JP2012021766A - Air conditioning device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve the problem with a conventional air conditioning device, wherein there is high possibility that a user continues to use until the device is broken down regardless of duration of services, so that the safety in a long-term use is not secured depending on a use environment.SOLUTION: The air conditioning device employs a refrigerating cycle for circulating a refrigerant by a compressor. The air conditioning device includes: an indoor unit installed indoor; a remote control for instructions of starting or stopping of the air conditioning device; a notation unit, which is arranged in the indoor unit body, for notating a standard duration of services of the air conditioning device; and a lapse display unit, which is arranged in the remote control, for notifying that a real duration of services has elapsed over the standard duration of services after the real duration of services of the air conditioning device has elapsed over the standard duration of services.

Description

  TECHNICAL FIELD The present invention relates to household appliances using a so-called refrigeration cycle in which refrigerant is compressed and circulated by a compressor, absorbed from a low-temperature heat source, and exhausted to a high-temperature heat source, and in particular, an air conditioner that performs indoor air conditioning and dehumidification This is related to ensuring safety in long-term use.

  In recent years, accidents accompanied by aging due to long-term use of household appliances have been frequently reported in newspapers and the like. Fire accidents such as electrical and electronic parts housed in household electrical appliances, such as capacitors, causing insulation deterioration due to long-term use, causing a short circuit and sparking, igniting dust accumulated over many years of use There are examples.

  On the other hand, in order to control global warming, from the viewpoint of effective use of resources, long-term use and long life of electrical appliances such as household appliances are being promoted socially. . For this reason, it is necessary for household appliances to maintain safety from the viewpoint of long-term use, and the manufacturer side needs to perform product design in consideration of this.

  In particular, household electrical appliances that use a refrigeration cycle that circulates refrigerant using a compressor such as an air conditioner among household electrical appliances can carry greater heat energy than the input energy due to the heat pump action, resulting in high energy savings. In order to demonstrate the effect, it is a very effective electrical appliance from the viewpoint of suppressing global warming.

  Therefore, refrigeration cycle type air conditioners are widely used for indoor air conditioning and dehumidification. Such an air conditioner is generally called an air conditioner by omitting an air conditioner. Due to its energy saving properties, in recent years, switching from combustion-type heating equipment to this air conditioner has been frequently seen for indoor heating. The same is true in cold regions. Therefore, ensuring safety in long-term use of air conditioners becomes an increasingly important issue.

  As a conventional technique for preventing accidents due to aging deterioration of such air conditioners, when the heat exchange capacity of the condensation side heat exchanger decreases due to aging deterioration, the operating capacity of the compressor is reduced in response to this decrease. There is an air conditioner that is controlled so as to decrease and is always operated in a stable state. (For example, refer to Patent Document 1).

JP 2004-294022 A (columns 0018 to 0020)

  In household appliances including conventional air conditioners, there is a high possibility that a user (consumer) will continue to use the appliance until it fails regardless of the period of use. For this reason, depending on the use environment, there is a possibility that the safety of the device cannot be ensured, for example, ignition occurs due to long-term use.

  Therefore, there is a concept of ensuring the safety to the user by setting the predetermined time within a short period of time when the use of household electrical equipment has elapsed for a predetermined time. . However, this kind of thinking is inconsistent with the long-term use of equipment promoted from the viewpoint of effective use of resources for the purpose of protecting the global environment. Therefore, it is necessary to achieve both effective use of resources by long-term use of household appliances including air conditioners and ensuring safety during long-term use.

  In the case of a conventional air conditioner that controls to reduce the operating capacity of a compressor in response to a decline in heat exchange capacity of the heat exchanger on the condensation side due to deterioration over time, this protects the compressor. However, it is extremely difficult for the user to recognize that the heat exchange capacity of the condensation side heat exchanger is reduced due to aging. Because the operating capacity of the compressor will be reduced, some users may feel that it has become less effective than before, but the reason can not be found, it will eventually break down and become inoperable It was difficult to say that the long-term use safety was ensured.

The present invention has been made to solve the above-described problems, and is intended to alert the user to safe use, ensure safety in long-term use, and further promote the protection of the global environment. and to provide an air conditioner location that allows the use of time.

An air conditioner according to the present invention is an air conditioner that uses a refrigeration cycle in which a refrigerant is circulated by a compressor, and can be used for indoor units installed indoors and for instructions to start and stop the air conditioner. and the remote controller is an external operating device, provided in the chamber main body, and a representation unit for representation standard use period of the air conditioning apparatus, provided in the remote controller, the actual period of use of the air conditioner is a standard use period And a progress display section for notifying that the actual use period has passed the standard use period after the elapse of time.

  In the air conditioner according to the present invention, the user can recognize the standard use period by the notation part, and can raise awareness of safety for long-term use and call attention, and the actual use period is standard use by the progress display part. Since the user can recognize that the period has elapsed, the safety check is performed at an appropriate time, the safety in continuous long-term use is ensured, and the effect of enabling long-term use is obtained.

Embodiment 1 FIG.
As an embodiment of the present invention, an air conditioner will be described as an example from household electrical appliances using a refrigeration cycle in which a refrigerant is compressed by a compressor and circulated. The air conditioner in this embodiment has an operating rotational speed of the compressor, more precisely, the rotational speed of the electric motor that is housed in the closed container of the compressor and similarly drives the compression mechanism portion housed in the sealed container. Is made variable by inverter control, and the operation capability of the air conditioner such as cooling and heating is made variable by changing the operation speed of the compressor.

  1 is a configuration diagram illustrating a refrigerant circuit and the like of an air-conditioning apparatus according to Embodiment 1 of the present invention. As shown in FIG. 1, this air conditioner is a separate type composed of an indoor unit 100 installed indoors and an outdoor unit 200 installed outdoors, and the space between the indoor unit 100 and the outdoor unit 200 is The refrigerant circuits are connected by connecting pipes 11a and 11b. The connection pipe 11a is a liquid-side connection pipe through which the refrigerant passes through the condensation step, and the connection pipe 11b is a gas-side connection pipe through which the refrigerant passes through the evaporation step.

  A control device for controlling the operation of the air conditioner is installed in each of the indoor unit 100 and the outdoor unit 200. The indoor unit 100 is provided with the indoor side control device 12, and the outdoor unit 200 is provided with the outdoor side control device 14. . The indoor side control device 12 and the outdoor side control device 14 are connected by an indoor / outdoor communication cable 29. The indoor / outdoor communication cable 29 is bundled together with the connection pipes 11a and 11b.

  The outdoor unit 200 includes a compressor 1 that compresses and discharges refrigerant, a refrigerant flow switching valve 5 that switches the flow direction of the refrigerant (hereinafter referred to as a four-way valve 5), and outdoor heat that exchanges heat between the outside air and the refrigerant. A decompression device 7 (hereinafter referred to as an expansion valve 7) such as an electronically controlled expansion valve that controls the opening degree according to a command from the exchanger 8 and the outdoor control device 14 and decompresses the high-pressure refrigerant to a low pressure is disposed. The machine 100 is provided with an indoor heat exchanger 6 that performs heat exchange between indoor air and refrigerant. These are sequentially connected by pipes including connection pipes 11a and 11b to constitute a refrigerant circuit, that is, a refrigeration cycle. Here, R410A, which is an HFC mixed refrigerant, is used as the refrigerant that is the working fluid circulating in the refrigeration cycle.

  The compressor 1 contains a rotary mechanism, a scroll type compression mechanism section, and an electric motor that drives the compressor mechanism section in an airtight container, and the electric power is transmitted through a glass terminal installed in the airtight container. When the electric motor is transmitted to the electric motor and rotated by the electric power, a low-pressure refrigerant is sucked into the compression mechanism and compressed, and discharged to the discharge pipe 2 outside the sealed container. The electric motor of the compressor 1 changes the number of rotations according to the voltage and frequency of supplied electric power. The electric motor of the compressor 1 is a DC in which a rare earth or ferrite permanent magnet is embedded in the rotor iron core. A motor is used.

  Here, the rotational speed of the electric motor of the compressor 1 is referred to as the rotational speed of the compressor 1. The compressor 1 is inverter-controlled by a compressor driving device 15 that is an inverter control device, and the rotation speed is variable. In order to change the rotation speed of the compressor 1, the compressor driving device 15 changes the voltage and frequency of the electric power supplied to the compressor 1. The operation start and stop of the compressor 1 are also controlled by the outdoor control device 14.

  The compressor 1 is an accumulator that temporarily stores the refrigerant that has not been completely evaporated and has arrived at the compressor 1 on the upstream side of the compressor mechanism portion and that has not been evaporated, thereby avoiding liquid compression in the compression mechanism portion. The accumulator 4 is connected to a suction pipe 3 for a refrigeration cycle.

  An indoor fan 9 that is a blower is installed in the vicinity of the indoor heat exchanger 6 inside the indoor unit 100, and an indoor fan drive device 13 that is a fan motor is controlled by the indoor side control device 12, and the indoor fan 9 Operation is started and stopped, and the rotation speed is changed. Similarly, in the outdoor unit 200, an outdoor fan 10 that is a blower is installed near the outdoor heat exchanger 8, and the outdoor fan drive device 16 that is a fan motor is similarly controlled by the outdoor control device 14. These fans 9 and 10 promote heat exchange between the air and the refrigerant in the heat exchangers 6 and 8. Basically, the rotational speed of both the indoor fan 9 and the outdoor fan 10 is linked to the rotational speed of the compressor 1, and when the compressor 1 is operated at a high speed and the refrigerant circulation amount flowing through the refrigerant circuit is large. The rotational speeds of the fans 9 and 10 are also increased, and the amount of heat exchange between the refrigerant and the air is increased.

  The room temperature thermistor 18 detects the actual current room temperature (the temperature of the air-conditioned room), and this detection signal is transmitted to the indoor control device 12. Then, information on the indoor temperature and the set temperature of the sensible temperature requested by the user is transmitted to the indoor control device 12 by an external operation device 25 (hereinafter referred to as a remote control 25) such as a wireless remote controller. The indoor control device 12 calculates a building load based on the difference between the temperature (room temperature) detected by the room temperature thermistor 18 and the set temperature, and outputs a signal for changing the rotational speed of the compressor 1 in accordance with the calculated building load. This is sent to the outdoor control device 14 via the external communication cable 29. The outdoor control device 14 transmits a command signal to the compressor drive device 15 based on the signal from the indoor control device 12, and the building load in which the rotation speed of the compressor 1 is calculated by inverter control of the compressor drive device 15. The number of rotations depends on.

  The variable range of the rotation speed of the compressor 1 is finite, and in this air conditioner, the normal maximum rotation speed of the compressor 1 is 120 rps. The outdoor control device 14 controls the compressor drive device 15 so that the maximum rotation speed of the compressor 1 is 120 rps, and the compressor drive device 15 also has a frequency and a rotation speed higher than 120 rps. The corresponding voltage is not supplied to the compressor 1.

In the indoor / outdoor communication cable 29, not only a communication line for exchanging control signals between the indoor side control device 12 and the outdoor side control device 14, but also electric power obtained by inserting the power plug 22 into an indoor outlet is supplied to the indoor unit. A power line for transmitting from 100 to the outdoor unit 200 is also included. Power transmitted et been Ru from the power supply line through the outdoor side control unit 14, in order to operate the compressor 1 and the outdoor fan 10, it is supplied to their drive device 15, 16.

  In the outdoor control device 14, the electric current (operating current) transmitted to the outdoor unit 200 through the indoor / outdoor communication cable 29 is detected. The current detected here is a primary side current. During operation, the outdoor control device 14 controls the detected operating current so that it does not exceed a predetermined threshold value. This threshold value is the maximum operating current, which is 18 A (ampere) in this air conditioner. The outdoor control device 14 has an operating current of the air conditioner (detected primary current) of 18 A so that the detected primary current during this operation does not exceed the maximum operating current, that is, 18 A. When it is about to exceed, control is performed to reduce the operating current of the compressor 1 and reduce the operating current.

  In this case, priority is given to control so that the current does not exceed the maximum operating current, rather than responding to the building load described above. As the maximum operating current, a value corresponding to the capacity of the power plug 22 is set, and the safety of the power plug 22 is maintained by giving priority to not exceeding this value. When the maximum operating current with a large tolerance for the capacity of the power plug 22 is set, if the detected operating current (primary side current) exceeds the maximum operating current, the operating rotational speed of the compressor 1 is set. It may be controlled to reduce the operating current.

  Further, the outdoor control device 14 detects the compressor current (operating current of the compressor 1) supplied from the inverter device (compressor drive device) 15 to the compressor 1 by calculating from the voltage and resistance. When the current (secondary side current) exceeds a predetermined threshold, the outdoor control device 14 takes measures to stop the operation of the compressor 1. In order to protect the components such as circuit elements used in the outdoor control device 14 and the compressor drive device 15 and the compressor 1 from a suddenly generated high current, this threshold value is a stop measure overcurrent, Generally, a value slightly larger than the above-described maximum operating current is set. In this air conditioner, the stop measure overcurrent is set to 19 A (ampere). In this air conditioner, the primary side current is used for the maximum operating current control, and the compressor current is used for the stop measure overcurrent. However, either one may be used, or vice versa. Also good.

  Further, in order to finely control the rotational speed of the compressor 1 and the fans 9 and 10 and the opening degree of the expansion valve 7 to bring the operating condition of the air conditioner closer to the user's request, the compressor 1 and An indoor tube temperature thermistor 20 that detects the surface temperature of the pipe is attached to a pipe through which the refrigerant of the indoor heat exchanger 6 of fin-and-tube type flows in order to protect the fans 9 and 10. Similarly, an outdoor tube temperature thermistor 21 that detects the surface temperature of the pipe is attached to the pipe through which the refrigerant of the outdoor heat exchanger 8 of the fin and tube type flows.

  These tube temperature thermistors 20 and 21 obtain the condensation temperature and evaporation temperature of the refrigerant, and the condensation pressure (discharge pressure, high pressure) and evaporation pressure (suction pressure, low pressure) are controlled from the temperatures by the outdoor control device 14 or the indoor side control. The device 12 grasps. In order to protect various components of the compressor 1 and other refrigerant circuits from high pressure, when the condensation pressure grasped by the indoor tube temperature thermistor 20 or the outdoor tube temperature thermistor 21 exceeds a predetermined threshold value, the compressor 1 The outdoor control device 14 performs a measure for stopping the operation. This threshold is the stop action pressure.

  The tube temperature thermistors 20 and 21 are attached to the pipes in the middle of the heat exchangers 6 and 8, respectively, but are installed on the surface of the U-shaped portion connecting the upper and lower refrigerant pipes at the side ends of the fins arranged in parallel. Is installed without hindrance, and accurate tube temperature can be detected. The tube temperature thermistors 20 and 21 may be attached so as to detect the tube temperature immediately before the inlet and immediately after the outlet, not in the middle of the heat exchangers 6 and 8, respectively.

  A discharge temperature thermistor 17 for detecting the surface temperature of the discharge pipe 2 is attached to the discharge pipe 2 for use in operation control and protection as with the tube temperature thermistors 20 and 21. Since the discharge temperature thermistor 17 is intended to grasp the temperature of the refrigerant gas discharged from the compressor 1, the discharge temperature thermistor 17 is preferably installed as close to the compressor 1 as possible in the discharge pipe 2. If the compressor 1 is a high-pressure shell type in which the discharge gas is once discharged from the compression mechanism into the sealed container and the inside of the sealed container is in a discharge pressure (high pressure) atmosphere, the discharge temperature thermistor 17 is connected to the sealed container of the compressor 1. You may attach to the outer surface.

  During the operation of the compressor 1, the outdoor control device 14 controls so that the temperature detected by the discharge temperature thermistor 17 (hereinafter referred to as discharge temperature) does not exceed a predetermined threshold value. This threshold value is the maximum operating discharge temperature, which is 115 ° C. in this air conditioner. When the discharge temperature is likely to exceed 115 ° C. so that the detected discharge temperature does not exceed the maximum operation discharge temperature, that is, 115 ° C., the outdoor control device 14 decreases the operation rotational speed of the compressor 1. And control to lower the discharge temperature.

  In this case, priority is given to control so that the discharge temperature does not exceed the maximum operation discharge temperature, rather than depending on the building load described above. In addition, when the operation maximum discharge temperature is exceeded, the operation rotational speed of the compressor 1 may be decreased to control the discharge temperature to be decreased. Further, when the discharge temperature reaches a predetermined threshold value that is higher than the maximum operation discharge temperature, the outdoor control device 14 takes measures to stop the operation of the compressor 1. This threshold value is the stop measure discharge temperature, and is set to 120 ° C. in this air conditioner.

  A defrosting detection thermistor 19 is attached to a pipe surface connecting the outdoor heat exchanger 8 and the expansion valve 7 and in the vicinity of the outdoor heat exchanger 8. The pipe temperature detected by the defrosting detection thermistor 19 is used during heating operation in which the outdoor heat exchanger 8 described later functions as an evaporator. In this case, the vicinity of the inlet of the outdoor heat exchanger 8 serving as an evaporator. A defrosting detection thermistor 19 is attached. When the piping temperature detected by the defrosting detection thermistor 19 is equal to or lower than a predetermined temperature, the outdoor control device 14 controls to perform a defrosting operation (defrosting operation) for removing frost attached to the outdoor heat exchanger 8. To do.

  By performing the defrosting operation, frost adhering to the outdoor heat exchanger 8 can be melted, and the outdoor heat exchanger 8 can be avoided from being covered with frost. Therefore, the air path of the outdoor fan 10 is not blocked by frost, the outdoor fan drive device 16 is protected, and the heat exchange capacity (evaporation capacity) of the outdoor heat exchanger 8 is not reduced by frost. Thus, a significant drop in the low pressure (the suction pressure of the compressor 1) and a large amount of liquid refrigerant being sucked into the compressor 1 can be avoided, and the compressor 1 can be protected.

  A command for the operation mode of the air conditioner based on the user's request is transmitted from the indoor control device 12 to the outdoor control device 14. The operation mode is a cooling operation, a dehumidifying operation, a heating operation, or the like. When the outdoor mode control device 14 receives the operation mode command signal, the outdoor heat exchanger 8 serves as the condenser and the indoor heat exchanger 6 serves as the cooling mode or dehumidifying operation command. The outdoor control device 14 moves the four-way valve 5 to control the flow direction of the refrigerant so as to become an evaporator. When the heating operation is instructed, the outdoor control device 14 reverses the four-way valve 5 in order to make the refrigerant flow such that the indoor heat exchanger 6 is used as a condenser and the outdoor heat exchanger 8 is used as an evaporator. To control. FIG. 2 shows the flow direction of the refrigerant during the cooling operation or dehumidification operation of the air conditioner, and FIG. 3 shows the flow direction of the refrigerant during the heating operation.

  4 is a perspective view showing a main body of the indoor unit 100 of the air-conditioning apparatus according to Embodiment 1. FIG. This indoor unit 100 is a wall-hanging type and is installed above the wall surface of the air-conditioned room. The indoor heat exchanger 6 and the indoor fan 9 described above are accommodated in the housing 30. In the indoor unit 100, a cross flow fan that is long in the longitudinal direction is used as the indoor fan 9, and is installed horizontally on the downstream side of the indoor heat exchanger 6. A front panel 31 serving as a design surface of the indoor unit 100 main body is installed on the front surface of the housing 30. The front panel 31 can be opened and closed in the vertical direction with the top as a fulcrum, and the interior of the housing 30 can be cleaned with the front panel 31 opened, and dust accumulation in the housing 30 can be prevented.

  Above the housing 30 and the front panel 31, a suction port 32 for sucking room air into the main body of the indoor unit 100 is formed. The suction port 32 may be formed in front of the front panel 31, or may be formed only in the housing 30 without being provided in the front panel 31. On the other hand, below the front panel 31 at the lower part of the housing 30, a blowout for releasing indoor air (conditioned air) after passing through the indoor heat exchanger 6 and exchanging heat with the refrigerant inside the indoor unit 100 main body to the outside. A mouth 33 is provided. A wind direction flap for adjusting the vertical direction and the horizontal direction of the conditioned air to be blown out is installed at the blowout port 33, and the direction of the air flow blown out by the indoor side control device 12 can be controlled. In FIG. 4, the air outlet 33 is illustrated as a state where the opening is closed by two wind direction flaps that adjust the airflow in the vertical direction (the operation of the indoor unit 100 is stopped).

  The lower portion of the housing 30 is formed in a gently curved shape. When the main body of the indoor unit 100 is installed on the indoor wall surface, the lower curved surface portion faces obliquely downward, The direction of the line of sight when a user is looking up at the main body of the indoor unit 100 is almost parallel. The blowout port 33 is also opened in the curved surface portion. And the receiving part 24 of the remote control 25 is installed on the side of the outlet 33 above the curved surface part.

A notation part 34 of the main body is provided between the outlet 33 of the curved surface part below the housing 30 and the remote control receiver 24. In the table marking portion 34, the name of the manufacturer, the model name of the air conditioner, the year of manufacture, etc. are specified. The notation 34 in the indoor unit 100, although they are constituted by pasting the sticker (seal) which are specified, may be formed by printing directly on the housing 30, You may comprise so that the surface may be marked by a type | mold at the time of resin molding of the housing | casing 30. FIG. And the notation part 34 of this indoor unit 100 main body has specified the standard use period of this air conditioning apparatus further. A notation example of the notation unit 34 is shown in FIG.

  As shown in FIG. 5, the user can recognize the standard use period of the air conditioner by notifying the standard use period of the air conditioner. For this reason, the user comes to call attention to safety in long-term use. The standard use period indicated in the notation unit 34 can raise the user's awareness of safety in long-term use and call attention. It is possible to collate the elapsed time since the user started using this air conditioner with the standard usage period indicated, and to raise safety awareness and raise awareness for long-term use. . It can also be used as a guide for inspection and replacement. As shown in FIG. 5, in the notation unit 34, when the notation of the standard use period is indicated with a large character compared with other information or indicated by changing the color, it is particularly Person's cognition is increased.

  The user or installer enters the start date of use or the start date of use in the notation section 34 with a magic so that the user can immediately grasp the start time of use of this air conditioner without having to remember each time. A column that can be used may be provided. Separately from the notation section 34, a space is provided in the vicinity of the notation section 34 where a sticker on which the use start date or use start date is written can be attached, and the use start date or use start can be separately provided. A seal capable of entering the date may be provided, and the user or installer may enter the date of start of use or the date of start of use on the seal and put it on the above space. In this way, by making it possible to specify the use start time near the notation of the standard use period, the user's awareness of safety for long-term use can be further enhanced.

Standard use period, the quality of the air conditioner, the reliability evaluation of the results and standard use environment, based on such operating time, time to time made it difficult to safety is maintained by way year deterioration Set by the manufacturer. In notation example of notation portion 34 shown in FIG. 5, and the standard duration of use of the air conditioner and 13 years. This period of 13 years will be described later. In addition, the notation 34 also includes a cautionary note that prompts the safety inspection to be performed when the product is used beyond the standard use period, and provides the user with caution ventilation for ensuring safety during long-term use. Guidance is provided for securing.

  In this way, it is desirable to provide the notation unit 34 that describes the standard use period at a position that is easily noticeable by the user. In the indoor unit 100, the notation unit 34 is provided on a curved surface portion that faces obliquely downward below the housing 30, so that when the user looks up at the main body of the indoor unit 100, the line of sight and the notation unit 34 are displayed. Becomes nearly orthogonal, easily noticeable by the user, and can fully achieve the purpose of notation (enhancing safety awareness and alerting the user to long-term use).

  In this indoor unit 100, a notation unit 34 is provided on the surface below the main body (housing 30), which is close to the line of sight when the user looks up at the indoor unit 100 installed on the wall surface. However, as described above, the notation unit 34 may be a position that is easily visible to the user, and may be, for example, the front surface of the main body of the indoor unit 100. When it is provided on the front, the lower part closer to the floor is more visible. When provided on the front, it may be provided on the front panel 31.

  Moreover, what is necessary is just to provide in the lower surface of the housing | casing 30, when providing the description part 34 in the front is not suitable for the design property of the indoor unit 100 main body. The notation section 34 is provided on the lower surface of the housing 30 on the back side from the outlet 33 (close to the wall surface where the indoor unit 100 is installed). If it provides in this position, when the user looks up the indoor unit 100 main body from the downward direction, the notation part 34 will come to the eye. In addition, if the notation part 34 is provided in the surface which faces a floor surface in the front and upper surface of a main body, if it is a floor-standing type indoor unit, if it is provided in the surface which faces a floor surface if it is a ceiling hanging type or ceiling embedded type indoor unit, it will be used. Easy to see.

  In FIG. 4, an operation lamp 35 is provided between the notation 34 of the curved surface portion below the housing 30 and the remote control receiver 24. When this air conditioner is operating, this operation is performed. The lamp 35 is turned on. Always lit during operation. Next to the operation lamp 35, a progress display unit 36 for displaying the progress state of the air conditioner with respect to the standard use period is installed. In the progress display unit 36, when the user continues to use the air conditioner, the lamp is turned on when the actual use period (actual use period) exceeds the standard use period described in the display unit 34. It comes to light up. Both the operation lamp 35 and the lamp of the progress display unit 36 use LEDs (light emitting diodes).

  The lamp of the progress display unit 36 may be turned on when the actual use period has passed the standard use period, but the appeal to the user is further enhanced by blinking (repetition of turning on and off). . In addition, it lights up from a predetermined period before the standard use period, for example, 6 months or 3 months ago, to notify that the actual use period is about to pass the standard use period, and to pass the standard use period. In such a case, the lamp may blink (repeatedly turn on and off) to notify that the standard usage period has elapsed.

  Also, install a lamp that lights up for a predetermined period before the standard use period and notifies that the standard use period is about to expire, and a lamp that lights or blinks when the standard use period is over. It may be. Here, the progress display part 36 is not limited to the structure which displays by lighting or blinking of a single lamp as mentioned above. For example, it may be configured with a liquid crystal display screen, and the fact that the standard usage period will soon be exceeded or that the standard usage period has been exceeded may be displayed directly in text or a figure.

  In addition, the display can be performed with more peace of mind by displaying on the progress display unit 36 such that the user can grasp how long the actual usage period is. FIG. 6 shows another example of the progress display unit 36, and the upper line 37 expresses the standard use period by its length. The upper line 37 may be a lamp lighting, printing, or a seal. Below the line 37, a progress status display means 38 in which a plurality of LEDs are arranged is provided. Then, the LEDs of the progress status display means 38 are lit in order from the end in accordance with the ratio of the actual usage period to the standard usage period. Thereby, the user can grasp | ascertain the present actual use period with respect to a standard use period.

  The user can recognize that the standard use period has expired by turning on all the LEDs of the progress display means 38. At this time, all the LEDs may be blinked. The line 37 indicating the standard usage period may be omitted. In addition, the progress status display means 38 is not indicated by the ratio of the actual use period to the standard use period, but LEDs corresponding to the number of years of the standard use period or the number of years divided are arranged directly for one year or a predetermined number of years. Each time, the LEDs may be lit in order from the end. The arrangement of the LEDs may be in the horizontal direction or the vertical direction, and may be determined according to the design of the indoor unit 100 main body and the space that can be displayed.

  FIG. 7 is a perspective view of the indoor unit 101 showing another embodiment of the progress display unit 36. Similar to the indoor unit 100, a notation unit 34 is installed on the side of the outlet 33. In the indoor unit 101 shown in FIG. 7, the front panel 31 that can be opened and closed in the vertical direction with the upper side as a fulcrum is painted with a bright color such as white or light beige on the back side of the transparent resin (the back side facing the room). Configured. Then, on the front part of the housing 30 located inside the front panel 31 in the closed state, a display frame having a display window shaped to display characters and shapes, and a plurality of LEDs installed in the display frame By installing the display mechanism and illuminating the LED, the light of the LED that has passed through the display window is transmitted through the front panel 31 including the painted surface, and the current indoor temperature, sensory temperature, and operating condition of the air conditioner Are displayed in front of the front panel 31 so that the user can grasp the information.

  Since the front surface of the front panel 31 can be used as a display space, it is possible to display a large amount of information, and there are advantages that the user can easily see and recognize a lot of information, and the design is excellent. The indoor unit 101 incorporates a progress display unit 36 in a transmission display mechanism to the front of the front panel 31. As shown in FIG. 7, the circled display at the left end of the display information in the figure indicates that the actual use period of the air conditioner is about to pass the standard use period or that the standard use period has passed. It is a progress display section 36 for informing. Continuous transparent display may be used, and display non-display may be repeated when the standard use period has passed. Since the display of the progress display unit 36 can be enlarged, appeal to the user is enhanced.

  Further, a portion for displaying temperature information (encircled by a broken line in FIG. 7) is provided at the right end of the display information, and this is used as the progress status display means 38. The display of this part can be switched by the remote controller 25 or the indoor unit 101 main body, and it is configured to switch from the temperature information to the display of the actual use period according to the display switching instruction of the user. The actual usage period may be displayed directly including the number of years including, for example, the month after the decimal point. Alternatively, the actual usage period may be displayed as a percentage of the standard actual usage period described in the notation unit 34, for example,%. It's okay.

  You may make it provide the display space of progress status display means 38 separately, without sharing temperature information and a display place. Since the display of the actual use period is not information that the user always needs, in this case, it is better to configure the display so that the actual use period is displayed according to the user's request.

  As described above, by installing the notation 34 on the product body and indicating the standard usage period, the user can recognize the standard usage period and can raise awareness of safety for long-term use and call attention. Since it takes a considerably long time to exceed the use period, it may happen that the user does not notice that the standard use period has passed. However, the progress display unit 36 displays that the actual use period will soon be over the standard use period or that the standard use period has passed, and informs the user so that the user can recognize it. By referring to and confirming the instruction manual according to the notation contents of the part 34 and the notation part 34, a request for a safety check from a specialist is made at an appropriate time. By conducting safety inspections, safety in long-term use can be ensured. And by conducting safety inspections and replacement of parts and repairs by specialists, it is possible to use the air conditioner continuously for a long period of time and contribute to the effective use of resources.

  In addition, since the actual use period is displayed directly or as a ratio to the standard use period by the progress status display means 38, the user can collate the actual use period obtained by this and the standard use period. Since the user's consciousness about the standard use period can be enhanced and the user can confirm the tolerance to the standard use period, the product (air conditioner) can be used with peace of mind.

  Next, the remote controller 25 will be described. FIG. 8 is a configuration diagram showing the remote controller 25. A display screen 27 displayed with a liquid crystal is arranged at the upper front side, and a plurality of operation buttons 28 are arranged below the display screen 27. On the upper surface of the remote controller 25, a transmission unit 26 that transmits an operation signal by the user toward the reception unit 24 of the indoor unit 100 main body is installed. The largest button among the operation buttons 28 is the operation button 28a. When the user presses the operation button 28a, the start and stop of the operation of the air conditioner are instructed.

The button adjacent to the operation button 28a is the operation mode switching button 28b, and the user instructs the operation mode. Here, automatic, cooling, dehumidification, heating, and air purification can be switched. The term “automatic” means that the air conditioner determines an operation mode that the user is satisfied from the information stored in the control devices 12 and 14 and the current environmental conditions, and operates in that operation mode. In the air cleaning, only the indoor fan 9 rotates, and the compressor 1 and the outdoor fan 10 are not operated.

  Next, the operation of the air conditioner according to Embodiment 1 will be described. After the purchase and installation of the air conditioner, when the operation button 28a of the remote controller 25 is pressed for the first time to start the operation of the air conditioner, the indoor side control device 12 activates the timer for calculating the actual use period. A program for the device 12 is configured. When the calculation is started, the actual use period calculation timer continues to operate even after the air conditioner is stopped. That is, the calculation of the actual usage period is continued. This actual use period calculation timer function is built in the indoor side control device 12.

  Further, the timer count (calculation) is continued regardless of which of the operation buttons 28 of the remote controller 25 is operated. For example, even after the operation button 28a is operated to stop the operation, even if the operation mode switching button 28b is operated to select or change the operation mode, the timer for calculating the actual use period continues to count. The program is configured.

  The timer that calculates the actual usage period starts calculation when it is first operated after installation. In the above, the calculation is started when the operation button 28a of the remote controller 25 is operated. However, the counting is started from the time when the operation is started by operating the main body operation button 23 installed in the main body of the indoor unit 100. Also good. In this case, it is desirable for a professional installer to press the main body operation button 23. The main body operation button 23 is provided inside the main body of the indoor unit 100 so as to appear when the front panel 31 is opened. Further, the actual use period calculation timer may start operating when the power plug 22 connected to the indoor unit 100 is connected to the outlet of the room.

  Since the actual use period calculation timer keeps counting even when the air conditioner is stopped, power for that purpose must be secured at all times. Therefore, a timer with a built-in battery may be used, but the cost is high. It is realistic to use the electric power obtained from the power plug 22, and this air conditioner obtains the operating power of the actual use period calculation timer from the power plug 22 as such. The amount of power used for the timer is very small. In this air conditioner, the operating power of the actual usage period calculation timer and the operating power of the remote control receiver 24 of the indoor unit 100 are consumed as standby power during stoppage. As a result, standby power is extremely low.

  If the power plug 22 is unplugged from the outlet, power will not be supplied to the actual use period calculation timer and the timer will not be able to count. Therefore, the actual use period counted by the timer will be the same as the time when the power plug 22 is unplugged. It will be shorter than the actual actual use period. For this reason, in this air conditioner, after starting the use of the air conditioner and starting the count of the actual use calculation timer, the standby power is extremely small for the reason described above so that the power plug 22 is not pulled out. It is called out clearly in the instruction manual.

  Thus, in this air conditioner, after the user actually starts using the air conditioner (from when the air conditioner is operated for the first time after installation), the timer that calculates the actual use period starts counting. Therefore, it is possible to grasp the accurate actual use period and provide it to the user. When the built-in battery timer is activated from the date of manufacture, for example, when the date of manufacture is April 1, 2007 and the standard use period is 13 years, the calculated value of the timer is March 2020. It is also possible to determine that the standard use period has passed when the 31st has been reached, but in this case, one year or more will elapse from the date of manufacture until the user actually uses it. If so, the standard usage period will elapse in a short actual usage period, and the actual usage time by the user until the standard usage period will be shortened.

  Possible causes of accidents in long-term use include deterioration of electrical and electronic parts, accumulation of dust inside the equipment, and deterioration such as rust and corrosion caused by the installation environment, but these are actually used by equipment (air conditioners) It happens after being done. The period from when the manufacturer manufactures the device to when the user uses the device is normally stored in the warehouse of the manufacturer or dealer. Under such conditions, outdoor solar radiation, rainwater, or salt damage It is safe to assume that there is almost no deterioration of the equipment because it is not exposed and there is no fear that the electric and electronic parts will deteriorate due to the heat generated by the operation. For this reason, like this air conditioner, after the user actually starts using it, the actual use period calculation timer is counted, and the accurate actual use period is grasped and provided to the user. It is possible to prevent the user from having distrust or unfairness that the actual use period is not accurate.

  In the above description, the actual use period calculation timer provided in the indoor control device 12 is used for grasping the actual use period, but another method for grasping the actual use period will be described below. As shown in FIG. 8, the remote controller 25 can display the current date on the display screen 27. The current date is grasped by counting with the timer from the entered date. When any operation button 28 is pressed by the remote controller 25 and the signal is transmitted from the transmission unit 26 to the reception unit 24 of the main body, this date information is also transmitted together. It is transmitted to the inner control device 12.

  And the receiving part 24 receives the date information when a user starts the use of an air conditioning apparatus by pushing the operation button 28a, and the indoor side control device 12 stores it. The indoor side control device 12 calculates the actual use period by comparing the current date information that is transmitted together with the operation command signal from the remote controller 25 with the stored use start date. The actual period of use can be grasped.

  Here, if the entered date information changes significantly during the process, for example, the date is not set correctly at the start of use, and the date information starts. If the indoor side control device 12 stores the date as the date and the time is set accurately thereafter, the indoor control device 12 may not be able to accurately grasp the actual usage period. obtain.

  Therefore, the standard time signal (transmitting station) used in the radio clock is used so that the current correct date information can be periodically acquired without manually setting the date information, that is, without using a timer. The remote controller 25 has a built-in antenna that can receive a signal transmitted from the country to cover the whole country. The standard time radio wave includes date information in addition to the time information. Therefore, the remote controller 25 can always acquire accurate date information. In addition, the user's trouble of manually inputting date information can be saved.

  In this way, the standard time radio wave is received, and the remote controller 25 always grasps accurate date information. Therefore, the date information stored in the indoor control device 12 when the use of the air conditioner is started is also checked. The current date information is also accurate date information, so that the indoor control device 12 can grasp the correct actual use period. In addition, since the time information can also be received, the correct time can be displayed on the display screen 27 of the remote control 25, or the correct time can be displayed when the user specifies the time and activates the on / off timer. In addition, the effect of starting and stopping the operation by the timer operation can be obtained. The interval at which the standard time radio wave is received and the information is read may be arbitrarily set, but once a day is sufficient.

  In addition, the remote controller 25 does not incorporate an antenna that can receive standard time radio waves, but directly installs the antenna in the main body of the indoor unit 100 so that the indoor control device 12 can grasp the date information of the standard time radio waves. You may comprise. Furthermore, since the remote controller 25 and the indoor unit 100 main body are indoors, it may be difficult to receive standard time radio waves depending on the region. Therefore, an antenna that can receive standard time radio waves may be installed in the outdoor unit 200 to increase the reception sensitivity. In this case, the received standard time information may be transmitted to the indoor control device 12 through the indoor / outdoor communication cable 29, or the outdoor control device 14 may calculate the actual use period. .

  The receiving antenna may be installed anywhere, and may be configured to grasp the actual use period using date information provided by the standard time radio wave. If date information and time information obtained from the standard time radio wave are displayed not only on the display screen 27 of the remote controller 25 but also on the indoor unit body, for example, on the front panel 31 of the indoor unit 101 body shown in FIG. Can be a substitute for a calendar or clock for the user. It has been described that the calculation of the actual use period is performed by the indoor control device 12 both when counting with a timer and when comparing the current date with the stored use start date. However, it may be implemented by the outdoor control device 14.

  In the above, the indoor side control device 12 or the outdoor side control device 14 has means for storing the date of operation for the first time after installation and means for grasping the current date, and from these dates, Although the indoor side control device 12 or the outdoor side control device 14 is configured to calculate the actual use period of the air conditioner, these means store and grasp only the year, not the date. Also good. The actual use period grasped by the calculation will be shifted by about one month at the maximum, but this shift is a slight period compared with the standard use period of 13 years. By using only the year and month, the microcomputer capacity of the indoor side control device 12 or the outdoor side control device 14 responsible for storage and calculation can be reduced.

  Next, a case where the actual usage period has passed the standard usage period of 13 years will be described. In the air conditioner in this embodiment, three steps are provided for the operation after the standard use period has elapsed.

  First, the first step will be described. When the actual usage period has passed the standard usage period, the progress display unit 36 installed in the main unit of the indoor unit 100 is lit or flashed, etc. Display that the actual usage period has passed the standard usage period and inform the user of that. The display by the progress display unit 36 is always displayed at least during operation after the air conditioning apparatus has passed the standard use period. If the display on the progress display unit 36 (display for notifying that the actual use period has passed the standard use period) is the lighting or blinking of the LED, the lighting or blinking is continued at least during the operation.

  As described above, if the standard use period of the air conditioner is simply described in the notation unit 34 or the instruction manual of the indoor unit 100 main body, it is left to the user's judgment that the actual use period has passed the standard use period. Therefore, it is difficult to say that safety alerts regarding long-term use are sufficient. However, as described above, the progress display unit 36 that informs that the actual use period has passed the standard use period is provided in the main body of the indoor unit 100, and after the standard use period has elapsed, at least during operation, By continuing to display the progress display unit 36, it is possible to alert the user to safety regarding long-term use. In addition, after the actual use period exceeds the standard use time, the progress display unit 36 is continuously displayed not only during operation but also during a stop so that more careful ventilation can be achieved. Good.

  The user learns from the display on the progress display section 36 that the actual use period has passed the standard use period, and contacts a specialist such as a service department designated by the manufacturer according to the description in the instruction manual. Then, the service department (special contractor) that has received the communication performs a designated safety check on the corresponding air conditioner and determines whether there is a safety problem even if it is continuously used.

  For example, the safety check can be performed by checking whether there is any dirt, discoloration, or insulation deterioration of the control devices 12 and 14 in the indoor / outdoor, the actual use period data recorded in the control devices 12 and 14, and the overcurrent stop measures in the program. Or whether the threshold value for protection such as the discharge temperature of the stop measure is a correct value, and the number of times the compressor 1 has stopped exceeding that threshold value is not large, A drainage path through which condensed water adhering to the indoor heat exchanger 6 or the like is discharged to the outside, whether it is not deteriorated by rust or corrosion, discoloration, dust accumulation or insulation deterioration in the power plug 22 of the indoor unit 100 Check whether there are cracks or holes that may cause dust accumulation or leakage on the drain hose.

  When it is determined by this safety check that there is no safety problem, the actual use period that has been calculated and grasped can be reset by specially operating the operation button of the remote controller 25 on the air conditioner. It is like that. Here, when the operation button 28a and the operation mode switching button 28b are simultaneously pressed for 5 seconds, the actual use period so far is reset. The actual use period until the reset is stored in the indoor control device 12 so that the accumulated actual use period with the actual use period after the reset can be grasped. In addition, the display of the progress display section 36 and the progress status display means 38 is reset with the reset of the actual use period. That is, the display is turned off (not displayed) or the display contents are restarted.

  In this way, in order to count a new actual use period after the safety inspection is performed, the actual use period can be reset only by operating the remote controller 25 without newly replacing parts such as the indoor control device 12 (new actual use). Since the air conditioner can be used continuously, the cost of the safety check can be suppressed, and the burden of the user's check cost can be reduced. And since the cost of the safety check is reduced, it becomes easier for the user to request a safety check.

  Note that the predetermined operation when resetting the actual usage period and the display of the progress display unit 36 is not limited to the operation by the remote controller 25, but is also a combination of the operation of the main unit of the indoor unit 100 and the operation of the remote control 25, or the main unit of the indoor unit 100 It may be a thing only to operate. However, the operation must be set to an operation setting that is not easily performed by the user to prevent malfunction.

  As a result, the user can continue to use the air conditioner until the next safety check. The period until the next safety check is the period corresponding to the standard use period after reset.The period until the next safety check is replaced with a new standard use period in the program, and the actual use period after reset is The progress display unit 36 and the progress status display means 38 display that the period until the safety check is about to approach or has passed, as in the case of the standard use period. In addition, the service department or specialist who has performed the safety check continuously indicates the next safety check time to the user so that it is displayed in the vicinity of the notation unit 34 or overlaid on the notation unit 34. Safety ventilation in the long-term use of.

  In the air conditioner of this embodiment, a plurality of periods until the second and subsequent inspections can be set. As such, it is programmed in the indoor control device 12 in advance. For example, again 13 years, half 6 years, or 2 shorter years. An arbitrary number of years may be set every year with the standard usage period as the longest. For this reason, the service department (specialist) that performed the safety inspection can select the period until the next safety inspection from these multiple setting periods according to the status of the inspection results, and an appropriate period is set. As a result, the safety for use after the safety check (long-term use) is increased, and the number of safety checks can be increased more than necessary, thereby avoiding the burden on the user and cost. .

  Finally, the service department (specialist) who has completed the safety check registers the model name of the equipment (air conditioner) that can be used for a longer period and the contact information of the user. Thereby, the manufacturer can provide the user with information related to the safety and quality of the product. Such information provision is performed by telephone, postal mail, electronic mail, presentation on the Internet, and the like, but it is properly used depending on the content of information and the degree of urgency.

  On the other hand, if a specialist in the service department, for example, determines that there is a safety problem if it continues to be used as it is, it will be repaired or specified in order to maintain safety and continue using it. Inform the user that the parts need to be replaced, and if the user's approval is obtained, repair or replace the parts so that they can continue to be used until the next safety check. The period until the next safety check, the reset of the actual use period, the operation of the progress display unit 36 and the progress status display means 38, etc. are the same as those described above when it is determined that there is no safety problem in the safety check. is there.

  As described above, the standard use period of the product is indicated in the notation section 34 of the main body and in addition to the instruction manual so that the user can recognize the standard use period. Since it takes a long period before the standard use period elapses, the user may not notice that the standard use period has passed. However, by displaying that the actual usage period has passed the standard usage time on the progress display section 36 of the main body and notifying the user, the user can recognize that the standard usage period has passed. Safety can be confirmed at an appropriate time according to the description of the unit 34 and the instruction manual. In addition, safety inspections and replacement / repair of some parts by specialists such as the service department designated by the manufacturer will enable safe and long-term use of the air conditioner without any safety problems. Can also contribute to the effective use of.

  Next, the second step after the standard usage period has elapsed will be described. After the progress display unit 36 displays that the actual use period has passed the standard use period, the progress display unit 36 is further lit or flashing to indicate that the actual use period has elapsed, Normal operation can be performed as usual. This predetermined period is a period for the user to perform a safety check by requesting a specialist. The safety check is completed during this period, and a new period of use is started until the next safety check. If it does so, the display of the progress display part 36 will also disappear.

  Note that the above predetermined period requires at least one year in consideration of the burden on the user. Further, if the safety check is accepted from a predetermined period before the time when the standard use period elapses, the period during which the user can request the safety check becomes longer, and the convenience for the user can be improved. In this case, a display notifying that the standard usage period will soon be passed can be effectively used. For example, as described above, if the display unit 36 displays that the standard use period is about to expire, the safety check is accepted from the time when this display is made. .

  However, when the safety display has not been performed after the predetermined period has elapsed since the progress display unit 36 displayed that the actual use period has passed the standard use period, the display of the progress display unit 36 is used. It is highly probable that the user will not request a safety check simply by calling attention. Further, if the operation is continued without performing a safety check, the deterioration over time further proceeds, and the safety of the product may not be maintained.

  Therefore, in this air conditioner, when the safety check is not performed during a predetermined period that requires a safety check and it is continuously used, the maximum operating capacity of the air conditioner is set as a second step. Take measures to reduce. By reducing the maximum operating capacity, the progress of aging deterioration is delayed as much as possible to give safety considerations, and if the user feels that the maximum heating capacity will decrease if heating, the warming will be bad. If the maximum cooling capacity is lowered, the user feels that the cooling is bad, and the standard use period indicated on the notation part 34 and the display on the progress display part 36 are recognized again to decide to conduct a safety check. become. That is, the decrease in the maximum driving capacity has an effect of motivating the user to request a safety check from a specialist.

  A method for reducing the maximum driving capacity will be described below. The first method is means for lowering the maximum operation speed of the compressor 1. As described above, the compressor 1 normally has a maximum operation speed of 120 rps, but this is reduced to, for example, 80 rps. In other words, no matter how large the difference between the detected temperature (room temperature) and the set temperature by the room temperature thermistor 18, the outdoor control device 14 has a compressor at a rotational speed higher than 80 rps with respect to the compressor drive device (inverter device) 15. No operation command of 1 is issued. If the operation maximum rotation speed of the compressor 1 is reduced, the refrigerant circulation amount of the refrigeration cycle is also reduced. If cooling, the maximum cooling capacity is reduced, and if heating, the maximum heating capacity is reduced.

  The second method is a means for reducing the maximum operating current. As described above, in this air conditioner, the outdoor control device 14 normally controls the operation current of the air conditioner so that it does not exceed 18A with the operation maximum current being 18A. Is reduced to, for example, 12A. When the operating current is likely to exceed the maximum operating current, the outdoor side control device 14 performs control to reduce the operating current by decreasing the rotation speed of the compressor 1, thereby reducing the maximum operating current. Therefore, the rotation speed of the compressor 1 is kept low, the refrigerant circulation amount of the refrigeration cycle is reduced, and the maximum operating capacity is reduced.

  The third method is a means for lowering the maximum operation discharge temperature. In this air conditioner, as described above, the maximum operation discharge temperature is usually 115 ° C. This operation maximum discharge temperature is lowered to 100 ° C., for example. Since the outdoor control device 14 performs control to lower the discharge temperature by reducing the rotation speed of the compressor 1 when the discharge temperature during operation detected by the discharge temperature thermistor 17 is likely to exceed the maximum operation discharge temperature. By reducing the maximum operation discharge temperature, the number of revolutions of the compressor 1 is consequently reduced, and the refrigerant circulation amount of the refrigeration cycle is reduced and the maximum operation capacity is reduced.

  The fourth method is means for reducing the maximum opening of the expansion valve 7. In this air conditioner, normally, the fully opened state of the expansion valve 7 is set to the maximum opening, but this maximum opening is reduced to, for example, 70% of the fully opened position. When the maximum opening degree of the expansion valve 7 is reduced, the refrigerant circulation amount of the refrigeration cycle is reduced and the maximum operation capacity is reduced.

  As a measure to be taken when the safety check is not carried out even after a predetermined period (one year in the above embodiment) after the actual use period has passed the standard use period, To reduce the maximum operating capacity of the conditioner, four means have been specifically described above for that purpose. The air conditioner may be configured such that all four of these are set, or any one or two or three selected may be set. In addition, if the method which can reduce the maximum capability of an air conditioning apparatus is used, it is not limited to the four means demonstrated, The means may be set arbitrarily.

  In the second step, in order to reduce the maximum driving capacity, the operation control set value to be reduced from the initial (normal normal use period before the set value) is set in advance with a specific value programmed (for example, in the above example) The maximum operating current may be changed from normal 18A to 12A, etc., but the changed set value may be changed from operating information immediately before reaching the standard usage period to immediately after the operating information (the rotational speed of the compressor 1, various The temperature of the thermistor) may be taken in by the indoor control device 12 and compared with the operation information in the normal state stored in the indoor control device 12 in advance, and may be calculated from the comparison result. By setting in this way, a new set value suitable for the device being used is obtained, and safety considerations can be given in accordance with the progress of aging degradation. When the usage environment is bad and the progress of aging is fast, the maximum driving capacity can be greatly reduced.

  In this way, in the case where the set value after the change is calculated according to the operating state of the equipment, the current operating information and the stored normal state are stored with a predetermined period even during the execution of the second step. The maximum driving capacity may be reduced step by step according to the situation. Even if the aging deterioration progresses rapidly to the engine where the second step is carried out, safety considerations can be given in accordance with the progress of the aging deterioration.

  In addition, the indoor control device 12 stores the history of the operation of the compressor 1 being stopped due to the operation of various protection means such as the stop measure overcurrent or the stop measure discharge temperature (the number of operations, the operation timing, etc.). Based on the history, in order to reduce the maximum driving capability in the second step, an operation control set value to be reduced from an initial set value may be calculated. Even if this setting is made, a new set value suitable for the device being used is obtained, and safety considerations can be given in accordance with the progress of aging degradation.

Here, another embodiment as the second step will be described. This alternative embodiment may be both with measures Ru lowers the maximum operating capability described above can be set. The measure of this other embodiment is a measure to lower the operation set value of the protection means provided in this air conditioner and increase the frequency at which the compressor 1 stops operation, that is, the continuous operation of the compressor 1. This is a measure to limit (limit the time during which the compressor 1 can be operated continuously). By doing this, the load on parts that have deteriorated over time is reduced, and safety considerations are given to slow down the progression as much as possible, and the user frequently stops the air conditioner without permission. As a result, it is determined that the standard use period indicated on the notation unit 34 and the display on the progress display unit 36 will be recognized again and a safety check will be performed. In other words, a decrease in the operation setting value of the protective means has an effect of motivating the user to request a safety check from a specialist.

  In this air conditioner, as described above, as a protection means, as described above, a means for stopping the operation of the compressor 1 when the compressor current exceeds the stop measure overcurrent, and a compressor 1 when the discharge temperature exceeds the temperature stop measure discharge temperature. A means for stopping the operation of the compressor 1 and a means for stopping the operation of the compressor 1 when the condensation pressure exceeds the stop action pressure are set. Therefore, the set value of at least one of the stop measure overcurrent, the stop measure discharge temperature, and the stop measure pressure, which is the operation set value (threshold value) at which these protection means operate, is lowered from the normal state.

  A measure is taken such as reducing the stop measure overcurrent, which was normally set to 19 A, to 14 A, for example, or reducing the stop measure discharge temperature, which is usually set to 120 °, to 105 ° C., for example. As a result, the frequency at which the operation of the compressor 1 is stopped is increased, and the continuous operation of the compressor 1 is restricted, which motivates the user to request a safety check from a specialist.

  As another example of the second step, the operation setting value of the protection means is lowered to limit the continuous operation of the compressor 1. However, regardless of the protection means, the control devices 12, 14 During this period, the compressor 1 may be configured to be forcibly stopped when a predetermined time has elapsed since the start of operation and to intentionally limit the continuous operation of the compressor 1. With this configuration, the continuous operation of the compressor 1 can be restricted regardless of the building load. Since the time during which the compressor 1 can be operated continuously is limited, the user is motivated to request a specialist for a safety check. As described above, as the second step, the maximum operating capacity of the air conditioner after a predetermined period (for example, one year) has passed without the safety check being performed after the actual use period has passed the standard use period. Measures are taken to reduce or limit the continuous operation of the compressor 1.

  Next, the third step after the actual usage period has passed the standard usage period will be described. The safety check is not performed even during the period in which the above-mentioned second step is taken, and the user continues to use (operate) in a state where the maximum capacity is reduced or continuous operation is restricted, When the actual use period has passed the standard use period, for example, 5 years have passed, the operation of the compressor 1 is prohibited, giving priority to avoiding accidents due to deterioration over time and ensuring the safety of users. Take measures to The operation of not only the compressor 1 but also the indoor fan 9 and the outdoor fan 10 is prohibited. Measures are taken to prohibit driving in all driving modes. However, even in such an operation-prohibited state, the progress display unit 36 indicating that the actual use period has passed the standard use period (such as lighting or blinking) is continuously displayed.

  Thus, as a third step, after the actual use period has passed the standard use period, a measure for prohibiting the operation of the compressor 1 after a predetermined period (for example, 5 years) has passed without a safety check being performed. Take. In addition, as the second step, the maximum operating capacity and the restriction on the continuous operation of the compressor described above are not taken, and the actual use period is a predetermined period after the standard use period has elapsed (the progress display unit 36 is displayed). In other words, the compressor 1 may be configured so that the operation prohibition of the compressor 1 is suddenly taken.

  The display of the progress display section 36 during the period when the driving prohibition measure, which is the third step, is performed, regardless of the operation of the user's remote control 25. For this reason, the user can grasp the reason why the air conditioner cannot be operated by referring to the instruction manual from the display of the progress display section 36 and the description contents of the notation section 34. Then, according to the instruction manual, if you want to continue using this air conditioner, request a safety check from a specialist such as the service department of the manufacturer. The third step, the operation prohibition measure, is to prevent accidents and ensure the safety of the user. For users who wish to continue using it, the motivation to request a safety check from a specialist is required. Produces a spurious effect.

  FIG. 9 shows the flow of the operation of the progress display unit 36 with respect to the period of use, the maximum operating speed of the compressor 1 and the maximum operating current of the air conditioner when the second step is a measure for reducing the maximum operating capacity. It is explanatory drawing shown. The progress display unit 36 in FIG. 9 is an example in which the LED is turned on when the actual use period exceeds the standard use period. The values in parentheses are setting examples of the air conditioner in this embodiment. Although the maximum operating current is reduced to 1 A from the execution of the three steps, this current is mainly used for the display of the progress display unit 36. The set value of the maximum operating current may be lowered to 1A. However, since the operation of the compressor 1 is actually prohibited at this time and no large power is required, the set value of the maximum operating current is the second. It may be 12A that has been lowered in steps.

  Next, the setting of the standard usage period will be described. As described above, in the air conditioner of this embodiment, the standard use period is set to 13 years. When the actual use period has passed the standard use period, the user needs to undergo a safety check by a specialist so that the user can continue to use it safely. Then, the user pays the cost for the safety inspection to a specialist (for example, a service department of the manufacturer) who has performed the inspection. For this reason, the standard use period should be set to a period in which the user can be satisfied with the safety inspection.

  For this reason, there is a standard usage period that the user can convince, and within that period, the manufacturer needs to design and manufacture the equipment so that the safety of the equipment is maintained. Therefore, the standard usage period that the user can convince is preferably selected based on the result of the investigation of the expected life of the product of the user and the relationship between the usage period of the device (product) and the market remaining rate. FIG. 10 is a graph showing a usage period of a home air conditioner (room air conditioner) intended to be used at home in the air conditioner and a remaining rate in the market.

  The life expected by the user for household electrical appliances (hereinafter, this life is called the expected life) is based on the survey results of each device, and the residual rate in the market for most products is approximately 50. Aggregated in the period from 20% to 20%. If the expected life of the user is set as the standard usage period, the user can be satisfied with the standard usage period. Therefore, the standard usage period is a guideline that many users can convince of the longest usage period in the usage period (expected life range) corresponding to the range of 50% to 20%. It becomes.

  The graph of FIG. 10 is a result of investigating the usage period of the home air conditioner (room air conditioner) and the market remaining rate for each usage period. In the case of a home air conditioner, as shown in the graph of FIG. The remaining rate gradually decreases with each use period, but starts to decrease rapidly from around 7 years. The product continues to exist in the market from the first use to around 21 years. In the case of an air conditioner for home use, there is a relationship between the period of use and the market remaining rate as shown in FIG.

  It can be seen that the usage period corresponding to the range of 50% to 20% in the figure, that is, the expected life of the user for the room air conditioner is about 10 to 13 years. Therefore, the standard use period of the room air conditioner should be set to the longest expected life in the user's expected life range, in other words, the use period of 13 years, which is a market remaining rate of 20%, or longer. Therefore, it becomes an appropriate standard usage period that many users can convince.

  If the standard usage period is set in this way, it will be a period in which the user will have a validity for receiving a safety check, and users and specialists (such as the service department of the manufacturer) ) Is less likely to cause problems, is efficient in operation, and has the effect of increasing the user's awareness of actively undergoing safety inspections. The manufacturer must design and manufacture the product so that the safety of the product can be maintained within the standard use period thus set.

  The expected life of the user is closely related to the market survival rate, that is, the expected lifetime can be replaced with the market survival rate. Therefore, if the period of use that provides the predetermined market survival rate of the device is used as a guideline for setting the standard period of use, an appropriate setting that the user can convince is possible. If it is selected and set from the usage period in which the market remaining rate is within a predetermined range (50% to 20% in the above case), the standard usage period reflecting the expected life of the user can be obtained. In addition, if the period of the lowest market presence rate (20% in the above case) in the predetermined range or a period longer than that period is used as a standard for setting the standard usage period, many users A standard period of use can be established that will satisfy the safety inspection after the elapse of time.

  In the air conditioner of this embodiment, as one of the methods for grasping the actual use transition period, the indoor side control device 12 or the outdoor side control device 14 stops the operation of the air conditioner after starting the operation for the first time. It is configured to keep track of the timer during the operation, but it is configured to estimate the actual usage time from this operation accumulated time by operating only during operation and integrating only the operation time. May be. In this configuration, when the standard use period is 13 years, for example, the operation time of the air conditioner for one day is assumed to be 8 hours, the use period for one year is 250 days, and the accumulated operation time is 26,000 hours (8 hours). * 250 days * 13 years = 26,000 hours), it is determined that the standard usage period has passed.

  By configuring in this way, the accuracy of counting the actual usage period is reduced (for example, a time significantly shorter than the accumulated operation time corresponding to the standard usage period assumed by the manufacturer and programmed in the control device by the manufacturer) However, since the timer of the indoor side control device 12 or the outdoor side control device 14 can be stopped while the air conditioner is stopped, the standby power of the air conditioner is reduced. There is an effect that can be made.

  FIG. 11 shows the flow of the operation of the progress display unit 36 with respect to the accumulated operation time, the maximum operation speed of the compressor 1 and the maximum operation current of the air conditioner in the case of the configuration in which the actual use period is estimated by integrating the operation time. It is explanatory drawing which shows. This is opposite to the case of directly grasping the actual use period in FIG. 9, and the values in () are setting examples of this embodiment. Although the period of the first step in FIG. 9 is one year, this period is also estimated from the accumulated operation time, and is set to 8 hours * 250 days = 2,000 hours corresponding to the assumption. After the accumulated operating time corresponding to the standard usage period has elapsed, the time when the third step starts is 8 hours * 250 days = 10,000 hours compared to 5 years in FIG. It ’s time to start.

  It should be noted that after the accumulated operation time corresponding to the standard use period has elapsed, the timer may be reset and newly accumulated operation time as shown in FIG. 11, but the accumulation of the timer may be continued and accumulated. Good. That is, the second step is started when the accumulated time of the timer reaches 28,000 hours, and the third step is started when 36,000 hours are reached.

  In the air conditioner of this embodiment, the progress display unit 36 indicating that the standard use period has elapsed is provided in the main body of the indoor unit 100. However, the progress display unit 36 may be provided in the remote controller 25. You may provide in both 100 main body and the remote control 25. FIG. When the progress display unit 36 is provided in the remote controller 25, it may be displayed on the display screen 27. If the display of the progress display unit 36 is displayed on the display screen 27 of the remote controller 25, there is an effect that the user can easily notice when operating the remote controller 25.

  In addition, if a lamp such as an LED is used for the progress display unit 36 and displayed by lighting or blinking, the manufacturing cost can be reduced, but the color of the lamp is recognized by the user, such as red or orange. Colors that are easy to use and feel warning are desirable. Further, the progress state in the progress display section 36 may be displayed by color. For example, the display when the standard usage period is approaching soon is displayed with a green or blue lamp, and when the standard usage period has passed, the display is switched to a display with a red or orange lamp. The fact that the standard usage period has passed may be displayed directly on the liquid crystal using a text or a figure. These have the effect of emphasizing user alerts.

  In addition, a voice guidance function may be installed so as to notify that the standard usage period has elapsed using voice or warning sound. The voice or warning sound is configured to be emitted for a predetermined time when the user operates the air conditioner after the standard use period has elapsed, or to be generated at predetermined intervals during the operation. Notification by voice or warning sound may be used in combination with a visual display such as a lamp, and has the effect of further enhancing the user's alert.

  In the air conditioner according to this embodiment, the HFC refrigerant R410A that is most frequently used in current home air conditioners is used as the refrigerant circulating in the refrigeration cycle. However, the refrigerant is not limited to this. Instead, the present invention can also be applied to an air conditioner using other refrigerants, for example, carbon dioxide which is not flammable or toxic and has high safety. In particular, in the case of flammable refrigerants, such as HFC-based R32 refrigerants and hydrocarbon-based natural refrigerants (propane, isobutane, etc.), ignition from components of the air conditioner may be an ignition source. Therefore, sufficient attention is required for ignition of parts due to aging, and the present invention is particularly effective for an air conditioner using a flammable refrigerant.

Further, as the air conditioner of this embodiment, the indoor side control device 12 is mainly responsible for grasping and resetting the actual use period, and the control for displaying the progress display section 36 and the progress status display means 38. However, the outdoor control device 14 may be implemented, or the two control devices 12 and 14 may share the roles.
Embodiment 2. FIG.

  In the air conditioning apparatus of the first embodiment described above, as a safety management method after the actual use period has passed the standard use period, a specialist (for example, a service department designated by the manufacturer) at the request of the user. However, in this second embodiment, as a safety management method after the actual use period has passed the standard use period, the user shall carry out a safety check by himself / herself. This will be described below. Except for the safety check, everything is the same as in the first embodiment, and the description other than the safety check is omitted.

  When a user requests the manufacturer or a service department designated by the manufacturer to perform a safety check under his / her own responsibility (the user's own responsibility), the manufacturer or service that received the request The department sends to the user an application form for applying for continued use by the user at their own risk. The manufacturer or service department accepts the application form entered by the user and sends a safety confirmation sheet for the air conditioner. Further, a method of resetting the count of the actual usage period in order to hide or reset the progress display unit 36 and the progress status display unit 38 (for example, operation of the remote controller 25 for resetting a timer for calculating the usage period). Contact the user. The count reset notification of the actual use period from the manufacturer or service department may be made after the user has notified the manufacturer or service department of the result of the confirmation table.

  In the safety confirmation table, the power plug 22 is not discolored, the power plug 22 is not loosely fitted with the outlet, and the drainage path of the condensed water is not clogged or leaked. There are no rust holes or corrosion on the outer parts of the outdoor unit 200, the fixing of the indoor unit 100 and the outdoor unit 200 is stable (fixed strength is maintained), or the burning smell during operation of the air conditioner It is advisable to include confirmation items such as whether there is an off-flavor, abnormal sound or vibration.

  In addition, on the application form for continuous use, the air conditioner model name, place of use (address of the place of installation, etc.), user name, user contact information (address, telephone number, e-mail address, etc.) are provided. Establish and have them listed. This enables manufacturers to provide users with information related to the safety of air conditioners that are in continuous use, either directly or through the service department, based on their contact information. It is possible to alert the user to the safety of long-term use.

  In the first and second embodiments, the air conditioner has been described as an example. However, the present invention is not limited to the air conditioner. Even when applied to other household electrical appliances using a refrigeration cycle in which the refrigerant is compressed by a compressor and circulated, the same effect as the effect on the air conditioner can be obtained. As other household electrical appliances using a refrigeration cycle, it can be applied to refrigerators, dehumidifiers, heat pump hot water supply devices, and the like. In the case of a hot water supply apparatus, since both the heat source unit and the water storage tank are arranged outdoors, the notation unit 34 is provided on the operation panel installed indoors, or the notation unit 34 is pasted on the wall surface in the vicinity of the operation panel, etc. It may be provided so as to be fixed. The progress display unit 36 may be provided on the operation panel.

  The air conditioner can also be applied to a so-called multi-air conditioner in which two or more indoor units are connected to one outdoor unit. In that case, the notation unit 34 is provided in each indoor unit. A progress display unit 36 is provided. Moreover, it is not a separate type separated into the indoor unit 100 and the outdoor unit 200 as in the above-described embodiment, but an integrated type in which a condenser and an evaporator are housed in one housing, for example, installed in a window. Even a window air conditioner can be applied.

  In addition, regarding the decrease in the maximum operating capacity in the second step or the restriction on the continuous operation of the compressor, the air conditioner used the current and discharge temperature as the operation control factor and the operating factor of the protection means. What is necessary is just to make it lower the setting value of the operation control factor corresponding to an apparatus, and the operation factor of a protection means. If the compressor of the refrigeration cycle, including the air conditioner, is a constant speed machine that does not support variable speed, and the equipment operates the driving ability by turning on and off the constant speed compressor, the second step is The maximum operating capacity may be reduced by controlling the compressor on time, that is, the operating time.

  In addition to household electrical appliances, equipment that can be applied to commercial equipment using a refrigeration cycle, such as packaged air conditioners (commercial air conditioners), commercial refrigeration equipment, showcases, vending machines, etc. Safety for long-term use can be ensured and alerts to users can be made.

  In addition, the present invention can be applied to other household electrical appliances that do not use a refrigeration cycle, can ensure safety in long-term use of the device, and can alert the user. For example, in the case of a television, the display of the progress display unit 36 may be configured to be expressed by means corresponding to the function and design of the device, such as the progress display unit 36 configured on the screen. As for the measures for reducing the maximum capacity in the second step, since the compressor is not provided, means for reducing the compressor rotational speed cannot be applied. If it is a machine, the number of revolutions during dehydration may be reduced, or means suitable for the equipment may be applied. The third driving prohibition measure may be appropriately used as long as the device cannot be operated even if the device is operated.

It is a block diagram of the refrigerant circuit etc. of the air conditioning apparatus in Embodiment 1 of this invention. In the block diagram of FIG. 1, it is a figure which shows the flow direction of the refrigerant | coolant at the time of air_conditionaing | cooling operation or dehumidification operation | movement of the air conditioning apparatus in Embodiment 1 of this invention. In the block diagram of FIG. 1, it is a figure which shows the flow direction of the refrigerant | coolant at the time of the heating operation of the air conditioning apparatus in Embodiment 1 of this invention. It is a perspective view which shows the indoor unit 100 of the air conditioning apparatus in Embodiment 1 of this invention. It is a figure which shows the example of a description of the description part 34 of this invention. It is a figure which shows an example of the progress display part 36 of this invention. It is a perspective view which shows the indoor unit 101 of the air conditioning apparatus by the other Example in Embodiment 1 of this invention. It is a figure which shows the remote control 25 of the air conditioning apparatus in Embodiment 1 of this invention. It is explanatory drawing which shows the flow of the operation | movement of the progress display part 36 with respect to the use period of the air conditioning apparatus in Embodiment 1 of this invention, the driving | operation maximum rotation speed of the compressor 1, and the driving | operation maximum electric current of an air conditioning apparatus. It is a figure which shows the relationship between the use period of a household air conditioner, a market residual rate, and a user's expected lifetime. Explanatory drawing which shows the operation | movement of the progress display part 36 with respect to the driving | running integration time of the air conditioning apparatus by Embodiment of this invention 1 in another Example, the driving | operation maximum rotation speed of the compressor 1, and the flow of the driving | operation maximum current of an air conditioning apparatus. It is.

  DESCRIPTION OF SYMBOLS 1 Compressor, 2 discharge piping, 3 suction piping, 4 accumulator, 5 refrigerant | coolant flow path switching valve (four-way valve), 6 indoor heat exchanger, 7 decompression device (expansion valve), 8 outdoor heat exchanger, 9 indoor fan, DESCRIPTION OF SYMBOLS 10 Outdoor fan, 11a Indoor / outdoor connection piping (liquid side), 11b Indoor / outdoor connection piping (gas side), 12 Indoor control device, 13 Indoor fan drive device, 14 Outdoor control device, 15 Compressor drive device (inverter device) ), 16 outdoor fan drive device, 17 discharge temperature thermistor, 18 room temperature thermistor, 19 defrost detection thermistor, 20 indoor tube temperature thermistor, 21 outdoor tube temperature thermistor, 22 power plug, 23 body operation button, 24 remote control receiver, 25 External operation device (remote control), 26 Remote control transmission unit, 27 Remote control display screen, 28 Remote control operation button, 28a MOCON operation button, 28b Operation mode switching button, 29 Indoor / outdoor communication cable, 30 Housing, 31 Front panel, 32 Air inlet, 33 Air outlet, 34 Notation part, 35 Operation lamp, 36 Progress display part, 37 Standard usage period expression Line, 38 progress display means, 100 indoor unit, 101 indoor unit, 200 outdoor unit.

Claims (5)

An air conditioner using a refrigeration cycle in which a refrigerant is circulated by a compressor,
Indoor units installed indoors;
A remote control that is an external operation device capable of instructing operation start and stop of the air conditioner ;
Provided in the main body of the indoor unit, and a representation unit for representation standard use period of the air conditioner,
A progress display unit provided in the remote control and informing that the actual use period has passed the standard use period after the actual use period of the air conditioner has passed the standard use period;
An air conditioner comprising: The remote control has a display screen to display with a liquid crystal,
The air conditioner according to claim 1, wherein the progress display unit displays on the display screen of the remote controller that the actual use period has passed the standard use period . An air conditioner using a refrigeration cycle in which a refrigerant is circulated by a compressor,
Indoor units installed indoors;
Provided in the main body of this indoor unit, a notation section that indicates the standard use period of the air conditioner,
Before a predetermined time period in which the actual use period expires a standard period of use of the air conditioner, and a progress display unit informing that the actual use period soon passed the standard use period,
An air conditioner comprising: An air conditioner using a refrigeration cycle in which a refrigerant is circulated by a compressor,
Indoor units installed indoors;
Provided in the main body of this indoor unit, a notation section that indicates the standard use period of the air conditioner,
Provided in this notation, the user or installer of the air conditioner can enter the use start date or use start date of the air conditioner,
An air conditioner comprising: An air conditioner using a refrigeration cycle in which a refrigerant is circulated by a compressor,
Indoor units installed indoors;
Provided in the main body of this indoor unit, a notation section that indicates the standard use period of the air conditioner,
A space provided near the notation, where the user or installer of the air conditioner can paste a seal on which the date of use or date of use of the air conditioner is written, and
An air conditioner comprising:

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