JP2011185547A - Service life management device, electric appliance and service life management method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a service life management device grasping deterioration over time of an electric appliance and providing and managing a service life enabling safe operation of the electric appliance, the electric appliance and a service life management method. <P>SOLUTION: The service life management device 200 managing the service life of the electric appliance includes: a current time acquisition part 21 acquiring current time at standard time; a storage part 23 storing beforehand the service life of the electric appliance; and a control part 22 comparing the standard time acquired by the current time acquisition part 21 with the service life and outputting a service life arrival signal when it is determined that the standard time exceeds the service life. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a life management apparatus, an electrical product, and a life management method for grasping deterioration with time of an electrical product and managing it by providing a life limit for safe operation of the electrical product.

  Conventionally, some devices have been equipped with a function to detect a defect in a component or body of an electrical product, or to notify the replacement time by counting the usage time of consumables (Patent Literature) 1). In the refrigerator disclosed in Patent Document 1, a replacement time is set for each consumable item, the usage time of the consumable item is counted, and the user is notified of the replacement time of the consumable item.

  In recent years, along with the prolongation of the life of electric products, there have also appeared electric products that measure deterioration with time in addition to the use time and number of use of the electric products (see Patent Document 2). In the washing machine disclosed in Patent Document 2, a clock function unit that counts aged deterioration of a product and a dedicated power source that drives the clock function unit when power is not supplied are provided to measure deterioration over time. .

JP-A-2005-114205 JP 2007-289453 A

  However, since the device that counts the usage time and the number of times of use does not count from the time of manufacture until the start of use, it cannot detect deterioration over time from the date of manufacture. Therefore, for example, when the product is used after being stored for a long time after manufacturing, there is a possibility that the time of use or the number of times of use may deteriorate over time before the product life is detected. In the refrigerator disclosed in Patent Document 1, the replacement time of consumables is determined based on the use time and frequency of use of the consumables, but the deterioration over time until the start of use after the consumables are used is taken into account. Absent.

  Further, in the washing machine disclosed in Patent Document 2, a clock function unit and a dedicated power source are provided for measurement of deterioration over time. However, since the time measurement process is performed by an internal counter, dedicated power source deterioration due to long-term non-use, etc. If an abnormality occurs in the internal counter, or if the time is set incorrectly, there is a possibility that the measurement of deterioration over time may not be performed normally.

  SUMMARY OF THE INVENTION The present invention has been made in view of such circumstances, and a life management device for managing the life of an electrical product to safely operate, taking into account the aging of the electrical product, an electrical product, and an approach different from the conventional one, The purpose is to provide a life management method.

  The life management device according to the present invention is a life management device that manages the life of some or all of the components that make up an electrical product, and a current time acquisition unit that acquires a standard time, and a lifetime of some or all of the components. A storage unit that stores the time in advance, a life comparison unit that compares the standard time acquired by the current time acquisition unit and the lifetime, and the lifetime comparison unit determines that the standard time exceeds the lifetime And a life management unit that outputs a predetermined signal.

  In the lifetime management apparatus according to the present invention, the lifetime may be a time lifetime indicated by time.

  In the life management apparatus according to the present invention, the life is a time life indicated by time, the storage unit stores in advance the manufacturing time of a part or all of the parts, and the life comparison unit The time difference between the acquired standard time and the manufacturing time is detected, the time difference is compared with the time life, and the life management unit determines that the time comparison unit exceeds the time life. In this case, the predetermined signal may be output.

  The life management apparatus according to the present invention may be configured such that the acquisition of the standard time and the comparison and determination by the life comparison unit are performed in time series.

  In the life management apparatus according to the present invention, a timepiece, a time correction unit that corrects the time of the timepiece with the standard time acquired by the current time acquisition unit, and a part or all of the parts using the timepiece. An integrated operating time management unit that integrates the operating time, wherein the storage unit stores in advance the integrated operating time life of some or all of the parts, and the life comparison unit manages the integrated operating time management When the life management unit determines that the accumulated operation time exceeds the accumulated operation time life, the predetermined operation time is compared with the predetermined operation time. The signal may be output.

  In the life management apparatus according to the present invention, a timepiece, a time correction unit that corrects the time of the timepiece with the standard time acquired by the current time acquisition unit, and a part or all of the parts using the timepiece. An integrated energization time management unit that integrates energization time, the storage unit stores in advance the integrated energization time life of some or all of the components, and the life comparison unit manages the integrated energization time management. When the life management unit determines that the accumulated energization time exceeds the accumulated energization time life, the predetermined energization time is compared with the accumulated energization time life. The signal may be output.

  In the lifetime management apparatus according to the present invention, the storage unit stores in advance the lifetime of a part or all of each component for a plurality of electrical products, and the lifetime comparison unit includes the acquired standard time and The lifetime management unit compares the lifetimes of the plurality of electrical products, and the lifetime management unit is configured to output the predetermined signal when the lifetime comparison unit determines that the standard time exceeds the lifetime. May be.

  An electrical product according to the present invention includes the above-described life management device.

  In the electrical product according to the present invention, the life management unit of the life management device may further include a control device configured to restrict the operation when a predetermined signal is output.

  The life management method according to the present invention includes a step of obtaining a standard time in a life management method for managing the life of part or all of the parts constituting an electrical product, and one of the parts stored in advance in a storage unit. A step of reading a part or all of the lifetime, and a step of comparing the acquired standard time with the read lifetime and outputting a predetermined signal when it is determined that the standard time exceeds the lifetime. It is characterized by that.

  In the present invention, the standard time is acquired, the acquired standard time is compared with the life of the electrical product stored in advance, and when the standard time is determined to exceed the product life, a predetermined life reaching signal is transmitted, If it is determined that the service life has not been exceeded, a predetermined service life reaching signal is not transmitted. The standard time is acquired by a current time acquisition unit such as a radio clock or an Internet time acquisition device, for example.

  In the present invention, the time life of the electric product may be stored in advance, and the time life may be compared with the standard time. In this case, it is preferable that the shortest aging time of the component parts constituting the electric product is the product time life. Note that the time life is preferably a unit suitable for an electric product for which life management is performed, such as year, month, day, hour, minute.

  In the present invention, the time life and manufacturing time of the electrical product may be stored in advance, a time difference between the standard time and the manufacturing time may be detected, and the time difference may be compared with the time life. As a result, the time-dependent deterioration time from the date of manufacture is not taken into consideration, and the time-dependent deterioration of the product can be measured even when a component with only the time-dependent deterioration time is set. The product manufacturing time may be a unit suitable for an electrical product that performs life management such as manufacturing year, month, day, hour, minute, and the like.

  In the present invention, the acquisition of the standard time and the life evaluation based on time / time may be executed in time series.

  In the present invention, a clock may be provided and the time of the clock may be corrected with the acquired standard time. Further, the operation time of some or all of the parts constituting the electrical product is integrated using the timepiece, the integrated operation time is compared with the integrated operation time life stored in the storage unit, and the integration is performed. When it is determined that the operating time exceeds the cumulative operating time life, the life management unit may transmit a life reaching signal. Thereby, in addition to the product life due to deterioration over time, the life of the electrical product can be detected based on the operation results. When the standard time cannot be acquired due to a communication failure or the like, the operation performance of the electrical product can be counted using a clock. When the standard time can be acquired, the clock is corrected with the standard time acquired from the current time acquisition unit, so that the operation results can be accurately counted.

  In the present invention, a clock may be provided and the time of the clock may be corrected with the acquired standard time. Furthermore, the energization time of a part or all of the parts constituting the electrical product is accumulated using the timepiece, and the accumulated energization time is compared with the accumulated energization time life stored in the storage unit. When it is determined that the energized time exceeds the accumulated energized time, the life management unit may transmit a life reaching signal. As a result, the lifetime of the electrical product can be detected not only by the usage frequency of the electrical product and the actual operation results, but also by the actual performance of the power supplied to the product in addition to the product lifetime due to deterioration over time. When the standard time cannot be acquired due to a communication failure or the like, the energization performance of the electrical product can be counted using a clock. When the standard time can be acquired, the clock is corrected with the standard time acquired from the current time acquisition unit, so that the energization results can be accurately counted.

  In the present invention, the storage unit stores a lifetime of a part or all of each component for a plurality of electrical products, and the lifetime comparison unit compares the standard time and the lifetime, respectively, You may make it manage the lifetime of a product, respectively.

  In the present invention, the electrical product may include a control device, and when the life reaching signal is transmitted, the control device may limit the operation of the electrical product.

  According to the present invention, it is possible to accurately measure deterioration over time from the time when an electrical product is manufactured over a long period of time, and when the electrical product reaches the end of its life, its operation can be surely limited. In particular, it is suitable for life management of home appliances that are expected to be used for a long period of time and electrical products including components that handle high loads such as high temperature, high voltage, and high voltage.

It is a schematic diagram which shows the structure of an air conditioner (electrical product) provided with the lifetime management apparatus which concerns on Embodiment 1 of this invention. It is a perspective view which shows the external appearance of the indoor unit of an air conditioner provided with the lifetime management apparatus which concerns on Embodiment 1 of this invention. It is a side longitudinal cross-sectional view which shows the example of a principal part structure of the indoor unit of an air conditioner provided with the lifetime management apparatus which concerns on Embodiment 1 of this invention. It is a perspective view which shows the external appearance of the outdoor unit of an air conditioner provided with the lifetime management apparatus which concerns on Embodiment 1 of this invention. It is a decomposition | disassembly schematic diagram which shows the principal part structural example of the outdoor unit of an air conditioner provided with the lifetime management apparatus which concerns on Embodiment 1 of this invention. It is a block diagram which shows the function structural example of the lifetime management apparatus which concerns on Embodiment 1 of this invention. It is a flowchart which shows operation | movement of the lifetime management apparatus which concerns on Embodiment 1 of this invention. It is a flowchart which shows operation | movement of the lifetime management apparatus which concerns on Embodiment 1 of this invention. It is a flowchart which shows operation | movement of the lifetime management apparatus which concerns on Embodiment 1 of this invention. It is a block diagram which shows the structure of the control apparatus of the air conditioner which concerns on Embodiment 2 of this invention. It is a block diagram which shows the function structural example of the lifetime management apparatus which concerns on Embodiment 2 of this invention. It is a flowchart which shows operation | movement of the lifetime management apparatus which concerns on Embodiment 2 of this invention. It is a flowchart which shows operation | movement of the lifetime management apparatus which concerns on Embodiment 2 of this invention.

  Hereinafter, the present invention will be specifically described with reference to the drawings showing embodiments thereof.

  In the following embodiments, the life management device according to the present invention is used in an air conditioner, and the life management device is incorporated in an indoor unit and an outdoor unit that constitute the air conditioner. explain.

(Embodiment 1)
FIG. 1 is a schematic diagram showing a configuration of an air conditioner including a life management apparatus according to an embodiment of the present invention. FIG. 2 is a perspective view showing an external appearance of an indoor unit of an air conditioner including the life management apparatus according to the embodiment of the present invention. FIG. 3 is a side longitudinal sectional view showing a configuration example of a main part of an indoor unit of an air conditioner provided with a life management apparatus according to an embodiment of the present invention. FIG. 4 is a perspective view showing an external appearance of an outdoor unit of an air conditioner equipped with a life management apparatus according to an embodiment of the present invention. FIG. 5 is an exploded schematic view showing a configuration example of a main part of an outdoor unit of an air conditioner provided with a life management apparatus according to an embodiment of the present invention.

  The air conditioner 100 including the life management apparatus 200 according to the present embodiment is a separate type, is installed above a wall in the house 15, and blows cold air or hot air 16 toward the room during operation. And an outdoor unit 14 installed on the ground along the outer wall of the house 15. The indoor unit 7 is provided with a control device 17 including a microcomputer that controls each device provided in the indoor unit 7. The outdoor unit 14 is provided with a control device 18 including a microcomputer that controls each device provided in the outdoor unit 14. The indoor unit 7 and the outdoor unit 14 incorporate the control devices 17 and 18, respectively, and are equipped with life management devices 200a and 200b for setting and managing the life of the electrical product.

  As shown in the perspective view of FIG. 2 and the side longitudinal sectional view of FIG. 3, the indoor unit 7 includes an indoor temperature measuring device 1 that measures the temperature of the air sucked from the room, a suction port from the room, An indoor heat exchanger 3 that is provided between the air outlet and exchanges heat with the sucked air and a temperature measuring device 2 that measures the temperature of the indoor heat exchanger 3 are provided.

  The indoor unit 7 is also provided at the blowout port of the indoor unit 7 on the air outlet side of the indoor unit 7, and is provided at the blowout port, the cross-flow indoor fan 4 that blows out the heat-exchanged air from the blowout port, An electric upper and lower louver 5 that swings the blown air in the vertical direction and an electric left and right louver 6 that is provided at the outlet and shakes the blown air in the left and right direction are provided. The indoor unit 7 includes a control device 17 having a microcomputer that controls each of the above devices, and a life management device 200a that is incorporated in the control device 17 and sets and manages the life of the indoor unit 7. The indoor unit 7 further includes an operation lamp (not shown).

  As shown in the perspective view of FIG. 4 and the exploded schematic diagram of FIG. 5, the outdoor unit 14 includes an outside air temperature measuring device 12 that measures the temperature of the sucked outside air, and an outside air inlet and an outdoor outlet. And an outdoor heat exchanger 8 for exchanging heat with the sucked outside air, and a temperature measuring device 13 for measuring the temperature of the outdoor heat exchanger 8.

  The outdoor unit 14 is also provided on the outlet side of the outdoor unit 14 of the outdoor heat exchanger 8, and the outdoor fan 9, the indoor heat exchanger 3, and the outdoor heat exchanger that blow out the heat-exchanged outside air from the outlet. Compressor 11 for compressing refrigerant flowing in a pipe (not shown) connecting 8, IPM (Intelligent Power Module) 19 for controlling compressor 11, and the direction in which refrigerant compressed by compressor 11 flows is determined during cooling or heating. And a four-way valve 10 that switches depending on the situation. Moreover, although the outdoor unit 14 is provided with the expansion valve, illustration is abbreviate | omitted. The outdoor unit 14 includes a control device 18 having a microcomputer that controls each of the above devices, and a life management device 200b that is incorporated in the control device 18 and sets and manages the life of the outdoor unit 14.

  The indoor unit 7 and the outdoor unit 14 control piping from the indoor unit 7 to the outdoor unit 14, a pipe for circulating refrigerant, a drain pipe for drainage, a wiring for flowing an operating current from the indoor unit 7 to the outdoor unit 14, and the like. Are connected by wiring for transmitting and receiving the control signal.

  Next, a life management apparatus 200 (200a, 200b) for setting and managing the life of the electrical product according to the present embodiment will be described with reference to the drawings. FIG. 6 is a block diagram illustrating a functional configuration example of the life management apparatus 200 according to the first embodiment. The life management device 200 stores the current time acquisition unit 21 that acquires the current time, the control unit 22 that detects the life of the electric product and transmits a life reaching signal when the electric product reaches the life, and stores the product life. Storage unit 23 to be stored.

  The current time acquisition unit 21 may be any device that can detect the current time, such as a radio clock or an Internet time acquisition device that acquires Japanese standard time in Japan.

  Whether the control unit 22 compares the current time and the product time life with the life management unit 201 that transmits a predetermined life arrival signal when the product life is reached based on the preset life of the electric product. Alternatively, the life comparison unit 202 that compares the product time life with the time difference between the current time and the manufacturing time, and the integration time management unit 203 that calculates the integration of the operation time, the energization time, and the energization frequency of the electrical product and stores it in the storage unit 23 And a time correction unit 204 that corrects the built-in clock of the electrical product at the current time. Note that the time correction unit 204 may not be provided if the electrical product does not include a built-in clock.

  When the life management unit 201 detects that the product life has been reached by the life comparison unit 202 or the accumulated time management unit 203, the life management unit 201 transmits a life reaching signal corresponding to the type of the detected product life or the mounted electrical product. To do.

  The life comparison unit 202 includes a time life comparison unit 205 and a time life comparison unit 206. The time life comparison unit 205 compares the acquired current time with the product time life stored in advance in the storage unit 23. The time life comparison unit 206 calculates a time difference between the acquired current time and the time when the electrical product is manufactured, and compares the calculated time difference with the product time life stored in the storage unit 23 in advance. The life comparison unit 202 transmits to the life management unit 201 the result of evaluating the product life by the time life comparison unit 205 and / or the time life comparison unit 206.

  In addition, in this Embodiment, although both the time life comparison part 205 and the time life comparison part 206 are provided, you may provide only either one. For example, in the case of mounting on a fan, only 87600 hours (about 10 years), which is the time life of the motor of the fan, is set, and the product life is evaluated by the time life comparison unit 206. As another example, when mounted on a gas fan heater, only the time life is set and evaluated by the time life comparison unit 205. As a result, for products whose safety may be impaired due to deterioration over time, the product shall be managed based on the time of life and notify the user of the effective expiration date of the electrical product (for example, write the effective expiration date on the product label) Or display on a liquid crystal display portion of an electric product).

  The integrated time management unit 203 includes an integrated operating time management unit 207, an integrated energization time management unit 208, and an integrated energization frequency management unit 209.

  The integrated operation time management unit 207 calculates the operation time up to the present time of the electric product or the components constituting the electric product and stores it in the storage unit 23, and further calculates the calculated operation time and the product stored in the storage unit 23 in advance. Or, compare the accumulated operating time life of the component parts.

  The integrated energization time management unit 208 calculates the energization time up to the present time of the electric product or the components constituting it, and stores it in the storage unit 23. Furthermore, the calculated energization time and the product stored in the storage unit 23 in advance. Or, compare the cumulative energization time life of the components.

  The integrated energization count management unit 209 calculates the current energization count of the electrical product or the components constituting it, and stores it in the storage unit 23. Furthermore, the calculated energization count and the product stored in the storage unit 23 in advance. Or, compare the cumulative energization frequency life of the components.

  The accumulated time management unit 203 transmits to the life management unit 201 the result of evaluating the product life in all or any of the accumulated operation time management unit 207, the accumulated energization time management unit 208, and the accumulated energization number management unit 209. . In this embodiment, the integrated operation time management unit 207, the integrated energization time management unit 208, and the integrated energization number management unit 209 are provided, but only one of them may be provided. For example, in an electrical product that is energized only at the time of use, such as a vacuum cleaner or an iron, it is managed only by the integrated operation time management unit 207 or by the integrated operation time management unit 207 and the integrated energization number management unit 209, and is always used for a refrigerator, a television, a video For an electrical product to be energized, it may be managed only by the integrated energization time management unit 208.

  The time correction unit 204 compares the difference between the acquired current time and the time of the electric product built-in clock held in the storage unit 23, and if there is a time difference greater than or equal to a predetermined time, Correct the time.

  The storage unit 23 includes an internal time storage unit 210, a product life storage unit 211, and an accumulated time storage unit 212. The internal time storage unit 210 is a storage unit that holds the time of the built-in clock of the electrical product, and holds the time counted by the built-in clock of the electrical product. In an electrical product that does not have a built-in clock, the internal time storage unit 210 may not be provided.

  The product life storage unit 211 is a non-volatile storage area, and stores the product time life, product time life, accumulated operation time life, accumulated energization time life, accumulated energization frequency life, and electrical product manufacturing time. is doing. The above time or time is stored in advance in the process of manufacturing the electric product. For example, it is stored in the final process of the assembly process of the electric product. Note that the setting value of the storage area can be reset by the service when, for example, the main part of the electrical product is replaced. Note that only one of the above set values can be used depending on the electric product to be mounted.

  The product time life is stored as a time-dependent deterioration time life determined by an electric product manufacturer. The aging lifetime stored here is the year, month, day, hour, minute, second, year, month, day, hour, minute as appropriate by the electrical manufacturer according to the electrical product. Units up to one of seconds may be used. Furthermore, each component constituting the electrical product may have a plurality of product time lives. In this case, the life reaching signal output from the life managing unit 201 can be changed in accordance with the component that has reached the product time life, and the operation of the electric product can be limited by various methods.

  The product time life is stored as the time-dependent deterioration time life from the production date determined by the electric product manufacturer. The time-degraded lifetime stored here is the year, month, day, hour, minute, second, year, month, day, hour, minute as appropriate by the electrical appliance manufacturer according to the electrical product. Units up to one of seconds may be used. Furthermore, each component constituting the electrical product may have a plurality of product time lives. In this case, the life reaching signal output from the life managing unit 201 can be changed in accordance with the parts that have reached the product time life, and the operation of the electric product can be limited by various methods.

  The accumulated operating time life is stored as the serviceable operating time as determined by the electrical product manufacturer. The accumulated operating time life stored here can be the year, month, day, hour, year, month, day, hour, minute, second, year, month, day, hour, Units up to either minutes or seconds may be used. Further, each component constituting the electrical product may have a plurality of accumulated operating time lives. In this case, the life reaching signal output from the life managing unit 201 can be changed in accordance with the component that has reached the accumulated operating time life, and the operation of the electric product can be limited by various methods.

  The accumulated energizing time life is stored as the durable energizing time determined by the electrical product manufacturer. The accumulated energizing time life stored here is the year, month, day, hour, year, month, day, hour, minute, second, year, month, day, hour, Units up to either minutes or seconds may be used. Further, each component constituting the electrical product may have a plurality of cumulative energization time lives. In this case, the life reaching signal output from the life managing unit 201 can be changed in accordance with the component that has reached the accumulated energizing time life, and the operation of the electric product can be limited by various methods.

  The cumulative energization frequency life is stored as the durable energization frequency as determined by the electrical product manufacturer. Each component constituting the electrical product may have a plurality of cumulative energization times. In this case, the life reaching signal output from the life managing unit 201 can be changed in accordance with the component that has reached the cumulative energization frequency life, and the operation of the electric product can be limited by various methods.

  The manufacturing time is stored as the manufacturing time determined by the electric product manufacturer in the process of manufacturing the electric product. For example, the date when an electrical product is assembled. The manufacturing time stored individually may be a detailed time up to year, month, day, hour, minute, second. For example, January 2000, January 1, 2000, January 1, 2000, 12:00 are considered.

  The integrated time storage unit 212 is a non-volatile storage area, and includes an integrated operation time storage unit 213, an integrated energization time storage unit 214, and an integrated energization number storage unit 215. The accumulated operating time storage unit 213 stores the accumulated usage time of the electrical product or the parts constituting the electrical product. The accumulated time stored in this storage area can be reset by a service when, for example, a main part of an electrical product is replaced.

  The accumulated operation time storage unit 213 holds the total operation time after the manufacture of the electrical product or the parts constituting the electrical product as determined by the electrical product manufacturer. The accumulated operating time stored here may be a unit up to year, month, day, hour, minute, or second. Furthermore, you may have several integrated operation time for every component which comprises an electric product. In this case, the accumulated operation time can be managed for each part. Therefore, the life reaching signal output from the life managing unit 21 can be changed according to the parts that have reached the accumulated operating time life, and the operation of the electric product can be limited by various methods.

  The accumulated energization time storage unit 214 holds the total energization time after the manufacture of the electrical product or the parts constituting the electrical product as determined by the electrical product manufacturer. The accumulated energization time stored here may be in units of year, month, day, hour, minute, or second. Furthermore, you may have several integrated energization time for every component which comprises an electric product. In this case, the integrated energization time can be managed for each part. Therefore, the life reaching signal output from the life managing unit 21 can be changed in accordance with the component that has reached the cumulative energization time life, and the operation of the electric product can be limited by various methods.

  The accumulated energization count storage unit 215 holds the total energization count after the manufacture of the electrical product or the parts constituting the electrical product. This cumulative energization count may have a plurality of cumulative energization counts for each component constituting the electrical product. In this case, the cumulative number of energizations can be managed for each part. Accordingly, the life reaching signal output from the life managing unit 21 can be changed according to the component that has reached the cumulative number of energization times, and the operation of the electric product can be limited by various methods.

  A processing procedure executed by the life management apparatus configured as described above will be described with reference to a flowchart. 7 to 9 are flowcharts showing the operation of the life management apparatus according to Embodiment 1 of the present invention. The air conditioner 100 is a separate type composed of the indoor unit 7 and the outdoor unit 14 as described above. The lifetime management device 200 is mounted on each of the indoor unit 7 and the outdoor unit 14, and the lifetime management device 200a of the indoor unit 7 sets and manages the lifetime of the indoor unit 7. The lifetime management device 200b of the outdoor unit 14 sets and manages the lifetime of the outdoor unit 14. First, a processing procedure executed by the life management apparatus 200a mounted on the indoor unit 7 will be described.

(Operation overview of the life management apparatus 200a)
The control device 17 of the indoor unit 7 is configured to operate when external power is supplied to the indoor unit 7 and to operate only the internal clock using the built-in power source when the external power is not supplied. Therefore, the lifetime management device 200a that sets and manages the lifetime of the electrical product mounted on the control device 17 of the indoor unit 7 operates while external power is being supplied to the indoor unit 7. In the manufacturing process of the indoor unit 7, the lifetime management device 200a stores the product time life, product time life, accumulated operating time life, accumulated energization time life, accumulated energization frequency life, and production time of the indoor unit 7. Yes.

  The built-in clock also uses a crystal transmission to accurately count the time, a frequency divider that makes it easy to interpret the year, month, day, and time of the transmission frequency from the crystal transmission, and counts these signals. A counter is provided. The counted data is stored in the internal time storage unit 210 of the storage unit 23 periodically via the control unit 22 at predetermined intervals when the life management apparatus 200a is powered on. The accumulated energization time and the accumulated operation time are counted by the life management apparatus 200a by using the time data counted by the counter of the built-in clock and stored in the internal time storage unit 210.

  When power is supplied to the indoor unit 7 from the outside, the control device 17 is activated, and the control unit of the life management device 200a incorporated in the control device 17 is also activated (step S101). The integrated energization count management unit 209 of the control unit 22 of the life management apparatus 200a reads the value of the integrated energization count from the integrated energization count storage unit 215 of the storage unit 23, increments it once, and integrates energization with the incremented integrated energization count. The number storage unit 215 is overwritten (step S102). The integrated energization time management unit 208 reads the value of the integrated energization time storage unit 214 in the storage unit 23 and starts counting the integrated energization time (step S103).

  The integrated energization frequency management unit 209 reads the integrated energization frequency life stored in the product life storage unit 211 of the storage unit 23, and obtains the integrated energization frequency life and the value stored in the integrated energization frequency storage unit 215. In comparison, it is determined whether or not the cumulative energization count reaches the cumulative energization count life (step S104). When it is determined that the cumulative energization count has exceeded the cumulative energization cycle life (step S104: YES), the life management unit 201 outputs a predetermined life reaching signal (step S105) and ends the process. Thereby, the control device 17 blinks the operation lamp of the indoor unit 7 and further prohibits the user's operation, for example, the operation start by the remote controller. If it is a remote controller that can transmit and receive with the main body of the air conditioner 100, an error code may be displayed on the remote controller, or a message may be displayed so as to make an inquiry to the service.

  If it is determined that the cumulative energization count does not exceed the cumulative energization count life (step S104: NO), the current time is acquired when the current time acquisition unit 21 is ready for use (step S106). The time correction unit 204 compares the acquired current time with the internal time stored in the internal time storage unit 210 of the storage unit 23, and if there is a certain difference or more, the time correction unit 204 uses the received current time as the internal time. The time storage unit 210 is overwritten to correct the internal time (step S107). For example, if the time difference is 3 minutes or more, the internal time is corrected, and if it is less than 3 minutes, the correction is not performed. Alternatively, if a period in which the internal time is not corrected for a predetermined period or longer continues, a method of correcting the internal time can be considered even if the time difference between the current time and the internal time is small. The predetermined period may be, for example, a case where one week has passed since the previous correction or a case where one month has passed.

  The time life comparison unit 205 acquires the product time life from the product life storage unit 211 of the storage unit 23, compares the acquired product time life with the previously acquired current time, and the current time reaches the product time life. It is determined whether or not (step S108). When it is determined that the current time has reached the product time life (step S108: YES), the life management unit 201 outputs a predetermined life arrival signal (step S105) and ends the process. For example, when the acquired current time is 10:00 on February 1, 2010 for an electrical product stored as January 2010 in the product time life, it is determined that the product life has been reached and a life reaching signal is output. Is done.

  On the other hand, when it is determined that the current time does not reach the product time life (step S108: NO), the accumulated energization time management unit 208 counts the value of the accumulated energization time and the product life storage unit 211 of the storage unit 23. The integrated energization time life value read out from is compared to determine whether the accumulated energization time value reaches the integrated energization time life value (step S109). When it is determined that the value of the accumulated energization time exceeds the value of the accumulated energization time life (step S109: YES), the life management unit 201 outputs a predetermined life arrival signal (step S105) and ends the process. For example, when the accumulated energization time life stored in the product life storage unit 211 is 87600 hours (about 10 years) and the counted accumulated energization time value exceeds 87600 hours, it is determined that the product life has been reached. The life reaching signal is output.

  On the other hand, when it is determined that the value of the cumulative energization time does not reach the value of the cumulative energization time life (step S109: NO), the detection interval timer is activated (step S110). The timer time of this detection interval timer may be, for example, 24 hours (1 day), or may be a value corresponding to the electrical product for one week or one month. The timer time is stored in advance in the process of manufacturing the air conditioner 100. For example, it is stored in the final process of the assembly process of the air conditioner 100.

  In the present embodiment, when the air conditioner 100 is connected to an external power source at the time of installation, the control device 17 is activated and enters a standby state. Thereafter, an operation start instruction is transmitted to the control device 17 of the indoor unit 7 by a user operation, for example, an operation start operation (for example, a cooling operation, a heating operation, or a dehumidifying operation) by a remote controller. The control device 17 of the indoor unit 7 receives the operation start instruction, shifts the indoor unit 7 from the standby state to the operation state, and notifies the life management device 200a of the operation start. Further, when an operation stop instruction is transmitted to the control device 17 of the indoor unit 7 by a user operation, for example, an operation stop operation by a remote controller, the control device 17 of the indoor unit 7 receives the operation stop instruction, The machine 7 is shifted from the operation state to the standby state, and the operation stop is notified to the life management apparatus 200a.

  The life management apparatus 200a determines whether or not an operation start notification has been received from the control apparatus 17 of the indoor unit 7 (step S111). When it is determined that it has been received (step S111: YES), the integrated operating time management unit 207 reads the value of the integrated operating time storage unit 213 in the storage unit 23 and starts counting the integrated operating time (step S112). . If it is determined that no data has been received (S111: NO), the process proceeds to step S117.

  The accumulated operating time management unit 207 compares the counted accumulated operating time value with the accumulated operating time life value read from the product life storage unit 211 of the storage unit 23, and accumulates the accumulated operating time value. It is determined whether or not the value of the operating time life has been reached (step S113). When it is determined that the value of the accumulated operation time exceeds the value of the accumulated operation time life (step S113: YES), the life management unit 201 outputs a predetermined life arrival signal (step S105) and ends the process. If it is determined that the value of the accumulated operation time does not reach the value of the accumulated operation time life (step S113: NO), the process proceeds to step S114.

  On the other hand, when it is determined that the life management apparatus 200a has not received the operation start notification from the control device 17 of the indoor unit 7 (step S111: NO), the life management apparatus 200a receives from the control device 17 of the indoor unit 7. It is determined whether or not an operation stop notification has been received (step S117). If it is determined that it has been received (step S117: YES), the counting of the accumulated operation time is stopped (step S118), and the counted value is stored in the storage unit 23. The accumulated operating time management unit 207 compares the counted accumulated operating time value with the accumulated operating time life value read from the product life storage unit 211 of the storage unit 23, and accumulates the accumulated operating time value. It is determined whether or not the value of the operating time life has been reached (step S119). When it is determined that the value of the accumulated operation time exceeds the value of the accumulated operation time life (step S119: YES), the life management unit 201 outputs a predetermined life arrival signal (step S105) and ends the process.

  The life management apparatus 200a determines in step S117 that an operation stop notification has not been received from the control device 17 of the indoor unit 7 (step S117: NO), or in step S119, the accumulated operation time value is integrated. When it is determined that the time life value has not been reached (step S119: NO), the process returns to step S114.

  In step S114, the life management apparatus 200a determines whether or not the set detection interval has passed (whether or not the timer time of the detection interval timer has timed out) (step S114). When it is determined that the set detection interval has not elapsed (the timer time of the detection interval timer has not timed out) (S114: NO), the life management apparatus 200a returns to step S111, and starts operation notification and operation stop notification. The determination relating to the reception of is repeated. When it is determined that the set detection interval has elapsed (the timer time of the detection interval timer has timed out) (S114: YES), the life management apparatus 200a stops the detection interval timer (step S115), and further detects the detection interval timer. Is reset (step S116), and the process returns to step S106. In general, when the air conditioner 100 is connected to an external power source at the time of installation, the external power source is hardly removed thereafter. With the configuration of the present embodiment, after the supply of external power is started and the control device 17 enters a standby state, the current time is acquired and the life evaluation based on the time / time is performed regardless of the operation of the air conditioner 100. It is periodically executed by the management apparatus 200a.

(Outline of operation of the life management apparatus 200b)
Next, operation | movement of the lifetime management apparatus 200b mounted in the outdoor unit 14 is demonstrated. The operation flow of the life management apparatus 200b mounted on the outdoor unit 14 is substantially the same as the operation flow of the life management apparatus 200a mounted on the indoor unit 7 described above. Therefore, although detailed description is omitted, portions different from the indoor unit 7 in the operation flow will be described below.

  In the manufacturing process of the outdoor unit 14, the lifetime management device 200 b manufactures the product time life and the integrated operation time life of the compressor 11 constituting the outdoor unit 14, the integrated energization time life of the IPM 19 that controls the compressor 11, and the manufacture of the outdoor unit 14. The time is stored. In the integrated energization time evaluation, the integrated energization time life of the IPM 19 is evaluated. In the accumulated operation time evaluation, the accumulated operation time life of the compressor 11 is evaluated. For example, the compressor product time life is 131400 hours (about 15 years), the cumulative operation time life is 61320 hours (about 7 years), and the IPM 19 cumulative power-on time life is 87600 hours (about 10 years). In addition, January 2010 is set as the manufacturing time of the outdoor unit 14.

  Further, since the outdoor unit 14 does not have a built-in clock, the time correction unit of the life management apparatus 200b and the internal time storage unit related thereto do not operate. The accumulated energization time and the accumulated operation time are counted by the life management apparatus 200b by using the time counting function of the control unit 22. In the evaluation of deterioration over time due to the product time life in the outdoor unit 14, since the product time life is not set, the time difference between the current time and the manufacturing time of the outdoor unit 14 is calculated, and the calculated time difference is compared with the product time life of the compressor. To evaluate.

  The external power supply supplied to the outdoor unit 14 is an operating current supplied from the indoor unit 7. When the air conditioner 100 is connected to an external power source at the time of installation, the control device 18 of the outdoor unit 14 is activated and enters a standby state. Thereafter, when the control device 17 of the indoor unit 7 receives an operation start instruction by a user operation, the control device 17 of the indoor unit 7 transmits the operation start instruction to the control device 18 of the outdoor unit 14. The control device 18 of the outdoor unit 14 shifts the outdoor unit 14 from the standby state to the operating state and notifies the life management device 200b of the start of operation. Similarly, when an operation stop instruction is received by the control device 17 of the indoor unit 7, the control device 17 of the indoor unit 7 transmits an operation stop instruction to the control device 18 of the outdoor unit 14. The control device 18 of the outdoor unit 14 shifts the outdoor unit 14 from the operation state to the standby state, and notifies the life management device 200b of the operation stop.

  The life reaching signal output by the life management device 200b mounted on the outdoor unit 14 is converted into a predetermined error code by the control device 18 of the outdoor unit 14, and then transmitted to the control device 17 of the indoor unit 7. . Therefore, the control device 17 of the indoor unit 7 detects that the outdoor unit 14 has reached the end of its life and restricts the operation of the air conditioner 100. That is, when the control device 17 of the indoor unit 7 detects the life end signal of the outdoor unit 14, the operation lamp of the indoor unit 7 blinks, and further, the user operation, for example, the start of operation by the remote controller is prohibited. If the remote controller is capable of transmitting and receiving, an error code may be displayed on the remote controller, or a message may be displayed so as to make an inquiry to the service.

(Embodiment 2)
In the first embodiment, the life management apparatus 200 includes a control unit and a storage unit, and is configured to independently execute the life management process of the air conditioner. On the other hand, in the second embodiment, the life management device 300 is stored in the storage units of the control devices 17 and 18 of the indoor unit 7 and the outdoor unit 14 as a life management program. By being read out and executed by the (CPU) in the temporary storage unit, it operates as a life management device.

  As shown in FIG. 1, the air conditioner 100 including the life management device 300 according to the second embodiment is a separate type, and is installed above the wall in the house 15, and the hot air or the cold air 16 is sent indoors. The indoor unit 7 that blows out and the outdoor unit 14 installed on the ground along the outer wall of the house 15 are provided. The indoor unit 7 is provided with a control device 17 having a CPU for controlling each device provided in the indoor unit 7. The outdoor unit 14 is provided with a control device 18 having a CPU that controls each device provided in the outdoor unit 14. The life management device 300 (300a, 300b) for setting and managing the life of the electrical product is incorporated in the control devices 17, 18 as a program.

  Since the components other than those described above of the air conditioner 100 according to Embodiment 2 are basically the same as the components of the air conditioner 100 according to Embodiment 1, detailed descriptions thereof are omitted. The description according to Embodiment 1 is used. Hereinafter, the structure of the control apparatus 17 of the indoor unit 7 of the air conditioner according to the second embodiment will be described.

  FIG. 10 is a block diagram illustrating a configuration of the control device 17 of the indoor unit 7 of the air conditioner according to the second embodiment. The control device 17 includes a CPU 171, a temporary storage unit 172, a storage unit 173, and a communication unit 174.

  The CPU 171 causes the control device 17 to operate as the life management device 300 according to the second embodiment by reading the life management program 17P stored in the storage unit 173 into the temporary storage unit 172 and executing it.

  The temporary storage unit 172 uses a RAM such as DRAM (Dynamic RAM) or SRAM (Static RAM) to store the life management program 17P read as described above, and the cumulative number of energizations used for the life management processing. The accumulated energization time, the accumulated operation time, etc. are temporarily stored. The temporary storage unit 172 temporarily stores various types of information generated by processing in addition to programs such as a control program read by the CPU 171.

  For the storage unit 173, an external storage device such as an EEPROM, a flash memory, or an SSD is used. The storage unit 173 stores the above-described life management program 17P. The storage unit 173 stores a product time life, a product time life, an accumulated operation time life, an accumulated energization time life, an accumulated energization frequency life, and an electrical product manufacturing time. The above time or time is stored in advance in the process of manufacturing the electric product. For example, it is stored in the final process of the assembly process of the electric product. Note that the setting value of the storage area can be reset by the service when, for example, the main part of the electrical product is replaced. Note that only one of the above set values can be used depending on the electric product to be mounted.

  The communication unit 174 realizes communication between the control device 17 and each component of the indoor unit. The CPU 171 can receive information from each component mounted on the indoor unit 7 via the communication unit 174, and can control by transmitting an instruction to each component.

  FIG. 11 is a block diagram illustrating a functional configuration example of the life management apparatus 300 according to the second embodiment. The life management apparatus 300 stores the current time receiving unit 31 that receives the current time, the control unit 32 that detects the life of the electrical product and transmits a life reaching signal when the electrical product reaches the life, and stores the product life. Storage unit 33 to be stored.

  The current time receiving unit 31 receives the current time from a current time acquisition device (not shown) that can detect the current time. Note that the current time acquisition device is, for example, built in an air conditioner, and is a radio clock or an Internet time acquisition device that acquires Japan Standard Time in Japan.

  The control unit 32 compares the current time and the product time life with the life management unit 301 that transmits a predetermined life arrival signal when the product life is reached, based on the preset life of the electric product, or compares the current time with the current time. A life comparison unit 302 that compares the product time life with the time difference between the manufacturing time and the integrated time management unit 303 that calculates the accumulated operating time or energization time of the electrical product and stores it in the storage unit, and the electrical product at the current time A time correction unit 304 for correcting the built-in clock is provided. Note that the time correction unit 304 may not be provided if the electrical product does not include a built-in clock. The storage unit 33 includes an internal time storage unit 310, a product life storage unit 311, and an accumulated time storage unit 312.

  The specific configurations and functions of the life management unit 301, the life comparison unit 302, the accumulated time management unit 303, the time correction unit 304, the internal time storage unit 310, the product life storage unit 311, and the accumulated time storage unit 312 of the lifetime management apparatus 300 are as follows. The lifetime management unit 201, the lifetime comparison unit 202, the accumulated time management unit 203, the time correction unit 204, the internal time storage unit 210, the product lifetime storage unit 211, and the accumulated time storage unit 212 of the lifetime management apparatus 200 in Embodiment 1, respectively. Since this is basically the same, detailed description is omitted.

  Hereinafter, a processing procedure executed by the life management apparatus 300 according to the second embodiment will be described with reference to a flowchart. 12 and 13 are flowcharts showing the operation of the life management apparatus according to Embodiment 2 of the present invention.

  The air conditioner 300 is a separate type composed of the indoor unit 7 and the outdoor unit 14 as described above. The lifetime management device 300 is mounted on each of the indoor unit 7 and the outdoor unit 14, and the lifetime management device 300a of the indoor unit 7 sets and manages the lifetime of the indoor unit 7. The lifetime management device 300b of the outdoor unit 14 sets and manages the lifetime of the outdoor unit 14. First, a processing procedure executed by the life management apparatus 300a mounted on the indoor unit 7 will be described.

(Operation overview of the life management device 300a)
The control device 17 of the indoor unit 7 is configured to operate when external power is supplied to the indoor unit 7 and to operate only the timepiece with the built-in power supply when external power is not supplied. Therefore, the life management device 300a functions while the external power is supplied to the indoor unit 7 and the control device 17 is operating.

  When power is supplied to the indoor unit 7 from the outside, the control device 17 is activated, and the life management program 17P stored in the storage unit 173 is read into the temporary storage unit 172 and executed, whereby the life management device 300a. Is activated (step S201). The cumulative energization count management unit 309 of the control unit 32 of the life management apparatus 300a reads the value of the cumulative energization count from the cumulative energization count storage unit 315 of the storage unit 33 and increments it once. The number storage unit 315 is overwritten (step S202). The accumulated energization time management unit 308 reads the value of the accumulated energization time storage unit 314 in the storage unit 33 and starts counting the accumulated energization time (step S203).

  The integrated energization frequency management unit 309 reads the integrated energization frequency life stored in the product life storage unit of the storage unit 33 and compares the accumulated energization frequency life with the value stored in the integrated energization frequency storage unit 315. Then, it is determined whether or not the cumulative energization count reaches the cumulative energization count life (step S204). When it is determined that the cumulative energization count has exceeded the cumulative energization cycle life (step S204: YES), the life management unit 301 outputs a predetermined life reaching signal to the control device 17 (step S205), and the process is terminated. Upon receiving this signal, the control device 17 blinks the operation lamp of the indoor unit 7 and further prohibits the user's operation, for example, the start of operation by the remote controller. If the remote control is capable of transmitting and receiving to and from the main body of the air conditioner, an error code may be displayed on the remote control, or a message may be displayed to inquire about the service.

  When it is determined that the cumulative energization count does not exceed the cumulative energization cycle life (step S204: NO), a detection interval timer (not shown) is activated (step S206). The timer time of this detection interval timer may be, for example, 24 hours (1 day), or may be a value corresponding to the electrical product for one week or one month. The timer time is stored in advance in the process of manufacturing the air conditioner. For example, it is stored in the final process of the assembly process of the air conditioner. The timer time can be reset by the user. Further, the detection interval timer can be set by the user so as to be invalidated.

  When external power is supplied to the indoor unit 7 and the current time acquisition device becomes usable, the current time reception unit 31 receives the current time from the current time acquisition device (step S207). The time correction unit 304 compares the received current time with the internal time stored in the internal time storage unit 310 of the storage unit 33, and if there is a certain difference or more, the time correction unit 304 uses the current time received. The time storage unit 310 is overwritten to correct the internal time (step S208). For example, if the time difference is 3 minutes or more, the internal time is corrected, and if it is less than 3 minutes, the correction is not performed. Alternatively, if a period in which the internal time is not corrected for a predetermined period or longer continues, a method of correcting the internal time can be considered even if the time difference between the current time and the internal time is small. The predetermined period may be, for example, a case where one week has passed since the previous correction or a case where one month has passed.

  The time life comparison unit 305 acquires the product time life from the product life storage unit 311 of the storage unit 33, compares the acquired product time life with the previously received current time, and the current time reaches the product time life. It is determined whether or not (step S209). When it is determined that the current time has reached the product time life (step S209: YES), the life management unit 301 outputs a predetermined life arrival signal (step S205) and ends the process. For example, when the acquired current time is 10:00 on February 1, 2010 for an electric product stored as January 2010 in the product time life, it is determined that the product life has been reached and the life arrival signal is controlled. It is output to the device 17.

  On the other hand, when it is determined that the current time does not reach the product time life (step S209: NO), the integrated energization time management unit 308 determines the value of the accumulated energization time counted and the product life storage unit 311 of the storage unit 33. The integrated energization time life value read out from is compared to determine whether the accumulated energization time value reaches the integrated energization time life value (step S210). When it is determined that the value of the accumulated energization time exceeds the value of the accumulated energization time life (step S210: YES), the life management unit 301 outputs a predetermined life arrival signal to the control device 17 of the indoor unit 7 for processing. Is finished (step S205). For example, when the cumulative energization time life stored in the product life storage unit 311 is 87600 hours (about 10 years) and the counted cumulative energization time value exceeds 87600 hours, it is determined that the product life has been reached. Then, a life reaching signal is output to the control device 17.

  On the other hand, when it is determined that the value of the cumulative energization time does not reach the value of the cumulative energization time life (step S210: NO), the life management device 300a enters a standby state until the detection interval timer times out. Here, when the air conditioner starts cooling, dehumidification, heating operation, or the like by a user operation, an operation start instruction from the user is transmitted to the control device 17 of the indoor unit 7. The control device 17 of the indoor unit 7 receives the instruction to start operation, shifts the indoor unit 7 from the standby state to the operating state, starts supplying power to the outdoor unit 14, and supplies the life management device 300a to the life management device 300a. The start of operation is notified (step S211: YES). Specifically, the control device 17 of the indoor unit 7 controls devices such as an operation lamp, a blower, and a wind direction changing plate of the indoor unit 7 to a predetermined state and starts supplying power to the outdoor unit 14. At the same time, the start of operation is notified to the life management device 300a, and the operation time measurement of the indoor unit 7 is started by the life management device 300a. Thereby, the air conditioner 100 will be in an operation state. Here, the operating time refers to the time during which the indoor unit 7 is in an operating state. Even if the indoor unit 7 changes to the operating state, the counting of the cumulative energization time is continued. In addition, when an operation stop instruction is transmitted to the control device 17 of the indoor unit 7 by the user's operation, the control device 17 of the indoor unit 7 receives the operation stop instruction and moves the indoor unit 7 from the operating state. A transition is made to the standby state, the power supply to the outdoor unit 14 is stopped, and an operation stop is notified to the life management apparatus 300a.

  On the other hand, when the life management apparatus 300a does not start the operation of the air conditioner by the user operation in the standby state (step S211: NO), the detection interval timer has not timed out (step S212: NO), step Returning to S211, the standby state is continued. If the detection interval timer has timed out (step S212: YES), the process returns to step S206 to activate the detection interval timer again. Thereby, while the indoor unit 7 is energized, the current time is periodically received, and the product life can be determined.

  When the indoor unit 7 starts operation (step S211: YES), the integrated operation time management unit 307 starts counting the integrated operation time with respect to the integrated operation time storage unit 313 in the storage unit 33 (step S213). ). And the lifetime management apparatus 300a judges whether the operation stop notification was received from the control apparatus 17 of the indoor unit 7 (step S214). By the user's operation, the air conditioner stops the cooling, dehumidification or heating operation, and the life management apparatus 300a repeats the determination related to the reception of the operation stop notification until the operation stop notification is received from the control device 17 (step S214: NO). Here, when the operation of the air conditioner is stopped by the user's operation and the life management device 300a receives the operation stop notification from the control device 17 (step S214: YES), the counting of the accumulated operation time is stopped and counted. The stored value is stored in the storage unit 33 (step S215). The accumulated operating time may be stored in the storage unit 33 every time it is counted. In this case, even when the count is suddenly interrupted due to a power failure or the like, an accurate accumulated operation time can be maintained.

  The accumulated operating time management unit 307 compares the counted accumulated operating time value with the accumulated operating time life value read from the product life storage unit 311 of the storage unit 33, and the accumulated operating time value is integrated. It is determined whether or not the time life value has been reached (step S216). When it is determined that the value of the accumulated operation time exceeds the value of the accumulated operation time life (step S216: YES), the life management unit 301 outputs a predetermined life arrival signal to the control device 17 of the indoor unit 7 (step S216). S205), the process ends.

  On the other hand, when it is determined that the value of the accumulated operation time does not reach the value of the accumulated operation time life (step S216: NO), the life management apparatus 300a proceeds to step S206. Thereby, the acquisition of the current time and the life evaluation based on the time / time are periodically executed. Further, when the air conditioner 100 is in an operating state, the evaluation and control relating to the accumulated operating time life are not performed. As a result, when the air conditioner 100 is in operation, the operation is not limited by life management so that the user is not inconvenienced, and after the operation of the air conditioner 100 is stopped by the user's operation, Acquisition and life evaluation by time and time are periodically performed.

(Outline of operation of the life management device 300b)
Next, operation | movement of the lifetime management apparatus 300b mounted in the outdoor unit 14 is demonstrated. The control device 18 of the outdoor unit 14 is configured to operate when external power is supplied via the indoor unit 7. Therefore, the life management device 300b functions while the external power supply is supplied to the outdoor unit 14 and the control device 18 is operating. The operation flow of the life management apparatus 300b mounted on the outdoor unit 14 is substantially the same as the operation flow of the life management apparatus 300a mounted on the indoor unit 7 described above. Therefore, although detailed description is omitted, portions different from the indoor unit 7 in the operation flow will be described below.

  The control device 18 of the outdoor unit 14 causes the control device 18 to operate as the life management device 300b by reading the life management program stored in the storage unit into the temporary storage unit and executing it. In the storage unit, in the manufacturing process of the outdoor unit 14, the product time life and the integrated operation time life of the compressor 11 constituting the outdoor unit 14, the integrated energization time life of the IPM 19 that controls the compressor 11, and the manufacturing time of the outdoor unit 14 are It is remembered. In the integrated energization time evaluation, the integrated energization time life of the IPM 19 is evaluated. In the accumulated operation time evaluation, the accumulated operation time life of the compressor 11 is evaluated.

  Further, since the outdoor unit 14 does not have a built-in clock, the time correction unit of the life management apparatus 300b and the internal time storage unit related thereto do not operate. Counting of the energized energization time and the accumulated operating time by the life management apparatus 300b is performed using the count function of the control unit 32. In the evaluation of deterioration over time according to the product time life in the outdoor unit 14, since the product time life is not set, the time difference between the current time and the manufacturing time of the outdoor unit 14 is calculated, and the product time life of the compressor is compared. evaluate. The external power supply supplied to the outdoor unit 14 is an operating current supplied from the indoor unit 7. In the second embodiment, in order to save power, when the user starts operations such as cooling, heating, and dehumidification, the indoor unit 7 supplies current to the outdoor unit 14, and the user stops operations such as cooling, heating, and dehumidification. When doing so, the indoor unit 7 cuts off the current to the outdoor unit 14. According to this, the time during which the electric current is supplied to the outdoor unit 14 is the operating time of the outdoor unit 14, but the indoor unit 7 immediately after the user stops the operation such as cooling, heating, dehumidification, etc. The electric power for rotating the blower fan of the outdoor unit 7 is supplied for a certain period of time in order to cool the electrical components of the outdoor unit without interrupting the current to. During this fixed time, the lifetime management device 300b evaluates the accumulated operating time of the outdoor unit 14.

  The life reaching signal output by the life management device 300b mounted on the outdoor unit 14 is converted into a predetermined error code by the control device 18 of the outdoor unit 14, and then transmitted to the control device 17 of the indoor unit 7. . Therefore, the control device 17 of the indoor unit 7 detects that the outdoor unit 14 has reached the end of its life and restricts the operation of the air conditioner 100. That is, when the control device 17 of the indoor unit 7 detects the life end signal of the outdoor unit 14, the operation lamp of the indoor unit 7 blinks, and further, the user operation, for example, the start of operation by the remote controller is prohibited. If the remote controller is capable of transmitting and receiving, an error code may be displayed on the remote controller, or a message may be displayed so as to make an inquiry to the service.

  In the above embodiment, the example in which the life management device is mounted on each of the indoor unit and the outdoor unit of the air conditioner has been described. However, the present invention is not limited to this. One lifetime management device may be mounted on the indoor unit or the outdoor unit, and the aging degradation of the indoor unit and the outdoor unit may be managed in an integrated manner by the lifetime management device.

The example in the case of being mounted on an air conditioner has been described above, but the life management device according to the present invention can be applied to general home appliances in the same format.
For example, in the case of mounting in a refrigerator, the manufacturing time of the refrigerator, the product time life of the compressor which is the main equipment of the refrigerator, and the integrated energization time life are set, and the product life is managed by the life management device. However, if the product is installed in an electrical product that causes inconvenience to the user if it stops for only a short time, such as a refrigerator, the product will reach the user's lifetime before the product lifetime management setting device stops operation. It is desirable to notify that the product life is approaching. For example, if a signal is generated from the life management unit one month before the product reaches the end of its product life, the control unit of the refrigerator will display through the display unit, operation lamp, or buzzer sound one month before the operation of the refrigerator stops. It is possible to notify the user in advance that the product life is approaching.

  Also, as an example other than being installed in a product, on a terminal that centrally manages electrical products on a home network, such as a home network, the computer program can be used to determine the home appliance's operating time and manufacturing time. It is also possible to manage deterioration over time.

  The disclosed embodiments should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

100 Air conditioner (electric product)
17, 18 Control device 200 Life management device 21 Current time acquisition unit 201 Life management unit 202 Life comparison unit 204 Time correction unit 207 Cumulative operation time management unit 208 Cumulative energization time management unit 23 Storage unit 300 Life management device 31 Current time reception unit 301 life management unit 302 life comparison unit 304 time correction unit 307 integrated operation time management unit 308 integrated energization time management unit 33 storage unit

Claims (10)

In a life management device that manages the life of some or all of the parts that make up an electrical product,
A current time acquisition unit for acquiring a standard time;
A storage unit for preliminarily storing a lifetime of part or all of the component;
A life comparison unit that compares the standard time acquired by the current time acquisition unit with the life;
A life management apparatus comprising: a life management unit that outputs a predetermined signal when the life comparison unit determines that the standard time exceeds the life. The lifetime management apparatus according to claim 1, wherein the lifetime is a time lifetime indicated by time. The lifetime is a time lifetime expressed in hours,
The storage unit stores in advance the manufacturing time of some or all of the parts,
The life comparison unit detects a time difference between the acquired standard time and the manufacturing time, compares the time difference with the time life,
The said lifetime management part is comprised so that the said predetermined signal may be output, when the said lifetime comparison part judges that the said time difference exceeds the said time lifetime. Life management device. The life management apparatus according to any one of claims 1 to 3, wherein the acquisition of the standard time and the comparison and determination by the life comparison unit are performed in time series. Watch and
A time correction unit for correcting the time of the clock with the standard time acquired by the current time acquisition unit;
An integrated operating time management unit that integrates the operating time of some or all of the parts using the timepiece,
The storage unit stores in advance the accumulated operating time life of some or all of the parts,
The life comparison unit compares the operation time accumulated by the accumulated operation time management unit with the accumulated operation time life,
The life management unit is configured to output the predetermined signal when the life comparison unit determines that the accumulated operation time exceeds the accumulated operation time life. Item 5. The life management device according to any one of Items 1 to 4. Watch and
A time correction unit for correcting the time of the clock with the standard time acquired by the current time acquisition unit;
An integrated energization time management unit that integrates energization times of some or all of the parts using the timepiece, and
The storage unit stores in advance the cumulative energization time life of some or all of the parts,
The life comparison unit compares the energization time accumulated by the accumulated energization time management unit with the accumulated energization time life,
The life management unit is configured to output the predetermined signal when the life comparison unit determines that the accumulated energization time exceeds the accumulated energization time life. Item 5. The life management device according to any one of Items 1 to 4. The storage unit stores in advance the life of some or all of each component for a plurality of electrical products,
The lifetime comparison unit compares the acquired standard time with the lifetimes of the plurality of electrical products,
The lifetime management unit is configured to output the predetermined signal when the lifetime comparison unit determines that the standard time exceeds the lifetime. The life management apparatus according to any one of the above items.   An electrical product comprising the life management device according to any one of claims 1 to 6. The electrical product according to claim 8, further comprising a control device configured to limit an operation of the life management unit of the life management device when a predetermined signal is output. In the life management method for managing the life of some or all of the parts constituting the electrical product,
Obtaining a standard time;
Reading the lifetime of a part or all of the parts stored in advance in the storage unit;
Comparing the acquired standard time with the read life, and determining that the standard time exceeds the life, a step of outputting a predetermined signal is provided.

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