be described below with reference to FIGS. In the present embodiment, constituent members having the same functions as those described in the first embodiment are denoted by the same reference numerals as those in the first embodiment, and detailed description thereof is omitted.

(Linked system)
As shown in FIG. 6, the interlocking system 100A according to the present embodiment includes a first device (electric device) 10A and a second device (partner device) 20A, and the second device 20A operates in the operation of the first device 10A. In this system, the second device 20A is operated by an infrared operation signal from the first device 10A so as to be linked.

  The first device 10A is different from the first device 10 described in the first embodiment in that it further includes a voice input unit 17. The other configuration is the same as that of the first device 10. The second device 20A is different from the configuration of the second device 20 described in the first embodiment in that an audio output unit 26 is further provided. Other configurations are the same as those of the second device 20.

  The audio output unit 26 is an audio output device. In the second device 20 </ b> A, when the infrared receiving unit 23 receives an operation signal, the control unit 21 outputs an audio signal (acceptance signal) indicating that the operation signal has been received from the audio output unit 26. In this embodiment, a buzzer sound is output as an audio signal indicating that an operation signal has been received.

  The voice input unit 17 is a sound collection device such as a microphone. In the first device 10A, when the audio input unit 17 receives the buzzer sound from the second device 20, the control unit 11 stops the rotation while sending the operation signal, and the first device 10A receives the operation signal. Return to the operation just before rotating while sending.

(Processing flow of each device in linked mode)
First, the processing flow of the first device 10A will be described. As illustrated in FIG. 7, the processes of S1 to S6 in the first device 10A are the same as the processes of S1 to S6 of the first device 10, respectively, and thus description thereof is omitted. After S6, the first device 10A determines whether a buzzer sound indicating that the infrared code has been received by the second device (reception completion) is detected (S7a). If a buzzer sound is detected (YES in S7a), the process proceeds to S8, and if not detected (NO in S7a), the processes from S5 are repeated. Since the process from S8 to S11 in the first device 10A is the same as the process from S8 to S11 in the second device 20, the description thereof is omitted. When the buzzer sound is not detected in S7a, the processing from S5 is repeated, but after repeating a predetermined time or a predetermined number of times, the rotation while sending the operation signal may be stopped.

  Next, the processing flow of the second device 20A will be described. As illustrated in FIG. 8, the processes of S21 and S22 in the second device 20A are the same as the processes of S21 and S22 of the second device 20, respectively, and thus description thereof is omitted. After S22, the second device 20A transmits an audio signal (acceptance signal) indicating that the infrared code has been received (reception completion) (S22a). Thereafter, the processing of S23 to S26 in the second device 20A is the same as the processing of S23 to S26 in the second device 20, and thus the description thereof is omitted.

[Embodiment 3]
Still another embodiment of the present invention will be described below with reference to FIG. In the present embodiment, constituent members having the same functions as those described in the first or second embodiment are denoted by the same reference numerals as those in the first or second embodiment, and detailed description thereof is omitted.

  As shown in FIG. 9, the interlocking system 100B according to the present embodiment includes a first device (electric device) 10B and a second device (partner device) 20B, and the second device 20B operates in the operation of the first device 10B. In this system, the second device 20B is operated by an operation signal using infrared rays from the first device 10B so as to be linked.

  The first device 10B is different from the first device 10 described in the first embodiment in that an infrared receiver 18 is further provided. The other configuration is the same as that of the first device 10. Further, the second device 20B is different from the configuration of the second device 20 described in the first embodiment in that an infrared transmission unit 27 is further provided. Other configurations are the same as those of the second device 20.

  In the second device 20B, when the infrared receiving unit 23 receives an operation signal, the control unit 21 transmits an acceptance signal indicating that the operation signal has been received from the infrared transmission unit 27 using infrared rays. In the first device 10B, when receiving the reception signal from the second device 20B, the control unit 11 stops the rotation while sending the operation signal, and rotates the first device 10B while sending the operation signal. Return to the previous operation.

  Since the processing flow of the first device 10B and the second device 20B in the interlock mode is substantially the same as that of the first device 10A and the second device 20A, respectively, description thereof will be omitted.

  Here, in the first device 10B, an infrared operation signal is received by the second device 20B during rotation and an infrared reception signal from the second device 20B can be received during rotation, that is, the first device. For example, the control unit 11 controls the rotation driving unit 14a to rotate 90 degrees over 36 seconds so that bidirectional infrared communication between the 10B and the second device 20B is established. The numerical values here are not limited.

  The infrared receiver 18 may be provided in the same manner as the receiver that receives an infrared operation signal from a remote controller that operates the first device 10B. If they are the same, the number of components in the first device 10B can be reduced.

[Embodiment 4]
Each of the first devices 10, 10A, 10B described in the first, second, and third embodiments may be realized by a logic circuit (hardware) formed in an integrated circuit (IC chip) or the like. It may be realized by software using a CPU (Central Processing Unit).

  In the latter case, the first devices 10, 10A, and 10B each include a CPU that executes a program instruction that is software that implements each function, and a ROM in which the program and various data are recorded so as to be readable by the computer (or CPU). (Read Only Memory) or a storage device (these are referred to as “recording media”), a RAM (Random Access Memory) for expanding the program, and the like. And the objective of this invention is achieved when a computer (or CPU) reads the said program from the said recording medium and runs it. As the recording medium, a “non-temporary tangible medium” such as a tape, a disk, a card, a semiconductor memory, a programmable logic circuit, or the like can be used. The program may be supplied to the computer via an arbitrary transmission medium (such as a communication network or a broadcast wave) that can transmit the program. The present invention can also be realized in the form of a data signal embedded in a carrier wave in which the program is embodied by electronic transmission.

  The present invention is not limited to the above-described embodiments, and various modifications are possible, and the present invention also relates to embodiments obtained by appropriately combining technical means disclosed in different embodiments. Is included in the technical scope. Furthermore, a new technical feature can be formed by combining the technical means disclosed in each embodiment.

[Summary]
The electric device (first device 10) according to the first aspect of the present invention has an interlock mode in which a communicable counterpart device (second device 20) is interlocked with the operation of the own device, and an operation signal for operating the counterpart device. A signal transmission unit (infrared transmission unit 13) for transmitting the communication signal with directivity, a rotation drive unit (14a) for changing the transmission direction of the operation signal by rotating the signal transmission unit, and the interlocking mode The control unit (11) controls the signal sending unit and the rotation driving unit so that the signal sending unit rotates while sending the operation signal.

  According to the above configuration, when the interlock mode is selected, the signal transmission unit rotates while transmitting an operation signal for operating the counterpart device. Therefore, even if only one signal transmission unit is provided, operation signals in a plurality of directions can be transmitted by rotation, and the operation signal transmission range can be expanded. Therefore, when the transmission range of the operation signal and the range of the receivable direction of the counterpart device overlap in any of the transmission directions during rotation, the counterpart device can receive the operation signal. Thus, according to the said structure, the electric equipment which can suppress communication with a partner apparatus and can suppress a product cost can be provided.

  In the electronic device according to aspect 2 of the present invention, in the aspect 1, the rotation driving unit rotates the signal transmission unit by rotating the main body of the device on which the signal transmission unit is installed.

  According to the above configuration, the signal transmission unit rotates as the device body rotates. Therefore, when applied to an apparatus in which the main body of the device itself is originally rotated, it is not necessary to newly form a mechanism for rotating the signal transmission unit, and the signal transmission unit can be rotated without increasing the product cost.

  In the electrical device according to aspect 3 of the present invention, in the aspect 1 or 2, the rotation driving unit rotates the signal transmission unit in the horizontal direction.

  According to the above configuration, by rotating in the horizontal direction, it is possible to widen the range in which the operation signal reaches with less movement.

  In the electric device according to Aspect 4 of the present invention, in any one of Aspects 1 to 3, the rotation driving unit rotates the signal sending unit with a change in elevation angle.

  According to the above configuration, the operation signal can be emitted in all directions by rotating the signal transmission unit with the elevation angle change, and the range in which the operation signal reaches can be expanded.

  The electrical device according to Aspect 5 of the present invention is the electrical apparatus according to any one of Aspects 1 to 4, wherein the signal transmission unit transmits the operation signal at a predetermined angle, a predetermined time, or a predetermined rotation speed. After that, the control unit returns the operation of the own device before the signal sending unit rotates while sending the operation signal.

  According to the above configuration, after the signal transmission unit rotates for a predetermined angle, a predetermined time, or a predetermined rotation speed while transmitting the operation signal, the signal transmission unit rotates while transmitting the operation signal. You can go back. Therefore, it can return without requiring a user's operation, and can be used according to the convenience of the user.

  In any one of the first to fifth aspects, the electrical device according to the sixth aspect of the present invention is a receiving unit (speech input unit 17, infrared receiving unit) that receives an acceptance signal indicating that an operation has been accepted from the counterpart device. 18), when the receiving unit receives the acceptance signal, the control unit returns the operation of the own device before the signal sending unit rotates while sending the operation signal.

  According to the above configuration, the receiving unit (the voice input unit 17 and the infrared receiving unit 18) that receives the reception signal from the counterpart device is provided. When the reception unit receives the reception signal, the signal transmission unit controls the operation of the own device. It can return before rotating while sending the operation signal. Therefore, after reliably establishing communication with the counterpart device, the operation of the device can be returned before the signal sending unit rotates while sending the operation signal. Moreover, it can return without requiring a user's operation and can be used according to the convenience of the user.

  Here, the reception unit may be a voice input unit that receives the reception signal as a voice signal, or may be an infrared reception unit that receives the reception signal as an infrared signal.

  An interlocking system according to an aspect 7 of the present invention includes the electrical device according to any one of the above aspects 1 to 6 and an operation receiving unit that receives the operation signal from the electrical device, and the operation of the electrical device And the other device linked to

  According to the above configuration, it is possible to construct an interlocking system capable of suppressing product costs and establishing communication between devices.

  In the interlocking system according to aspect 8 of the present invention, in the aspect 7, the operation receiving unit includes a sensor unit and a lens that is disposed to face the sensor unit and guides the operation signal to the sensor unit. Has a peripheral portion whose diameter is increased in a tapered shape from the incident surface toward the output surface.

  According to the above configuration, since the lens has a peripheral portion whose diameter is increased in a tapered shape, even when a communication medium having a large incident angle (for example, exceeding 30 °) is incident on the incident surface of the lens, the communication medium is incident on the lens. The incident angle at the inner surface of the peripheral side portion can be made larger than when there is no taper, and the communication medium incident on the lens can be totally reflected at the peripheral side portion. That is, it is possible to prevent the communication medium from being emitted (leaked) from the peripheral side portion. The communication medium totally reflected at the peripheral side portion passes through the exit surface of the lens and enters the sensor portion. Thereby, even when a communication medium having a large incident angle is incident, it can be guided to the sensor unit, and the sensor unit can receive an operation signal.

  In the interlocking system according to aspect 9 of the present invention, in the aspect 8, the incident surface of the lens is formed as a concave surface.

  According to the above configuration, since the incident surface of the lens is formed as a concave surface, even at a large incident angle where the incident angle is around 45 °, the infrared light incident on the incident surface is guided to the peripheral side portion and It can be totally reflected and incident on the sensor unit. In addition, by making the incident surface concave, it is possible to suppress an increase in reflectance at the incident surface of the lens due to Fresnel reflection compared to a case where the incident surface is a flat surface, resulting in communication reaching the sensor unit. The amount of media can be increased. Moreover, since the incident surface is concave, the direction in which the communication medium incident on the incident surface of the lens exits from the exit surface of the lens can be expanded. For example, the optical axis shift between the lens and the sensor unit or the lens Even if an attachment error such as an attachment interval with the sensor unit occurs, infrared rays emitted from the lens can be incident on the sensor unit. Therefore, the tolerance for the aforementioned mounting error is increased, and the mechanical design of the counterpart device is facilitated.

  In the interlocking system according to Aspect 10 of the present invention, in any one of Aspects 7 to 9, the electrical device is a heating device, the counterpart device is a humidifier, and includes a humidity sensor. When the detected humidity is not within the predetermined range, the control unit controls the signal sending unit and the rotation driving unit so that the signal sending unit rotates while sending the operation signal.

  According to the said structure, a humidifier can be made to interlock | cooperate with operation | movement of a heating apparatus according to the detection of a humidity sensor, ie, a heating apparatus can be operated with appropriate humidity. Therefore, it is possible to provide the user with a comfortable space with both humidity and temperature.

  In addition, the electrical device according to each aspect of the present invention may be realized by a computer. In this case, a program for causing the computer to realize the electrical device by operating the computer as a control unit included in the electrical device, and A computer-readable recording medium on which it is recorded also falls within the scope of the present invention.

  The present invention can be used for an interlocking system in which a plurality of devices operate in cooperation.

10, 10A, 10B First equipment (electronic equipment)
11 Control unit 13 Infrared transmission unit (signal transmission unit)
14 Operation part 14a Rotation drive part 16 Temperature / humidity detection part 17 Voice input part (reception part)
18 Infrared receiver (receiver)
20, 20A, 20B Second device (partner device)
21 Control unit 23 Infrared receiving unit (operation receiving unit)
24 operation unit 26 audio output unit 27 infrared transmission unit 100, 100A, 100B interlocking system S sensor unit L lens

Claims (5)

It has an interlocking mode that links the partner device that can communicate with the operation of its own device,
A signal sending unit for sending an operation signal for operating the counterpart device in a communication medium having directivity;
A rotation drive unit that rotates the signal sending unit to change the sending direction of the operation signal;
And an electric power control unit that controls the signal transmission unit and the rotation driving unit so that the signal transmission unit rotates while transmitting the operation signal when the interlock mode is selected. machine.   After the signal sending unit rotates for a predetermined angle, a predetermined time, or a predetermined number of rotations while sending the operation signal, the control unit sends the operation signal to the operation of its own device. The electric device according to claim 1, wherein the electric device is returned immediately before rotating. A receiving unit for receiving an acceptance signal indicating that the operation signal has been received from the counterpart device;
3. The control unit according to claim 1, wherein when the reception unit receives the reception signal, the control unit returns the operation of the device immediately before the signal transmission unit rotates while transmitting an operation signal. 4. Electrical equipment. The electrical device according to any one of claims 1 to 3,
An interlocking system comprising: an operation receiving unit that receives the operation signal from the electric device; and a counterpart device that is interlocked with the operation of the electric device. The operation receiving unit includes a sensor unit, and a lens that is disposed to face the sensor unit and guides the operation signal to the sensor unit.
The interlocking system according to claim 4, wherein the lens has a peripheral portion whose diameter is increased in a tapered shape from the incident surface toward the output surface.

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