JP6077264B2 - Futon dryer - Google Patents

Description

The present invention relates to a futon dryer used by inserting a portion between the mattress and the duvet.

  The futon dryer includes a blowing unit and a heating unit inside the exterior body, and heats the outside air sucked from the suction port and discharges it from the discharge port. The discharge port side is inserted and arranged between the mattress and the comforter, and heated drying air is supplied between them to dry each futon.

  The futon dryer described in Patent Document 1 includes a duct that communicates with a suction port at one end of the exterior body. The duct constitutes an air passage, and an air blowing means and a heating means are disposed inside, and the heated drying air is discharged from the discharge port at the tip of the duct. Moreover, it arrange | positions between a mattress and a comforter, and the arm for forming a ventilation space between these is mounted.

  Moreover, the futon dryer of patent document 2 arrange | positions the mat | matte which is ventilation space between a mattress and a comforter, and connects a discharge outlet to this mat. When the drying air is fed into the mat, the mat expands, and the drying air that is fed in small amounts from the entire surface of the mat is applied to each futon.

  Since the futon dryer of each patent document can form a ventilation space between the mattress and the comforter with an arm or a mat, the drying air can be efficiently blown to every corner. However, when not in use, a storage space for an arm or a mat is required, so the storage property is poor. In addition, the futon dryer of Patent Document 2 has a low amount of airflow delivered from the mat, so the futon drying efficiency is poor.

JP-A-6-218190 JP 2012-19988 A

  It is an object of the present invention to reduce the space when not in use and eliminate the need for additional parts and to improve the drying efficiency.

  In order to solve the above-mentioned problems, the futon dryer of the present invention has a suction port, a suction portion disposed outside the comforter, and a discharge portion, and an insertion portion disposed between the mattress and the comforter. And an air blower that is disposed in the air passage extending from the suction port to the discharge port, sucks outside air from the suction port and discharges it from the discharge port, and heats the air sucked from the suction port by the blower unit And a control means for executing a drying course having a blowing step for operating the blowing means without operating the heating means before the drying step for operating the blowing means and the heating means. It is configured. The mattress is a material on which a person lies, and includes a bed mat. A comforter is a material that covers a person and includes a blanket.

  The control method of the futon dryer is executed after the air blowing step by sucking outside air from the air inlet of the suction portion by the air blowing means and discharging it from the outlet of the insertion portion disposed between the mattress and the comforter. And a drying step in which the outside air sucked from the suction port by the blowing unit is heated by the heating unit and discharged from the discharge port.

  When the air blowing step for operating only the air blowing means without operating the heating means is performed before the drying step for operating the heating means, a gap (air blowing space) can be formed between the close mattress and the comforter. . Therefore, an arm or mat made of separate parts is unnecessary, and the storage space when not in use can be saved. In addition, the number of parts can be reduced and the cost can be reduced. Furthermore, when the drying step is executed, the heated drying air can be directly supplied to the futon, so that the drying efficiency can be improved.

  Moreover, since the air blowing space can be formed in the air blowing step, excessive heating of the drying air can be prevented when the drying step is executed. That is, when the drying step is executed without forming the blowing space by the blowing step, there is no place for the heated drying air, and the air flows backward to the suction portion. Then, the drying air is sucked again from the suction port and reheated, which may cause excessive heating. However, it is possible to reliably prevent such a problem from occurring.

The amount of air blown by the air blowing means in the air blowing step is preferably equal to or larger than the air flow amount of the air blowing means in the drying step.
The futon dryer of the present invention has a suction port, a suction portion disposed outside the comforter, a discharge port, an insertion portion disposed between the mattress and the comforter, and the suction port. Disposed in the air passage leading to the discharge port, sucking outside air from the suction port and discharging from the discharge port, heating means for heating the air sucked from the suction port by the blow unit, It is good also as a structure provided with the control means which performs the drying course which has the step which operates the said ventilation means more than the ventilation volume in the said drying step before the drying step which operates the said ventilation means and the said heating means.
If it does in this way, a ventilation space can be formed reliably.

  It is preferable that the drying course executed by the control unit includes a body cooling step of operating the blowing unit without operating the heating unit after the drying step. In this way, since the insertion portion whose temperature has been raised by the execution of the drying step can be cooled, handling safety can be improved.

  The drying course executed by the control means includes a futon cooling step in which the air blowing means is operated without operating the heating means between the drying step and the airframe cooling step, and the execution time is longer than the airframe cooling step. It is preferable to have a blow finish course to perform. In this way, it is possible to reliably lower the temperature of the futon that has been heated in the drying step and to provide a bed according to wishes.

  The drying course executed by the control means preferably includes an eco course in which the execution time of the blowing step is longer than the execution time of the drying step. In this way, the futon can be surely dried after reducing power consumption (energy saving).

  Since the futon dryer of this invention can form a ventilation space between futons at a ventilation step, the arm and mat which consist of another components are unnecessary, and can save the storage space at the time of non-use. Also, by performing the drying step in this state, the heated drying air can be directly supplied to the futon, so that the drying efficiency can be improved.

Sectional drawing which shows the futon dryer of the 1st use condition of embodiment which concerns on this invention. The perspective view of FIG. The perspective view which shows the futon dryer of a folded state. The perspective view which shows the futon dryer of a 2nd use condition. The block diagram which shows the structure of a futon dryer. The time chart which shows the structure of each drying course. The flowchart which shows control of a futon dryer. The flowchart which shows the interruption stop process of FIG. The flowchart which shows control of a 1st heating step. The flowchart which shows the normal heating control of FIG. The flowchart which shows the low temperature determination of FIG. The flowchart which shows the interruption heating control of FIG. The flowchart which shows control of a 2nd heating step. The flowchart which shows control of a 3rd heating step. The flowchart which shows control of a ventilation step and a futon cooling step. The flowchart which shows control of a body cooling step.

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

  1 to 4 show a futon dryer 10 according to an embodiment of the present invention. As shown in FIGS. 2 to 4, the futon dryer 10 includes an exterior body having a discharge member 17 that is hingedly connected to the dryer body 11. Inside, a fan 22 that is a blowing means and a PTC heater 24 that is a heating means are disposed, and the sucked outside air is heated and discharged. In the present embodiment, an air blowing space is formed between the mattress and the comforter without using separate parts such as an arm and a mat, thereby saving space when not in use and improving the drying efficiency.

  As shown in FIG. 1 and FIG. 2, the dryer main body 11 includes a suction portion 12 that is exposed and disposed outside the comforter, and an overlapping portion 14 that is an insertion portion that is inserted and disposed between the mattress and the comforter. Is provided. The suction part 12 has a rectangular tube shape extending in the lateral direction (width direction), and a suction port 13 for taking in outside air is formed on both side surfaces. The overlapping portion 14 is formed lower than the overall height of the suction portion 12, and a step portion 15 made of a vertical wall extending upward is formed between the overlapping portion 14 and the suction portion 12. By this step part 15, it can suppress that a comforter is hung on the suction part 12. FIG.

  A hinge connection portion 16 is provided at the end of the overlapping portion 14 opposite to the suction portion 12. The hinge connecting portion 16 has a cylindrical shape with both lateral ends opened, and the internal space constitutes a part of the air passage 21. The discharge member 17 is connected, and can be rotated between the first use state (futon dry state) shown in FIG. 2 and the folded state shown in FIG. Moreover, as shown in FIG. 4, the back surface 12a of the suction part 12 can be made into the standing state which has been arrange | positioned on the floor, and the discharge member 17 can be made to incline by a predetermined angle and can be in a 2nd use state (clothing dry state).

  As shown in FIGS. 2 and 3, the discharge member 17 is an insertion portion that is disposed between the mattress and the comforter together with the overlapping portion 14 in the first use state. A pair of connecting portions 18 and 18 are provided on both sides of the hinge connecting portion 16 so as to be turnable. The overall height is lower than the overall height of the suction portion 12, and the inside is hollow. A louver 19 is disposed at the tip opening, and a pair of discharge ports 20 are provided on both sides thereof.

  As shown in FIG. 1, an air passage 21 extending from the suction port 13 to the discharge port 20 is formed inside the exterior body, and a fan 22 and a PTC heater 24 are disposed in the air passage 21. The fans 22 are sirocco fans and are respectively disposed inside the suction port 13 in the suction part 12. It is rotated by a drive motor 23 which is drive means disposed between the pair of fans 22 and 22. The PTC (Positive Temperature Coefficient) heater 24 has a self-temperature control function based on the ambient temperature. The PTC heater 24 is disposed in the overlapping portion 14 in a state where it is disposed in the heat transfer member 25 having a large number of fins.

  When the fan 22 is operated, outside air is taken into the suction part 12 from the suction port 13 and sent out into the superposition part 14. After being heated by the PTC heater 24 in the overlapping portion 14, it is discharged from the discharge port 20 via the hinge connection portion 16 and the discharge member 17. In order to detect the heating temperature of the drying air by the PTC heater 24, a thermistor 26, which is a temperature detecting means, is arranged in the overlapping portion 14 on the downstream side of the heat transfer member 25 with respect to the blowing direction by the fan 22. It is installed.

  An operation panel 27 is provided on the upper surface of the suction portion 12 in the first use state so as to be positioned on the step portion 15 side, and an operation substrate 28 is provided on the inner side thereof. As shown in FIG. 5, the operation board 28 is provided with switches 29a to 29e as input means and LEDs 30a to 30o as display means so as to correspond to each part of the operation panel 27.

  The switch 29a is a power on / off switch and is repeatedly turned on and off each time it is operated. The switch 29b is a start switch, and the drying course selected by the operation is executed. The switch 29c is a selection switch, and the drying course can be selected in the order of "standard", "blow finish", "eco", "warming", and "tick countermeasure". The switch 29d is a hot air / air blowing switch, and can select a drying course of clothes and the like in the order of “warm air” and “air blowing”. The switch 29e is a time selection switch, and the execution time of warm air or air can be selected in the order of “15” “30” “45” “60” “75” “90” “120” “180”.

  The LEDs 30a to 30e are provided beside character displays of “standard”, “blow finish”, “eco”, “warm”, and “anti-tick”, and indicate a selection state by operating the switch 29c. The LEDs 30f and 30g are provided beside the character display of “warm air” and “air blowing”, and indicate a selection state by operating the switch 29d. The LEDs 30h to 30o are provided beside the execution time numbers and indicate a selection state by operating the switch 29e.

  As shown in FIG. 1, a substrate case 31 is disposed in the suction portion 12 so as to be located on the back surface (inside) of the step portion 15, and a control substrate 32 connected to the operation substrate 28 is disposed therein. It is installed. On the control board 32, a current detection circuit (current detection means) 33 for detecting a current value supplied to the PTC heater 24 is mounted. Further, a microcomputer 34 as a control means is mounted on the control board 32.

  The microcomputer 34 controls the fan 22 and the PTC heater 24 according to a program stored in the ROM 35 which is a built-in storage unit, and executes a predetermined drying course selected from two or more types of drying courses. As shown in FIG. 6, the drying course includes “standard”, “fan finish” and “eco” which are general futon drying courses, “warm” and “tick countermeasures” which are special drying courses for futons, clothing, etc. It is also equipped with “warm air” and “fan” which are general-purpose drying courses that can be used for the

  Each drying course is composed of a combination of a first (air flow rate adjustment) drying step, a second (heating amount adjustment) drying step, a third (non-adjustment) drying step, an air blowing step, a futon cooling step, and an airframe cooling step. Yes. Among them, the air blowing step and the futon cooling step differ only in that the execution times are different, and thus are substantially a combination of five types of steps.

  Here, the execution of the first or second drying step means that one of the first drying step and the second drying step is executed. Similarly, performing the third or second drying step means performing one of the third drying step and the second drying step. In this embodiment, first, the first or third drying step is executed, and when the detected temperature Th by the thermistor 26 becomes higher than a set upper threshold value T1 (for example, 70 ° C.), the second drying step is executed.

  In the first drying step, the heating amount by the PTC heater 24 is kept constant, and the air volume W0 by the fan 22 is set on the basis of the detected temperature Th of the thermistor 26 and adjusted based on the reference air volume W0. As a result, the temperature of the drying air is adjusted to the set target temperature (including the range) Tx1. However, when used in a cold district or when the PTC heater 24 is deteriorated, the detected temperature Th of the drying air is detected even after a set waiting time t0 (for example, 5 minutes) has elapsed after the start of heating. Does not rise to the target temperature Tx1. Therefore, when the detection temperature Th detected by the thermistor 26 becomes lower than the set lower threshold value T2 (for example, 40 ° C.) after the standby time t0 has elapsed, the gust threshold value T3 (for example, 50 ° C.) that is higher than the lower limit threshold value T2 is exceeded. The air volume W by the fan 22 is lowered so as to increase the temperature of the drying air. When the detected temperature Th by the thermistor 26 becomes higher than the gust threshold value T3, the air volume W of the fan 22 is increased to the reference air volume W0, and the drying air is blown off strongly. The fan 22 may be operated with an air volume higher than the reference air volume W0 (for example, a duty ratio of 100%).

  In the second drying step, the amount of air blown by the fan 22 is kept constant (maximum), and the PTC heater 24 is on / off controlled based on the temperature detected by the thermistor 26. Thus, the temperature of the drying air is adjusted to the set target temperature (including the range) Tx2. The on / off control of the PTC heater 24 is performed so that the drying air is temperature-controlled (heated) to the target temperature Tx2 at a set target temperature increase time t (one cycle of cooling (for example, 30 seconds)) or longer. The off time t2 is adjusted. In the present embodiment, the PTC heater 24 is operated at a constant power, and the off time t2 is adjusted to become gradually longer. Accordingly, the on-time t1 is adjusted within the target temperature increase time t.

  In the third drying step, the heating amount by the PTC heater 24 is kept constant, and the air blowing amount by the fan 22 is kept constant (maximum). In the air blowing step and the futon cooling step, the operation of the PTC heater 24 is stopped, and the air blowing amount by the fan 22 is kept constant (maximum). In the airframe cooling step, the operation of the PTC heater 24 is stopped, and the amount of air blown by the fan 22 is kept constant (weak (for example, duty ratio 35%)). In addition, the ventilation volume in a ventilation step and a futon cooling step is larger than the ventilation volume in a 1st drying step, and is more than the ventilation volume in a 2nd and 3rd drying step (same).

  In the futon drying course, before the first drying step for operating the fan 22 and the PTC heater 24, the air blowing step for operating only the fan 22 is executed. Thereby, a clearance gap (blower space) is formed between the close mattress and the comforter. In the special drying course, the first drying step is executed without executing the air blowing step. For the warm air of the general-purpose drying course, the third drying step is executed without executing the blowing step. The general-purpose drying course is blown without executing the drying step.

  In all drying courses, the airframe cooling step in which only the fan 22 is operated is executed at the end (after the drying step in the futon drying course). As a result, the heated overlapping portion 14 and the discharge member 17 are cooled to improve safety in handling. Further, the blow finish course executes a futon cooling step in which only the fan 22 is operated between the drying step and the airframe cooling step. As a result, the temperature of the futon raised in the drying step is surely lowered and the bed is made as desired.

  As for the execution time of each step in each drying course, “standard”, “blow finish”, “eco”, “warm”, “anti-tick” are set in advance, and “warm air” and “fan” are set by the operation of the switch 29e. To do. In the blow finish course, the execution time of the futon cooling step (for example, 15 minutes) is longer than the execution time of the airframe cooling step (for example, 20 seconds). Therefore, the temperature of the heated futon can be surely lowered, and a bed according to wishes can be obtained. In the eco course, the execution time of the air blowing step (for example, 46 minutes) is longer than the execution time of the drying step (for example, 44 minutes). Therefore, the futon can be surely dried after reducing power consumption (energy saving).

  Next, the control by the microcomputer 34 will be specifically described.

  When a predetermined drying course is selected by operating the switches 29c to 29e of the operation panel 27 and executed by operating the switch 29b, the microcomputer 34 performs the drying process in step S1 and the step S3 in FIG. The monitoring process is processed in parallel.

  In the drying process of step S1, each step is executed in the order shown in FIG. 6 according to the selected course, and when the process is completed (step S2), the drying process is terminated. The first drying step, the second drying step, the third drying step, the air blowing step, the futon cooling step, and the machine body cooling step executed in each course will be described in detail later.

  In the monitoring step of step S3, the current value A energized to the PTC heater 24 via the current detection circuit 33 is detected. When the detected current value A becomes lower than the set lower limit current value A0, the air flow rate W by the fan 22 is reduced by 20%. Accordingly, the drying air is reliably heated to the target temperatures Tx1 and Tx2 while monitoring the deterioration state of the PTC heater 24 that can improve the safety of the product.

  In the monitoring step, the thermistor 26 detects the detection temperature Th of the drying air every predetermined time (for example, 25 ms). When the first or third drying step is being performed, the process proceeds to the second drying step when the upper limit threshold T1 is reached. Moreover, when it becomes higher than the abnormal heating temperature T4 (for example, 85 degreeC) heated too much (step 4), the interruption stop process of step S5 and the abnormality alerting | reporting process of step S6 will be processed in parallel. The abnormal heating temperature T4 is likely to occur when the drying air discharged from the discharge port 20 due to misuse or the like swirls and is sucked again from the suction port 13 and reheated.

  As shown in FIG. 8, in the interrupt stop process in step S5, the microcomputer 34 stops (turns off) the PTC heater 24 in step S5-1, and then turns the fan 22 in a power supply rate of 35% in step S5-2. Make it work. Next, after starting and resetting the 20-second timer in step S5-3, it waits until the 20-second timer counts up in step S5-4. When the 20-second timer counts up, the fan 22 is turned off in step S5-5 and the process returns (proceeds to step S7). In the state where the interruption stop predetermined is completed, the drying process in step S1 is in a temporarily stopped (interrupted) state.

  Further, in the abnormality notifying step in step S <b> 6, the microcomputer 34 outputs a notification sound by a piezoelectric buzzer (not shown) mounted on the control board 32 and blinks predetermined LEDs 30 a to 30 e mounted on the operation board 28. This abnormality notification process is continued until the start switch 29b is operated in step S7 or the power on / off switch 29a is operated in step S7.

  In step S7, it is detected whether or not the start switch 29b of the operation panel 27 has been operated. When the operation of the start switch 29b is detected, the process proceeds to step S2, and the continuation of the interrupted drying process of step S1 is executed. If the operation of the start switch 29b is not detected, the process proceeds to step S8.

  In step S8, it is detected whether or not the power on / off switch 29a of the operation panel 27 has been operated. When detecting the operation of the power on / off switch 29a, the microcomputer 34 ends the drying process even in an interrupted state where all the steps of the drying process in step S1 are not completed. If the operation of the power on / off switch 29a is not detected, the process returns to step S6 and the abnormality notification process is continued.

  Next, the first drying step executed in the drying course of “standard”, “blow finish”, “eco”, “warm”, and “anti-tick” will be described.

  As shown in FIG. 9, in the first drying step, the microcomputer 34 starts the heating control after performing the continuous use determination in steps S10 to S16. This first drying step is continued until the execution time set for each course elapses.

  Specifically, in step S10, the drive motor 23 is energized with a duty ratio of 100% to operate the fan 22, and in step S11, the thermistor 26 takes in the initial temperature Th0 that is unheated air. In step S12, it is determined whether or not two minutes have elapsed since the operation of the fan 22 was started. If 2 minutes have elapsed, the process proceeds to step S17, and if 2 minutes have not elapsed, the process proceeds to step S13.

  In step S13, the process waits until 5 seconds have elapsed since the initial temperature Th0 was acquired. After 5 seconds have elapsed, in step S14, the comparison temperature Th1 is captured. In step S15, it is determined whether the temperature difference between the initial temperature Th0 and the comparison temperature Th1 is 2 ° C. or less (Th1-Th0 ≦ 2 ° C.). To do. If it is not 2 ° C. or lower, the captured comparison temperature Th1 is set as the initial temperature Th0, and the process returns to step S13. If it is 2 ° C. or lower, the process proceeds to step S17.

  That is, in the case of continuous use, the temperature inside the overlapping portion 14 is raised by the residual heat of the PTC heater 24. Therefore, a temperature difference ΔTh between the initial temperature Th0 and the comparative temperature Th1 after 5 seconds is calculated, and when it is 2 ° C. or less, it can be determined that it is not continuous use, and when it is higher than 2 ° C., it is continuous use. It can be judged.

  In step S17, the air flow rate W is adjusted stepwise so that the fan 22 operating at a duty ratio of 100% is operated at a duty ratio of 75%. For example, the number of rotations of the drive motor 23 (= the amount of blown air W) is gradually adjusted by decreasing or increasing by 1 to 5% every second. When the fan 22 is operated at a duty ratio of 75%, the detected temperature (outside air temperature) Th2 of the thermistor 26 is taken in step S18, and the target temperature Tx1 (upper limit is, for example, 68 ° C.) to be temperature-controlled is set in step S19. The target temperature Tx1 is a temperature obtained by adding a coefficient α (for example, 30 ° C.) set for each course to the taken-in outside air temperature Th2.

  Thereafter, in step S20, after the PTC heater 24 is turned on, the normal heating control in step S21 and the low temperature determination in step S22 are performed in parallel. As a result of the low temperature determination in step S22, when the flag f indicating whether or not the low temperature determination is 1 (low temperature determination), the process proceeds to step S24, and interrupt heating control is performed instead of the normal heating control in step S21. Execute. That is, the normal heating control in step S21 is interrupted. When f is 0 (non-low temperature determination), the normal heating control is continued without executing the interrupt heating control.

  As shown in FIG. 10, in the normal heating control in step S21, first, in step S21-1, the process waits until 15 seconds elapse. When 15 seconds have elapsed, the process waits until the temperature Th3 of the drying air heated by the PTC heater 24 becomes higher than the target temperature Tx1. That is, after taking in the temperature Th3 of the heated drying air in step S21-2, it is determined in step S21-3 whether the air temperature Th3 is higher than the target temperature Tx1. When the air temperature Th3 is low, the process returns to step S21-2, and when the air temperature Th3 is high, the process proceeds to step S21-4.

  In step S21-4, the duty ratio is increased by β% (for example, 1 to 5%) which is set, and the air blow rate W of the fan 22 is increased. Then, the process waits until 5 seconds elapse in step S21-5. When 5 seconds have elapsed, in step S21-6, after the air temperature Th3 is captured, it is determined in step S21-7 whether the air temperature Th3 is higher than the target temperature Tx1. When the air temperature Th3 is high, the process returns to step S21-4, and the blowing amount W by the fan 22 is increased. If the air temperature Th3 is low, the process proceeds to step S21-8.

  In step S21-8, it is determined whether or not the air temperature Th3 is higher than the temperature obtained by subtracting 5 ° C. from the target temperature Tx1, that is, whether or not the air temperature Th3 is lower than the target temperature Tx1 by less than 5 ° C. If it is high, that is, if the temperature difference ΔTh is less than 5 ° C. and low, the process returns to step S21-5. If it is low, that is, if the temperature difference ΔTh is 5 ° C. or more lower, the process proceeds to step S21-9.

  In step S21-9, the duty ratio is decreased by γ% (for example, 1 to 5%), and the air flow W of the fan 22 is decreased. Then, the process waits for 5 seconds in step S21-10. When 5 seconds have elapsed, in step S21-11, the air temperature Th3 is captured, and then the process proceeds to step S21-12.

  In step S21-12, it is determined whether or not the air temperature Th3 is higher than the temperature obtained by subtracting 5 ° C. from the target temperature Tx1, that is, whether or not the air temperature Th3 is lower than the target temperature Tx1 by less than 5 ° C. If it is high, that is, if the temperature difference ΔTh is less than 5 ° C. and low, the process returns to step S21-5. If it is low, that is, if the temperature difference ΔTh is 5 ° C. or more lower, the process proceeds to step S21-9.

  As shown in FIG. 11, in the low temperature determination in step S22, first, in step S22-1, the process waits until 5 minutes have elapsed from the start of the operation (heating) of the PTC heater 24. After 5 minutes, in step S22-2, the air temperature Th3 is captured, and then the process proceeds to step S22-3.

  In step S22-3, it is determined whether or not the air temperature Th3 is lower than the lower limit threshold T2. If it is less than the lower limit threshold T2, it is determined that there is insufficient heating due to use in a cold region or the deterioration of the PTC heater 24, and 1 is input to f and the process returns. Thereby, the interruption heating control of step 24 is performed. If it is equal to or greater than the lower limit threshold T2, it is determined that the PTC heater 24 is not in use in a cold region and the general use state is not deteriorated, and 0 is input to f and the process returns. Thereby, the normal heating control of step S21 continues to be executed without the interrupt heating control of step 24 being executed.

  As shown in FIG. 12, in the interrupt heating control in step S24, first, in step S24-1, the air flow rate W is adjusted stepwise so that the fan 22 is operated at a duty ratio of 75%. Then, it waits until 5 minutes pass at step S24-2, and when 5 minutes pass, after taking in air temperature Th3 at step S24-3, it progresses to step S24-4.

  In step S24-4, it is determined whether or not the air temperature Th3 is equal to or lower than the lower limit threshold T2. If it is higher than the lower limit threshold value T2, the process proceeds to step S24-5, and after adjusting the air flow rate W stepwise so as to operate the fan 22 at a duty ratio of 75%, the normal heating control step S21 shown in FIG. Proceed to -2. On the other hand, if it is equal to or lower than the lower threshold T2, the process proceeds to step S24-6.

  In step S24-6, the duty ratio is decreased by γ% which is set, and the air flow rate W of the fan 22 is decreased. Then, the process waits until 5 seconds elapse in step S24-7. When 5 seconds have elapsed, in step S24-8, it is determined whether or not the air blow rate W of the fan 22 is the minimum setting (for example, duty ratio 30%). If it is the minimum setting, the process proceeds to step S24-9, and if it is not the minimum setting, the process proceeds to step S24-11.

  In step S24-9, it is determined whether or not the minimum air volume setting continues for 60 seconds. If it continues for 60 seconds, the process proceeds to step S24-10, and the air flow W is adjusted stepwise so that the fan 22 is operated at a duty ratio of 75%, and then fixed to 75% and interrupt heating control is performed. continue. If it has not continued for 60 seconds, the process proceeds to step S24-11.

  In step S24-11, after taking in the air temperature Th3, it is determined in step S24-12 whether the air temperature Th3 is equal to or higher than the gust threshold value T3. If it is less than the gust threshold value T3, the process returns to step S24-6. If the gust threshold value T3 is greater than or equal to the gust threshold value T3, the process proceeds to step S24-13, and after adjusting the air flow rate W stepwise to operate the fan 22 with a duty ratio of 75%, the process waits until 60 seconds elapse. Return to S24-2.

  Thus, in the first drying step, the air flow rate W is adjusted based on the set reference air volume W0. However, when used in a cold region or when the PTC heater 24 is deteriorated, the drying air cannot be heated to the target temperature Tx1 by heating with the PTC heater 24, and becomes lower than the lower threshold T2. For this reason, when the detected temperature Th3 by the thermistor 26 becomes lower than the set lower threshold value T2, the air volume W by the fan 22 is lowered from the reference air volume W0. As a result, heating of the drying air is promoted and can be heated to a temperature higher than the lower limit threshold T2.

  However, when the air flow rate W is lowered, the drying air stays around the discharge port 20 and cannot be spread to every corner between the mattress and the comforter. Therefore, when the detection temperature Th3 of the drying air becomes higher than the gust threshold value T3, the air volume W is increased to the reference air volume W0. Thereby, the drying air staying around the discharge port 20 can be spread to every corner between the mattress and the comforter. Therefore, even when used in a cold region or when the PTC heater 24 is deteriorated, the purpose of drying the futon can be reliably achieved.

  Next, the second drying step executed in place of the first or third drying step in the drying course of “standard”, “fan finish”, “eco”, “warm”, “tick countermeasure”, and “warm air” will be described.

  As shown in FIG. 13, in the second drying step, the microcomputer 34 operates in step S30 to operate the fan 22 with the air flow rate W having a duty ratio of 100%, and then waits for 60 seconds in step S31. When 60 has elapsed, after the air temperature Th3 is taken in at step S32, the process proceeds to step S33.

  In step S33, the process waits until the air temperature Th3 becomes equal to or lower than the target temperature Tx2 (for example, 70 ° C.). When the air temperature Th3 becomes equal to or lower than the target temperature Tx2, the process proceeds to step S34. That is, it is determined whether or not the temperature is higher than the target temperature Tx2. If the temperature is lower than the target temperature Tx2, the process returns to step S32. If the temperature is higher than the target temperature Tx2, the process proceeds to step S34.

  In step S34, the on time t1 and the off time t2 of the PTC heater 24 are initially set (for example, t1 = 3 seconds, t2 = 5 seconds). Thereafter, after the PTC heater 24 is turned off in step S35, the process waits until the off time t2 elapses in step S36. When the off time t2 elapses, the PTC heater 24 is turned on in step S37, and then waits until the on time t1 elapses in step S38.

  When the on-time t1 has elapsed, the process waits until the air temperature Th3 becomes higher than the target temperature Tx2. That is, after taking in the air temperature Th3 in step S39, it is determined in step S40 whether the air temperature Th3 is higher than the target temperature Tx2. If it is equal to or lower than the target temperature Tx2, the process returns to step S39. If it is higher than the target temperature Tx2, the process proceeds to step S41.

  In step S41, it is determined whether or not 30 seconds or more have elapsed after the PTC heater 24 is turned off. If 30 seconds or more have elapsed, the process returns to step S35. If 30 seconds have not elapsed, the process proceeds to step S42, the off time t2 is added by 5 seconds, and the process returns to step S35.

  Thus, in the second drying step, the on-time t1 and the off-time t2 of the PTC heater 24 are adjusted so that the drying air is heated to the set target temperature Tx2 over the set target temperature increase time t. For this reason, the number of cooling cycles of the PTC heater 24 can be reduced while the drying air is reliably heated to the target temperature Tx2, so that the product life can be reliably extended.

  Next, the third drying step executed in the drying course of “standard”, “blow finish” and “warm air” will be described.

  As shown in FIG. 14, in the third drying step, the microcomputer 34 operates the fan 22 with the air flow rate W having a duty ratio of 100% in step S50, and then turns on the PTC heater 24 in step S51. After that, in step S52, it waits until the timer setting time set by “standard” and “blow finish” or the timer setting time set by the user by “warm air” elapses, and when the timer setting time elapses. Return (end).

  Next, the air blowing step executed in the drying course of “standard”, “fan finishing”, “eco” and “air blowing” and the futon cooling step executed in the drying course of “fan finishing” will be described.

  As shown in FIG. 15, in the air blowing (futon cooling) step, the microcomputer 34 operates the fan 22 with the air blowing amount W with a duty ratio of 100% in step S60, and then turns off the PTC heater 24 in step S61. . Thereafter, in step S62, the process waits until a preset timer setting time or a timer setting time set by the user elapses, and returns (ends) when the timer setting time elapses.

  Next, the airframe cooling step executed in all drying courses will be described.

  As shown in FIG. 16, in the airframe cooling step, the microcomputer 34 operates the fan 22 with the air flow rate W having a duty ratio of 35% in step S70, and then turns off the PTC heater 24 in step S71. Thereafter, in step S72, the process waits until a preset timer setting time elapses, and returns (ends) when the timer setting time elapses.

  As shown in FIG. 6, the air blowing step is executed before the drying step for operating the PTC heater 24, and the air blowing amount W is equal to or larger than the air blowing amount W of the drying step. Therefore, a clearance (blower space) can be formed between the close mattress and the comforter. Therefore, in order to form the ventilation space, an arm or a mat made of different parts is not necessary. Therefore, the number of parts can be reduced and the cost can be reduced. Moreover, since the futon dryer 10 of the present embodiment can be folded by hinge-connecting the discharge member 17 to the dryer main body 11, the storage space when not in use can be saved.

  Furthermore, in the drying step executed after the blowing step, the drying air heated by the formed blowing space can be directly supplied to the futon, so that the drying efficiency can be improved. And since the ventilation space is formed in the ventilation step, when the drying step is executed, excessive heating of the drying air can be prevented. That is, when the drying step is executed without forming the blowing space by the blowing step, there is no place for the heated drying air, and the air flows backward to the suction portion 12 side. If it does so, drying air will be suck | inhaled again from the suction inlet 13, and it will be reheated, and an excessive heating may arise. However, in this embodiment, it is possible to reliably prevent such a problem from occurring.

  When the first and third drying steps in which the heating amount by the PTC heater 24 is made constant are executed and the detected temperature Th by the thermistor 26 becomes higher than the upper limit threshold value T1, the heating amount is adjusted by controlling the PTC heater 24 on and off. Perform a second drying step. Therefore, if the drying air does not become excessively heated due to misuse or the like, the first or third drying step is continued to be executed. Accordingly, since the number of cooling cycles of the PTC heater 24 can be significantly reduced while ensuring the safety of the product, the product life can be extended.

  In addition, the futon dryer 10 and its control method of the present invention are not limited to the configuration of the above embodiment, and various modifications can be made.

  For example, in the above-described embodiment, the PTC heater 24 having a self-temperature control function is used as the heating unit, but it may be configured by a heating wire heater. In the above embodiment, the airframe cooling step is executed at the end of all the courses. However, when there is a step in which the PTC heater 24 is not operated before, such as an air blow finishing course or an air blow course, the airframe cooling step is executed. It is good also as a structure which does not. Further, the step executed before the drying step is a blowing step in which the PTC heater 24 is not operated, but may be a step in which the PTC heater 24 is operated as long as the fan 22 is operated at an amount higher than the blowing amount in the drying step. .

  Furthermore, the target temperatures Tx1 and Tx2 including the predetermined range are set in consideration of the outside air, but may be set to a preset fixed temperature (including the range). And in the said embodiment, although it was set as the structure which performs a ventilation amount adjustment drying step and the detection amount Th3 continues performing a heating amount adjustment drying step when the detection temperature Th3 becomes higher than the set upper limit threshold value T1, it is based on the detection temperature Th3. Any configuration may be used as long as one of the air flow rate adjustment drying step and the heating amount adjustment drying step is executed.

DESCRIPTION OF SYMBOLS 10 ... Futon dryer 11 ... Dryer main body 12 ... Suction part 12a ... Back surface 13 ... Suction port 14 ... Superimposition part (insertion part)
15 ... Step part 16 ... Hinge connection part 17 ... Discharge member (insertion part)
DESCRIPTION OF SYMBOLS 18 ... Connection part 19 ... Louver 20 ... Discharge port 21 ... Air flow path 22 ... Fan (blower means)
23 ... Drive motor 24 ... PTC heater (heating means)
25 ... Heat transfer member 26 ... Thermistor (temperature detection means)
27 ... Operation panel 28 ... Operation board 29a-29e ... Switch 30a-30o ... LED
31 ... Board case 32 ... Control board 33 ... Current detection circuit (current detection means)
34 ... Microcomputer (control means)
35 ... ROM

Claims (5)

In a futon dryer that forms an air blowing space between a mattress and a comforter without using a separate member such as an arm or mat,
A suction port having a suction port and disposed on the outside of the comforter;
An insertion portion having a discharge port and disposed between the mattress and the comforter;
Blower means disposed in the air passage extending from the suction port to the discharge port, for sucking outside air from the suction port and discharging from the discharge port;
Heating means for heating air sucked from the suction port by the blowing means;
Control means for executing a drying course including a blowing step for operating the blowing means without operating the heating means before the drying step for operating the blowing means and the heating means ,
The futon dryer is characterized in that the air blowing space is formed when the air blowing amount by the air blowing means in the air blowing step is equal to or larger than the air blowing amount by the air blowing means in the drying step . The drying course control means executes, the after drying step, futon dryer according to claim 1, characterized in that it comprises a body cooling step of operating the blowing means without operating said heating means. The drying course executed by the control means includes a futon cooling step in which the air blowing means is operated without operating the heating means between the drying step and the airframe cooling step, and the execution time is longer than the airframe cooling step. The futon dryer according to claim 2 , further comprising a blow finish course. Drying course in which the control means is executed, according to any one of claims 1 to 3, characterized in that it has an eco course that the execution time of the air blowing step longer than the execution time of the drying step Futon dryer. In a futon dryer that forms an air blowing space between a mattress and a comforter without using a separate member such as an arm or mat,
A suction port having a suction port and disposed on the outside of the comforter;
An insertion portion having a discharge port and disposed between the mattress and the comforter;
Blower means disposed in the air passage extending from the suction port to the discharge port, for sucking outside air from the suction port and discharging from the discharge port;
Heating means for heating air sucked from the suction port by the blowing means;
A control means for executing a drying course having a step of operating the air blowing means at a flow rate equal to or higher than the air blowing amount in the drying step before the drying step of operating the air blowing means and the heating means ,
The futon dryer is characterized in that the blowing space is formed by the amount of air blown by the blower means in the step of operating before the drying step being equal to or larger than the amount of air blown by the blower means in the drying step. .

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