JP5315901B2 - Bathroom ventilation dryer - Google Patents

Description

  The present invention relates to a bathroom laundry dryer mainly used for drying laundry in a bathroom in a general household.

  In recent years, there has been an increasing demand for drying laundry indoors due to the increase in the weather, outdoor air pollution, the number of employed housewives, crime prevention problems, and changes in lifestyle, and places where bathrooms are dried indoors. Bathroom ventilating dryers used as a have become widespread.

 Many bathroom ventilation dryers of this type have already been invented, and it is known that the drying state of laundry is detected by relative humidity or absolute humidity in the bathroom and the drying operation is automatically stopped.

A conventional bathroom ventilation dryer 102 will be described with reference to FIG. The bathroom ventilation dryer 102 provided in the bathroom 101 includes a ventilation fan 103, a circulation fan 104, a heat exchanger 105 as a heating means, and a humidity detection means, and the bathroom air that has passed through the heat exchanger 105 by the circulation fan 104 is obtained. Heating and exhausting the water vapor in the bathroom with the ventilation fan 103 dries the laundry suspended in the bathroom. Humidity detection means 106 is provided inside the bathroom, and the humidity detection means 106 detects the humidity in the bathroom 101 and compares it with a reference value to determine the dry state of the laundry 107 (for example, Patent Document 1). reference).
JP 2002-221388 A

  In such a conventional bathroom laundry dryer, it is known that a humidity sensor is used to detect a humidity index such as relative humidity and absolute humidity. Molecular humidity sensors are common. However, bathroom laundry dryers are expected to be exposed to high-temperature and high-humidity environments, such as laundry drying operations by heating and daily bathing activities, and humidity sensors are installed in bathroom laundry dryers. However, there was a problem in terms of durability of the sensor element. Further, the relative humidity is high in the bathroom during the laundry drying operation, and there is a problem that it is difficult to ensure accuracy with the humidity sensor for humidity detection in a high humidity environment.

  The present invention solves such a conventional problem, and does not detect the drying of the laundry based on the humidity index that requires the installation of a humidity sensor whose durability and detection accuracy are problems. The purpose is to improve the durability and detection accuracy of the detection sensor by detecting the drying of the laundry based on a temperature index that can be utilized by a highly reliable temperature sensor in terms of accuracy. Another object of the present invention is to improve the reliability and accuracy of laundry drying detection by improving the durability and detection accuracy of the detection sensor, thereby preventing the laundry from being dried and reducing unnecessary drying operations.

In order to achieve the above object, the present invention provides a ventilation means for discharging the air inside the bathroom, a ventilation means for circulating and blowing the air in the bathroom and blowing the air on the laundry suspended in the bathroom, and A heating means provided in the ventilation path, a first temperature detection means for detecting the temperature of the bathroom, a second temperature detection means for detecting the temperature of the adjacent room that hits the wind on the ventilation path of the bathroom, and the first Control means for controlling the output of the heating means, the output of the blower means and the output of the ventilation means from the detected temperature of the temperature detecting means and the detected temperature of the second temperature detecting means, and detecting the heating output of the heating means. , the output of the heating means is controlled to be constant by the control means, the dry state of the laundry is detected from the temperature difference obtained by subtracting the detected temperature from the temperature detected by the first temperature sensing means a second temperature sensing means , Detection of the first temperature detection means After the temperature difference obtained by subtracting the temperature detected by the second temperature detection means from the temperature of the first-time steady state, that the temperature difference is to stop the operation when it becomes a steady state a second time via the time zone of increasing It is. By this means, general-purpose temperature detection means such as a temperature sensor can be utilized, and the durability and detection accuracy of the detection means can be improved. Further, by automatically stopping the drying operation, the laundry can be prevented from being dried and wasteful drying operations can be reduced.

  Another means is that the second temperature detection means is placed in the ventilation path from the adjacent room to the bathroom. By this means, detection accuracy can be improved.

In addition, other means are provided in the ventilation path of the ventilation means, the ventilation means for discharging the air inside the bathroom, the ventilation means for circulating and blowing the air in the bathroom and blowing the wind on the laundry suspended in the bathroom, Heating means, first temperature detecting means for detecting the temperature of the bathroom, second temperature detecting means for detecting the temperature of the adjacent room that hits the wind on the ventilation path of the bathroom, and first temperature detecting means A control means for controlling the output of the heating means, the output of the blower means and the output of the ventilation means from the detected temperature and the detected temperature of the second temperature detection means, and detecting the heating output of the heating means, and heating by the control means The drying state of the laundry is controlled from the temperature difference obtained by subtracting the time average value of the temperature detected by the second temperature detection means from the time average value of the temperature detected by the first temperature detection means. It detects, first of When the temperature difference obtained by subtracting the detection temperature of the second temperature detection means from the detection temperature of the degree detection means becomes the second steady state after the first steady state and then the temperature difference passes through the increasing time zone. The operation is stopped . By this means, general-purpose temperature detection means such as a temperature sensor can be used, and the detection accuracy of the detection means can be improved. Further, by automatically stopping the drying operation, the laundry can be prevented from being dried and wasteful drying operations can be reduced.

  According to the present invention, it is possible to detect the drying of the laundry based on the temperature index. Moreover, general-purpose temperature detection means such as a temperature sensor can be used, and the durability and detection accuracy of the detection means can be improved. Further, by automatically stopping the drying operation, it is possible to prevent the laundry from being dried and to reduce unnecessary drying operations. In addition, it is possible to perform drying with the minimum necessary heating amount by the desired drying end time, and to improve the accuracy of drying determination.

According to the first aspect of the present invention, there are provided ventilation means for discharging the air inside the bathroom, air blowing means for circulating and blowing the air in the bathroom and blowing air on the laundry suspended in the bathroom, and air blowing by the air blowing means. Heating means provided in the path, first temperature detection means for detecting the temperature of the bathroom, second temperature detection means for detecting the temperature of the adjacent room that hits the wind on the ventilation path of the bathroom, A control means for controlling the output of the heating means, the output of the blower means and the output of the ventilation means from the detection temperature of the temperature detection means and the detection temperature of the second temperature detection means, and detecting the heating output of the heating means; The control means controls the output of the heating means to be constant, detects the dry state of the laundry from the temperature difference obtained by subtracting the detection temperature of the second temperature detection means from the detection temperature of the first temperature detection means , Detection temperature of the first temperature detection means Intended to stop the operation when the detected temperature difference temperature by subtracting the can after one round of the steady state, the temperature difference becomes a steady state a second time over time period of an increase in the second temperature detection means from the Yes, because the amount of water vapor generated from the laundry is detected by the amount of change in bathroom temperature as the amount of heat removed from the bathroom as latent heat of vaporization, general-purpose temperature detection means such as temperature sensors can be used, and the durability and detection of the detection means It has the effect of improving accuracy. In addition, since the drying situation is grasped by the change in water vapor generation during the drying process of the laundry due to the temperature difference, the automatic operation of the drying operation is automatically stopped to prevent the laundry from being dried out and reducing unnecessary drying operation. Have.

In the invention according to claim 2 of the present invention, the second temperature detecting means is stored in the ventilation path from the adjacent room to the bathroom, and the temperature of the air flowing into the bathroom from the adjacent room can be accurately detected. The detection accuracy can be improved.

Invention of Claim 3 of this invention is the ventilation means which discharges the air inside a bathroom, the ventilation means which circulates and blows the air in a bathroom, and blows air on the laundry suspended in the bathroom, The ventilation of a ventilation means Heating means provided in the path, first temperature detection means for detecting the temperature of the bathroom, second temperature detection means for detecting the temperature of the adjacent room that hits the wind on the ventilation path of the bathroom, A control means for controlling the output of the heating means, the output of the blower means and the output of the ventilation means from the detection temperature of the temperature detection means and the detection temperature of the second temperature detection means, and detecting the heating output of the heating means; Washing is performed from the temperature difference obtained by subtracting the time average value of the temperature detected by the second temperature detection means from the time average value of the temperature detected by the first temperature detection means by controlling the output of the heating means to be constant by the control means. Check the dryness of the object And detection after the temperature difference obtained by subtracting the temperature of the first-time steady state, the steady state of the second time the temperature difference over time zones increase in the second temperature detection means from the detected temperature of the first temperature sensing means The operation will be stopped at the moment, and the ambient temperature in the adjacent room or bathroom will be detected by averaging the detected values even for temporary temperature fluctuations caused by resident's daily activities, etc. Thus, a general-purpose temperature detection means such as a temperature sensor can be used, and the detection accuracy of the detection means can be improved. In addition, since the drying situation is grasped by the change in water vapor generation during the drying process of the laundry due to the temperature difference, the automatic operation of the drying operation is automatically stopped to prevent the laundry from being dried out and reducing unnecessary drying operation. Have.

  Hereinafter, embodiments of the present invention will be described with reference to FIGS.

(Embodiment 1)
FIG. 1 is a sectional view of a bathroom provided with a bathroom ventilation dryer according to Embodiment 1 of the present invention. In FIG. 1, a bathroom ventilation dryer 1 is provided in a ceiling portion of a bathroom 2, and the bathroom 2 and the adjacent room 3 are communicated with each other via a door gallery 4. Function as. In the bathroom ventilation dryer 1, a ventilation air passage is configured by connecting an intake port 5 for sucking air from the bathroom 2, an exhaust blower 6 as a ventilation means, and an exhaust port 7 for discharging the air of the bathroom 2 to the outside. Yes. The exhaust blower 6 is driven by a brushless DC motor with a constant air flow control function, and can maintain a constant air flow without being affected by outdoor air or duct pressure loss, so the temperature of the bathroom 2 can be stabilized and the accuracy of dryness detection Can be improved. In addition, a circulation air passage is configured by communicating with a suction port 8 for sucking air from the bathroom 2, a circulation fan 9 as a blowing means, an electric heater 10 as a heating means, and a blowout port 11 for blowing air into the bathroom 2. ing. Specifically, a halogen heater, a sheathed heater, a PTC heater, or the like is used as the electric heater 10. Note that a louver may be provided at the outlet 11 to change the direction of the blowing air so that air can be blown evenly. A temperature sensor 12 as first temperature detecting means is provided inside the suction port 8. The temperature sensor 12 is a thermistor or the like. The temperature sensor 12 only needs to be able to detect the air temperature in the bathroom 2 and may be provided inside the suction port 5.

  FIG. 2 is a front view of the operation unit of the bathroom ventilation dryer according to Embodiment 1 of the present invention.

  An operation unit 13 as input means for setting the operation of the bathroom ventilation dryer 1 is provided on the wall surface of the adjacent room 3 that hits the windward on the ventilation path. As shown in FIG. 2, the operation unit 13 includes a power button 13a, a start button 13b, a clothes drying button 13c, a heating button 13d, and a ventilation button 13e, and the operation mode can be selected from clothes drying, heating, and ventilation. . The operation unit 13 also sets a target end time setting button 13f that can set a target end time when the clothes drying mode is selected, and a dry weight of the laundry to be dried when the clothes drying mode is selected. A clothing weight setting button 13g that can be used is provided. The operation mode can be selected from clothes drying, heating and ventilation. In the clothes drying mode, the laundry 14 suspended from a clothes-drying basket (not shown) can be dried by operating the exhaust fan 6, the circulation fan 9, and the heating means 10. Further, inside the operation unit 13, a temperature sensor 15 as a second temperature detection unit is provided so that the air in the adjacent chamber can be ventilated. The thermistor etc. are used for the temperature sensor 15 similarly to the temperature sensor 12.

  The bathroom ventilation dryer 1 also includes control means 16 that is electrically connected to the operation unit 13, the temperature sensors 12 and 15, the exhaust fan 6, the circulation fan 9, and the electric heater 10. The control means 16 is provided with a microcomputer or the like and has functions such as calculation, storage, and timer. The control means 16 performs calculation based on the instruction information sent from the operation unit 13 and the temperature detection information by the temperature sensors 12 and 15, and the exhaust blower 6. Operate and control the circulation fan 9 and the electric heater 10. As the output control of the electric heater 10, the energization time control for the electric heater 10 is performed, and it is not necessary to provide a plurality of output notches in the electric heater 10, and the cost can be reduced.

  Next, basic operations of the constituent elements in the first embodiment will be described.

  First, before the operation of the bathroom ventilation dryer 1, the heating output of the electric heater 10 is determined as a heating means according to the input values of the target time setting button 13f and the clothing weight setting button 13g of the operation unit 13 of the bathroom ventilation dryer 1. Is done. The specific value of the heating output of the electric heater 10 is not shown here because it depends on specific performance values of the bathroom ventilation dryer 1 such as the exhaust capacity of the exhaust blower 6 and the ventilation capacity of the circulation fan 9. However, the control output 16 is such that the heating output of the electric heater 10 decreases as the number of hours input by the target time setting button increases, and the heating output of the electric heater 10 increases as the weight input by the clothing weight setting button increases. As a result of the calculation, the heating output of the electric heater 10 is determined.

  Subsequently, the control means 16 of the bathroom ventilation dryer 1 energizes the electric heater 10, the exhaust blower 6, the circulation blower 9, and the like in response to an input from the operation unit 13 and starts the clothes drying operation. The circulation blower 9 sucks air in the bathroom 2 from the suction port 5, heats the sucked air with the electric heater 10, and blows warm air to the laundry 14 suspended in the bathroom 2 through the blowout port 11. ing. By the supply of warm air to the laundry 14 by the circulation blower 9, the moisture contained in the laundry 14 is evaporated and the laundry 14 is dried.

  On the other hand, the exhaust blower 6 sucks air in the bathroom 2 from the suction port 5 and discharges the sucked air from the discharge port 7 to the outdoors. Moreover, since the inside of the bathroom 2 becomes negative pressure by the exhaust fan 6, the air in the adjacent room 3 is taken into the bathroom 2 through the door gallery 4. The air taken into the bathroom 2 from the adjacent room 3 takes in water vapor generated from the laundry 14 and is discharged outside. As described above, the air blowing operation to the laundry 14 by the circulation blower 9 and the water vapor discharge operation from the inside of the bathroom 2 to the outdoors by the exhaust air blower 6 are simultaneously performed, so that the laundry 14 is efficiently dried.

  FIG. 3 is a diagram showing temporal changes in the moisture content of the laundry and the temperature difference between the bathroom and the adjacent room when the laundry in the first embodiment is dried. FIG. 4 is a flowchart showing a processing flow of dryness detection in the first embodiment. Here, the control operation in the clothes drying mode according to the first embodiment will be described with reference to FIGS.

  When the clothes drying operation is performed in the bathroom ventilation dryer 1 and the laundry 14 is dried, the temperature in the bathroom 2 and the adjacent room 3 is sequentially output from the temperature sensor 12 and the temperature sensor 15 to the control means 16. In the control means 16, based on the output θ 1 from the temperature sensor 12 and the output θ 2 from the temperature sensor 15, the ratio (Δ (θ 1 −θ 2) / Δτ) of the temperature difference displacement Δ (θ 1 −θ 2) with respect to the constant time Δτ. ) Is calculated. The laundry water content w accompanying the operation of the bathroom ventilation dryer 1 and the temperature difference (θ1−θ2) between the bathroom 2 and the adjacent room 3 behave, for example, as shown in FIG. The time area of the drying process of the laundry 14 is roughly divided into a rising area, a constant rate drying area, and a reduced rate drying area. That is, in the rising region, the temperature difference (θ1−θ2) is in a steady state after a certain time has elapsed after the rapid increase. In the constant rate drying region, since water vapor is constantly generated from the laundry 14, the temperature difference (θ1-θ2) is maintained substantially constant. In the rate-decreasing drying region, the amount of water vapor generated from the laundry 14 gradually decreases, so that the room temperature of the bathroom 2 gradually increases as the latent heat of vaporization decreases, and thereafter water vapor is generated from the laundry 14. The temperature difference (θ1−θ2) is in a steady state when it disappears and the latent heat of vaporization becomes zero.

  To determine the dry state of the laundry 14, (Δ (θ1-θ2) / Δτ) is monitored over time. First, it is judged that (Δ (θ1−θ2) / Δτ) is almost zero, so that the drying process is shifted to the constant rate drying region, and then (Δ (θ1−θ2) / Δτ) is obtained. When it becomes positive, it is judged that the constant rate drying region has shifted to the decreasing rate drying region, and after that (Δ (θ1-θ2) / Δτ) is almost zero, it is judged that the drying is considered to be finished. . The control means 16 uses this dry determination method to end the dry detection process as follows.

  First, based on the input values of the target time setting button 13f and the clothing weight setting button 13g of the operation unit 13 of the bathroom ventilation dryer 1, the control means 16 determines the heating output of the electric heater 10 as a heating means (S1). . When the clothes drying button 13c is pressed, the clothes drying operation of the bathroom ventilation dryer 1 starts (S2), and the control means 16 outputs the output θ1 of the temperature sensor 12 and the output θ2 of the temperature sensor 15 with respect to the displacement Δτ of the operation time. When the ratio (Δ (θ1−θ2) / Δτ) of the displacement Δ (θ1−θ2) of the temperature difference to the predetermined value a or less (S3), the drying process of the laundry 14 is constant rate drying from the rising region. Judged to have moved to the area. On the other hand, when the ratio (Δ (θ1-θ2) / ΔτΔ) is greater than the predetermined value a (S3), the control means 16 determines that the drying process of the laundry 14 remains in the rising region, The process is repeated until the value a becomes less than or equal to a.

  Subsequently, the control means 16 compares the ratio (Δ (θ1-θ2) / Δτ) of the displacement Δ (θ1-θ2) of the temperature difference between the output θ1 of the temperature sensor 12 and the output θ2 of the temperature sensor 15 with respect to the displacement Δτ of the operation time. ) Is equal to or greater than the predetermined value b (S4), it is determined that the drying process of the laundry 14 has shifted from the constant rate drying area to the decreasing rate drying area. On the other hand, when the ratio (Δ (θ1-θ2) / Δτ) is smaller than the predetermined value b (S4), the control means 16 determines that the drying process of the laundry 14 remains in the constant rate drying region, The process is repeated until the predetermined value b is reached.

  Subsequently, the control means 16 compares the ratio (Δ (θ1-θ2) / Δτ) of the displacement Δ (θ1-θ2) of the temperature difference between the output θ1 of the temperature sensor 12 and the output θ2 of the temperature sensor 15 with respect to the displacement Δτ of the operation time. ) Becomes equal to or less than the predetermined value c (S5), it is determined that the laundry 14 has been dried, and the clothes drying operation in the bathroom ventilation dryer 1 is stopped to stop the drying process (S6). On the other hand, when the ratio (Δ (θ1-θ2) / Δτ) is larger than the predetermined value c (S5), the control unit 16 determines that the laundry 14 still contains moisture, and the predetermined value c. Repeat the process until:

  The time Δτ is preferably larger than the time width for calculating the power consumption P as the output of the heating means, and is a multiple of the time width for calculating the power consumption P as the output of the heating means. = About 10 minutes. Further, the predetermined values a, b and c are values close to zero and are determined in consideration of measurement errors of the temperature sensors 12 and 15, for example, the temperature detection response speed of the temperature sensors 12 and 15 is If it is smaller than Δτ, if the temperature measurement sensitivity of the temperature sensors 12 and 15 is 0.05 ° C., the predetermined values a, b, and c are 0.5, which is about 10 times the temperature measurement sensitivity.

  Note that the detected temperatures of the temperature sensors 12 and 15 are also expected to be shifted due to individual differences in the sensors and changes over time. Therefore, the output values of the temperature sensors 12 and 15 are set to θ1 and θ2 after the clothing drying operation is completed. It is possible to provide a control process for correcting the temperature difference, thereby improving the accuracy in detecting the drying of the laundry.

  As described above, according to the first embodiment, the drying of the laundry 14 is detected based on the temperature index, and the temperature difference (θ1−θ2) between the output θ1 from the temperature sensor 12 and the output θ2 from the temperature sensor 15 is detected. The drying of the laundry 14 can be detected by detecting this, and the durability and detection accuracy of the detection means can be improved by utilizing a general-purpose temperature detection means, and washing can be performed by automatically stopping the drying operation. It is possible to prevent the dryness of goods and wasteful drying operation.

( Reference form 1 )
In the first embodiment, control is performed to keep the output of the electric heater 10 as heating means constant, and the temperature difference (θ1−) between the output θ1 from the temperature sensor 12 and the output θ2 from the temperature sensor 15 detected at that time. Control means 16 for judging the drying of the laundry by monitoring the temporal change of θ2) was provided. On the other hand, in Embodiment 1 of this reference , after the start of the laundry drying operation, the air drying without heating is preferentially performed by the operation of only the exhaust air blower 6 and the circulation air blower 9, and the user sets by the control means 16 The operation of the electric heater 10 as the heating means is an operation mode that starts with a time difference according to the input value of the target time setting button 13f of the operation unit 13 and the drying state of the laundry 14. That is, the energy-saving operation mode aims to reduce the heating amount as much as possible within the target drying time. Note that the constituent elements of the reference embodiment 1 are the same as those of the first embodiment, and a description thereof will be omitted.

Next, basic operations of the constituent elements in Reference Embodiment 1 will be described.

  First, before starting the clothing drying operation of the bathroom ventilation dryer 1, the input values of the target time setting button 13f and the clothing weight setting button 13g of the operation unit 13 of the bathroom ventilation dryer 1 are set. The control means 16 energizes the exhaust blower 6 and the circulation blower 9 in response to a clothes drying operation input instruction by the clothes drying button 13c from the operation unit 13, and starts the air drying operation without using the heating means. The circulation blower 9 sucks the air in the bathroom 2 from the suction port 5, and the sucked air is blown to the laundry 14 suspended in the bathroom 2 through the blowout port 11. By blowing air to the laundry 14 by the circulation blower 9, the latent heat of evaporation is deprived from the air in the bathroom 1 due to evaporation of moisture accompanying the drying of the laundry 14, and the air temperature in the bathroom 1 is lowered. Therefore, by monitoring the temperature difference (θ2−θ1) between the output θ1 from the temperature sensor 12 and the output θ2 from the temperature sensor 15, the magnitude of the water evaporated from the laundry 14 due to the ventilation of the circulation fan 9 is estimated. be able to. That is, by comparing the drying determination coefficient d calculated from the initial moisture content before the clothes start drying of the laundry 14 with the time integral value ∫ (θ2-θ1) Δτ of the temperature difference (θ2-θ1), the laundry The dry judgment can be made. Furthermore, since the temperature difference (θ2−θ1) has become almost zero, it is detected that water has not evaporated from the laundry 14 and the drying of the laundry 14 is confirmed from a different viewpoint, so that the drying can be performed. The accuracy of judgment is improved.

  Further, depending on the season such as the rainy season, the laundry 14 may not be dried within the target time set by the target time setting button 13f only by the air-drying operation. Operation starts and shifts to heat drying operation.

Figure 5 is a diagram showing the temporal change of the temporal integration value of the temperature difference and the temperature difference between the water content, bathroom and next room laundry during drying the laundry in the present first reference. 6 is a flow chart showing the processing flow of the drying control in the present first reference. Here, the control operation in the clothes drying mode in the present first reference, will be described with reference FIGS. 5-6.

  In the clothes drying mode, the moisture content w of the laundry 14 when switching from the air drying operation to the heat drying operation, the temperature difference (θ2−θ1) between the output θ1 from the temperature sensor 12 and the output θ2 from the temperature sensor 15; The time integrated value ∫ (θ2-θ1) Δτ of the temperature difference (θ2-θ1) behaves as shown in FIG. 5, for example. The control means 16 determines whether the laundry 14 is dried or whether the electric heater 10 is energized based on a change in the time integral value ∫ (θ2-θ1) Δτ of the temperature difference (θ2-θ1). When 乾燥 (θ2−θ1) Δτ exceeds the indicated drying determination coefficient d, it is determined that the laundry 14 has been dried and the drying operation is automatically stopped to reduce useless drying operations. it can.

As the drying determination coefficient d, when the input value of the estimated weight setting button 13g is 6 kg according to the input value of the clothing weight setting button 13g, the ratio of the moisture content to the dry weight of the laundry dehydrated by the washing machine is approximately 1. : Since it is about 2, it can be estimated that the initial water content of the laundry is 3 kg. In order to evaporate 3 kg of water, a sensible heat amount equivalent to the latent heat of vaporization is required, and the drying determination coefficient d is calculated from the quotient of the latent heat of vaporization and (ventilation amount × specific heat). Therefore, when the exhaust amount of the exhaust blower 6 is 200 m ³ / h, the dry determination coefficient d is about 26. Thereby, the precision of dry determination can be improved irrespective of the dry weight of the laundry 14 changing.

  In addition, when 加熱 (θ2−θ1) Δτ is less than the heating determination coefficient e shown in FIG. 5, the electric heater is energized and switched to the heating and drying operation so that the heating means can be appropriately controlled to save energy. Can be planned. The heating determination coefficient e is expressed by a function expression g (t) of the remaining time t with the input value of the target time setting button 13f as a base point. The coefficient in the function formula is a value that is determined by the input value of the clothing weight setting button 13g, the heating determination coefficient e, and the drying performance of the bathroom ventilation dryer 1 and determined by the result of the drying experiment. Cannot be shown. Thereby, it is possible to perform drying with the minimum necessary heating amount by the desired drying end time set by the target time setting button 13f.

Next, the flow of the drying detection process in Reference Embodiment 1 will be described with reference to FIG.

  The control means 16 is set by a target time setting button 13f of the operation unit 13 of the bathroom ventilation dryer 1 (S11), and is set by a clothing weight setting button 13g of the operation unit 13 of the bathroom ventilation dryer 1. The drying determination coefficient d is set by condition input (S12).

  Next, the control means 16 starts the clothes drying operation of the bathroom ventilation dryer 1 (S13), and the temperature difference (θ2) between the time average value θ1 of the output of the temperature sensor 12 and the time average value θ2 of the output of the temperature sensor 15 is reached. -Θ1) time integral value ∫ ((θ2-θ1) Δτ) is sequentially calculated from the start of operation, and when the drying determination coefficient d is greater than or equal to (S14), all the moisture contained in the laundry 14 has evaporated. After confirming that the temperature difference (θ2−θ1) between the time average value θ1 of the output of the temperature sensor 12 and the time average value θ2 of the output of the temperature sensor 15 is smaller than g as a reconfirmation of drying, the laundry 14 Is determined to be dry, the operation in the bathroom ventilation dryer 1 is stopped and the drying process is stopped (S16). On the other hand, when the time integral value ∫ ((θ1-θ2) Δτ) is smaller than the drying determination coefficient d (S14), the control means 16 determines that the laundry 14 still contains moisture and determines the next step ( Proceed to S17).

  Next, the control means 16 calculates the heating determination coefficient e according to the remaining time t until drying determined from the input value of the target time setting button 13f and the elapsed time after the start of drying (S17), and the temperature sensor 12 When the time integrated value ∫ ((θ2−θ1) Δτ) of the temperature difference (θ2−θ1) between the output time average value θ1 and the output time average value θ2 of the temperature sensor 15 is equal to or less than the heating determination coefficient e ( S18), energization of the electric heater 10 is started, and the process proceeds to the heating and drying operation (S19). On the other hand, if the time integral value ∫ ((θ1-θ2) Δτ) is larger than the heat determination coefficient e (S18), the control means 16 may cause the laundry 14 to dry within the target time in the air drying operation. The determination returns to the previous step (S14).

  Next, the control means 16 compares the ratio Δ (θ1-θ2) of the temperature difference between the time average value θ1 of the output of the temperature sensor 12 and the time average value θ2 of the output of the temperature sensor 15 with respect to the displacement Δτ of the operation time ( When [Delta] ([theta] 1- [theta] 2) / [Delta] [tau]) is equal to or less than a predetermined value f (S20), it is determined that the laundry 14 has been dried and the operation in the bathroom ventilation dryer 1 is stopped to stop the drying process (S16). On the other hand, when the ratio (Δ (θ1-θ2) / ΔτΔ) is greater than the predetermined value f (S20), the control means 16 determines that the laundry 14 still contains moisture, and determines the predetermined value. The process is repeated until it becomes f or less.

  The time Δτ is preferably larger than the time width for calculating the power consumption P as the output of the heating means, and is a multiple of the time width for calculating the power consumption P as the output of the heating means. = About 10 minutes. Further, the predetermined values f and g are values close to zero and are determined in consideration of the accuracy and sensitivity of the temperature sensors 12 and 15. For example, when the temperature detection response speed of the temperature sensors 12 and 15 is smaller than Δτ, if the temperature measurement sensitivity of the temperature sensors 12 and 15 is 0.05 ° C., the predetermined values f and g are 10 times the temperature measurement sensitivity. It becomes about 0.5.

  Note that the detected temperatures of the temperature sensors 12 and 15 are also expected to be shifted due to individual differences in the sensors and changes over time. Therefore, the output values of the temperature sensors 12 and 15 are set to θ1 and θ2 after the clothing drying operation is completed. It is possible to provide a control process for correcting the temperature difference, thereby improving the accuracy in detecting the drying of the laundry.

  The time Δτ is preferably larger than the time width for calculating the power consumption P as the output of the heating means and a multiple of the time width for calculating the power consumption P as the output of the heating means. The predetermined values f and g are values close to 0 and are determined in consideration of measurement errors of the temperature sensors 12 and 15.

  The time used for averaging as the time average values θ1 and θ2 calculated from the output from the temperature sensor 12 and the output from the temperature sensor 15 is, for example, one minute, and the detection data of the temperature sensor 12 and the temperature sensor 15 Therefore, the detection accuracy of the detection means can be improved.

  As described above, according to the second embodiment, the latent heat of vaporization based on the amount of water vapor generated from the laundry 14 is the time average value θ1 of the output from the temperature sensor 12 and the time average value of the output from the temperature sensor 15. Utilizing a relationship equivalent to the amount of sensible heat based on the temperature difference (θ1−θ2) from θ2, and automatically stopping the drying operation by automatically stopping the drying operation can reduce useless drying operations. At the same time, the accuracy of drying determination can be improved. In addition, the laundry 14 can be dried with a minimum amount of heat by minimizing the energization of the electric heater 10 in response to the request for the desired drying completion time by the target time setting button 13f.

( Reference form 2 )
In Embodiment 1 or Reference Embodiment 1 , an electric heater is used as the heating means. However, in Embodiment 3, a hot water heater is used as the heating means. The heating output detection method is different.

FIG. 7 is a cross-sectional view of a bathroom provided with a bathroom ventilation dryer according to Reference Embodiment 2 of the present invention. 7, a description thereof will be omitted for the same components and control operation as Embodiment 1 or references of the first embodiment. A hot water heater 21 as a heating means is provided on the leeward side of the circulation fan 9 to constitute a circulation air passage. The hot water heater 21 is connected to a hot water boiler 22 and a hot water pipe 23 provided separately from the bathroom ventilation dryer 1, and hot water heated by the hot water boiler 22 is supplied at a constant flow rate. Further, the hot water pipe 23 of the hot water heater 21 has a temperature sensor 24 as a third temperature detecting means for detecting the temperature on the hot water outlet side, and a temperature as a fourth temperature detecting means for detecting the temperature on the hot water inlet side. A sensor 25 is provided and is electrically connected to the control means 16. A thermistor or the like is used for the temperature sensor 24 and the temperature sensor 25. Since the hot water supplied from the hot water boiler circulates at a constant flow rate, the fluctuation of the heating output in the hot water heater 21 as the heating means is the temperature difference between the detected temperature θ3 in the temperature sensor 24 and the detected temperature θ4 in the temperature sensor 25. It is only necessary to monitor (θ4-θ3). Therefore, in the case of the first embodiment or the second embodiment in which the electric heater is used, the power consumption P is calculated as the output of the electric heater 10 as the heating means, but in the case of the third embodiment, the heating is performed. (Θ4-θ3) is used as the output of the hot water heater 21 as means. Further, a temperature sensor 26 as a second temperature detecting means is provided in the door gallery 4 as a ventilation path from the adjacent room 3 to the bathroom 2 to accurately detect the temperature of the air flowing into the bathroom 2 from the adjacent room 3. It becomes possible to improve detection accuracy.

In this manner, according to Embodiment 2 of this reference, even when using hot water heater 21 as a heating means, without adding special parts as such as adding a temperature sensor 24, 25 laundry 14 It is possible to judge the drying of.

  The temperature sensor 26 as the second temperature detection means is provided in the door gallery 4 as an air passage from the adjacent room 3 to the bathroom 2. For example, a duct or the like is provided between the adjacent room 3 and the bathroom 2. It is only necessary to provide another ventilation path as an air supply path from the adjacent room 3 to the bathroom 2 so that the temperature sensor is provided in the duct communicated by the road, and there is no difference in the operation effect.

  The bathroom ventilation dryer of the present invention is installed in a highly sealed space such as a bathroom in a house, and is useful as a drying device used for drying laundry.

Sectional drawing of the bathroom provided with the bathroom ventilation dryer in Embodiment 1 of this invention The front view of the operation part of the bathroom ventilation dryer in Embodiment 1 of this invention. The figure which shows the time change of the moisture content of the laundry in drying the laundry in this Embodiment 1, and the temperature difference of a bathroom and an adjacent room. The flowchart which shows the processing flow of dryness detection in this Embodiment 1. The figure which shows the time change of the moisture content of the laundry at the time of drying the laundry in this reference form 1, the temperature difference of a bathroom and an adjacent room, and the time integral value of a temperature difference. The flowchart which shows the processing flow of the drying control in this reference form 1 . Sectional drawing of the bathroom provided with the bathroom ventilation dryer in the reference form 2 of this invention Sectional view of a bathroom with a conventional bathroom ventilation dryer

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Bathroom ventilation dryer 6 Exhaust fan 9 Circulation fan 10 Electric heater 12 Temperature sensor 13 Operation part 14 Laundry 15 Temperature sensor 16 Control means 21 Hot water heater 24 Temperature sensor 25 Temperature sensor 26 Temperature sensor

Claims (3)

Ventilation means for discharging the air inside the bathroom, air blowing means for circulating air in the bathroom and blowing air on the laundry suspended in the bathroom, heating means provided in the air flow path of the air blowing means, A first temperature detecting means for detecting the temperature of the bathroom, a second temperature detecting means for detecting the temperature of the adjacent room on the wind path in the bathroom, the detected temperature of the first temperature detecting means and the first temperature Control means for controlling the output of the heating means, the output of the blower means, and the output of the ventilation means from the detected temperature of the temperature detecting means, and detecting the heating output of the heating means, and heating by the control means The output of the means is controlled to be constant, the dry state of the laundry is detected from the temperature difference obtained by subtracting the detected temperature of the second temperature detecting means from the detected temperature of the first temperature detecting means, and the first Detection of temperature detection means After the time of the steady state temperature difference obtained by subtracting the detected temperature is one time of the second temperature sensing means, stop the operation at the time when the temperature difference becomes a second time in a steady state over time zones increase bath room ventilation dryer. Bathroom ventilating dryer according to claim 1, characterized in that housed in ventilation passage for the bathroom the second temperature detection means from the next room. Ventilation means for discharging the air inside the bathroom, air blowing means for circulating air in the bathroom and blowing air on the laundry suspended in the bathroom, heating means provided in the air flow path of the air blowing means, A first temperature detecting means for detecting the temperature of the bathroom, a second temperature detecting means for detecting the temperature of the adjacent room on the wind path in the bathroom, the detected temperature of the first temperature detecting means and the first temperature Control means for controlling the output of the heating means, the output of the blower means, and the output of the ventilation means from the detected temperature of the temperature detecting means, and detecting the heating output of the heating means, and heating by the control means The output of the means is controlled to be constant, and the laundry is dried from the temperature difference obtained by subtracting the time average value of the temperature detected by the second temperature detection means from the time average value of the temperature detected by the first temperature detection means. State Knowledge and, after the detected temperature of the first temperature sensing means in the steady state temperature difference obtained by subtracting the detected temperature is one time of the second temperature sensing means, the temperature difference is a second time constant via a time zone increases bath room ventilation dryer you stop the operation at the time when the state.

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