JP2021081089A - Information transmission device, equipment, communication system, communication method and program - Google Patents

Abstract

To allow for immediate acquisition, from equipment, of equipment information of the equipment.SOLUTION: A control device 3 is arranged in a housing of equipment. The control device 3 comprises: a soundwave receiving unit 31 and a soundwave transmitting unit 32 which communicate with a terminal device by soundwave; a storage device 33 which stores equipment information 330 on a state of the equipment; and a microcomputer 30 which transmits the equipment information 330 read out from the storage device 33 to the terminal device via the soundwave transmitting unit 32 when receiving an information request notification which requests transmission of the equipment information 330 via the soundwave receiving unit 31.SELECTED DRAWING: Figure 2

Description

The present invention relates to information transmitting devices, devices, communication systems, communication methods and programs.

In the maintenance of air-conditioning equipment, information on the status of the air-conditioning equipment (hereinafter referred to as equipment information) is displayed on the remote control of the air-conditioning equipment, and the operator visually recognizes the displayed equipment information to check the status of the air-conditioning equipment. It is common practice to grasp.

However, since the judgment of the state of the air conditioner is left only to the operator who visually recognizes the device information displayed on the remote controller, there is a concern that the accuracy cannot be guaranteed. Further, since the device information is not acquired as data, it is not possible to analyze the state of the air conditioner in detail, and there is a problem that high-precision maintenance is difficult.

To solve this problem, there is known a technique in which device information of an air conditioner is acquired by a terminal device by communication between a terminal device possessed by an operator and a remote controller (for example, Patent Document 1).

JP-A-2019-20033

However, in general, most of the device information is stored in the storage device provided in the outdoor unit of the air conditioner, and in order to acquire the device information using the terminal device as described above, the remote controller-indoor unit- It is necessary to go through the communication path of outdoor unit-indoor unit-remote control, and there is a problem that it takes time to complete the acquisition of device information.

The present invention has been made to solve the above problems, and an object of the present invention is to provide an information transmission device or the like that enables immediate acquisition of device information of the device from the device.

In order to achieve the above object, the information transmission device according to the present invention is
An information transmitter located inside the housing of a device.
Terminal communication means that communicates with the terminal device by sound waves,
A storage means for storing device information related to the state of the device, and
When an information request notification requesting transmission of the device information is received from the terminal device via the terminal communication means, the device information read from the storage means is transmitted to the terminal device via the terminal communication means. It is provided with a control means.

According to the present invention, it is possible to immediately acquire device information of the device from the device.

The figure which shows the whole structure of the communication system which concerns on Embodiment 1 of this invention. A block diagram showing a hardware configuration of the control device according to the first embodiment. Block diagram showing the hardware configuration of the terminal device of the first embodiment The figure which shows the functional structure of the microcomputer provided in the control device of Embodiment 1. The figure for demonstrating the detail of the communication control part in the control device of Embodiment 1. The figure which shows an example of the result of frequency analysis of the sound wave of the ambient environment which collected sound in Embodiment 1. The figure which shows an example of the case where the noise level exceeding the threshold value is detected in the sound wave of a carrier frequency in Embodiment 1. The figure for demonstrating the search for a new carrier frequency in Embodiment 1. The figure which shows the functional structure of the microcomputer provided in the terminal apparatus of Embodiment 1. A flowchart showing a procedure of device information transmission processing executed by the control device of the first embodiment. A flowchart showing a procedure of device information acquisition processing executed by the terminal device of the first embodiment. The figure which shows the whole structure of the communication system which concerns on Embodiment 2 of this invention. The figure which shows the functional structure of the microcomputer provided in the control device of Embodiment 2. The figure for demonstrating the details of the communication control part in the control device of Embodiment 2. The figure which shows the functional structure of the microcomputer provided in the terminal apparatus of Embodiment 2. A flowchart showing a procedure of device information transmission processing executed by the control device of the second embodiment. A flowchart showing a procedure of device information acquisition processing executed by the terminal device of the second embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

(Embodiment 1)
FIG. 1 is a diagram showing an overall configuration of a communication system 1 according to a first embodiment of the present invention. The communication system 1 is a system for acquiring device information regarding the state of the outdoor unit 2 from the outdoor unit 2 by communication. The communication system 1 includes a control device 3 and a terminal device 4. In the present embodiment, the communication between the control device 3 and the terminal device 4 is performed by sound waves of 20 Hz to 20 kHz (so-called audible range).

The control device 3 is an example of an information transmission device according to the present invention. The control device 3 is arranged inside the metal housing of the outdoor unit 2 constituting the air conditioner, and as shown in FIG. 2, the microcomputer 30, the sound wave receiving unit 31, the sound wave transmitting unit 32, and the storage device. 33 and. The outdoor unit 2 is an example of the device according to the present invention, and the sound wave receiving unit 31 and the sound wave transmitting unit 32 are examples of the terminal communication means according to the present invention.

Although not shown, the microcomputer 30 is a microcomputer including a microprocessor (Microprocessor), a RAM (Random Access Memory), a ROM (Read Only Memory), and the like, and controls the outdoor unit 2 in an integrated manner. Details of the functions of the microcomputer 30 will be described later.

The sound wave receiving unit 31 receives sound waves in the surrounding environment (hereinafter, simply referred to as the surrounding environment), converts the received sound waves into digital signals, and outputs the received sound waves to the microcomputer 30 via the signal line 34. Specifically, the sound wave receiving unit 31 includes a sound collecting unit 310 and an A / D conversion circuit 311. The sound collecting unit 310 is, for example, a microphone, collects sound waves in the surrounding environment, converts the collected sound waves into an analog signal, and outputs the sound waves to the A / D conversion circuit 311 via the signal line 312. The A / D conversion circuit 311 converts the analog signal output from the sound collecting unit 310 into a digital signal, and outputs the analog signal to the microcomputer 30 via the signal line 34. The sound wave receiving unit 31 may include a filter circuit, an amplifier circuit, a demodulation circuit, and the like. Further, the A / D conversion circuit 311 may be included in the microcomputer 30.

The sound wave transmission unit 32 converts a digital signal output from the microcomputer 30 and input via the signal line 35 into sound waves and transmits the digital signal to the terminal device 4. Specifically, the sound wave transmission unit 32 includes a D / A conversion circuit 320 and a sound wave unit 321. The D / A conversion circuit 320 converts a digital signal output from the microcomputer 30 and input via the signal line 35 into an analog signal, and outputs the digital signal to the sounding unit 321 via the signal line 322. The sounding unit 321 is a speaker, a buzzer, or the like, and converts an analog signal output from the D / A conversion circuit 320 into sound waves and outputs the sound wave. The sound wave transmission unit 32 may include a filter circuit, an amplifier circuit, a modulation circuit, and the like. Further, the D / A conversion circuit 320 may be included in the microcomputer 30.

The storage device 33 is an example of the storage means according to the present invention. The storage device 33 is composed of a readable and writable non-volatile semiconductor memory such as an EEPROM (Electrically Erasable Programmable Read-Only Memory) and a flash memory, and is connected to the microcomputer 30 via a signal line 36. The storage device 33 stores the device information 330. The device information 330 is information regarding the state of the outdoor unit 2. The device information 330 includes, for example, the opening degree of the LEV (Linear Expansion Valve), the outdoor unit 2, and various sensors installed in each of the one or a plurality of indoor units connected to the outdoor unit 2. The detection result etc. are included.

In addition, the storage device 33 is a refrigerant circuit (not shown) including a communication program for communicating with the terminal device 4 and the main operation of the outdoor unit 2, that is, a compressor, a heat exchanger, an expansion valve, a four-way valve, and the like. ) And the data used when executing these programs are stored.

The terminal device 4 is an example of the terminal device according to the present invention. The terminal device 4 is an electronic device carried by a user such as a smartphone or a tablet terminal. As shown in FIG. 3, the terminal device 4 includes a microcomputer 40, a sound wave receiving unit 41, a sound wave transmitting unit 42, a user interface 43, and a storage device 44.

Although not shown, the microcomputer 40 is a microcomputer including a microprocessor, a RAM, a ROM, and the like, and controls the terminal device 4 in an integrated manner. Details of the functions of the microcomputer 40 will be described later.

The sound wave receiving unit 41 receives the sound wave of the surrounding environment, converts the received sound wave into a digital signal, and outputs the received sound wave to the microcomputer 40 via the signal line 45. Specifically, the sound wave receiving unit 41 includes a sound collecting unit 410 and an A / D conversion circuit 411. The sound collecting unit 410 is, for example, a microphone, collects sound waves in the surrounding environment, converts the collected sound waves into an analog signal, and outputs the sound waves to the A / D conversion circuit 411 via the signal line 412. The A / D conversion circuit 411 converts the analog signal output from the sound collecting unit 410 into a digital signal, and outputs the analog signal to the microcomputer 40 via the signal line 45. The sound wave receiving unit 41 may include a filter circuit, an amplifier circuit, a demodulation circuit, and the like. Further, the A / D conversion circuit 411 may be included in the microcomputer 40.

The sound wave transmission unit 42 converts a digital signal output from the microcomputer 40 and input via the signal line 46 into sound waves and transmits the digital signal to the control device 3 of the outdoor unit 2. Specifically, the sound wave transmitting unit 42 includes a D / A conversion circuit 420 and a sounding unit 421. The D / A conversion circuit 420 converts a digital signal output from the microcomputer 40 and input via the signal line 46 into an analog signal, and outputs the digital signal to the sounding unit 421 via the signal line 422. The sounding unit 421 is a speaker, a buzzer, or the like, and converts an analog signal output from the D / A conversion circuit 420 into sound waves and outputs the sound wave. The sound wave transmission unit 42 may include a filter circuit, an amplifier circuit, a modulation circuit, and the like. Further, the D / A conversion circuit 420 may be included in the microcomputer 40.

The user interface 43 includes a display device such as a liquid crystal display and an organic EL display, and an input device such as a push button, a touch panel, and a touch pad. The user interface 43 displays various screens and the like according to the user operation under the control of the microcomputer 40 via the signal line 47, receives the operation input from the user, and signals the received operation as the signal line. It is sent to the microcomputer 40 via 47.

The storage device 44 includes a readable and writable non-volatile semiconductor memory such as an EEPROM and a flash memory. The storage device 44 contains various programs including an application program (hereinafter referred to as a device information acquisition application) for communicating with the control device 3 and acquiring device information, and data used when executing these programs. Is memorized.

In the control device 3, the microcomputer 30 functionally includes a communication control unit 300 and a main control unit 301, as shown in FIG. The communication control unit 300 is an example of the communication control means according to the present invention, and when an information request notification requesting transmission of device information is received from the terminal device 4 via the sound wave receiving unit 31, the device information is received from the storage device 33. The 330 is read out, and the read device information 330 is transmitted to the terminal device 4 via the sound wave transmission unit 32. Details of the communication control unit 300 will be described later.

The main control unit 301 controls the main operation of the outdoor unit 2. For example, when the user performs an operation related to air conditioning via a remote controller installed in the room, the main control unit 301 controls the operation of the refrigerant circuit described above according to the content of the operation. Further, the main control unit 301 is installed in each of the opening degree of the LEV, the outdoor unit 2 and one or a plurality of indoor units connected to the outdoor unit 2, for example, when an event such as periodic and / or user operation occurs. The device information including the detection results of various sensors is acquired, and the acquired device information is stored in the storage device 33 as the device information 330.

In detail, as shown in FIG. 5, the communication control unit 300 includes an information request notification receiving unit 302, a noise level determination unit 303, a device information transmitting unit 304, a frequency search unit 305, and a frequency change requesting unit 306. And a frequency changing unit 307. These functional units are realized by executing the above-mentioned communication program stored in the storage device 33 by the CPU of the microcomputer 30.

The information request notification receiving unit 302 receives the information request notification requesting the transmission of the device information transmitted from the terminal device 4 via the sound wave receiving unit 31. In the present embodiment, the communication between the control device 3 and the terminal device 4 is performed by a sound wave modulated by an FSK (Frequency Sift Keying) modulation method. More specifically, a binary FSK modulation method is adopted as the FSK modulation method, and "0" and "1" are represented by two frequencies (f0, f1; f0 <f1) in the audible range (frequency f0 is "". It represents "0" and the frequency f1 represents "1"). Hereinafter, the set of the frequency f0 and the frequency f1 will be referred to as a carrier frequency modulation pattern.

The information request notification receiving unit 302 receives the information request notification by demodulating the digital signal output from the A / D conversion circuit 311 based on the current modulation pattern. In the present embodiment, the initial values of the modulation pattern are frequency f0 = 12 kHz and frequency f1 = 18 kHz, and the frequency f1 is appropriately changed by the frequency changing unit 307 described later.

The noise level determination unit 303 is an example of the noise level determination means according to the present invention. The noise level determination unit 303 detects the noise level of sound waves in the surrounding environment based on the carrier frequency indicated by the modulation pattern, and determines whether or not the detected noise level is equal to or less than a predetermined noise level threshold value. .. The noise level determination unit 303 makes the determination using, for example, SNR (Signal-Noise Ratio). Specifically, first, the noise level determination unit 303 frequency-analyzes the sound waves in the surrounding environment collected by the sound wave receiving unit 31 by a well-known method such as a fast Fourier transform.

From the result of the frequency analysis, the noise level determination unit 303 centers on the frequency f1 (for example, 18 kHz) on the high frequency side of the two frequencies (f0, f1) indicated by the modulation pattern, and determines the frequency band Δf. The noise level is detected from the inside. Then, the noise level determination unit 303 compares the detected noise level with the threshold value, and determines whether or not the noise level is equal to or less than the threshold value.

FIG. 6 shows an example of the result of frequency analysis performed by the noise level determination unit 303 by the fast Fourier transform. From the waveform shown in FIG. 6, it can be seen that the signal levels of "0" and "1" received from the terminal device 4 appear on the frequency f0 and the frequency f1, respectively. In FIG. 6, for convenience, the signal levels at the frequency f0 and the frequency f1 are shown to appear on the same waveform by peak hold, but in the present embodiment, "0" and "1" are transmitted in a time division manner. It shall be.

As a result of the above frequency analysis, FIG. 7 shows noise exceeding the threshold value on the harmonic side, that is, in the frequency band Δf centered on the frequency f1, due to the motor operation of the compressor, fan, etc. included in the outdoor unit 2, for example. An example is shown when a level is detected.

When the noise level determination unit 303 determines that the noise level is equal to or lower than the threshold value, the device information transmission unit 304 reads the device information 330 from the storage device 33 and transmits the read device information 330 to the terminal device 4. Specifically, the device information transmission unit 304 modulates the digital signal indicating the read device information 330 with the current modulation pattern, and transmits the digital signal to the terminal device 4 via the sound wave transmission unit 32.

The frequency search unit 305 is an example of the frequency search means according to the present invention, and the frequency search unit 305 searches for a frequency at which the noise level is equal to or lower than the threshold value in the sound wave of the ambient environment. Specifically, the frequency search unit 305 searches for the center frequency in the frequency band Δf where the noise level is equal to or less than the threshold value as a new frequency f1 from the result of the frequency analysis by the noise level determination unit 303 (see FIG. 8). ..

The frequency change requesting unit 306 is an example of the changing requesting means according to the present invention, and requests the terminal device 4 to change the carrier frequency on the harmonic side to the frequency searched by the frequency searching unit 305. Specifically, a change request notification in which the current frequency f0 and the searched new frequency f1 are stored is generated, and the digital signal indicating the generated change request notification is modulated by the current modulation pattern, and the sound wave transmission unit is used. It is transmitted to the terminal device 4 via 32.

The frequency changing unit 307 is an example of the frequency changing means according to the present invention, and changes the carrier frequency (that is, frequency f1) on the harmonic side at the time of modulation and demodulation to the frequency searched by the frequency search unit 305. That is, the frequency changing unit 307 changes the modulation pattern of the carrier frequency based on the search result of the frequency searching unit 305. After that, the modulation and demodulation by the communication control unit 300 are performed based on the changed modulation pattern.

In the terminal device 4, the microcomputer 40 functionally includes the information request notification transmitting unit 400, the change request notification receiving unit 401, the frequency changing unit 402, the device information receiving unit 403, and the device information receiving unit 403, as shown in FIG. The information display unit 404 is provided. These functional units are realized by the CPU of the microcomputer 40 executing the above-mentioned device information acquisition application stored in the storage device 44.

The information request notification transmission unit 400 transmits an information request notification requesting transmission of device information to the control device 3. Specifically, when the user activates the device information acquisition application and the user performs a predetermined operation for acquiring the device information, the information request notification transmission unit 400 outputs a digital signal indicating the information request notification as a binary FSK. It is modulated by a modulation method and transmitted to the control device 3 via the sound wave transmission unit 42. The information request notification transmission unit 400 periodically sends the information request notification to the control device 3 until the change request notification is not received from the control device 3, in other words, until the reception of the device information from the control device 3 is started. Send to.

The information request notification transmission unit 400 modulates a digital signal indicating an information request notification with a modulation pattern of the current carrier frequency managed by the microcomputer 40. In the present embodiment, the initial values of the modulation pattern are frequency f0 = 12 kHz and frequency f1 = 18 kHz, and the frequency f1 is appropriately changed by the frequency changing unit 402 described later.

The change request notification receiving unit 401 receives the above-mentioned change request notification transmitted from the control device 3 via the sound wave receiving unit 41. Specifically, the change request notification receiving unit 401 receives the change request notification by demodulating the digital signal output from the A / D conversion circuit 411 based on the current modulation pattern.

The frequency changing unit 402 changes the modulation pattern of the carrier frequency based on the change request notification received by the change request notification receiving unit 401.

The device information receiving unit 403 receives the device information 330 transmitted from the control device 3 via the sound wave receiving unit 41. Specifically, the device information receiving unit 403 receives the device information 330 by demodulating the digital signal output from the A / D conversion circuit 411 based on the current modulation pattern, and stores the received device information 330. Store in device 44.

The information display unit 404 displays the device information 330 received by the device information receiving unit 403 on the display device of the user interface 43 in a predetermined manner.

FIG. 10 is a flowchart showing a procedure of device information transmission processing executed by the control device 3. In the device information transmission process, the power of the control device 3 is turned on (that is, the power of the outdoor unit 2 is turned on), and the CPU of the microcomputer 30 activates the communication program stored in the storage device 33. It will be started.

When the device information transmission process is started, the control device 3 initializes the carrier frequency (step S101). Specifically, the control device 3 initializes the modulation pattern of the carrier frequency (frequency f0, f1). In the present embodiment, as described above, the initial values of the modulation pattern are frequency f0 = 12 kHz and frequency f1 = 18 kHz.

Eventually, when an information request notification requesting transmission of device information is received from the terminal device 4 (step S102; YES), the control device 3 frequency-analyzes the sound waves in the surrounding environment (step S103). From the result of the frequency analysis, the control device 3 detects the noise level from the predetermined frequency band Δf centering on the frequency f1 on the high frequency side of the modulation pattern, compares the detected noise level with the threshold value, and makes noise. It is determined whether or not the level is equal to or lower than the threshold value (step S104).

When the noise level is equal to or lower than the threshold value (step S104; YES), the control device 3 reads the device information 330 from the storage device 33, modulates the digital signal indicating the read device information 330 with the current modulation pattern, and uses sound waves. It is transmitted to the terminal device 4 (step S105). When the transmission of the device information 330 is completed, the process of the control device 3 returns to step S101.

On the other hand, when the noise level exceeds the threshold value (step S104; NO), the control device 3 searches for a frequency whose noise level is equal to or lower than the threshold value as a new frequency f1 from the result of the frequency analysis in step S103 (step S104; NO). Step S106). When the frequency search is completed, the control device 3 requests the terminal device 4 to change the carrier frequency (step S107). Specifically, the control device 3 generates a change request notification in which the current frequency f0 and the searched new frequency f1 (for example, 15 kHz) are stored, and generates a digital signal indicating the generated change request notification. It is modulated by a modulation pattern and transmitted to the terminal device 4 by sound waves.

Then, the control device 3 changes the carrier frequency (that is, frequency f1) on the harmonic side in the modulation pattern to the searched frequency (for example, 15 kHz) (step S108). After that, the process of the control device 3 returns to step S102.

FIG. 11 is a flowchart showing a procedure of device information acquisition processing executed by the terminal device 4. In the device information acquisition process, the above-mentioned device information acquisition application installed in the terminal device 4 is activated, and a user (for example, a worker of construction, maintenance, etc.) performs an operation related to the acquisition of device information. It will be started.

When the device information acquisition process is started, the terminal device 4 initializes the carrier frequency (step S201). That is, the terminal device 4 initializes the modulation pattern (frequency f0, f1) of the carrier frequency. In the present embodiment, the initial values of the modulation pattern are frequency f0 = 12 kHz and frequency f1 = 18 kHz.

Next, the terminal device 4 transmits an information request notification requesting the transmission of device information to the control device 3 (step S202). Specifically, the terminal device 4 modulates the digital signal indicating the information request notification with the current modulation pattern, and transmits it to the control device 3 by sound waves.

After that, when the change request notification is received from the control device 3, that is, when the carrier frequency change request is received (step S203; YES), the carrier frequency modulation pattern is changed based on the received change request notification (step S204). ). After that, the process of the terminal device 4 returns to step S202.

On the other hand, if the change request notification from the control device 3 is not received even after the predetermined reception waiting time (for example, 10 seconds) has elapsed, it is assumed that the terminal device 4 has not requested the change of the carrier frequency. The determination is made (step S203; NO), and the device information 330 is received from the control device 3 (step S205). When the reception of the device information 330 is completed, the terminal device 4 stores the received device information 330 in the storage device 44, displays it on a liquid crystal display or the like in a predetermined manner (step S206), and ends the device information acquisition process. To do.

As described above, according to the communication system 1 of the first embodiment, the device information regarding the state of the outdoor unit 2 is directly acquired from the outdoor unit 2 by the communication between the control device 3 of the outdoor unit 2 and the terminal device 4. be able to. Therefore, the user can immediately acquire the device information, and the efficiency of the maintenance work can be improved.

Further, since the acquired device information is stored in the terminal device 4, it is possible to analyze the state of the air conditioner including the outdoor unit 2 in detail.

Further, although the housing of the outdoor unit 2 is made of metal, the communication between the control device 3 of the outdoor unit 2 and the terminal device 4 is performed by sound waves, so that the communication is not hindered. Therefore, it is not necessary to perform communication after removing the housing once, and the efficiency of maintenance work can be improved.

Further, since the communication between the control device 3 and the terminal device 4 is performed by sound waves in the audible range, reflection and absorption in the housing of the outdoor unit 2 are suppressed, and the user can obtain device information even from a position slightly away from the outdoor unit 2. Can be obtained.

Further, by using sound waves in the audible range, it is possible to adopt a generally distributed terminal device such as a smartphone, which is equipped with an acoustic device such as a speaker or a microphone, instead of a dedicated terminal device as the terminal device 4. Is.

Further, since the communication between the control device 3 and the terminal device 4 is performed by the sound wave modulated by the FSK modulation method, the noise immunity to the amplitude of the sound wave in the surrounding environment is improved, and more stable communication becomes possible. ..

Further, when the noise level exceeds the threshold value in the sound wave of the surrounding environment, the control device 3 searches for a frequency at which the noise level is equal to or lower than the threshold value, changes the carrier frequency to the searched frequency, and determines the terminal device 4. Request a change in carrier frequency. Then, the terminal device 4 that receives such a request changes the carrier frequency to the frequency searched by the control device 3. As a result, the noise immunity to the carrier frequency of the sound waves in the surrounding environment is improved, and more stable communication can be realized between the control device 3 and the terminal device 4.

When requesting the terminal device 4 to change the carrier frequency, the frequency change requesting unit 306 does not have to notify the frequency searched by the frequency searching unit 305. In this case, the frequency changing unit 402 of the terminal device 4 may change the frequency f1 to a frequency sequentially selected from a plurality of preset frequency candidates (for example, 17, 16, 15, 14, 13 kHz).

Further, the noise level determination unit 303 detects the noise level in the predetermined frequency band Δf in place of the above determination or in addition to the above determination, centering on the frequency f0 on the low frequency side. , The detected noise level may be compared with the threshold value to determine whether or not the noise level is below the threshold value.

Then, when the noise level determination unit 303 determines that the noise level detected from the frequency band Δf centered on the frequency f0 exceeds the threshold value, the frequency search unit 305 sets the noise as a new frequency f0. Search for frequencies where the level is below the threshold. In this case, the frequency change request unit 306 generates a change request notification in which the searched new frequency f0 and the current frequency f1 or the searched new frequency f1 are stored in the terminal device 4. The generated digital signal indicating the change request notification is modulated by the current modulation pattern and transmitted to the terminal device 4 via the sound wave transmission unit 32. Then, the frequency changing unit 307 changes the carrier frequency based on the search result of the frequency searching unit 305.

Further, when the frequency search unit 305 searches for a new frequency f0 or new frequencies f0, f1, the frequency change request unit 306 does not notify the terminal device 4 of each searched frequency without notifying the terminal device 4. A change in frequency f0 or frequencies f0, f1 may be requested. In this case, the frequency changing unit 402 of the terminal device 4 changes the frequency f0 to a frequency sequentially selected from a plurality of frequency candidates preset for the frequency f0, and sets the frequency f1 to a plurality of preset frequencies f1. It suffices to change to the frequency sequentially selected from the frequency candidates of.

(Embodiment 2)
Subsequently, a second embodiment of the present invention will be described. In the following description, components and the like common to the first embodiment are designated by the same reference numerals, and the description thereof will be omitted.

FIG. 12 is a diagram showing an overall configuration of the communication system 1A according to the second embodiment of the present invention. The communication system 1A includes a control device 3A and a terminal device 4A. In the present embodiment, the communication between the control device 3A and the terminal device 4A is performed by sound waves of 20 Hz to 20 kHz (so-called audible range).

The control device 3A is an example of the information transmission device according to the present invention, and is arranged inside the metal housing of the outdoor unit 2 like the control device 3 of the first embodiment. The hardware configuration of the control device 3A is the same as that of the control device 3 (see FIG. 2). However, the function of the microcomputer 30 of the control device 3A is different from that of the microcomputer 30 of the control device 3. As shown in FIG. 13, the microcomputer 30 of the control device 3A includes a communication control unit 300A instead of the communication control unit 300.

As shown in FIG. 14, the communication control unit 300A includes an information request notification reception unit 302, a noise level determination unit 303, an equipment information transmission unit 304A, a frequency search unit 305, and a frequency change unit 307. These functional units are realized by the CPU of the microcomputer 30 of the control device 3A executing a communication program stored in the storage device 33 for communicating with the terminal device 4A.

As shown in FIG. 14, the communication control unit 300A is different from the communication control unit 300 in that the device information transmission unit 304A is provided instead of the device information transmission unit 304 and the frequency change request unit 306 is not provided. ..

When the device information transmission unit 304A receives the information request notification transmitted from the terminal device 4A, the device information transmission unit 304A modulates the response signal indicating that the information request notification has been received with the current modulation pattern, and the terminal device via the sound wave transmission unit 32. Send to 4A. After that, the device information transmission unit 304A reads the device information 330 from the storage device 33, modulates the digital signal indicating the read device information 330 with the current modulation pattern, and transmits the digital signal indicating the read device information 330 to the terminal device 4A via the sound wave transmission unit 32. ..

The terminal device 4A is an example of the terminal device according to the present invention. Similar to the terminal device 4 of the first embodiment, the terminal device 4A is an electronic device carried by a user such as a smartphone or a tablet terminal. The hardware configuration of the terminal device 4A is the same as that of the terminal device 4 (see FIG. 3). However, the function of the microcomputer 40 of the terminal device 4A is different from that of the microcomputer 40 of the terminal device 4.

As shown in FIG. 15, the microcomputer 40 of the terminal device 4A includes an information request notification transmitting unit 400, a frequency changing unit 402A, a device information receiving unit 403, and an information display unit 404. These functional units are realized by the CPU of the microcomputer 40 of the terminal device 4A executing a device information acquisition application which is an application program for acquiring device information stored in the storage device 44.

As shown in FIG. 15, the function of the microcomputer 40 of the terminal device 4A is that the frequency changing unit 402A is provided instead of the frequency changing unit 402, and the change request notification receiving unit 401 is not provided. It is different from the microcomputer 40.

The frequency changing unit 402A may wait for a predetermined reception time (for example, 10 seconds) to elapse after the information request notification requesting the transmission of device information is transmitted to the control device 3A by the information request notification transmitting unit 400. When the response signal from the control device 3A is not received, the modulation pattern of the carrier frequency is changed. The initial values of the modulation pattern of the present embodiment are the frequency f0 = 12 kHz and the frequency f1 = 18 kHz, as in the first embodiment. The frequency changing unit 402A changes the frequency f1 on the harmonic side to a frequency sequentially selected from a plurality of preset frequency candidates (for example, 17, 16, 15, 14, 13 kHz).

FIG. 16 is a flowchart showing a procedure of device information transmission processing executed by the control device 3A. In the device information transmission process, the power of the control device 3A is turned on (that is, the power of the outdoor unit 2 is turned on), and the CPU of the microcomputer 30 activates the communication program stored in the storage device 33. It will be started.

When the device information transmission process is started, the control device 3A initializes the carrier frequency (step S301). Specifically, the control device 3A initializes the modulation pattern of the carrier frequency (frequency f0, f1). Next, the control device 3A frequency-analyzes the sound waves in the surrounding environment (step S302). From the result of the frequency analysis, the control device 3A detects the noise level from the predetermined frequency band Δf centering on the frequency f1 on the high frequency side of the modulation pattern, compares the detected noise level with the threshold value, and makes noise. It is determined whether or not the level is equal to or lower than the threshold value (step S303).

When the noise level is equal to or less than the threshold value (step S303; YES), the control device 3A determines whether or not the information request notification requesting the transmission of the device information has been received from the terminal device 4A (step 304). If the information request notification has not been received (step S304; NO), the process of the control device 3A returns to step S302.

On the other hand, when the information request notification is received (step S304; YES), the control device 3A modulates the response signal indicating that the information request notification has been received with the current modulation pattern, and transmits the sound wave to the terminal device 4A. (Step S305). After step S305, the control device 3A modulates the digital signal indicating the device information 330 read from the storage device 33 with the current modulation pattern, and transmits it to the terminal device 4A by sound waves (step S306). When the transmission of the device information 330 is completed, the process of the control device 3A returns to step S301.

When NO in step S303, that is, when the noise level exceeds the threshold value, the control device 3A searches for a frequency whose noise level is equal to or lower than the threshold value as a new frequency f1 from the result of the frequency analysis in step S302 (step). S307). Then, the control device 3A changes the carrier frequency (that is, frequency f1) on the harmonic side in the modulation pattern to the searched frequency (for example, 15 kHz) (step S308). After that, the process of the control device 3A returns to step S302.

FIG. 17 is a flowchart showing a procedure of device information acquisition processing executed by the terminal device 4A. In the device information acquisition process, the above-mentioned device information acquisition application installed in the terminal device 4A is activated, and a user (for example, a worker of construction, maintenance, etc.) performs an operation related to the acquisition of device information. To be started.

When the device information acquisition process is started, the terminal device 4A initializes the carrier frequency (step S401). That is, the terminal device 4A initializes the modulation pattern (frequency f0, f1) of the carrier frequency.

Next, the terminal device 4A transmits an information request notification requesting the transmission of device information to the control device 3A (step S402). Specifically, the terminal device 4A modulates the digital signal indicating the information request notification with the current modulation pattern, and transmits it to the control device 3A by sound waves.

After that, when the response signal indicating that the information request notification has been received is received from the control device 3A (step S403; YES), the terminal device 4A receives the device information 330 from the control device 3A (step S405). When the reception of the device information 330 is completed, the terminal device 4A stores the received device information 330 in the storage device 44, displays it on a liquid crystal display or the like in a predetermined manner (step S406), and ends the device information acquisition process. To do.

On the other hand, if the response signal from the control device 3A is not received even after the predetermined reception waiting time (for example, 10 seconds) has elapsed (step S403; NO), the terminal device 4A has a frequency on the harmonic side. The modulation pattern of the carrier frequency is changed by changing f1 to a frequency sequentially selected from a plurality of frequency candidates (step S404). After that, the process of the terminal device 4A returns to step S402.

As described above, according to the communication system 1A of the second embodiment, the device information regarding the state of the outdoor unit 2 is directly acquired from the outdoor unit 2 by the communication between the control device 3A of the outdoor unit 2 and the terminal device 4A. be able to. Therefore, the user can immediately acquire the device information, and the efficiency of the maintenance work can be improved.

Further, since the acquired device information is stored in the terminal device 4A, it is possible to analyze the state of the air conditioner including the outdoor unit 2 in detail.

Further, although the housing of the outdoor unit 2 is made of metal, the communication between the control device 3A and the terminal device 4A of the outdoor unit 2 is performed by sound waves, so that the communication is not hindered. Therefore, it is not necessary to perform communication after removing the housing once, and the efficiency of maintenance work can be improved.

Further, since the communication between the control device 3A and the terminal device 4A is performed by sound waves in the audible range, reflection and absorption in the housing of the outdoor unit 2 are suppressed, and the user can obtain device information even from a position slightly away from the outdoor unit 2. Can be obtained.

Further, by using sound waves in the audible range, it is possible to adopt a generally distributed terminal device such as a smartphone, which is equipped with an acoustic device such as a speaker or a microphone, instead of a dedicated terminal device as the terminal device 4A. Is.

Further, since the communication between the control device 3A and the terminal device 4A is performed by the sound wave modulated by the FSK modulation method, the noise immunity to the amplitude of the sound wave in the surrounding environment is improved, and more stable communication becomes possible. ..

Further, when the noise level exceeds the threshold value in the sound wave of the surrounding environment, the control device 3A searches for a frequency at which the noise level is equal to or lower than the threshold value, and changes the carrier frequency to the searched frequency. On the other hand, when the terminal device 4A cannot receive the response signal from the control device 3A after transmitting the information request notification, the terminal device 4A changes the carrier frequency to a frequency sequentially selected from a plurality of preset frequency candidates. As a result, the noise immunity to the carrier frequency of the sound waves in the surrounding environment is improved, and more stable communication can be realized between the control device 3A and the terminal device 4A.

The noise level determination unit 303 detects the noise level in the predetermined frequency band Δf in place of the above determination or in addition to the above determination, centering on the frequency f0 on the low frequency side. , The detected noise level may be compared with the threshold value to determine whether or not the noise level is below the threshold value.

Then, when the noise level determination unit 303 determines that the noise level detected from the frequency band Δf centered on the frequency f0 exceeds the threshold value, the frequency search unit 305 sets the new frequency f0 to noise. A frequency whose level is equal to or lower than the threshold is searched, and the frequency changing unit 307 changes the carrier frequency based on the search result of the frequency searching unit 305.

The present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the gist of the present invention.

For example, the device according to the present invention is not limited to the outdoor unit, and may be a home electric appliance such as a television, a refrigerator, a microwave oven, a rice cooker, a vacuum cleaner, or other equipment.

Further, communication between the control devices 3 and 3A and the terminal devices 4 and 4A may be performed by sound waves in the inaudible range (that is, ultrasonic waves).

Further, communication between the control devices 3 and 3A and the terminal devices 4 and 4A may be performed by sound waves modulated by a modulation method such as ASK (Amplitude Shift Keying) or PSK (Phase Shift Keying).

In addition, all or part of the functional parts of the control devices 3 and 3A (see FIGS. 5 and 14) and all or part of the functional parts of the terminal devices 4 and 4A (see FIGS. 9 and 15) are dedicated hardware. It may be realized. Dedicated hardware is, for example, a single circuit, a composite circuit, a programmed processor, an ASIC (Application Specific Integrated Circuit), an FPGA (Field-Programmable Gate Array), or a combination thereof.

The communication program and device information acquisition application in each of the above embodiments are CD-ROM (Compact Disc Read Only Memory), DVD (Digital Versatile Disc), magneto-optical disc (Magneto-Optical Disc), and USB (Universal). Serial Bus) It is also possible to store and distribute in a computer-readable recording medium such as a memory, a memory card, or an HDD.

Further, each communication program may be stored in a storage device included in a server (not shown) on the Internet, and the corresponding communication program may be downloaded from the server to the control devices 3 and 3A. Similarly, each device information acquisition application is stored in a storage device of a server (not shown) on the Internet so that the corresponding device information acquisition application is downloaded from the server to the terminal devices 4 and 4A. You may.

1,1A communication system, 2 outdoor unit, 3,3A control device, 4,4A terminal device, 30,40 microcomputer, 31,41 sound receiver, 32,42 sound transmitter, 33,44 storage device, 34,35 , 36, 45, 46, 47, 48, 312, 322, 421, 422 signal line, 43 user interface, 300, 300A communication control unit, 301 main control unit, 302 information request notification reception unit, 303 noise level determination unit, 304, 304A Equipment information transmission unit, 305 frequency search unit, 306 frequency change request unit, 307, 402, 402A frequency change unit, 310,410 sound collector, 311,411 A / D conversion circuit, 320, 420 D / A Conversion circuit, 321,421 sounding unit, 330 device information, 400 information request notification transmitter, 401 change request notification receiver, 403 device information receiver, 404 information display

Claims (11)

An information transmitter located inside the housing of a device.
Terminal communication means that communicates with the terminal device by sound waves,
A storage means for storing device information related to the state of the device, and
When an information request notification requesting transmission of the device information is received from the terminal device via the terminal communication means, the device information read from the storage means is transmitted to the terminal device via the terminal communication means. An information transmission device including a control means. The information transmission device according to claim 1, wherein the device is an outdoor unit of an air conditioner. The information transmitting device according to claim 1 or 2, wherein the terminal communication means communicates with the terminal device by sound waves in an audible range. The information transmission device according to any one of claims 1 to 3, wherein the terminal communication means communicates with the terminal device by sound waves modulated by an FSK (Frequency Sift Keying) modulation method. The communication control means
A noise level determining means for detecting the noise level of sound waves in the surrounding environment based on the carrier frequency by the FSK modulation method and determining whether or not the detected noise level is equal to or less than the threshold value.
When the noise level exceeds the threshold value, a frequency search means for searching for a frequency at which the noise level is equal to or lower than the threshold value in the sound wave of the surrounding environment
The information transmitting device according to claim 4, further comprising a frequency changing means for changing the carrier frequency to the searched frequency. The information transmission device according to claim 5, wherein the communication control means further includes a change requesting means for requesting the terminal device to change the carrier frequency when the noise level exceeds a threshold value. The information transmitting device according to claim 6, wherein the change requesting means notifies the terminal device of the frequency searched by the frequency searching means. A device including the information transmitting device according to any one of claims 1 to 7 inside a housing. It is equipped with an information transmission device and a terminal device arranged inside the housing of the device.
The information transmitting device is
A terminal communication means that communicates with the terminal device by sound waves,
A storage means for storing device information related to the state of the device, and
When an information request notification requesting transmission of the device information is received from the terminal device via the terminal communication means, the device information read from the storage means is transmitted to the terminal device via the terminal communication means. A communication system including a control means. The terminal device transmits an information request notification requesting the transmission of device information regarding the state of the device to the information transmitting device arranged inside the housing of the device by sound waves.
A communication method in which when the information transmitting device receives the information request notification, the device information is transmitted to the terminal device by sound waves. The computer placed inside the housing of the device,
When an information request notification requesting transmission of device information regarding the state of the device is received from the terminal device via the terminal communication means that communicates with the terminal device by sound wave, the device information is transmitted to the terminal via the terminal communication means. A program that functions as a communication control means for transmitting to a device.

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