JP2005134081A - Equipment with infrared communicating function - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide equipment with infrared communicating function, which hardly causes inhibition of infrared communication even if an infrared ray receiving element is arranged within a display part. <P>SOLUTION: The display part 40A comprises a display circuit board 43 for mounting a temperature display part (light emitting indicator) 47, and a main circuit board 45 for mounting an infrared transmitting and receiving part (infrared ray receiving element and infrared ray emitting element) 49. The main circuit board 45 is arranged with a space so as to be located on the deep side of the display circuit board 43. The display circuit board 43 has an opening (translucent part) 43A formed in a position corresponding to the infrared transmitting and receiving part 49 mounted on the main circuit board 45. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a device having an infrared communication function.

Conventionally, when a device such as a refrigerator breaks down, an abnormality factor is estimated by diagnosing the error code displayed by the device or the actual operation status (see, for example, Patent Document 1).
JP 2000-121229 A (FIG. 16)

However, since the amount of information such as an error code is not so large, there are many cases where an abnormality factor cannot be specified only by diagnosis based on such information. In this case, since it is necessary to disassemble and investigate the equipment, there is a problem that it takes time to identify the cause of the abnormality.
In view of this, it has been considered to use a portable terminal capable of infrared communication with a device and analyze the operation information of the device on the portable terminal side to identify the cause of the abnormality.
For this purpose, it is necessary to attach an infrared light receiving element to the device side. The mounting position is preferably provided in the display unit already provided in the device from the viewpoints of space constraints and design simplicity.
However, in many cases, a light-emitting indicator such as an LED is used in the display unit to make it easy to see the display of temperature, error code, etc. If an infrared light receiving element is arranged in the display unit, the light-emitting indicator There was a possibility that a small amount of infrared rays from the laser beam would enter the infrared light receiving element and inhibit infrared communication.
The present invention has been completed based on the above circumstances, and an object thereof is to provide a device having an infrared communication function in which infrared communication is hardly hindered even when an infrared light receiving element is arranged in a display unit. And

As a means for achieving the above object, the invention of claim 1 includes an indicator having a light emitting display capable of emitting and displaying, and an infrared light receiving element for receiving infrared rays transmitted from a portable terminal. In the device having an infrared communication function for performing infrared communication with the portable terminal, the infrared light receiving element is in the vicinity of the light emitting display, and the light emitting surface of the light emitting display It is located in the back | inner side of the said display part rather than.
In addition, it does not specifically limit as an apparatus, For example, a refrigerator, a freezer, an ice maker, a dishwasher etc. are included.

According to a second aspect of the present invention, in the first aspect, the infrared light receiving element is mounted on a main circuit board different from the display circuit board on which the light emitting display is mounted, and the main circuit board is The display circuit board is disposed so as to be located on the back side of the display circuit board with a space therebetween, and the display circuit board is formed with a light transmitting portion that transmits the infrared light at a position corresponding to the infrared light receiving element. Features.
According to a third aspect of the present invention, in the second aspect of the present invention, the main circuit board is mounted with a control circuit for controlling the device.

<Invention of Claim 1>
According to the structure of this claim, the infrared light receiving element is provided on the back side of the light emitting surface of the light emitting display. Since the light emitting display emits infrared light mainly toward the front side of the light emitting surface, the infrared light receiving element provided on the back side of the light emitting display is not easily affected by the infrared light emitted by the light emitting display.
Therefore, infrared communication is hardly hindered between the device and the portable terminal.
<Invention of Claim 2>
According to the configuration of the present claims, the arrangement relationship in which the infrared light receiving element is positioned on the back side of the light emitting display can be rationally realized by using two substrates. That is, since the light emitting display is mounted on the display circuit board, the display circuit can be configured by the same board alone, the design and inspection can be simplified, and the infrared light necessary for communication is provided on the main circuit board. Since it is supposed to mount the light receiving element, it is possible to configure the communication circuit with the same board and simplify the design and inspection. It can be located on the back side.
<Invention of Claim 3>
A control circuit is mounted on the main circuit board together with the infrared light receiving element. Therefore, the loss until the signal based on the infrared light received by the infrared light receiving element reaches the control circuit is reduced.

<Description of the entire concrete usage model>
A refrigerator-freezer 10 (corresponding to the device of the present invention) 10 according to an embodiment of the present invention will be described with reference to FIGS. The following model assumes that a service person in charge of maintenance mainly operates the mobile phone 13 as a field tester (however, it is applicable not only to service persons but also to users and device administrators). is there). FIG. 1 shows the concept of the whole model, a refrigerator-freezer 10, a mobile phone (corresponding to the mobile terminal of the present invention) 13 capable of infrared communication with the refrigerator 10, the mobile phone 13 and the Internet (of the present invention). The concept of the web server 17 connected via the communication network 15 and the database server 19 connected to the web server 17 is shown. The outline of this system will be described. Mainly, a service person in charge of maintenance obtains various operation information related to the refrigerator / freezer 10 such as the operation status of each part from the refrigerator / freezer 10 using the mobile phone 13, and based on the operation information. Diagnosis (reading of abnormal factors) is performed by a program in the mobile phone, and the result (abnormal factors) is displayed.

  Then, when a predetermined site is accessed via the Internet 15 and an abnormal factor is transmitted to the web server 17, the web server 17 refers to the database server 19 to identify an identification code of a part related to the abnormal factor. Next, the web server 17 transmits an identification code of a part related to the abnormality factor to the mobile phone 13. Thus, this system is configured. Note that even when there are a plurality of refrigerators 10, the mobile phone 13 is configured to establish communication with a specific one of them using a known identification method.

The details will be described below. The refrigerator-freezer 10 of this embodiment has illustrated the 4-door refrigerator refrigerator, and as shown in FIG. 2, the refrigerator-freezer main body 21 is formed from the heat insulation box body by which the front was opened, and it is in the four corners of a bottom face. The interior is a storage chamber 23 supported by the provided legs 22. A partition frame 26 having a cross shape is provided in the opening 25 on the front surface, and a total of four entrances 27 are formed on the top, bottom, left, and right, and a door 28 is attached to each entrance 27 in a double door manner. Of the four divided storage rooms 23, the upper right one is a freezing room, and the other is a refrigeration room.
On the other hand, a machine room 30 is provided above the refrigerator body 21, and two sets of cooling circuits including a compressor 51, a condenser 53, and the like are installed therein, one of which is used for a freezer room and the other is a refrigerator. It is for room use.

A laterally long opening 30A is formed on the right side of the front side wall of the machine room 30, and a control box 40 having a display unit 40A on the front surface is attached to the rear thereof (see FIG. 2). The control box 40 also includes an operation unit (not shown) for controlling the cooling circuit of the refrigerator 10 and the like.
As shown in FIGS. 3 and 4, the control box 40 includes a case 41 having a substantially rectangular parallelepiped shape and a temperature display unit (corresponding to a light emitting display capable of light emission display) 47 housed in the case 41. Display circuit board 43 and main circuit board 45 on which infrared transmission / reception unit 49 is mounted (infrared light receiving element and infrared light emitting element are built in infrared transmission / reception part 49). In the case 41, the main circuit board 45 is arranged at an interval so as to be located on the back side of the display circuit board 43.
The front wall 41A located in front of the display circuit board 43 is made of a transparent resin or the like, and the rear surface of the front wall 41A is left with a position corresponding to the temperature display unit 47 and the infrared transmission / reception unit 49 to be shielded from printing. 41B is given.

Mounted on the display circuit board 43 are temperature display portions 47 and 47 such as LEDs, and circuit components 44 such as ICs for display circuits, transistors, resistors, capacitors, and the like. The display circuit board 43 has an opening (corresponding to a translucent part that transmits infrared rays) 43 </ b> A at a position corresponding to the infrared transmission / reception part 49 mounted on the main circuit board 45. The main circuit board 45 is mounted with circuit components 45A such as an IC, a transistor, a resistor, and a capacitor that form a control circuit for controlling the communication circuit and the refrigerator 10.
As described above, the infrared transmission / reception unit 49 is located in the vicinity of the temperature display unit 47 and on the far side of the display unit 40A from the light emitting surface 47A of the temperature display unit 47.
In the present embodiment, two temperature display portions 47 are provided, and a plurality of types of temperature display are possible. For example, both the freezer compartment temperature and the refrigerator compartment temperature are displayed. An outside air temperature sensor 50 is attached to the side of the control box 40 so that the outside air temperature can be detected (see FIG. 5).

Next, the cooling circuit will be described with reference to FIG. In the present embodiment, two sets of cooling circuits are provided as described above, but since both structures are basically the same, only one cooling circuit will be described in the following description.
In the cooling circuit, a condenser 53 is connected to the outlet side (high pressure side) of the compressor 51, and a refrigerant flow in which an expansion valve 55, a capillary tube 57, and a cooler 59 (evaporator) are connected in series on the downstream side. A pipe is provided and connected to the inlet side (low pressure side) of the compressor 51. In addition, an internal fan 61 is disposed near the boundary between the machine room 30 and the storage room 23, and a filter 63 and a condenser fan 65 are provided on the front side of the condenser 53.
Further, in this embodiment, a defrosting operation is appropriately performed using a timer or the like. When the defrosting operation start signal is input, the cooling operation is stopped and the defrosting heater 67 provided in the cooler 59 is energized to perform defrosting. When the defrost sensor (defrost sensor) 69 detects that the temperature of the cooler 59 has risen to a predetermined level or more, it is considered that the defrost has been completed, and the power supply to the defrost heater 67 is released. The cooling operation is resumed after a predetermined drainage time.

Further, a clogging detection sensor (condenser temperature sensor) 71 is attached to the outlet of the condenser 53 so that the temperature rise of the condenser 53 when the filter 63 of the condenser 53 is clogged can be detected. Yes.
In addition, an internal temperature sensor 73 is attached in the vicinity of the internal fan 61 so that the internal temperature can be detected.

<Description of control means>
As shown in FIG. 6, the refrigerator / freezer 10 is provided with a control means 81. On the input side of the control means 81, an internal temperature sensor 73, an outside air temperature sensor 50, a clogging inspection sensor 71, a removal filter are provided. The compressor 51, the defrost heater 67, the internal fan 61, and the condenser fan 65 are connected to the output side of the frost sensor 69.
The control means 81 is connected to a storage means (information storage means) 83 so that the temperature detected by each sensor can be stored in time series.
The flowchart shown in FIG. 7 shows a flow of processing for storing operation information (measured temperature of each sensor, etc.) of the refrigerator / refrigerator 10 together with time information. In this embodiment, every predetermined time interval (for example, 1 The operation information is recorded every hour). The processing program is stored in the storage unit 83 (specifically, ROM, RAM, EPROM, HDD, etc.).

When a predetermined time has elapsed since the previous process (S10: YES), the operation information, specifically the operation status (driving status), the set temperature, the measured temperature of the outside air temperature sensor 50, in association with the time information, The measurement temperature of the internal temperature sensor 73, the measurement temperature of the defrost sensor 69, the measurement temperature of the clogging sensor 71, and error output information (for example, information output when the refrigerator 10 is abnormally heated and urgently stops) Is stored (S20). A clock program for obtaining the stored time is provided in the control means 81, for example. As a result, the operation information and the time information are associated with each other and stored in the storage unit 83 as shown in FIG.
The control means 81 includes an operation control unit 81A for controlling each operation such as operation / stop of the compressor 51, the defrost heater 67, the internal fan 61, and the condenser fan 65, and a control code transmitted from the mobile phone 13. Is provided with a remote control unit 81B for giving an operation command corresponding to the control code to the operation control unit 81A.
With this configuration, when a control code is transmitted from the mobile phone 13 to the infrared communication unit 88, the compressor 51, the defrost heater 67, and the like can be remotely operated.
The control means 81 is connected to an infrared communication unit 88 (corresponding to a reception means and a transmission means), and can transmit and receive with the mobile phone 13 by infrared rays. In the infrared communication unit 88, an infrared transmission / reception unit 49 having a light emitting unit (infrared light emitting element) and a light receiving unit (infrared light receiving element), an infrared communication control unit 89 for performing infrared communication protocol control, and infrared transmission / reception timing management A timing management unit 91 is provided.

The flowchart shown in FIG. 9 shows the flow of processing for transmitting the operation information of the refrigerator 10, and this processing program is stored in the storage means 83 (specifically, ROM, RAM, EPROM, HDD, etc.). Has been.
When the transmission request signal from the mobile phone 13 is received (S30: YES), the operation information is transmitted to the mobile phone 13 by infrared rays together with the ID of the refrigerator-freezer 10 (corresponding to the unique information of the refrigerator-freezer 10) (S40). The ID is unique to each refrigerator-freezer 10, and has a structure of “model name number + unique number”, for example, and is stored in the storage unit 83. Specifically, for example, “A” of ID “A0001” represents the model name “refrigerated refrigerator A”, and “B” of ID “B0001” represents the model name “refrigerated refrigerator B”. The number following “A” or “B” is a unique number for identifying each refrigerator-freezer 10.
In this way, by adding the ID to the operation information, it is possible to identify which specific refrigerator-freezer 10 the operation information received by the web server 17 described later is.
As will be described later, a control signal for resetting unique information such as an ID can be transmitted from the infrared communication unit 101 of the mobile phone 13, and the control means 81 of the refrigerator-freezer 10 receives the control signal. Based on this, the unique information such as the ID stored in the storage unit 83 can be reset (rewritable) (the control unit 81 also functions as a unique information resetting unit (rewriting unit)). Therefore, the ID can be easily reset by the mobile phone 13 even after the refrigerator 10 is shipped.

<Description of mobile phone>
On the other hand, the mobile phone 13 includes a terminal control means 93 for controlling the mobile phone 13, a storage means 95 for storing data such as operation information transmitted from the predetermined program and the refrigerator 10 connected thereto, and terminal control. Wireless communication means 97 controlled by means 93 to transmit / receive radio waves to / from the base station, and display means such as a liquid crystal panel controlled by display control unit 93B in terminal control means 93 to display predetermined data contents 99 is provided.
In the storage means 95, as shown in FIG. 12, an abnormality factor storage unit 95A for storing an abnormality factor database (abnormality factor DB) including various abnormality factors associated with each operation information of the refrigerator 10 is shown in FIG. Thus, a control code storage unit 95B that stores a control code database (control code DB) including control codes associated with operation commands for various operations such as operation / stop of the refrigerator / freezer 10 is provided.
In the abnormality factor database, as shown in FIG. 12, the abnormality factors in each case are stored in association with the operation information (relationship between the operation status and the measured temperature) from (1) to (8). An abnormality factor is stored in one record in association with each operation information, and has fields for operation information and abnormality factor.

Here, the correspondence between the operation information and the abnormality factor in the abnormality factor database will be described in detail.
(1) During operation of the refrigeration circuit (compressor 51), if the refrigerator 10 is operating normally, the relationship between the measured temperature of the clogging inspection sensor 71 ≥ the measured temperature of the outside air temperature sensor 50 should be satisfied. . This is because, during the operation of the refrigeration circuit, due to the heat generated by the condenser 51, the measured temperature of the clogging inspection sensor 71 disposed in the vicinity thereof should be higher than the measured temperature of the outside air temperature sensor 50 (FIG. 5).
Therefore, when the measured temperature of the clogging inspection sensor 71 is equal to the measured temperature of the outside air temperature sensor 50 during the operation of the refrigeration circuit, the cause is an abnormality of the compressor 51, the clogging inspection sensor 71 or the outside air temperature sensor. 50 abnormalities, or refrigerant leakage from the refrigeration circuit is considered.
Therefore, during operation of the refrigeration circuit (compressor), if the measured temperature of the clogging inspection sensor 71 is equal to the measured temperature of the outside air temperature sensor 50, the compressor 51 is abnormal, the clogging inspection sensor 71 or the outside air temperature sensor 50 is Corresponding to an abnormality or refrigerant loss from the refrigeration circuit.
In the present embodiment, when the temperature difference between the measurement temperature of the clogging inspection sensor 71 and the measurement temperature of the outside air temperature sensor 50 is within 5 degrees, the measurement temperature of the clogging inspection sensor 71 ≈ the outside air temperature sensor 50. Judging from the measured temperature.

(2) During operation of the refrigeration circuit (compressor), if the refrigerator-freezer 10 is operating normally, the relationship of the measured temperature of the internal temperature sensor 73 ≥ the measured temperature of the defrost sensor 69 should be satisfied. This is because the defrost sensor 69 is closer to the cooler 59 cooled by the operation of the refrigeration circuit (compressor) than the internal temperature sensor 73 (see FIG. 5).
When the refrigerator 10 is normal, the above relationship should hold, and therefore, when the refrigeration circuit (compressor) is in operation, the measured temperature of the internal temperature sensor 73 <the measured temperature of the defrost sensor 69. Corresponds to the abnormality of the internal temperature sensor 73 or the defrost sensor 69.
In this embodiment, when the measured temperature of the internal temperature sensor 73 is lower than the measured temperature of the defrost sensor 69 by, for example, 5 degrees or more, the measured temperature of the internal temperature sensor 73 <the measured temperature of the defrost sensor 69 and Judgment is made.

(3) In the refrigerator 10, when the internal temperature becomes the set temperature and the refrigeration circuit (compressor) is stopped, the relationship between the measurement temperature of the internal temperature sensor 73 ≈ the measurement temperature of the defrost sensor 69 is established. It should be. This is because in this state, the temperatures in the machine room and the cabinet are considered to be stable near the set temperature.
When the refrigerator 10 is normal, the above relationship should hold. Therefore, when the temperature of the internal temperature sensor 73 is not equal to the temperature measured by the defrost sensor 69 while the refrigeration circuit is stopped, the internal temperature It corresponds to the abnormality of the sensor 73 or the defrost sensor 69.
In this embodiment, when the difference between the measured temperature of the internal temperature sensor 73 and the measured temperature of the defrost sensor 69 is 5 degrees or more, the measured temperature of the internal temperature sensor 73 ≠ measured by the defrost sensor 69. Judging to be temperature.

(4) Further, during energization of the defrost heater 67, if the refrigerator-freezer 10 is operating normally, the relationship between the measured temperature of the internal temperature sensor 73 ≦ the measured temperature of the defrost sensor 69 should be satisfied. This is because the measured temperature of the defrost sensor 69 attached to the defrost heater 67 should be higher than the measured temperature of the internal temperature sensor 73 due to the heat generated by the defrost heater 67 (see FIG. 5).
When the measured temperature of the internal temperature sensor 73> the measured temperature of the defrost sensor 69 while the defrost heater 67 is energized, the cause is only when the internal temperature sensor 73 or the defrost sensor 69 is abnormal. In addition, there may be a case where the defrost heater 67 itself is disconnected and the temperature does not increase.
Accordingly, when the measured temperature of the internal temperature sensor 73> the measured temperature of the defrost sensor 69 while the defrost heater 67 is energized, an abnormality in the internal temperature sensor 73 or the defrost sensor 69 or the defrost heater 67 It corresponds to the disconnection.

(5) In any operating state (always), the measurement temperature of the defrost sensor 69 << the measurement temperature of the internal temperature sensor 73 (difference of 20 K (20 degrees) or more), or the measurement temperature of the defrost sensor 69 >> It cannot be the temperature measured by the internal temperature sensor 73 (difference of 20K (20 degrees) or more). This is because it is unlikely that there will be a difference in measured values of 20K or more because the positions of both sensors are close.
Therefore, when any one of these relationships is established, any abnormality of the defrost sensor 69 or the internal temperature sensor 73 is dealt with.

(6) Also, in any operating state (always), the measured temperature of the clogging inspection sensor 71 <the measured temperature of the outside air temperature sensor 50 (difference of 10 K (10 degrees) or more) does not occur.
This is because the condenser 53 arranged near the measurement temperature of the clogging inspection sensor 71 generates heat but cannot absorb heat.
Therefore, when this relationship is established, any abnormality of the clogging inspection sensor 71 or the outside air temperature sensor 50 is dealt with.

(7) While the refrigeration circuit (compressor) is stopped, if the refrigerator / freezer 10 is operating normally, the relationship between the measurement temperature of the clogging inspection sensor and the measurement temperature of the outside air temperature sensor should be satisfied. This is because the temperature in the machine room is substantially uniform when the refrigeration circuit is stopped.
Therefore, when the temperature measured by the clogging inspection sensor 71 >> the measured temperature of the outside air temperature sensor 50 (for example, when a temperature difference of 40 degrees or more occurs) while the refrigeration circuit is stopped, the cause is An abnormality in the clogging inspection sensor 71 or the outside air temperature sensor 50 is considered.
Therefore, when the temperature measured by the clogging inspection sensor 71 >> the temperature measured by the outside air temperature sensor 50 while the refrigeration circuit is stopped, the abnormality is detected in the clogging inspection sensor 71 or the outside air temperature sensor 50. .

(8) Further, in any operating state (always), the inside and outside of the refrigerator-freezer 10 cannot be higher than 70 ° C. Therefore, the measurement temperature of the clogging inspection sensor 71> 70 ° C. and the outside air temperature sensor 50 If the measured temperature is higher than 70 ° C., it corresponds to the possibility of the fire of the clogging inspection sensor 71 and the outside air temperature sensor 50 or the outside air temperature (environment temperature) being high.
Further, as shown in FIG. 13, the control code database stores operation commands such as operation / stop of each part in association with the control codes M1 to M8.
The terminal control means 93 displays a diagnosis unit 93A that reads out the abnormality factor of the refrigerator 10 by referring to the abnormality factor storage unit 95A based on the received various operation information, and the abnormality factor and other information on the display unit 99. And a display control unit 93B.
Further, the terminal control means 93 reads out the required control codes (M1 to M8) stored in the control code database based on the operation of the operation means such as a button of the mobile phone 13, and transmits the infrared communication unit (transmission of the present invention). The operation control unit 93 </ b> C for transmitting to the infrared communication unit 88 of the refrigerator / freezer 10 is provided. The terminal control means 93 is also provided with a unique information resetting section 93D that transmits a control signal from the infrared communication unit 101 for resetting the unique information based on an operation of an operation means such as a button of the mobile phone 13. It has been.
Moreover, as shown in FIG. 10, the terminal control means 93 is connected to the infrared communication unit 101, and can transmit and receive signals with the refrigerator-freezer 10 by infrared rays. The infrared communication unit 101 includes a transmission / reception control unit 103, an infrared transmission / reception unit 105 having a light emitting unit and a light receiving unit, an infrared communication control unit 107, a speaker unit 109 for outputting sound, and a microphone unit 111 for inputting sound. Yes.

Here, the diagnosis performed by the diagnosis unit 93A of the mobile phone 13 will be described.
The flowchart shown in FIG. 11 shows the flow of diagnostic processing, and this processing program is stored in the storage means 95 (specifically, ROM, RAM, EPROM, HDD, etc.). The program stored in the mobile phone 13 such as the processing program can be downloaded from, for example, a download site on the Internet homepage operated by the manufacturer of the refrigerator 10 or a recording medium such as a CD-ROM. It is supposed to be available from.

  When the infrared communication unit 101 of the mobile phone 13 receives the operation information from the refrigerator-freezer 10 (S50: YES), the display control unit 93B displays the content on the display means 99 (S55). For example, “While the refrigeration circuit is in operation, the set temperature is ○○ ° C, the outside air temperature sensor is measured ○○ ° C, the inside temperature sensor is measured ○○ ° C, the defrosting sensor is measured Temperature ”is displayed. By looking at this display, the service person grasps the current situation and thereby estimates the cause of the abnormality. When the service man requests a diagnosis by operating a button or the like (S60: YES), the diagnosis is started (S65). In the present embodiment, the service person performs diagnosis by selecting operation information to be diagnosed from the operation information transmitted from the refrigerator 10. At this time, the number of pieces of operation information to be selected is not particularly limited, and one or more pieces of operation information are selected (for example, only operation information during operation of the refrigeration circuit on October 2, 2003, 11:00 in FIG. 8). Or all of the operation information of October 1, 2003 11: 00 to October 2, 2003 11:00 in FIG. 8 may be used).

In this diagnosis process, when certain operation information is input, the diagnosis unit 93A searches and extracts (reads) an abnormality factor from the abnormality factor database based on the operation information. For example, if the operation status of the operation information is that the refrigeration circuit is operating and the relationship between the measured temperatures is the measured temperature of the clogging inspection sensor 71 ≈ the measured temperature of the outside air temperature sensor 50, the abnormality of the compressor is considered as an abnormal factor. The abnormality of the clogging inspection sensor, the abnormality of the outside air temperature sensor, and the lack of solvent from the refrigeration circuit are read out.
Then, the diagnosis result (abnormal factor) is displayed on the display means 99 (S70). At this time, for example, “Diagnosis has been completed. It is determined that the compressor is abnormal or is abnormal. Please send when requesting the part identification code” is displayed.
Next, when a transmission request to the web server 17 is made, for example, when a predetermined button operation is performed on the mobile phone 13 (S75: YES), the ID of the refrigerator 10 and the abnormality factor are transmitted to the web server 17 via the Internet 15. (S80).

<Description of web server>
As shown in FIG. 14, the web server 17 includes a transmission / reception means 17A. When a service person accesses a site such as a manufacturer of the refrigerator 10 through the Internet 15 using the mobile phone 13, the service is provided. It is a computer that transmits various data to the cellular phone 13 such as a man. Further, the web server 17 refers to the database server 19 as necessary, and transmits predetermined information to the mobile phone 13.
Further, when data of a certain field is input to the web server 17, an extraction unit 17C that searches a database in various database storage units 19B of the database server 19 and extracts a record including the input data or data included in the record. Is provided.

<Description of database server>
The database server 19 is a computer that stores various databases related to the refrigerator 10.
In this embodiment, the web server 17 and the database server 19 are configured as separate devices, but the functions of both may be provided in one device.
The database server 19 is provided with various database storage units 19B. As shown in FIG. 15, a user database (user DB), a service history database (service history DB), a service category database (service category DB), a component identification code A database (part identification code DB) is provided.

The user database is for accumulating user information of each refrigerator-freezer 10 in one record. As shown in FIG. 15, the refrigerator-freezer ID, user name, address, telephone number, service person in charge (specification) A service person in charge of maintenance of the refrigerator) has a mail address field.
As shown in FIG. 15, the service category database stores the service content type for each record, and has a service category code and a service content field. The service category code is the primary key of the service category database, and the service content is input of specific service content such as replacement of various sensors, sending of notifications that the maintenance period has arrived, sending of recall guidance, etc. Thus, the service category database compares the service type with the service category code.

  As shown in FIG. 15, the service history database stores information on services actually performed for each service, and has fields of history ID, date and time (service date and time), refrigerator-freezer ID, and service classification code. “History ID” is the primary key of the service history database assigned to each record, “Date and time” is the date when the service was actually performed, and “Refrigerator ID” is the identification of the service performed. The ID of the refrigerator / freezer is input, and the service classification code of the service classification database is input to “service classification code”.

  As shown in FIG. 15, the component identification code database stores the component identification codes of the components for each record. The component identification code database includes a component identification code in the component / refrigerator refrigerator A and a component identification code field in the refrigerator refrigerator B. Have. The sensor name and the like are input to the component, and the identification code corresponding to the type of refrigerator is input to the component identification code. Thus, the component identification code database compares various abnormality factors (component names) with the component identification codes related thereto.

As described above, the extraction unit 17C of the web server 17 searches the database in the various database storage unit 19B and extracts a record including the input data or data included in the record. Specifically, when the extraction unit 17C inputs a certain refrigerator-freezer ID, it searches for a record including the refrigerator-freezer ID, extracts a user name, an address, a telephone number, a responsible serviceman mail address from the user database, and a service history database. The service category code is extracted from the service category database, and the service content corresponding to the service category code extracted from the service history database is extracted from the service category database.
The extracting unit 17C extracts a part identification code corresponding to the part related to the abnormality factor from the part identification code database.

  Here, processing performed by the web server 17 will be described. As shown in the flowchart of FIG. 16, when the web server 17 receives the ID and the abnormality factor transmitted from the mobile phone 13 of the service person (S100: YES), the extraction unit 17C includes the ID. Search records, extract user name, address, telephone number, and responsible serviceman mail address from user database, extract service classification code from service history database, and correspond to service classification code extracted from service history database Service contents are extracted from the service category database (S110).

  Next, the extraction unit 17C reads the component identification code number of the sensor or the like corresponding to the abnormality factor from the component identification code database (S130). Then, the diagnosis result indicating the abnormality factor, the related component identification code, the service history of the refrigerator 10, the user name, etc. is transmitted (output) to the mobile phone 13 of the requesting serviceman to perform the processing. The process ends (S140).

In the specific use model of the refrigerator-freezer 10 described above, the refrigerator-freezer 10 collects and stores operation information related to the refrigerator-freezer 10. When the transmission request signal is received from the mobile phone 13, the operation information is transmitted to the mobile phone 13. Then, in the mobile phone 13, the contents of the operation information are displayed on the display means 99.
Further, in the mobile phone 13, even if a user or a service person does not diagnose the refrigerator / freezer 10 by his / her own experience or the like, the abnormality of the mobile phone 13 can be objectively specified by the diagnosis.
In order to establish such a model, it is necessary to prevent the infrared communication between the refrigerator-freezer 10 and the mobile phone 13 from being hindered. According to the present embodiment, the infrared transmitting / receiving unit 49 is provided on the back side of the light emitting surface 47 </ b> A of the temperature display unit 47. Since the temperature display unit 47 emits infrared light mainly toward the front side of the light emitting surface, the infrared transmission / reception unit 49 provided on the back side thereof is not easily affected by the infrared rays emitted from the temperature display unit 47. Therefore, infrared communication between the refrigerator-freezer 10 and the mobile phone 13 is not hindered and can be performed smoothly.
Further, according to the configuration of the present embodiment, the arrangement relationship in which the infrared transmission / reception unit 49 is positioned on the back side of the temperature display unit 47 can be rationally realized by using two substrates. That is, since the temperature display unit 47 is mounted on the display circuit board 43, the display circuit can be configured by the board alone, the design and inspection can be simplified, and the main circuit board 45 can be used for communication. Since the necessary infrared transmission / reception unit 49 is mounted, a communication circuit can be configured by using the same board alone to simplify the design and inspection. Can be positioned behind the temperature display 47.
In addition, since the infrared transmission / reception unit 49 is provided in the display unit 40A covered with a transparent resin plate (front wall 41A), a serviceman or the like does not need to remove the front panel or the like. Infrared communication can be performed through the plate.
The main circuit board 45 is mounted with a circuit component 45 </ b> A that constitutes a control circuit together with the infrared transmission / reception unit 49. Therefore, the loss until the signal based on the infrared light received by the infrared transmission / reception unit 49 reaches the control circuit is reduced.

<Other embodiments>
The present invention is not limited to the embodiments described with reference to the above description and drawings. For example, the following embodiments are also included in the technical scope of the present invention, and further, within the scope not departing from the gist of the invention other than the following. Various modifications can be made. Note that each of the routines (processing procedures) described above is merely an example, and can be changed as appropriate.
(1) In the said embodiment, although the temperature display part (light emission display) 47 was set to LED etc., if a light emission display displays a light emission, it will not specifically limit. For example, a liquid crystal with a backlight may be used.
(2) In the above embodiment, the temperature display unit (light emitting display) 47 is mounted on the display circuit board 43, and the infrared transmission / reception unit 49 is mounted on the main circuit board 45. It does not have to be mounted on the board. It may be supported by a simple support plate.
(3) In the said embodiment, although the example of the refrigerator-freezer 10 was mentioned and demonstrated as an apparatus, it is not specifically limited, For example, it is possible to apply also to a refrigerator, a freezer, an ice maker, a dishwasher, etc.
(4) In the above embodiment, transmission / reception of operation information (operating state, measured temperature) and the like is performed between the refrigerator-freezer 10 as a device and the portable terminal. The content of the signal is not particularly limited. For example, the power failure record information about the power failure date and time, and the operation information of each relay in the control circuit inside the device may be transmitted to the mobile terminal.
(5) In the above embodiment, the mobile phone 13 is used as the mobile terminal. However, various mobile terminals such as a PDA can be used in addition to the mobile phone 13.

Overview diagram showing the entire usage model Perspective view of refrigerator Front view of control box Cross section of control box Cross section of a refrigerator Block diagram showing the structure of a refrigerator-freezer Flowchart showing operation information storage routine The figure which shows the data memorized in the freezer Flow chart showing operation information transmission routine Block diagram showing the configuration of a mobile phone Flow chart showing diagnostic processing routine Schematic diagram showing the table of the abnormality factor database Schematic diagram showing the control code database table Block diagram of configuration of web server and database server Overview diagram showing tables in each database Flow chart showing server processing routine

Explanation of symbols

40A ... Display unit 40 ... Control box 41 ... Case 43 ... Display circuit board 43A ... Opening (translucent part)
45 ... main circuit board 47 ... temperature display (light emitting display)
49. Infrared transmitter / receiver (infrared light receiving element and infrared light emitting element)

Claims (3)

The display unit includes a light emitting display capable of light emission display, and includes an infrared light receiving element that receives infrared rays transmitted from a portable terminal, and performs infrared communication with the portable terminal. In equipment with infrared communication function,
An apparatus having an infrared communication function, wherein the infrared light receiving element is located in the vicinity of the light emitting display and further on the back side of the display unit than the light emitting surface of the light emitting display.   The infrared light receiving element is mounted on a main circuit board different from the display circuit board on which the light emitting display is mounted, and is overlapped with a gap so that the main circuit board is located on the back side of the display circuit board. 2. The apparatus having an infrared communication function according to claim 1, wherein the display circuit board is formed with a light transmitting portion that transmits the infrared light at a position corresponding to the infrared light receiving element. .   The apparatus having an infrared communication function according to claim 2, wherein a control circuit for controlling the apparatus is mounted on the main circuit board.

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