JP3892126B2 - Hand dryer - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a hand drying apparatus for washing hands in a washroom or a toilet and drying wet hands with warm air.
[0002]
[Prior art]
Conventionally, this type of hand-drying apparatus is known as shown in FIGS.
[0003]
As shown in the figure, the main body 101 fixed to the wall surface is composed of a front case 102 and a water tray 103 protruding from the lower part, and a drying space 102 a is formed between the front case 102 and the water tray 103. . The front case 102 is provided with a blowing means 104 for generating a high-pressure high-speed air flow, a heating means 105, and a control means 108. A blowing duct 106 for guiding the warm air generated by the blowing means 104 and the heating means 105 is provided. A blow-out nozzle 106 a having a rapidly reducing shape is formed at the tip of the blowing duct 106. The blowing nozzle 106 a is located at the lower end of the front case 102 and is installed so as to blow air toward the water tray 103. In addition, a detecting means 110 for detecting a hand put out into the drying space 102a is provided in the vicinity of the blowing nozzle 106a, and the control means 108 receives the detection signal from the detecting means 110 and turns the blowing means 104 and the heating means 105 on. Drive control. In addition, a protrusion band 107 is formed on the front and left and right sides of the water tray 103.
[0004]
When a wet hand is inserted into the dry space 102a in the above configuration, it is detected by the detection means 110, warm air is formed by the air blowing means 104 and the heat generating means 105, and the air is blown from the blowing nozzle 106a. At this time, warm air hits the hand that has been put out, and the hand is dried. When the hand is withdrawn, the detection means 110 is not detected, so the air blowing means 104 and the heat generating means 105 are stopped.
[0005]
Moreover, although the water droplets away from the hand are collected in the water receiving tray 103 on the bottom surface, they are easily scattered by the air blown by the air blowing nozzle 106a, so that they are scattered by the front and side protrusion bands 107 of the water receiving pan 103. Was to prevent.
[0006]
[Problems to be solved by the invention]
In such a conventional hand-drying device, since air is blown from the blow nozzle toward the water tray, the water tray tends to vibrate and the noise becomes loud, and when the hand is pushed out into the drying chamber, the air flow is disturbed and wind noise is generated. There is a problem that the noise increases, and because the blowing nozzle is on one side, there is a problem that both sides of the hand out cannot be dried at the same time, reducing the noise generated in the drying chamber during blowing and simultaneously drying both sides of the hand It is required to be able to do it.
[0007]
In addition, part of the airflow blown from the blowout nozzle passes without being hit by the hand and is dispersed around the drying chamber, and the airflow hitting the hand is similarly dispersed around the hand, so that the hand is dried. However, there is a problem that the blown airflow is not sufficiently utilized, and it is required to improve the drying efficiency by effectively using the airflow from the blowout nozzle so as not to be wasted.
[0008]
In addition, since the blowing duct is connected to the downstream side of the heat generating means, warm air leaks from the connecting portion, the temperature inside the front case rises, and an increase in the ambient temperature of the control means causes a thermal load on the electrical components. If it adds, there exists a subject that it becomes easy to cause a failure, and it is requested | required that a warm air does not leak into a front case.
[0009]
In addition, since there is an opening on the side of the drying chamber, there is a problem that the airflow inside the drying chamber escapes and the drying efficiency deteriorates, and it is required to prevent the airflow from escaping outside the drying chamber. .
[0010]
Also, when the airflow changes direction in the drying chamber, that is, in a portion with a small radius of curvature such as the bottom surface of the drying chamber, the airflow is disturbed to the left and right as the wind direction changes, so the airflow easily escapes beyond the protruding band. There is a problem, and it is required to prevent airflow from escaping from the bottom of the drying chamber.
[0011]
Further, there is a problem that the drying efficiency is deteriorated unless the airflow or the hot air is widely distributed throughout the drying chamber, and it is required that the airflow or the hot air can be circulated throughout the drying chamber.
[0012]
In addition, when the hand is placed in a horizontal direction in the drying room, the airflow spreads on the upper surface of the hand, but there is a problem that the airflow reaching the lower surface of the hand is reduced and drying cannot be performed efficiently. It is required that the air flow around.
[0013]
In addition, the airflow from the blowout nozzle gradually spreads back and forth in the air, and part of the airflow escapes to the outside of the drying chamber when it hits the protruding wall. It is required that the air flow does not escape outside the drying chamber.
[0014]
In addition, the airflow circulating in the drying chamber flows along the wall surface and returns to the blowout nozzle. It is required to form a circulating flow without disturbing the flow.
[0015]
In addition, depending on the direction of the protruding wall, there is a problem that an impact noise is generated when the blower nozzle blows against the protruding wall, and the circulation flow in the drying chamber is disturbed, reducing the noise generated in the protruding wall and ensuring the circulation flow. It is required that it can be formed.
[0016]
The present invention solves such a conventional problem, prevents noise caused by vibration of the water tray and wind noise, and can simultaneously dry both sides of the hand with a blowing nozzle provided in one direction, In addition, it is possible to improve the drying efficiency by effectively using the air flow of the blowing nozzle, to prevent the hot air generated by the blower and the heating element from leaking into the main body, and to the side of the drying chamber The airflow that escapes from the air can be reduced to increase the drying efficiency, and the airflow that escapes from the portion where the cross-sectional shape of the drying chamber has a small radius of curvature to the side can be reduced, and the drying efficiency can be increased. It can circulate the airflow to increase the drying efficiency, can also efficiently dry the lower side of the hand that has been put out, can prevent the blown airflow of the blowing nozzle from escaping to the outside of the protruding wall, Blowing It is possible to form a circulating flow without disturbing the air flow, also has an object to provide a hand dryer which is capable of reliably forming a circulating air while reducing noise caused by the protruding wall.
[0019]
[Means for Solving the Problems]
  In order to achieve the above object, the hand drying device of the present invention has a blower provided in the main body, a drying chamber having a substantially C-shaped cross section recessed in the front surface of the main body, and an air flow from the blower. A blow drying nozzle having a blowing nozzle for feeding into a drying chamber, and having a protruding wall at a front end of the drying chamber, wherein the blowing direction of the blowing nozzle is directed toward the protruding wall, the blowing air current from the blowing nozzle Is,in frontThe circulation flow is formed by swirling along the inner wall surface of the drying chamber and joining the blown airflow.
[0020]
And according to this invention, the hand-drying apparatus which can improve drying efficiency effectively using the airflow of a blowing nozzle is obtained.
[0021]
Another means is that a heating element is provided in a blowing duct integrally formed with a blowing nozzle, and the heating element is arranged between the blower and the blowing nozzle.
[0022]
And according to this invention, the hand dryer which can prevent a warm air from leaking from a connection part and spreading in a main body is obtained.
[0023]
Another means is that a continuous rib is erected on the inner peripheral edge of the side opening of the drying chamber.
[0024]
And according to this invention, the hand dryer which can reduce the air volume which escapes from the side surface of a drying chamber, and can raise drying efficiency is obtained.
[0025]
Another means is to increase the height dimension of the continuous rib located at the portion where the cross-sectional shape of the drying chamber has a small radius of curvature.
[0026]
And according to this invention, the hand dryer which can reduce the air volume which escapes from the lower part in a drying chamber, and can raise drying efficiency is obtained.
[0027]
Another means is that a blowing nozzle is provided at the front end of the drying chamber.
And according to this invention, the hand-drying apparatus which can circulate airflow widely in a drying chamber and can raise drying efficiency is obtained.
[0028]
The other means is provided by tilting the blowing direction of the blowing nozzle toward the drying chamber.
[0029]
And according to this invention, the hand drying apparatus which can dry efficiently also the back side of a hand is obtained.
[0030]
Further, the other means includes a blower provided in the main body, a drying chamber having a substantially C-shaped cross section provided in the front surface of the main body, and a blowout nozzle for sending the airflow from the blower into the drying chamber. And the outer front-end | tip part of this blowing nozzle is made longer than an inner front-end | tip part.
[0031]
And according to this invention, the hand-drying apparatus which can prevent that the blowing airflow of a blowing nozzle escapes to the outer side of a protrusion wall is obtained.
[0032]
Further, the other means includes a blower provided in the main body, a drying chamber having a substantially C-shaped cross section provided in the front surface of the main body, and a blowout nozzle for sending the airflow from the blower into the drying chamber. A wind direction changing plate having a curved surface is erected in a drying chamber inside the shibuki nozzle.
[0033]
And according to this invention, the hand dryer which can change the direction of a circulating flow just before a blowing nozzle is obtained.
[0034]
Another means is that the angle formed by the inner surface of the protruding wall with the blowing direction of the blowing nozzle is set to 45 degrees or less.
[0035]
And according to this invention, the hand dryer which can reduce the noise which arises in a protrusion wall and can form a circulating wind reliably is obtained.
[0037]
DETAILED DESCRIPTION OF THE INVENTION
  The present invention has a blower provided in the main body, a drying chamber having a substantially C-shaped cross section recessed in the front surface of the main body, and a blowout nozzle for sending the airflow from the blower into the drying chamber, The drying chamber includes a projecting wall at a front end, and a hand drying device in which the blowing direction of the blowing nozzle is directed toward the protruding wall, and a blowing airflow from the blowing nozzle is,in frontA large swirl along the inner wall surface of the drying chamber forms a circulation flow by joining the blown airflow, and when the airflow blown from the blowout nozzle hits the hand that has been drawn out, the airflow changes direction. When the airflow hits the back of the hand and no airflow hits the hand that has been put out, drying is performed in the drying chamber, and both have the action of effectively utilizing the airflow away from the hand to enhance the drying effect.
[0038]
Further, a heating element is provided in a blowing duct integrally formed with a blowing nozzle, and the heating element is arranged between the blower and the blowing nozzle. Hot air that has passed through the heating element is blown through the blowing duct. Since it is guided and travels to the middle and is ejected without leaking and warm air does not leak into the main body, it has the effect of preventing thermal damage to the control unit due to warm air leakage.
[0039]
In addition, continuous ribs are erected on the inner periphery of the side opening of the drying chamber, and the continuous rib provided on the periphery of the side opening of the drying chamber prevents airflow in the drying chamber from escaping from the side. Thus, the airflow can be maintained in the drying chamber.
[0040]
Moreover, the cross-sectional shape of the drying chamber is made by increasing the height of the continuous rib located at the portion where the radius of curvature is small, and when the airflow circulating in the drying chamber changes direction at the bottom, the flow is disturbed. It is easy to escape to the outside from the side opening, but the height of the continuous rib is increased at the part where the cross-sectional shape of the drying chamber is located at the part where the radius of curvature is small, so that the airflow escapes from the side. It has the effect | action that it can suppress and can maintain the air flow circulation in a drying chamber.
[0041]
In addition, the blowing nozzle is provided at the front end of the drying chamber, and the airflow or warm air that flows from the blowing nozzle at the upper end of the front surface toward the inner surface side of the protruding wall can be circulated throughout the drying chamber. It has an effect that airflow or warm air can be applied so as to wrap the hand that has been put out into the room.
[0042]
In addition, the blowing direction of the blowing nozzle is inclined toward the drying chamber, and when the hand is inserted horizontally or obliquely downward in the drying chamber, the drying chamber is divided into upper and lower spaces by the hand and tilted. The airflow that has been sent out from the suction nozzle and passed through the surface of the hand has a function of being able to efficiently dry the lower surface of the hand by branching at the rear wall and flowing below the upper and lower spaces partitioned in the drying chamber.
[0043]
And a blower provided in the main body, a drying chamber having a substantially C-shaped cross section recessed in the front surface of the main body, and a blowout nozzle for sending airflow from the blower into the drying chamber. This is because the outer tip is longer than the inner tip, and the air flow that is blown out from the blowing nozzle is deflected and spreads in the direction of the inner tip that is shorter than the longer outer tip when blown out. , It does not diffuse in the direction of the outer tip, and has the effect of preventing the blown airflow from escaping to the outside of the protruding wall.
[0044]
And a blower provided in the main body, a drying chamber having a substantially C-shaped cross section recessed in the front surface of the main body, and a blowout nozzle for sending airflow from the blower into the drying chamber. A wind direction changing plate having a curved surface is erected in the inner drying chamber, and the blown airflow circulates in the drying chamber and approaches the blowing nozzle from the lateral direction, but along the wind direction changing plate having a curved surface. Since the direction is changed by approximately 90 degrees, the airflow is in the same direction as the blowing direction of the blowing nozzle, and the circulation flow can be formed without disturbing the blowing flow of the blowing nozzle.
[0045]
In addition, the angle formed by the inner surface of the protruding wall with the blowing direction of the blowing nozzle is set to 45 degrees or less, and the air blown from the blowing nozzle is received at a shallow acute angle along the surface of the protruding wall to soften the impact. In addition, it becomes an introduction part of direction change at the bottom of the drying chamber and has an effect that smooth direction change can be performed.
[0046]
Embodiments of the present invention will be described below with reference to the drawings.
[0047]
【Example】
Example 1
As shown in FIGS. 1 to 4 to 6, the main body 1 fixed to the wall surface includes a blower unit 2 that generates a high-speed airflow, and a drying unit 4 that includes a drying chamber 3 having a substantially C-shaped cross section at a lower portion thereof. Have.
[0048]
The blower unit 2 includes a blower 5 such as a turbo blower that generates a high-speed airflow and a blowout duct 6. A blowout nozzle 6 a is formed at the tip of the blowout duct 6. A control means 8 is provided in the vicinity of the blower unit 2.
[0049]
The drying unit 4 is provided with the blowing nozzle 6a at the upper part of the drying chamber 3, and has an opening 3c for inserting a hand below the blowing nozzle 6a. Non-contact type detection means 10 for detection is provided. The control means 8 receives the detection signal from the detection means 10 and drives and controls the blower 5.
[0050]
Moreover, the drying unit 4 is provided with a protruding wall 4a that forms a part of the drying chamber 3 at the lower part of the front surface, and the blowing direction of the blowing nozzle 6a is set toward the protruding wall 4a.
[0051]
In the above configuration, when a hand is inserted into the drying chamber 3 as shown in FIGS. 1 and 4B, the detection means 10 detects the hand and the detection output is turned on. 5a is operated to send a high-speed air flow from the blowout nozzle 6a. The high-speed airflow blown from the blowout nozzle 6a hits the surface of the hand, and dries while separating attached water droplets.
[0052]
Further, the high-speed airflow is separated vertically at the rear wall surface of the drying chamber 3 to generate the circulation flows 7a and 7b vertically along a substantially C-shaped cross-sectional shape. At this time, since the circulating flow 7b flows along the back side (lower side) of the hand, the back side of the hand can be dried simultaneously. Therefore, in the drying chamber 3, the airflow is simultaneously applied to both sides of the inserted hand, and the drying efficiency can be improved.
[0053]
Also, as shown in FIGS. 2 and 4 (a), when the high-speed airflow blown from the delivery nozzle 6a does not hit the hand, the high-speed airflow flows into the tip and the inner surface of the protruding wall 4a at a shallow angle as it is. Since the wind direction is changed by being guided from the bottom surface having the bottom to the rear wall surface, the impact force on the drying unit 4 is reduced, the occurrence of turbulence is reduced, and vibration and noise can be reduced.
[0054]
In the present embodiment, the air blowing unit is provided on the upper part of the drying unit. However, even if the air blowing unit is provided on the lower part of the drying unit, the same effect can be obtained.
[0055]
  In addition, the thing of the drying chamber whose cross-sectional shape is substantially E shape was shown as a reference implementation shape in FIG.
[0056]
(Example 2)
In the following examples, the same components as those described in the previous examples are given the same reference numerals, and detailed description thereof is omitted.
[0057]
As shown in FIG. 1 to FIG. 4 to FIG. 6, a drying chamber 3 recessed in the front surface of the main body is provided, and a blowout nozzle 6 a that blows a high-speed air current is provided in the drying chamber 3. A projecting wall 4a faces the opening 3C on the front surface of the main body 1 below the blowing nozzle 6a. The inner surface of the drying chamber 3 is continuously formed with a smooth plane or curved surface.
[0058]
In the above configuration, as shown in FIGS. 1 and 4B, when a hand is inserted into the drying chamber, a high-speed air current is blown out from the blowing nozzle 6a and hits the surface of the hand, and drying is performed while blowing off water droplets. Further, the airflow flows from the rear wall surface of the drying chamber 3 so as to swirl along the inner surface of the protruding wall 4a through the bottom surface and reaches the back surface of the hand. Thus, by blowing a single airflow against the front and back surfaces of the hand and drying, the blown airflow can be used effectively.
[0059]
Further, as shown in FIGS. 2 and 4 (a), when the airflow of the blowing nozzle 6a passes without hitting the hand, the high-speed airflow flows into the tip and the inner surface of the protruding wall 4a as it is from the bottom surface having a curved surface. Change the flow direction to the rear wall. Furthermore, the rear wall surface rises, passes through the upper wall surface, and merges with the blown airflow of the blowout nozzle 6a to form a circulation flow. This circulation flow can dry the entire wall surface of the drying chamber 3 over a wide range. The amount of moisture remaining in the drying chamber 3 can be reduced. Therefore, even when the blown airflow of the blowout nozzle 6a does not hit the hand that has been pushed out, the inner wall surface of the drying chamber 3 can be efficiently dried, and the blown airflow can be used effectively.
[0060]
(Example 3)
As shown in FIGS. 1-6, in the blowing duct 6 attached to the blowing side of the air blower 5, the heat generating bodies 6b, such as a semiconductor heater, are accommodated. The blowing nozzle 6 a is formed in a rapidly reducing shape at the tip of the blowing duct 6. The control means 8 is housed in the main body 1 together with the blower 5 and the blowout duct 6, and receives the detection signal from the detection means 10 to drive and control the blower 5 and the heating element 6b.
[0061]
In the above configuration, when a hand is inserted into the drying chamber 3, the blower 5 and the heating element 6b are driven by detection by the detection means 10, and high-speed hot air is blown out from the blowing nozzle 6a. At this time, since the heating element 6b is accommodated in the blowing duct 6, the air flow sent from the blower 5 to the blowing duct 6 is heated when passing through the heating element 6b, and the blowing nozzle is not leaked on the way. 6a can be blown out as high-speed hot air.
[0062]
Moreover, even if an airflow leaks from the connection part of the air blower 5 and the blowing nozzle 6a, since the airflow is before passing the heat generating body 6b, the atmospheric temperature in the main body 1 does not rise significantly.
[0063]
Therefore, since the warm air can be prevented from leaking into the main body 1 from the connection portion, it is possible to prevent a thermal adverse effect due to an increase in the ambient temperature of the control means 8 in advance.
[0064]
(Example 4)
As shown in FIGS. 1 to 4 to 6, continuous ribs 3 b are erected on the inner peripheral edge of the substantially C-shaped opening 3 a formed on both side surfaces of the drying chamber 3.
[0065]
In the above configuration, when the hand is inserted into the drying chamber 3, the blower 5 and the heating element 6b are driven by the detection means 10, and a high-speed air current is blown out from the blowing nozzle 6a. Some include vector components, and some airflow escapes from the side openings 3 a to the outside of the drying chamber 3. However, what flows in the horizontal direction along the wall surface of the drying chamber 3 is blocked by the continuous rib 3b provided on the inner peripheral edge and stays in the drying chamber 3, and the circulating airflow in the drying chamber 3 can be maintained. Since the air volume to be obtained is sufficiently obtained, the drying efficiency of the hand can be increased.
[0066]
(Example 5)
As shown in FIGS. 1-4, the height dimension of the continuous rib 3b provided in the side opening part 3a of the drying chamber 3 is enlarged in the part where the curvature radius of the drying chamber 3 becomes small.
[0067]
For example, the curvature radius of the bottom curved surface is made small so that the bottom of the drying chamber 3 changes the direction of the air flow within a limited depth dimension. Furthermore, the height dimension of the continuous rib 3b erected on the side of the bottom surface is increased.
[0068]
In the above configuration, the high-speed air flow blown from the blowing nozzle 6a changes direction at the bottom surface of the drying chamber 3 to form a circulating flow, but when the high-speed air flow changes direction, the air flow is disturbed. Because of this, there is also an airflow that tries to escape from the drying chamber 3 over the continuous rib 3b. However, since the height dimension of the continuous rib 3b provided at the bottom of the drying chamber 3 is increased, the circulating air flow in the drying chamber 3 can be maintained without letting the air flow escape to the outside. Furthermore, it is possible to prevent water droplets collected at the bottom of the drying chamber 3 from being scattered from the side openings 3a, thereby preventing the surroundings from becoming dirty.
[0069]
(Example 6)
As shown in FIGS. 1 to 4, a blowing nozzle 6 a is provided in the upper front portion of the drying chamber 3, and the blowing nozzle 6 a is positioned at the upper end of the front opening of the drying chamber 3.
[0070]
The airflow sent from the blower 5 is blown out at high speed from the blowing nozzle 6a at the upper front of the drying chamber 3 toward the lower protruding wall 4a.
[0071]
In the above configuration, the blowing nozzle 6a is provided at the upper front portion of the drying chamber 3, that is, located at the upper end of the entire opening, and thus blows air toward the protruding wall 4a at a high speed so that a high-speed air current hits the hand. Even in the case where it directly hits the protruding wall 4a, it flows so as to circulate through the drying chamber 3 having a substantially C-shaped cross section, eliminates the dead space where the air current does not reach, and allows the air flow to spread throughout the drying chamber 3 in a short time. be able to.
[0072]
Accordingly, the airflow is sufficiently distributed to the front and back surfaces of the hand inserted into the drying chamber 3, improving the drying efficiency of the hand, shortening the drying time of the wet hand, and further reducing the entire wall surface in the drying chamber 3. It can be dried at the same time.
[0073]
(Example 7)
As shown in FIGS. 1 to 4, a blowing nozzle 6 a that blows a high-speed air stream is provided at an upper portion of the drying chamber 3 so as to be inclined toward the inner surface of the drying chamber 3. That is, the blowing direction of the high-speed air stream is inclined toward the drying chamber 3 with respect to the perpendicular A that is lowered from the tip of the blowing nozzle 6a.
[0074]
In the above configuration, when the hand is pushed out horizontally or obliquely downward in the drying chamber 3, the blowing nozzle 6a provided on the upper portion of the drying chamber 3 is inclined toward the inside of the drying chamber 3, so that the high-speed airflow is A large amount of airflow 7b flows in the downward direction when the surface of the air flows toward the rear wall surface of the drying chamber 3 and is separated vertically by the rear wall surface. The airflow 7b flows along the curved surface of the bottom and the protruding wall 4a, changes direction, hits the back surface (lower surface) of the hand, and can efficiently dry the lower surface of the hand.
[0075]
Further, since the projecting wall 4a is provided at the lower front portion of the drying chamber 3, a space is always generated in the drying chamber 3 below the hand that has been pushed out, and the separated airflow circulates through the lower space. It is possible to dry the front and back of the hand at the same time.
[0076]
(Example 8)
As shown in FIGS. 1 to 4 to 5, the size of the outer tip 6 c of the blowing nozzle 6 a that blows out the high-speed airflow is longer than the size of the inner tip 6 d. A protruding wall 4a is located in the blowing direction of the blowing nozzle 6a.
[0077]
In the above configuration, when the airflow sent from the blower 5 passes through the blowout nozzle 6a formed at the tip of the blowout duct 6, pressure is applied by the rapidly reducing shape of the blowout nozzle 6a, and the airflow is increased and blown out. At this time, since the outer tip 6c of the blowing nozzle 6a is formed longer than the inner tip 6d, the compressed air current is blown while being deflected in the direction of the inner tip 6d, and the air current spreading toward the outer tip 6c is The amount of airflow blown out can be prevented from escaping to the outside of the protruding wall 4a located in the blowing direction of the blowing nozzle 6a. Therefore, since the total air volume blown from the blowing nozzle 6a can be sent into the drying chamber 3 without omission, it is possible to increase the drying efficiency by circulating a large amount of air.
[0078]
Example 9
As shown in FIGS. 1 to 4 to 5, a wind direction changing plate 11 is erected on the upper wall surface of the drying chamber 3 in the vicinity of the horizontally long blowing nozzle 6 a.
[0079]
The wind direction changing plate 11 has a curved surface and serves to change the circulating flow along the upper wall surface of the drying chamber 3 to the blowing direction of the blowing nozzle 6a.
[0080]
In the above-described configuration, the high-speed air stream ejected from the blow nozzle 6a moves as a circulating flow in the drying chamber 3 along the inner surface of the protruding wall 4a, and the flow direction is changed downward by the wind direction changing plate 11 on the upper wall surface. The air direction is changed in substantially the same direction as the blowing nozzle 6a.
[0081]
Therefore, the high-speed air flow of the blowing nozzle 6a is not disturbed by the return of the circulation flow, and the circulation flow is formed in the drying chamber 3 by combining the return of the circulation flow in accordance with the blowing direction of the blowing nozzle 6a. Can be promoted.
[0082]
(Example 10)
As shown in FIGS. 1-4, the blowing nozzle 6a is provided facing the protruding wall 4a provided in the lower front part of the drying chamber 3, and as shown in FIG. 2, the blowing direction of the blowing nozzle 6a and the protruding wall 4a The angle α formed by the inner surface is set to 45 degrees or less. That is, the blowing direction of the blowing nozzle 6a provided in the upper part of the drying chamber 3 intersects the protruding wall 4a at a shallow angle.
[0083]
In the above configuration, the high-speed air flow blown from the blow nozzle 6a hits the protruding wall 4a at a shallow acute angle, so that there is little impact on the protruding wall 4a, and generation of vibration and noise can be suppressed.
[0084]
In addition, the projecting wall 4a accepts the high-speed air flow without disturbance, so that the direction of the high-speed air current can be smoothly changed as an introduction portion when the direction of the drying chamber 3 changes from the bottom surface to the rear wall surface. A circulating flow can be reliably formed.
[0085]
【The invention's effect】
As is clear from the above embodiments, according to the present invention, a projecting wall projecting upward is provided at the lower front portion of the drying chamber having a substantially C-shaped cross section, and the blowing direction of the blowing nozzle is directed to the projecting wall. Further, it is possible to provide a hand drying device that can reduce vibrations and noise at the bottom of the drying chamber and can simultaneously dry both sides of the hand with a one-way blowing nozzle.
[0086]
In addition, when the blown airflow from the blowout nozzle hits one side of the hand drawn out into the drying chamber, the airflow that has left the hand swirls along the inner wall surface of the drying chamber, hits the other side of the hand, If the airflow does not hit, the swirling airflow will be swirled along the inner wall of the drying chamber to form a circulating flow. Even if the blown airflow does not hit the hand, the circulating flow formed in the drying chamber can move over the inner wall surface of the drying chamber to dry the water adhering to the wall surface. It is possible to provide an effective hand drying device that can effectively use the blown airflow to increase the drying efficiency of the hand.
[0087]
In addition, a heating element is provided in the blowing duct integrally formed with the blowing nozzle, and the heating element is arranged between the blowing device and the blowing nozzle so that the hot air does not leak before the blowing nozzle, and is controlled. It is possible to provide a hand-drying device that is effective in preventing adverse thermal effects on the device.
[0088]
In addition, by providing a continuous rib at the periphery of the side opening of the drying chamber, it is possible to maintain the circulation flow so that the air in the drying chamber does not escape from the side opening and enhance the hand drying effect. An effective hand dryer can be provided.
[0089]
Also, by increasing the height of the continuous rib where the cross-sectional shape of the drying chamber has a smaller radius of curvature, it prevents the circulating high-speed airflow from getting over the continuous rib when the direction changes in the drying chamber. Thus, it is possible to provide a hand-drying device that is effective in maintaining the formation of a circulating flow.
[0090]
Further, by providing a blow nozzle at the end of the drying chamber having a substantially C-shaped cross section and blowing the air flow toward the protruding wall located in front of the drying chamber, there is no dead space in the drying chamber. Can be distributed throughout the drying chamber, and a hand-drying device having an effect of improving the drying efficiency can be provided.
[0091]
In addition, by tilting the blowing direction of the blowing nozzle provided at the end of the drying chamber having a substantially C-shaped cross section toward the drying chamber, a large amount of air flows around the hand that is put into the drying chamber. Can be efficiently dried.
[0092]
In addition, by making the outer tip of the blow nozzle longer than the inner tip, the air flow traveling to the outside of the blow nozzle is reduced, the air flow does not escape to the outside of the protruding wall, and a large amount of air is circulated in the drying chamber. It is possible to provide a hand-drying device having an effect of improving the drying efficiency.
[0093]
In addition, by installing an air direction change plate having a curved surface in the vicinity of the inner tip of the blowing nozzle, the high-speed airflow of the blowing nozzle is not disturbed by the return of the circulating flow, and the return of the circulating flow is blown out. By merging in accordance with the blowing direction of the nozzle, it is possible to provide a hand-drying device that is effective in promoting the formation of a circulating flow in the drying chamber.
[0094]
In addition, the angle formed by the inner surface of the protruding wall provided at the lower front part of the drying chamber with the blowing direction of the blowing nozzle is 45 degrees or less, so that the angle at which the high-speed airflow from the blowing nozzle hits the protruding wall becomes a shallow acute angle and softens the impact. When it is received, it suppresses the generation of vibration and noise, and when the airflow does not hit the hand, it functions as an introduction part when the high-speed airflow changes direction from the bottom surface of the drying chamber to the rear wall surface, ensuring the formation of a circulating flow In addition, it is possible to provide a hand-drying apparatus having an effect of being able to fill the drying chamber with airflow.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view when an airflow hits the hands of the hand drying apparatus according to Embodiments 1 to 10 of the present invention.
[Figure 2] Cross-sectional view when airflow does not hit the hand
[Figure 3]referenceCross-sectional view showing the shape
4A is a photograph showing a thermoview image displayed on a display when no airflow hits the hands of Examples 1 to 10. FIG.
  (B) A photograph showing a thermoview image displayed on the display when airflow hits the same hand
FIG. 5 is an enlarged cross-sectional view around the blowout nozzles of Examples 3 to 8 and 9
FIG. 6 is a front view of the first to fourth embodiments.
FIG. 7 is a sectional view of a conventional hand dryer.
FIG. 8 (a) A photograph showing a thermoview image displayed on the display when no airflow hits the same hand.
  (B) A photograph showing a thermoview image displayed on the display when airflow hits the same hand
[Explanation of symbols]
  1 Body
  3 Drying room
  3a Side opening
  3b Continuous rib
  4a protruding wall
  5 Blowers
  6 Blowout duct
  6a Outlet nozzle
  6b Heating element
  6c Outer tip
  6d Inner tip
  11 Wind direction change board

Claims (8)

A blower provided in the main body, a drying chamber having a substantially C-shaped cross section provided in front of the main body, and a blowout nozzle for sending an airflow from the blower into the drying chamber. front ends comprising a projection wall, a hand dryer comprising towards the delivery direction to the protruding wall of the outlet nozzle, outlet air flow from the blowing nozzle is greatly pivoted along the inner wall surface of the front Symbol drying chamber A hand-drying device that forms a circulating flow by joining the blown airflow. The hand-drying device according to claim 1, wherein a heating element is provided in a blowing duct integrally formed with a blowing nozzle, and the heating element is disposed between the blowing device and the blowing nozzle. The hand dryer according to claim 1 or 2, wherein a continuous rib is provided on the inner periphery of the side opening of the drying chamber. The hand dryer according to claim 3, wherein the height of the continuous rib located at a portion where the radius of curvature of the drying chamber is small is increased. The hand drying apparatus according to any one of claims 1 to 4, wherein a blowing nozzle is provided at a front end of the drying chamber. The hand-drying apparatus in any one of Claims 1-5 provided inclining the blowing direction of the blowing nozzle toward the drying chamber. A blower provided in the main body, a drying chamber having a substantially C-shaped cross section provided in front of the main body, and a blowout nozzle for sending an airflow from the blower into the drying chamber, inside the blowout nozzle of the drying chamber, the hand drying apparatus according to any one of claims 1 to 6 comprising erected wind direction changing plate having a curved surface. The hand dryer according to any one of claims 2 to 7, wherein an angle formed by the inner surface of the protruding wall with the blowing direction of the blowing nozzle is 45 degrees or less.

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