JPH0719585A - Indicating device of humidity of air conditioner - Google Patents

Abstract

PURPOSE:To make indication of humidity unvaried for a prescribed time after a defrosting operation and to leave off indicating a detected value of a humidity sensor which shows an error from indoor humidity on the occasion of the defrosting operation. CONSTITUTION:In order to make indication of humidity by a humidity indicating means unvaried during a defrosting operation and until a prescribed waiting time T passes after completion of the defrosting operation in an air conditioner wherein a humidity sensor 1 is provided in the vicinity of an inlet of a cabinet, the waiting time T is set beforehand in a control means 17, in a first way, or the waiting time T at a time point just after the completion of the defrosting operation is calculated on the basis of a detected value of the humidity sensor 1 at the time point, in a second way. In a third way, the calculated waiting time Tn is stored E<2>PROM 25 sequentially and, with the average value of the current time value Tn and the past time values T1, T2... Tn-1 used as the waiting time T, the time for which the indication of humidity is fixed is set.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a humidity display device for displaying indoor humidity during operation in an air conditioner such as a dehumidifier having a humidity sensor and an air conditioner having a dehumidifying function.

[0002]

2. Description of the Related Art Generally, an air conditioner of this type is provided with a cooler (evaporator) arranged in an air passage in a body, such as a dehumidifier disclosed in Japanese Utility Model Laid-Open No. 2-137633. )
The indoor air is dehumidified by cooling and dehumidifying the indoor air by repeating the cycle of reheating the air by the condenser arranged behind the cooler and returning it to the room.

FIG. 6 shows an example of a concrete structure of a general dehumidifier which is structured and operates as described above. In the dehumidifier shown in this figure, a suction port 2 is formed on the front surface of the upper half of the cabinet 1 that constitutes the outer shell of the machine body.
The cooler 3 and the condenser 4 are arranged in that order in the rear of the.

A fan motor 5 is provided behind the condenser 4.
Is arranged, and a fan 6 is interlockingly connected to the fan motor 5. Further, an outlet 7 is formed in the upper rear part of the cabinet 1, and by driving the fan 6, the indoor air sucked from the inlet 2 on the front of the cabinet passes through the cooler 3 and the condenser 4, The air is blown out from the air outlet 7 into the room.

A dew tray 8 and a drain tank 9 are provided in the lower half of the cabinet 1. The dew tray 8 collects condensed water generated by the cooling and dehumidifying of the cooler 3, and is arranged in a portion below the cooler 3, the condenser 4 and the fan 6. The drainage tank 9 is detachably attached to the cabinet 1 below the drain port 8a formed at the lowest portion of the dew tray 8 toward the front side. The condensed water generated by the cooler 3 is collected by the dew tray 8 and stored in the drainage tank 9 through the drain port 8a.

FIG. 7 shows a structure of a cooling cycle in the dehumidifier having the above structure. In this figure, 10 is a compressor for compressing a refrigerant gas, which is arranged behind a drainage tank installation site in a cabinet (FIG. 6).
reference). Further, 11 is a dryer and 12 is a capillary tube, and the dryer 11 and the capillary tube 12 are provided in this order in the refrigerant gas flow path between the condenser 4 and the cooler 3. Thirteen
Is a solenoid valve that switches the flow path of the refrigerant gas.

During the dehumidifying operation, the solenoid valve 13 is switched to the pipe side connected to the condenser 4, and the refrigerant circulates in the flow path indicated by the solid arrow. In this case, the refrigerant gas compressed by the compressor 10 radiates heat in the condenser 4 to be condensed and becomes a high temperature and high pressure liquid. The liquid refrigerant is dried by the dryer 11 and then depressurized by the capillary tube 12,
The cooler 3 absorbs heat and vaporizes the cooler 3 itself.

The mixed refrigerant, which has been vaporized in the cooler 3 into the low-temperature refrigerant gas and the refrigerant liquid, is further completely vaporized in the piping of the cooling cycle to become the refrigerant gas, which is sucked into the compressor 10. A circulating cooling cycle system is formed.

In this cooling cycle system, the room air sucked from the suction port 3 by the fan 6 is cooled and dehumidified by the cooler 3 and, at this time, the room air is cooled to be contained in the air. Once the water becomes dehumidified water,
After adhering to the cooler 3 itself, water is collected by the dew tray 8 as described above, and further dripped into the drainage tank 9 through the drain port 8a and stored. On the other hand, the air that has been cooled and dehumidified is stored in the condenser 4
Is heated by and is discharged into the room from the outlet 7.

By the way, when the dehumidifying operation is performed at a low room temperature, the temperature of the cooler 3 drops to below the freezing point and frost adheres to the air, which interrupts the flow of air and makes the dehumidifying operation thereafter impossible. Become. In such a case, the temperature of the cooler 3 detected by the temperature sensor 14 installed in the cooler 3 in the control means (not shown) constituted by a microcomputer and the control means provided in the control means. A timer is used to determine the frosted state on the cooler 3 and switch to defrosting operation.

That is, when the control means determines that the dehumidifying operation cannot be continued, the electromagnetic valve 13 is energized to switch the refrigerant flow path in the direction indicated by the broken line arrow. As a result, the refrigerant gas that has been compressed by the compressor 10 and has become hot gas directly flows to the cooler 3, raising the temperature of the cooler 3 and performing defrosting. The control means stops the fan motor 5 during the defrosting operation.

In the air conditioner having the dehumidifying operation function as described above, a humidity display device for displaying the indoor humidity during operation has been conventionally provided. That is, in the conventional humidity display device, a humidity sensor 15 for detecting the indoor temperature is provided in a portion of the cabinet where accurate indoor humidity can be detected, in the vicinity of the rear of the suction port 2 in this example, and , The upper cabinet 1 which is a separate member from the main body of the cabinet 1.
The humidity display means 16 for displaying the indoor humidity is provided in a.

The indoor humidity detected by the humidity sensor 15 is input to the control means, and the control means compares the detected humidity with a preset proper humidity (for example, 60%) to detect the detected humidity. In addition to controlling the dehumidifying operation so as to approach the set humidity, the indoor humidity at that time is displayed by controlling the power supply to the lamp provided in the humidity display means 16.

[0014]

However, the conventional humidity display device described above has a problem in that the indoor humidity cannot be accurately displayed during the defrosting operation. That is, during the defrosting operation, the cooler 3 is heated by the hot gas sent from the compressor 10 and the temperature rises, and the frost attached to the cooler 3 evaporates, and the fan motor Since 5 is stopped, the flow of air in the cabinet is delayed.

Therefore, the temperature and relative humidity inside the cabinet near the suction port 2 where the humidity sensor 15 is installed rises, and the humidity detected by the humidity sensor 15 is necessarily higher than the indoor humidity outside the cabinet. It will show a high value. Therefore, during the defrosting operation, the humidity display section on the upper cabinet 1a does not display accurate indoor humidity.

The present invention has been made in order to solve the above problems, and provides an accurate indoor humidity display not only during dehumidifying operation but also during defrosting operation as in dehumidifying operation. It is an object to provide a humidity display device for an air conditioner that can be operated.

[0017]

In order to achieve the above object, in the first configuration of the present invention, a humidity sensor for detecting indoor humidity and a humidity value detected by the humidity sensor are constantly provided during dehumidifying operation. A humidity display means for displaying and a display control means for not changing the humidity display by the humidity display means during the defrosting operation and after a predetermined waiting time elapses after the defrosting operation is completed are provided.

Further, in order to make the fixed time not the set value as described above but the time value according to the actual situation, in the second configuration of the present invention, the display control means is operated during the defrosting operation and The dehumidifying operation has a function of not changing the humidity display by the humidity display means until a certain waiting time elapses, and further, based on the detection value of the humidity sensor immediately after the defrosting operation ends, the waiting time at that time A waiting time calculating means for calculating time is added.

Further, in order to make the fixed time into a time value more suitable for the actual situation, in the third structure of the present invention, a waiting time provisional calculation means having the same structure as the waiting time calculation means is provided, and In addition to this, storage means and waiting time execution value calculation means are provided.

The storage means successively stores the time values temporarily calculated by the waiting time temporary calculation means, and is composed of a rewritable memory that does not require a backup power source. Also,
The waiting time execution value calculation means is an average value of the current time value tentatively calculated by the waiting time tentative calculation means and the time value tentatively calculated by the waiting time tentative calculation means in the past and stored in the storage means. The execution value of the waiting time is calculated according to.

In the above structure, the storage means may be specifically composed of any one of an E ² PROM, a flash memory and a non-volatile rewritable memory.

[0022]

According to the first configuration of the present invention described above, during the defrosting operation and after completion of the defrosting operation, the information of the humidity sensor detecting the indoor humidity is not input for a preset constant time,
The humidity display of the humidity display means holds the value before the defrosting operation.
That is, during the defrosting operation and for a while after the end of the operation, the relative humidity near the site where the humidity sensor is installed rises, and the humidity sensor cannot detect the accurate indoor humidity.

However, the room humidity during that time is usually
This is considered to be close to the detection value of the humidity sensor immediately before the defrosting operation. Therefore, the humidity display during the above period related to the defrosting operation is maintained without changing the value immediately before the defrosting operation, and is returned to the humidity display based on the humidity sensor input until a certain time elapses after the defrosting operation ends. I try not to.

According to the second aspect of the present invention described above, the waiting time calculating means does not preset a fixed time after the defrosting operation is finished, but the waiting time calculation means detects the detected value of the humidity sensor immediately after the defrosting operation is finished. Since the calculation is performed based on the above, it is possible to calculate the accurate time after each defrosting operation until the humidity can be displayed based on the humidity sensor input, based on the indoor humidity at that time.

According to the third aspect of the present invention, the time value calculated by the operation equivalent to the waiting time calculation means is not used as it is, but is integrated with the past time value stored in the storage means. Since the average value is the execution value for a fixed time,
Furthermore, the accurate time can be calculated according to the actual situation, and the accuracy of the humidity display is further improved.

[0026]

Embodiments of the present invention will be described below with reference to the drawings. Note that the mechanical configurations of the dehumidifiers targeted by the following first to third examples are basically the same as those shown in FIG. 6 above, and the configuration of the cooling cycle thereof is also the above. Since these are the same as those shown in FIG. 7, these figures are shared by the respective embodiments, and the portions having the same configuration and operation are designated by the common reference numerals and their description is omitted to avoid duplication. .

FIG. 1 shows a dehumidifier control system common to the first to third embodiments. In this figure, reference numeral 17 is a control means composed of a microcomputer, which controls the entire operation including dehumidifying operation and defrosting operation of the dehumidifier, and stores the CPU 18 which is the control center thereof and a control program. It is provided with a ROM 19 and a RAM 20 for storing necessary data at the time of calculation.

Further, the detection data of the temperature sensor 14 and the humidity sensor 15 are input to the CPU 18 via the I / O port 21. Further, the CPU 18, based on these sensor inputs, the humidity display means 16, the compressor driving means 22,
The outputs of the solenoid valve driving means 23 and the fan motor driving means 24 are controlled. Reference numeral 25 is an E ² PROM as a storage means incorporated in the control means 17 in the third embodiment,
It is not added to the control means 17 in the first and second embodiments.

(First Embodiment) FIG. 2 shows a flow chart of the control means 17 in the first embodiment. In this embodiment, when the operation of the dehumidifier is started, the indoor humidity detection data of the humidity sensor 15 is read in step # 10, and the humidity state corresponding to the data is displayed on the humidity display means 16 in step # 20.

As a lamp used for this display, for example, a plurality of LEDs are used, and by arranging the LEDs in the upper cabinet 1a, for example, suitable humidity, a little increase,
It is displayed in three stages of higher convenience. In this case, it can be said that suitable humidity is suitable because the detected humidity is 60% or less, a little higher is 60 to 70%, and a higher is 70% or more because it is suitable for many people's feelings.

When the input humidity detected by the humidity sensor 15 exceeds the optimum humidity range, that is, 60%, the compressor 10 is connected via the compressor driving means 22 and the fan motor driving means 24 in step # 30. Dehumidifying operation is performed by operating the fan motor 5. When the humidity is appropriate, that is, 60% or less, the compressor 10 and the fan motor 5 are stopped via the driving means 22 and 24, and the dehumidifying operation is completed.

As described above, during the dehumidifying operation, the humidity sensor 15 is constantly input, the humidity display means 16 displays the humidity based on the detection data of the sensor 15, and the compressor 10 and the fan motor 5 are turned on. Control OFF.

Next, the dehumidifying operation is performed at a low room temperature,
If the cooler 3 is highly likely to be frosted, the frosted state on the cooler 3 is determined in step # 40. In this case, whether or not to perform the defrosting operation is determined as follows.

That is, the temperature detection data of the cooler 3 detected by the temperature sensor 14 is read, the cooler temperature is a preset constant temperature, for example, 1 ° C. or less, and the compressor 10 operates. The CPU 18 integrates the remaining time by a counter configured as software, and when the integrated time reaches a set time, for example, 30 minutes, the defrosting operation is performed. This means that the room temperature during the dehumidification operation is kept at a low temperature until the set time is reached, and it is determined that the frost formation reaches the allowable limit.

If the room temperature exceeds 1 ° C. during the counting, the process returns to step # 10 and the dehumidifying operation is continued until the humidity becomes appropriate. Therefore,
When entering the defrosting operation, the compressor 10 is in an operating state.

When the defrosting operation is started, step # 50
The solenoid valve 13 is operated and the fan motor 5 is stopped. At this time, since the compressor 10 is operating as described above, the refrigerant gas that has been compressed by the compressor 10 and becomes hot gas flows in the direction indicated by the broken line in FIG. The frost that has risen and adhered to the cooler 3 is removed.

Whether or not the defrosting has been completed is determined based on the temperature of the cooler 3 (step # 60). That is, the temperature detected by the temperature sensor 14 is a preset temperature,
For example, when the temperature becomes 10 ° C. or higher, it is determined that all the frost adhering to the cooler 3 has been removed, and the defrosting operation ends. After the defrosting operation is completed, the solenoid valve 13 is stopped and the fan motor 5 is operated in step # 70.

In this embodiment, the humidity sensor 1 is operated during the defrosting operation.
5 is not input, the humidity display on the humidity display means 16 is not changed, and the display before the defrosting operation is started is held. Furthermore, after the defrosting operation is completed, a preset waiting time T
After waiting for a while, the reading operation of the humidity sensor input is restored.

By doing so, the temperature near the humidity sensor 15 increased by the defrosting operation is lowered, and thereby the relative humidity near the sensor 15 is waited until it is substantially equal to the indoor humidity. . as a result,
Humidity data immediately before the defrosting operation is displayed on the humidity display means 16 from the start of the defrosting operation to the end of the defrosting operation and the elapse of the waiting time T, and thereafter, the humidity based on the detection data of the humidity sensor 15 again. Is displayed, it is possible to avoid performing a humidity display that is significantly different from the actual indoor humidity.

(Second Embodiment) In the second embodiment of the present invention,
The operation shown in FIG. 3 is added to the flowchart showing the operation of the control means in the first embodiment shown in FIG. That is, in the present embodiment, the waiting time T is not a preset time, but the waiting time T at that time is calculated based on the detection value of the humidity sensor 15 immediately after the defrosting operation is completed.

FIG. 4 shows the humidity difference around the humidity sensor 15 at the start and end of the defrosting operation. Assuming that the humidity detected by the humidity sensor 15 at the start of the defrosting operation is d1 and the humidity detected at the end of the defrosting operation is d2, the temperature around the humidity sensor 15 increases due to the defrosting operation, as shown in FIG. Humidity also rises and the humidity sensor 15
The detected humidity of 1 also greatly increases from d1 to d2. After the defrosting operation is completed, the relative humidity is lowered until it matches the indoor humidity.

It has been found that the rise and fall of the humidity near the humidity sensor 15 both change linearly.
Therefore, assuming that the humidity change after Δt time after the defrosting is Δd, the time T until the humidity detected by the humidity sensor 15 returns to the humidity at the start of the defrosting can be calculated by an equation. T = (d2-d1) × (Δt / Δd) ……………… Formula

In this embodiment, in step # 80, the waiting time T is determined using the calculated value obtained by the above equation. By doing so, it is possible to more accurately determine the waiting time T until the detection data of the sensor 15 that changes due to the temperature increase in the vicinity of the humidity sensor 15 due to the defrosting operation correctly detects the actual indoor humidity. .

(Third Embodiment) In the third embodiment of the present invention,
The operation shown in FIG. 5 is added to the flowchart showing the operation of the control means in the first embodiment shown in FIG. 2, and the waiting time T is calculated as follows. That is, in step # 85, the waiting time T _n after the end of the current defrosting operation is calculated by using the formula in the second embodiment, and the time value T _n is set as a temporary value to the E ² PROM 25.
To memorize.

Then, in step # 90, the time values T ₁ , T _2, ... Calculated by the same calculation method after the past defrosting operation.
... T _n-1 is read from the E ² PROM 25, and the time value T _n calculated this time is applied to an equation to calculate the execution value T of this time. T = (T ₁ + T ₂ + …… + T _n ) / n ………………………… Formula

This execution value T is, as is clear from the equation,
Time values T ₁ , T ₂ from the past to this time calculated by the formula
Since it is the average value of T _n , the fluctuation of the calculated value due to the use environment is averaged, and the accuracy of the waiting time T is further improved.

_If the data of past time values T ₁ , T _2, ..., T _n are stored in the RAM 20, they are erased when the power is turned off. Therefore, in this embodiment, the E ² PROM ^{2 is} used.
5 is used. In addition, when the average value is used as the waiting time T as described above, for example, when the indoor temperature greatly changes due to the influence of the external temperature during the defrosting operation,
Amount of change Δ in humidity detected by the humidity sensor 15 after the defrosting operation ends
Even if d becomes extremely small, the waiting time T can be prevented from becoming unnecessarily long.

That is, when an unnecessarily long waiting time T is set, for example, when the dehumidifying operation is finished and the humidity is returned to the humidity at the start of the defrosting operation, the external humidity rises during defrosting. In some cases, the humidity may not return to the level when the defrosting operation is started, and in such a case, the waiting time T is wasted. By adopting the average value as in the present embodiment, such a demerit can be eliminated.

Although the E ² PROM 25 is used as the storage means in the third embodiment, the same function can be achieved by other flash memory or non-volatile rewritable memory.

[0050]

As described above, according to the present invention, the display control means which does not change the humidity display by the humidity display means during the defrosting operation and after the completion of the defrosting operation and until a predetermined waiting time has elapsed. By providing, the humidity display should not be changed while the humidity detected by the humidity sensor is different from the indoor humidity during the defrosting operation, that is, while there is an error that cannot be ignored in the detected value of the humidity sensor. Since it is set, the inaccurate humidity display can be eliminated.

According to claim 2, the humidity change after the defrosting operation is completed by adding the waiting time calculating means for calculating the waiting time at that time based on the detection value of the humidity sensor immediately after the defrosting operation is completed. Since the waiting time is calculated from, the waiting time is appropriate according to the usage environment.

According to claim 3, the storage means constituted by a rewritable memory that does not require a backup power source, and the current time value temporarily calculated by the temporary calculation means having substantially the same function as the waiting time calculation means, Since the execution value of the waiting time is calculated by an average value with the time value temporarily calculated by the waiting time temporary calculation means and stored in the storage means in the past, the past waiting time data is stored in the memory. By storing the data, even if the power is turned off, the data will not be erased, and by using the data to average the waiting time, even when the external humidity suddenly changes during defrosting. Can handle.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a control system common to first to third embodiments of the present invention.

FIG. 2 is a flowchart showing the operation of the control system in the first embodiment.

FIG. 3 is a characteristic diagram showing changes in humidity from the start of the defrosting operation to the end of the defrosting operation.

FIG. 4 is a flowchart showing a part of the operation of the control system in the second embodiment.

FIG. 5 is a flowchart showing a part of the operation of the control system in the third embodiment.

FIG. 6 is a schematic cross-sectional view showing a general air conditioner.

FIG. 7 is a configuration diagram schematically showing the cooling cycle.

[Explanation of symbols]

1 Cabinet 1a Upper cabinet 2 Suction port 3 Cooler 4 Condenser 5 Fan motor 6 Fan 7 Air outlet 8 Dew tray 9 Drain tank 10 Compressor 11 Dryer 12 Capillary tube 13 Electromagnetic valve 14 Temperature sensor 15 Humidity sensor 16 Humidity display means 17 Control Means 18 CPU 19 ROM 20 RAM 21 I / O port 22 Compressor drive means 23 Electromagnetic valve drive means 24 Fan motor drive means 25 E ² PROM

Claims (4)

[Claims] 1. A humidity sensor for detecting indoor humidity, a humidity display means for constantly displaying a humidity value detected by the humidity sensor during dehumidification operation, and preset during defrosting operation and after completion of defrosting operation. And a display control unit that does not change the humidity display by the humidity display unit until a predetermined waiting time elapses. 2. A humidity sensor for detecting indoor humidity, a humidity display means for constantly displaying a humidity value detected by the humidity sensor during dehumidifying operation, and a certain waiting time during defrosting operation and after completion of defrosting operation. Display control means that does not change the humidity display by the humidity display means until time passes, and waiting time calculation means that calculates the waiting time at that time based on the detection value of the humidity sensor immediately after the end of the defrosting operation. A humidity display device for an air conditioner, comprising: 3. A humidity sensor for detecting indoor humidity, a humidity display means for constantly displaying a humidity value detected by the humidity sensor during dehumidifying operation, and a certain waiting time during defrosting operation and after completion of defrosting operation. Display control means that does not change the humidity display by the humidity display means until time passes, and temporary calculation of the waiting time at that time based on the detection value of the humidity sensor immediately after the end of the defrosting operation Means, a rewritable memory that does not require a backup power source, and a storage means that sequentially stores the time value temporarily calculated by the waiting time temporary calculation means, and a current time temporarily calculated by the waiting time temporary calculation means. The execution value of the waiting time is calculated by an average value of the time value and the time value that is tentatively calculated by the waiting time tentative calculation unit and stored in the storage unit in the past. Humidity display device of an air conditioner characterized by comprising a latency execution value calculating means for, the. 4. The humidity display device for an air conditioner according to claim 3, wherein the storage means is composed of any one of an E ² PROM, a flash memory and a non-volatile rewritable memory.