JP6045977B2 - Hot air treatment equipment - Google Patents

Description

  The present invention relates to a hot air treatment apparatus such as a dish dryer, a dishwasher, a dehumidifier dryer, a futon dryer, and a sterilizer.

  Patent Document 1 describes a tableware dryer in which outside air is taken in from a suction port by a blowing means and hot air heated by a heating means is supplied into a drying chamber. This tableware dryer is provided with temperature detecting means for detecting an abnormality at the air outlet facing the drying chamber. This temperature detection means can quickly detect that the air outlet has been blocked due to misuse.

  However, when the air outlet is completely blocked, the air blowing by the air blowing means is blocked. In this case, the heat superheated by the heating means is not transmitted to the temperature detecting means arranged at the outlet. Thus, parts around the heating means (for example, the wall defining the duct) can be overheated. Further, when a thermal fuse is mounted as a safety device, the thermal fuse is melted and the device cannot be operated.

JP 2011-217812 A

  An object of the present invention is to allow ventilation in a duct even when the air outlet is completely blocked, and to prevent the peripheral parts of the heating means from being overheated.

  In order to solve the above problems, a hot air treatment apparatus of the present invention includes a main body having a drying chamber that can be opened and closed by a lid, a duct having an air outlet facing the drying chamber, and the air outlet from the air outlet through the duct. In the hot air treatment apparatus, comprising: a blowing unit that supplies air into the drying chamber; and a heating unit that heats the air supplied by the blowing unit, to the discharge port on the downstream side in the blowing direction from the heating unit of the duct. An exhaust duct having a directed discharge direction in a range of 90 degrees to 180 degrees with respect to the blowing direction in the duct before branching is provided. Here, the range from 181 degrees to 269 degrees is substantially included in the range from 90 degrees to 180 degrees.

  In the case of this hot air treatment device, when the air outlet is completely blocked due to misuse, it is impossible to blow air from the air outlet into the drying chamber, but exhaust is possible through the exhaust duct. Therefore, since the ventilation in the duct is not blocked, the air around the heating means is not overheated. Therefore, it is possible to prevent parts around the heating means from being overheated. In addition, since the exhaust duct exhaust direction is set in the range of 90 degrees to 180 degrees with respect to the duct blowing direction, all or most of the heated hot air is blown out in the normal use state where it is not misused. To the drying chamber.

  A temperature detection for disposing an overheat prevention element for preventing overheating by the heating means downstream of the heating means in the duct and detecting a temperature of hot air downstream of the overheat prevention element in the air blowing direction. Preferably means are provided. Here, when the exhaust duct is not provided, when the outlet is completely blocked, the surroundings of the heating means are overheated. Therefore, the overheat prevention element is activated before detection by the temperature detection means, and the operation of the equipment is stopped. It becomes impossible. However, in the present invention, the ventilation in the duct is not completely blocked by the formation of the exhaust duct. Therefore, the temperature increase can be detected by the temperature detecting means before the overheat prevention element is activated (for example, 172 ° C.) (for example, 86 ° C.). As a result, the operation of the device can be prevented from becoming impossible due to the operation of the overheat prevention element.

  In this case, it is preferable that the exhaust duct is branched and provided on the downstream side in the air blowing direction of the temperature detecting means. In this way, when the air outlet is blocked, the temperature rise can be reliably detected by the temperature detecting means.

  The exhaust port of the exhaust duct is preferably opened outside the drying chamber. As an example, the outlet of the exhaust duct is opened outside the drying chamber and inside the main body. In this way, both the outlet and the outlet are not blocked at the same time. Therefore, it is possible to reliably ensure ventilation in the duct and to reliably prevent overheating of the peripheral parts of the heating means.

  It is preferable that the warm air discharged from the discharge port of the exhaust duct can be discharged to the outside of the main body. In this way, heated air can be reliably discharged outside. Therefore, it is possible to reliably prevent abnormal overheating of peripheral components of the heating means.

  The exhaust duct is provided adjacent to the side of the air outlet of the duct. The air outlet is a portion from which the heated hot air is discharged, so that there is little fluid resistance at the time of discharge. Therefore, it is possible to reduce the possibility that the warm air flows into the exhaust duct in the normal use state. Moreover, a branch part and a discharge port can be arrange | positioned effectively by providing in the side part of a blower outlet.

  In the hot air treatment apparatus of the present invention, even if the air outlet is blocked due to misuse, the air can be exhausted through the exhaust duct, so that ventilation in the duct can be secured. Therefore, overheating of the peripheral parts of the heating means can be prevented. In addition, since the exhaust duct exhaust direction is set in the range of 90 degrees to 180 degrees with respect to the duct blowing direction, all or most of the heated hot air is blown out in the normal use state where it is not misused. To the drying chamber.

The perspective view which shows the tableware dryer of 1st Embodiment which concerns on this invention. Sectional drawing of FIG. The rear side exploded perspective view of FIG. Schematic which shows the duct of 1st Embodiment. The exploded perspective view of a blower outlet unit. The bottom view which shows the 1st member of a blower outlet unit. The top view which shows the 2nd member of a blower outlet unit. Sectional drawing which shows the 1st and 2nd channel | path by a blower outlet unit. Sectional drawing which shows the 3rd channel | path by a blower outlet unit. Sectional drawing which shows the 1st and 2nd channel | path of a blower outlet unit. Sectional drawing which shows the 2nd and 3rd channel | path of a blower outlet unit. Sectional drawing which shows the exhaust duct of a blower outlet unit. The perspective view which shows the blower outlet unit and rear cover of 2nd Embodiment. The perspective view which shows the 2nd member of the blower outlet unit of 3rd Embodiment. Schematic which shows the modification of a duct.

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

(First embodiment)
1 and 2 show a tableware dryer 10 which is a hot air processing apparatus according to a first embodiment of the present invention. The tableware dryer 10 includes a main body 11 having a drying chamber 12 that can be opened and closed by lids 18A and 18B, a water receiving tray 21 and baskets 23A and 23B that are detachably disposed in the drying chamber 12. In addition, the main body 11 includes a fan 24 that is a blowing unit and a heater 26 that is a heating unit, and includes a duct 24 for discharging warm air heated to a predetermined temperature into the drying chamber 12.

  The main body 11 includes a drying chamber 12 having an open front end. The drying chamber 12 includes a bottom wall 13, a rear wall 14 erected from the rear edge of the bottom wall 13, a pair of side walls 15 and 15 erected from the side edge of the bottom wall 13, The upper wall 16 that covers the upper ends of the side walls 15 and 15 is defined. A front side of the opened drying chamber 12 is rotatably attached to a hinge connecting portion 17 projecting from the upper wall 16, and a pair of lids 18A and 18B that rotate horizontally about a vertical axis. It is blocked by.

  The bottom wall 13 is provided with a drain hole 19 in the center. Each side wall 15 is provided with a guide rail 20 at an intermediate position in the height direction. On the upper surface of the bottom wall 13, a water receiving tray 21 having a drain hole 21 a located on the drain hole 19 is disposed. A storage container 22 for storing water adhering to tableware discharged from the drain holes 19 and 21a is detachably disposed at the lower portion of the bottom wall 13. The lower basket 23 </ b> A is placed on the water receiving tray 21. Both ends of the upper basket 23 </ b> B are inserted into the guide rails 20, 20 of the side walls 15, 15, and are arranged in an intermediate portion in the height direction of the drying chamber 12.

  The main body 11 extends from the vicinity of the center of the upper wall 16 to the center of the rear wall 14 in the height direction, has a suction port 33 on one end side located on the upper wall 16, and blows on the other end side located on the rear wall 14. A duct 24 having an outlet 69 is provided. As shown in FIG. 4, a fan 25 that sucks outside air from the suction port 33 and discharges it from the outlet 69 and a heater 26 that heats the air sucked by the fan 25 are disposed inside the duct 24. The fan 25 is a sirocco fan that sucks air along the rotation axis and blows air radially outward. The heater 26 is a nichrome wire heater in which a nichrome wire is wound spirally. The heater 26 is disposed on the downstream side in the air blowing direction by the fan 25. In addition, on both sides of the duct 24 of the rear wall 14, there are provided exhaust parts 27 (see FIG. 1) that are made of a plurality of slits extending in the vertical direction and exhaust the air in the drying chamber 12 to the outside.

  As shown in FIGS. 2 and 3, the duct 24 includes a rear portion of the upper space portion 30 that extends from the front end to the rear end of the upper wall 16 and a rear space that extends downward from the upper end to the center of the rear wall 14. Part 35. The duct 24 is provided with an opening 28 in the rear wall 14, which is one surface that defines the rear space 35, for disposing the fan 25 and the heater 26, and the opening 28 is blocked by the rear cover 41. Has been. The opening 28 is provided with an attachment frame 29 for attaching the rear cover 41 so as to protrude outward.

  The upper space portion 30 is defined by a pair of side plate portions 31, 31 protruding downward from the upper wall 16 and a lower plate portion 32 that continues the lower end portions of the side plate portions 31, 31. A suction port 33 for taking in outside air is formed in the center of the upper wall 16 which is the center in the front-rear direction of the upper space 30. In the upper space portion 30, the rear side from the suction port 33 constitutes the duct 24, and the front side from the suction port 33 constitutes the accommodating portion 77 described later. The hinge connecting portions 17 of the lids 18A and 18B including the suction port 33 are covered with an upper cover 34 that is detachably disposed on the upper wall 16. The outside air flows from the gap between the upper wall 16 and the upper cover 34 and flows into the duct 24 through the suction port 33.

  The rear space portion 35 includes a pair of side plate portions 36 and 36 projecting forward from the side edge of the opening portion 28 of the rear wall 14, an inner plate portion 37 continuing the inner end portion of the side plate portions 36 and 36, and It is defined by a rear cover 41 disposed in the opening 28. The side plate portion 36 is continuous with the side plate portion 31 of the upper space portion 30 and constitutes an integral wall. The inner plate portion 37 continuously forms an integral wall through the lower plate portion 32 and the inclined plate portion 38. In the lower part of the rear space part 35, an arrangement part 39 for arranging the air outlet unit 45 is formed. The arrangement portion 39 is wider in width than the upstream side of the rear space portion 35. Further, a communication port 40 communicating with the inside of the drying chamber 12 is formed between the lower end edge of the inner plate portion 37 located in the arrangement portion 39 and the lower end edge of the opening portion 28.

  The rear cover 41 is attached to the attachment frame 29 of the opening 28 by screwing. A frame wall 43 that forms an involute passage 42 projects from the inner surface side of the rear cover 41. The involute passage 42 is closed by screwing the mounting board 44. A fan 25 is rotatably disposed on the mounting substrate 44 so as to be positioned within the frame wall 43, and a drive motor (not shown) for the fan 25 is disposed on the opposite surface.

  The disposing unit 39 is provided with a blower outlet unit 45 for mixing hot air heated by the heater 26 and discharging the air with a uniform temperature distribution. As shown in FIG. 5, the air outlet unit 45 includes a first member 50 disposed on the suction port 33 side and a second member 60 disposed on the communication port 40 side. By the first member 50 and the second member 60, an inflow portion 46 (first passage) in which the heater 26 is disposed, and a pair of diversion portions 47A and 47B (second passage) branching from the inflow portion 46, A merging portion 48 (third passage) that joins the diverting portions 47A and 47B is formed. Further, in the present embodiment, when the air outlet 69 is blocked, the exhaust duct 49 is formed to send the air blown by the fan 25 to the outside of the drying chamber 12 and ensure ventilation in the duct 24. .

  As shown in FIG. 5 and FIG. 6, the first member 50 has a rectangular upper plate 51 and a lid shape with a lower end opening having a rectangular tubular outer plate 52 provided on the outer peripheral edge of the upper plate 51. . The first member 50 is provided with a bracket portion 53 for fixing to the second member 60 by screwing.

  An inflow portion 46 is formed in the first member 50 so as to be positioned on the rear cover 41 side in the assembled state to the main body 11. The inflow portion 46 is disposed at the outlet of the involute passage 42 and communicates with the suction port 33 side. The inflow portion 46 has a rectangular cylindrical shape in which the dimension in the horizontal direction X is narrower than the horizontal dimension of the upper plate 51 and the dimension in the vertical direction Y is substantially the same as the vertical dimension of the upper plate 51. The inflow portion 46 has an upper end located above the upper plate 51 and a lower end located at the same height as the lower end of the outer plate 52. In the inflow portion 46, the inner end plate 54 in the vertical direction Y is positioned at the approximate center of the upper plate 51, and the outer end plate 55 facing the inner end plate 54 protrudes outward from the upper plate 51. The inner end plate 54 engages with the upper end of the partition wall 65 of the second member 60 described below at the lower end.

  In the first member 50, the region excluding the inflow portion 46 constitutes the outlet side of the flow dividing portions 47 </ b> A and 47 </ b> B and the inlet side of the merging portion 48 in the inside surrounded by the outer plate 52. The diversion portions 47A and 47B are formed on the outer side where the inflow portion 46 is formed with an extension line of the inner end plate 54 indicated by a one-dot chain line in FIG. The merge portion 48 is formed on the inner side where the inflow portion 46 is not formed with the extension line of the inner end plate 54 as a boundary.

  In addition, on both side portions of the first member 50 in the lateral direction X, discharge portions 56 that are outlet sides of the exhaust duct 49 are formed. The discharge portion 56 is partitioned from the flow dividing portions 47A and 47B and the merging portion 48 by a partition wall 57. As shown in FIG. 12, the discharge part 56 is an L-shaped passage in which a connection port 58 is formed on the merging part 48 side, and a discharge port 59 is formed on the diversion part 47A, 47B side. The discharge port 59 is opened outside the drying chamber 12. Specifically, as shown in FIG. 5, the partition wall 57 includes a first partition portion 57 a extending in a direction orthogonal to the partition wall 65 of the second member 60 to be described later, and the partition wall 65 into the flow dividing portions 47 </ b> A and 47 </ b> B. And a second partition 57b extending in parallel with the upper plate 51 so as to be positioned. A region on the merging portion 48 side where the second partition portion 57b is not formed constitutes the connection port 58. A discharge port (outlet) 59 is formed in a region on the side of the flow dividing portions 47A and 47B surrounded by the first and second partition portions 57a and 57b.

  As shown in FIGS. 5 and 7, the second member 60 includes a frame plate 61 having a convex shape in plan view facing the outer plate 52 of the first member 50 and the outer end plate 55 of the inflow portion 46. In the frame plate 61, the projecting portion 62 facing the outer end plate 55 of the inflow portion 46 is inclined inward toward the lower side so that the lower end edge is rectangular. A mounting portion 63 for mounting on the arrangement portion 39 is provided on the outer peripheral portion of the frame plate 61. The mounting portion 63 is provided with a screw boss 64 that faces the bracket portion 53 of the first member 50.

  Inside the frame plate 61, a partition wall 65 is provided so as to extend in the lateral direction X that defines the inflow portion 46, the flow dividing portions 47 </ b> A and 47 </ b> B, and the joining portion 48. The partition wall 65 extends in the opposite direction from the lower end edge of the frame plate 61 toward the upper end edge with respect to the blowing direction by the inflow portion 46. As shown in FIG. 10, an engagement plate portion 66 that engages with the inner end plate 54 of the inflow portion 46 is formed at the center of the upper end of the partition wall 65. In the interior of the second member 60, with the partition wall 65 as a boundary, the projecting portion 62 side constitutes the diverting portions 47 </ b> A and 47 </ b> B, and the opposite side constitutes the merging portion 48. As shown in FIG. 11, the flow dividing portions 47 </ b> A and 47 </ b> B and the merging portion 48 communicate with each other in the first member 50 that is the tip of the partition wall 65.

  As shown in FIGS. 7 and 8, the lower ends of the flow dividing portions 47 </ b> A and 47 </ b> B are closed by the bottom plate 67. That is, the bottom plate 67 is provided so as to be closed from the lower end edge of the frame plate 61 on the projecting portion 62 side to the lower end edge of the partition wall 65. At the center of the bottom plate 67, a branch portion 67a having a triangular shape protrudes. This branching portion 67a is located at a portion facing the blowing direction from the inflow portion 46, extends from the center of the outlet of the inflow portion 46, which is the upper end of the frame plate 61, to the bottom plate 67, and divides the warm air supplied from the inflow portion To do. In each of the diversion portions 47A and 47B, the hot air supplied from the inflow portion 46 of the first member 50 collides with the branch portion 67a, the bottom plate 67, the frame plate 61, and the upper plate 51 of the first member 50. By doing this, the blowing direction is changed. Specifically, the branch portion 67a and the bottom plate 67 of the second member 60 constitute a first bend portion 68A that changes the downward blowing direction from the inflow portion 46 to a lateral (outward) direction that is an orthogonal direction. In addition, the bottom plate 67 and the frame plate 61 of the second member 60 constitute a second bend portion 68B that changes the horizontal air blowing direction upward. Further, the frame plate 61 of the second member 60 and the upper plate 51 of the first member 50 constitute a third bend portion 68C that changes the upward blowing direction to the lateral (front) direction.

  As shown in FIGS. 7 and 9, the merging unit 48 merges the warm air from the divergence units 47A and 47B, and sends out the temperature distribution to be uniform. The lower end edge of the merging portion 48 is positioned at the communication port 40 of the arrangement portion 39 and constitutes a blower outlet 69 that faces the drying chamber 12 of the main body 11. As shown in FIG. 11, the air outlet 69 is inclined upward from the partition wall 65 to the inner end plate 61 a of the frame plate 61, and can be discharged at a wide angle from the rear wall 14 defining the drying chamber 12 toward the bottom wall 13. is there. As shown in FIG. 9, a plurality of louvers 70 extending along the air blowing direction to the air outlet 69 are formed inside the merging portion 48. Every other louver 70 a located in the inflow portion 46 extends upward beyond the upper end of the partition wall 65 and supports the wall of the inflow portion 46. As shown in FIG. 7, constricted portions 71 are provided on both sides of the merging portion 48, which are opposite positions in the air blowing direction from the outlets of the flow dividing portions 47A and 47B, to narrow the area where ventilation is possible. The throttle portion 71 is composed of a plate portion provided so as to partially close the upper ends of the louvers 70b, 70b located at both ends. Thereby, the area | region in which the aperture | diaphragm | squeeze part 71 can ventilate becomes narrower than the part which does not provide the aperture | diaphragm | squeeze part 71. FIG.

  As shown in FIGS. 9 and 12, communication portions 72 of the exhaust duct 49 that communicate with the discharge portion 56 of the first member 50 are provided on both sides of the merging portion 48. The communication portion 72 is provided adjacent to the side portion of the air outlet 69 by a partition wall 73 provided in parallel between the louver 70b and the frame plate 61 located at both ends. The partition wall 73 extends from the lower end edge of the inner end plate 61 a of the frame plate 61 to the inner surface of the partition wall 57 of the discharge unit 56. Thereby, between the blower outlet 69 and the lower end edge of the partition wall 73, the ventilation | gas_flowing part 74 (branch part) which can ventilate by the ventilation by the fan 25 turning is formed. The discharge direction through the communication portion 72 is opposite (180 degrees) with respect to the air blowing direction at the junction 48 before branching.

  In a normal use state in which the air outlet 69 is not blocked, the fluid resistance between the louvers 70 and 70 is low, so that warm air does not flow into the exhaust duct 49 with the reverse discharge direction and high fluid resistance. All or most of it is discharged into the drying chamber 12. On the other hand, in the misuse state where the air outlet 69 is blocked, the fluid resistance between the louvers 70, 70 increases, so that the air passage 74 passes between the louvers 70 b and the partition wall 73 at both ends and turns about 180 degrees at the ventilation portion 74. Then, the warm air can be sent out of the drying chamber 12 through the communication portion 72 and the discharge portion 56 of the exhaust duct 49. Exhaust from the duct 24 through the exhaust duct 49 to the outside also occurs when both ends (parts) of the air outlet 69 in which the ventilation portion 74 is formed are blocked.

  In the duct 24 in which the air outlet unit 45 is disposed, a region extending from the suction port 33 to the outlet (lower end) of the inflow portion 46 of the air outlet unit 45 constitutes a first passage in which the fan 25 and the heater 26 are disposed. To do. In addition, the diversion portions 47A and 47B in the outlet unit 45 form a pair of second passages that branch from the first passage and blow air in a direction different from the first passage. Furthermore, the confluence | merging part 48 in the blower outlet unit 45 is connected to the downstream of each 2nd channel | path, and comprises the 3rd channel | path which joins the warm air from each 2nd channel | path. Among them, the downstream side of the first passage including the heater 26, the second passage, and the third passage are aggregated in the outlet unit 45 as described above, and are arranged outside the rear wall 14 that defines the drying chamber 12. Yes.

  As shown in FIGS. 4 and 8, the tableware dryer 10 of the present embodiment includes a temperature fuse 75 that is an overheat prevention element for preventing the heater 26 from overheating, and a temperature for detecting the heated hot air temperature. A thermistor 76 serving as temperature detecting means is provided.

  The thermal fuse 75 is disposed on the downstream side of the heater 26 in the inflow portion 46. The thermal fuse 75 is connected in series to the heater 26 and melts when the temperature exceeds a set temperature (for example, 172 ° C.) due to overheating, thereby interrupting energization of the heater 26.

  The thermistor 76 is disposed in one of the current dividing portions 47B on the downstream side of the thermal fuse 75. The thermistor 76 is located upstream of the ventilation part 74 to which the exhaust duct 49 is branched. In the present embodiment, the diverter 47B is disposed in the second bend portion 68B that is a corner portion between the bottom plate 67 and the frame plate 61. This portion is a portion where the warm air heated by the heater 26 is mixed by the first bend portion 68A and then secondarily mixed. Therefore, the thermistor 76 can detect the temperature of the warm air having a uniform temperature distribution.

  As shown in FIGS. 2 and 4, in the upper space 30, a space located on the opposite side of the fan 25 in the blowing direction with respect to the suction port 33 is used as a housing 77 for housing the control board 80. In the accommodating portion 77, a substrate holder 78 for disposing the control substrate 80 is disposed. Further, an operation panel portion 79 is formed at the front end of the accommodating portion 77.

  Electronic parts (not shown) for controlling the fan 25 and the heater 26 are mounted on the control board 80. A microcomputer (control means) which is one of the electronic components controls energization to the fan 25 and the heater 26 based on the detection value input from the thermistor 76. Specifically, the heater 26 is turned on when the hot air temperature detected by the thermistor 76 falls below a lower limit value (for example, 50 ° C.). When the hot air temperature based on the detection value of the thermistor 76 exceeds an upper limit value (for example, 86 ° C.), the heater 26 is turned off. That is, the threshold value for shutting off the energization of the heater 26 based on the detection value of the thermistor 76 is lower than the set temperature at which the thermal fuse 75 operates due to overheating.

  The control board 80 is provided with a heat sink 81 that is a heat dissipating element for dissipating heat generated by the electronic component. The heat sink 81 includes an attachment part 82 attached to the electronic component via the control board 80 and a wind receiving part 83 extending from the inside of the accommodating part 77 to the lower part facing the suction port 33. Further, the wind receiving portion 83 includes a guide surface 84 that is inclined toward the downstream side in the blowing direction by the fan 25 and is disposed so as to face the suction port 33. The heat sink 81 is formed by bending a metal (for example, aluminum) plate material having good thermal conductivity. The edge of the guide surface 84 located on the suction port 33 side is located at the end (the accommodating portion 77 side) of the suction port 33 on the side opposite to the blowing direction. Thereby, the guide surface 84 guides the air sucked from the suction port 33 to the downstream side in the blowing direction by the fan 25.

(Flow of warm air during normal use)
As shown in FIG. 2 and FIG. 4, in the tableware dryer 10, external air is sucked from the suction port 33 when the fan 25 is rotated. The sucked room temperature air first collides with the guide surface 84 of the heat sink 81 and is guided downstream of the duct 24. At this time, the heat sink 81 is cooled by heat exchange with room temperature air.

  Thus, since the tableware dryer 10 of this embodiment is provided with the wind-receiving part 83 which opposes the suction inlet 33, it is located in the ventilation direction reverse side with respect to the suction inlet 33, and accommodation with little flow of air Even in the portion 77, the heat generated by the electronic component mounted on the control board 80 can be reliably radiated. Moreover, since the wind receiving part 83 has the guide surface 84 which protrudes toward the suction inlet 33 and guides it to the ventilation direction downstream side, while being able to maintain the air flow in the duct 24 satisfactorily, the surface area with which the air contacts is increased. Since it can be secured sufficiently, the heat dissipation performance can be improved.

  The air guided from the suction port 33 to the downstream side of the duct 24 is blown from the upper space portion 30 to the rear space portion 35. And it flows in into the inflow part 46 of the blower outlet unit 45 in the downstream of the rear side space part 35, is heated by the heater 26, and becomes warm air. In the temperature distribution in this state, the heating temperature gradually decreases as the distance from the heater 26 increases.

  The heated warm air is sent from the inflow part 46 to the diversion parts 47A and 47B. In the flow dividing portions 47A and 47B, first, the air collides with the branching portion 67a, the air blowing direction is changed to an oblique direction along the inclined surface of the branching portion 67a, and the hot air whose temperature distribution is uneven is mixed. Next, the hot air is further mixed by colliding with the bottom plate 67 and changing the blowing direction to the orthogonal direction (horizontal outward). Subsequently, it collides with the frame plate 61 and the air blowing direction is changed to an orthogonal direction (vertically upward), thereby further mixing. Subsequently, it collides with the upper plate 51 and is further mixed by changing the blowing direction to the orthogonal direction (horizontal front direction).

  In this way, the warm air mixed by a plurality of collisions is sent to the junction 48 from the diverters 47A and 47B. In the merging portion 48, first, it collides with the outer plate 52 and the blowing direction is changed to the orthogonal direction. At this time, the blowing direction of the warm air from each of the diverters 47A and 47B remains partly changed vertically downward and changed horizontally inward. In addition, the air volume in which the blowing direction is changed to the vertically downward direction is suppressed by the throttle portion 71 provided at the position opposite to the outlets of the flow dividing portions 47A and 47B. As a result, the warm air from the flow dividing portions 47A and 47B has a large amount of air inward in the horizontal direction and is mixed by the merging (collision) of the warm airs.

  The hot air mixed by the merging is further mixed by colliding with the louver 70, then passes through the gap between the louvers 70, 70 and is discharged toward the bottom wall 13 of the drying chamber 12. Thereafter, the gas swirls in the drying chamber 12 and flows upward, and is exhausted from the exhaust unit 27 to the outside of the main body 11. At this time, the dishes are dried by passing between the dishes arranged in the drying chamber 12.

  Thus, in the tableware dryer 10 of this embodiment, since the warm air heated by the heater 26 is mixed by collision several times before it is discharged from the outlet 69 into the drying chamber 12, the warm air is heated. The temperature distribution of the wind can be made uniform. Therefore, it is possible to reliably prevent the drying state (efficiency) from being biased depending on the position of the tableware set in the drying chamber 12.

  Moreover, in this embodiment, since the blower outlet unit 45 which has several bend part 68A-68C which changes a ventilation direction to an orthogonal direction is provided, without changing the dimension from the heater 26 to the blower outlet 69, it is compact. A uniform temperature distribution can be ensured with a sufficient volume. In addition, the mixing action for making the temperature distribution uniform can be more reliably realized by the throttle portion 71 and the louver 70 provided in the merge portion 48.

  Furthermore, since the blower outlet unit 45 including the heater 26 is disposed outside the rear wall 14 that defines the drying chamber 12, the overall height of the main body 11 can be prevented from being increased, and the suction port 33 can be formed. You can set the desired position. And since the blower outlet unit 45 discharges warm air from the blower outlet 69 toward the bottom wall 13 of the drying chamber 12, it is possible to reliably increase the lower temperature of the drying chamber 12, which is difficult to raise the temperature. it can.

  And since the thermistor 76 which detects the warm air temperature heated with the heater 26 is arrange | positioned in the diversion | distribution part 47A, 47B which has several bend part 68A-68C, the exact numerical value (temperature) without a bias is detected. can do. Therefore, the temperature in the drying chamber 12 can be reliably adjusted without causing overheating or underheating.

(Flow of warm air when misused)
The tableware dryer 10 may be misused by hooking the cloth on the basket 23B in order to dry and sterilize the cloth different from the original purpose. In this misuse state, when the cloth has completely blocked the air outlet 69, the air blowing toward the air outlet 69 by the fan 25 is blocked. As a result, the air around the heater 26 is overheated, but the heat is not transmitted to the thermistor 76. In this case, parts around the heater 26 (for example, a wall defining the duct 24) may be overheated. And there is a possibility that the thermal fuse 75 mounted as a safety device operates.

  However, in the present embodiment, since the exhaust duct 49 is provided on the downstream side of the heater 26 of the air outlet unit 45, the heated air can be blown to the outside of the drying chamber 12 through the exhaust duct 49. Therefore, the ventilation in the duct 24 is not interrupted.

  Specifically, when the air outlet 69 is closed, the fluid resistance between the louvers 70 and 70 increases, so that the flow toward the louvers 70 and 70 is blocked in the junction 48. As a result, the outlet of the warm air is opened to the outside of the drying chamber 12, passes between the louvers 70 b at both ends having a lower fluid resistance than between the louvers 70, 70, and the partition wall 73, and flows into the ventilation portion 74. Thereafter, the warm air swirls in the ventilation portion 74 and flows into the communication portion 72, and then is sent out of the drying chamber 12 through the discharge port 59 of the discharge portion 56. In the present embodiment, the warm air discharged from the discharge port 59 is sucked by the fan 25 again.

  Thus, in the tableware dryer 10 of this embodiment, ventilation in the duct 24 can be ensured even when the air outlet 69 is blocked due to misuse. Moreover, since the discharge port 59 is opened in the main body 11 and outside the drying chamber 12, the discharge port 59 is not blocked. Therefore, it is possible to prevent the peripheral parts of the heater 26 from being overheated via air. Further, the temperature rise can be detected by the thermistor 76 before the thermal fuse 75 is activated. As a result, it is possible to prevent the operation of the tableware dryer 10 from being impossible due to the operation of the temperature fuse 75. Further, since the exhaust duct 49 is provided at the side of the air outlet 69, the ventilation portion 74 and the discharge port 59 which are branched portions with the duct 24 can be effectively arranged.

(Second Embodiment)
FIG. 13 shows the outlet unit 45 and the rear cover 41 of the tableware dryer 10 of the second embodiment. The second embodiment is different from the first embodiment in that the hot air discharged from the exhaust duct 49 can be discharged to the outside of the main body 11. Specifically, the first member 50 of the outlet unit 45 is provided with a discharge port 59 that is an outlet of the exhaust duct 49 so that only the outer plate 52 that faces the rear cover 41 opens. The rear cover 41 is provided with an exhaust portion 85 that is inserted into the discharge port 59 by closing the opening 28. The exhaust portion 85 has a rectangular tube shape with both ends open. In the second embodiment configured as described above, the same operations and effects as the first embodiment can be obtained. In addition, when the air outlet 69 is closed, the heated air can be reliably discharged to the outside, so that abnormal overheating can be reliably prevented.

(Third embodiment)
FIG. 14 shows the second member 60 of the outlet unit 45 of the tableware dryer 10 of the third embodiment. The second embodiment is different from the first embodiment in that each louver 70 is provided with a communication hole 86 communicating with the ventilation portion 74. In 3rd Embodiment comprised in this way, when all or one part of the blower outlet 69 is obstruct | occluded, it can exhaust to the exhaust duct 49 reliably.

  In addition, the warm air processing apparatus of this invention is not limited to the structure of the said embodiment, A various change is possible.

  For example, in the above-described embodiment, the discharge direction of the exhaust duct 49 is set to turn 180 degrees with respect to the air blowing direction at the junction 48 that is a branching portion. However, as shown in FIG. You may set as follows. Even if it does in this way, the effect | action and effect substantially the same as 1st Embodiment can be acquired. That is, in the exhaust duct 49 of the present invention, setting the discharge direction toward the discharge port 59 in the reverse direction may be set in the range of 90 to 180 degrees with respect to the blowing direction in the duct 24 before branching. . This is because when the temperature is in the range of 1 to 89 degrees, there is a high possibility that hot air leaks into the exhaust duct 49 during normal use. However, this is not the case when an opening / closing valve that opens when the exhaust duct 49 reaches a predetermined pressure is interposed. Moreover, in the said embodiment, although the exhaust duct 49 was provided adjacent to the side part of the blower outlet 69, if it is the downstream of the heater 26, a branch position can be changed as desired.

  In the first embodiment, the air in the duct 24 is exhausted to the drying chamber 12 by the exhaust duct 49. In the second embodiment, the air in the duct 24 is exhausted to the outside of the main body 11 by the exhaust duct 49. Another abnormal time air outlet different from the air outlet 69 may be provided on the wall defining the drying chamber 12, and the hot air from the outlet 59 may be discharged into the drying chamber 12 from the air outlet for abnormal time.

  And in the said embodiment, although the exhaust duct 49 branched and connected to the duct 24 of this invention was employ | adopted for the vertical type tableware dryer 10 with a high total height, the upper part of the main body 11 was made openable and closable with a circular-arc-shaped cover body. The dome-shaped tableware dryer 10 may be configured to employ the duct 24 of the present invention. Moreover, although the hot air processing apparatus of the present invention has been described by applying the tableware dryer 10 that dries dishes, a dishwasher, dehumidifier dryer, futon dryer, sterilizer, etc., heats and discharges air. If it is an apparatus which does, the same effect | action and effect can be acquired by employ | adopting the exhaust duct 49 of this invention.

10 ... Tableware dryer (hot air treatment device)
DESCRIPTION OF SYMBOLS 11 ... Main body 12 ... Drying chamber 18A, 18B ... Lid 21 ... Water receiving tray 23A, 23B ... Basket 24 ... Duct 25 ... Fan (blower means)
26. Heater (heating means)
DESCRIPTION OF SYMBOLS 33 ... Suction port 45 ... Outlet unit 46 ... Inflow part 47A, 47B ... Diverging part 48 ... Confluence part 49 ... Exhaust duct 50 ... 1st member (air outlet unit)
56 ... discharge part 58 ... connection port 59 ... discharge port 60 ... 2nd member (air outlet unit)
61 ... Frame plate 65 ... Partition wall 67 ... Bottom plate 67a ... Branching part 69 ... Blowout port 70 ... Louvre 74 ... Ventilation part (branching part)
75 ... Thermal fuse (overheat prevention element)
76. Thermistor (temperature detection means)
77 ... Accommodating part 80 ... Control board 81 ... Heat sink

Claims (3)

A main body having a drying chamber that can be opened and closed by a lid, a duct having an air outlet facing the drying chamber, an air supply means for supplying air from the air outlet to the drying chamber through the duct, and supplied by the air blowing means A hot air treatment apparatus comprising heating means for heating air to be
An exhaust duct is branched and provided downstream of the heating means of the duct in the air blowing direction ,
Characterized in that said exhaust duct is connected to the side of the outlet of the duct, the discharge direction toward the discharge port is in the range of from 90 degrees to 180 degrees with respect to the blowing direction in the duct before the branch A warm air treatment device.   The hot air treatment apparatus according to claim 1, wherein the discharge direction of the exhaust duct is swiveled 180 degrees with respect to the blowing direction in the duct. The blowing direction downstream side of said heating means in said duct, with overheat prevention device to prevent overheating due to the heating means is arranged, in the blowing direction downstream side of the overheating prevention device, for detecting the temperature of hot air A temperature detecting means is disposed ;
The hot air processing apparatus according to claim 1 or 2 , wherein the exhaust duct is branched and provided downstream of the temperature detection means in the blowing direction .

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