JP2013063238A - Heat blower - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heat blower that can prevent hair and skin from being damaged.SOLUTION: The heat blower 1 includes: an air channel 4 which is placed within a housing 3 and is provided with a suction port 4a and a discharge port 4b at both ends; an air supply unit 5 which is placed in the upstream of the air channel 4 and is configured to introduce air through the suction port 4a and discharge the air through the discharge port 4b; a heating unit 6 which is provided on the downstream side of the air supply unit 5 and is configured to heat the air; a mist generating unit 10 configured to generate mist containing an acidic component; a detecting unit 11 configured to detect acidity of the mist generated by the mist generating unit 10; and a controller 8 configured to control an amount of mist generated by the mist generating unit 10. The controller 8 controls the amount of mist generated by the mist generating unit 10 according to the acidity of the mist which is detected by the detection unit 11.

Description

  The present invention relates to a heated air blower.

  2. Description of the Related Art Conventionally, a heated air blowing device is known in which a mist generating device that generates weak acid mist is provided in a main body case, and weak acid mist is discharged from an outlet (for example, see Patent Document 1).

  In Patent Document 1, a weakly acidic mist in the range of 3.5 to 6.0 pH that gently acts on the skin and hair is discharged. In this way, by discharging the weak acid mist, the effects of the weak acid mist can be efficiently applied to the hair and scalp, and the treatment effect can be obtained by tightening the cuticle to make the hair moist. Yes.

JP 2009-136303 A

  However, with the above-described conventional technology, it is possible to discharge acidic mist having an acidity in the range of 3.5 to 6.0 pH, but it is not possible to control the amount of discharged acidic mist. Therefore, an excessive amount of an acidic component is imparted to hair damaged by bleaching or perm or dry skin, and the dehydration reaction by the acidic component is promoted, and there is a possibility that the hair or skin is damaged.

  Then, an object of this invention is to obtain the heating air blower which can suppress damaging hair and skin.

  The first feature of the present invention is that the air flow path is provided in the housing and provided with suction ports and air outlets on both sides, and is arranged upstream of the air flow path and introduces air from the air suction port. Generated from the blower outlet, a heating unit provided on the downstream side of the blower unit to heat the blown air, a mist generating unit that generates mist containing an acidic component, and the mist generating unit. A detection unit that detects the acidity of the mist, and a control unit that controls the amount of mist generated by the mist generation unit, wherein the control unit determines the acidity of the mist detected by the detection unit. Accordingly, the gist is to control the amount of mist generated by the mist generator.

  The gist of the second feature of the present invention is that the mist generating part is provided in the air flow path, and the detecting part is arranged downstream of the mist generating part.

  According to a third aspect of the present invention, the air flow path includes a branch path that is branched from the downstream side of the air blowing unit and the upstream side of the heating unit and is supplied with air that does not pass through the heating unit, The gist is that at least a part of the mist generated by the mist generation unit is supplied to the branch path, and the detection unit is provided on the downstream side of the branch path.

  According to a fourth aspect of the present invention, the control unit drives the mist generation unit when the air blowing unit is driven, so that the acidity of the mist detected by the detection unit becomes a predetermined value or less. Further, the gist is to control the mist generating unit.

  According to a fifth feature of the present invention, the control unit drives the mist generating unit when the air blowing unit is driven, and the acidity of the mist detected by the detecting unit is within a predetermined value or less. The gist of the invention is to control the mist generator so as to be constant.

  In a sixth aspect of the present invention, the control unit drives the mist generation unit when the air blowing unit is driven, and the acidity of the mist detected by the detection unit is within a predetermined value or less. The gist is to control the mist generating unit so as to repeat the increase and decrease.

  According to a seventh aspect of the present invention, the heated air blowing device includes an air flow rate switching unit that switches an air flow rate, and a second control unit that controls an amount of mist generated by the mist generating unit, The gist of the second control unit is to control the mist generation unit so that the mist generation amount decreases when the blast amount switching unit is driven to decrease the blast amount.

  According to an eighth aspect of the present invention, the heating air blower includes air blowing temperature switching means for switching the air blowing temperature, and a second control unit that controls the amount of mist produced by the mist producing unit, The gist of the second control unit is to control the mist generation unit so that the amount of mist generation decreases when the blowing temperature switching means is driven and the blowing temperature is lowered.

  According to the present invention, the controller of the heated air blower controls the amount of mist generated by the mist generator according to the acidity of the mist detected by the detector. Therefore, it is possible to suppress excessive discharge of mist containing an acidic component. As a result, it becomes possible to discharge mist containing an acidic component in an amount suitable for the hair quality and skin quality, and it is possible to suppress damage to the hair and skin.

It is side sectional drawing which shows typically the hair dryer concerning 1st Embodiment of this invention. It is a timing chart which shows the method of controlling the production amount of the mist produced | generated by the mist production | generation part by the control part concerning 1st Embodiment of this invention. It is a graph which shows typically the relationship between the detected nitrate ion density | concentration and the electric current which flows into an acidic mist production | generation part. It is a graph which shows typically change of an average friction coefficient at the time of giving mist containing an acidic ingredient to hair. It is side sectional drawing which shows typically the hair dryer concerning the 1st modification of 1st Embodiment of this invention. It is side sectional drawing which shows typically the hair dryer concerning the 2nd modification of 1st Embodiment of this invention. It is a timing chart which shows the method of controlling the production amount of the mist produced | generated by the mist production | generation part by the control part concerning 2nd Embodiment of this invention. It is a timing chart which shows the method of controlling the production amount of the mist produced | generated by the mist production | generation part by the control part concerning 3rd Embodiment of this invention. It is side sectional drawing which shows typically the hair dryer concerning 4th Embodiment of this invention. It is a timing chart which shows the method of controlling the production amount of the mist produced | generated by the mist production | generation part by the 2nd control part concerning 4th Embodiment of this invention. It is side sectional drawing which shows typically the hair dryer concerning 5th Embodiment of this invention. It is a timing chart which shows the method of controlling the production amount of the mist produced | generated by the mist production | generation part by the 2nd control part concerning 5th Embodiment of this invention. It is a sectional side view which shows typically the hair dryer concerning 6th Embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Below, a hair dryer is illustrated as a heating air blower. Note that similar components are included in the following embodiments. Therefore, in the following, common reference numerals are given to those similar components, and redundant description is omitted.

(First embodiment)
The hair dryer 1 as a heating air blower concerning this embodiment is provided with the holding part 1a as a part which a user grasps with a hand, and the main-body part 1b couple | bonded in the direction which cross | intersects the holding part 1a. In use, the grip portion 1a and the main body portion 1b are configured to have a substantially T-shaped or L-shaped appearance (substantially T-shaped in this embodiment). Further, the power cord 2 is pulled out from the protruding end of the grip portion 1a. And the holding | grip part 1a is divided | segmented into the base part 1c and the front-end | tip part 1d by the side of the main-body part 1b, and these base part 1c and the front-end | tip part 1d are connected rotatably via the connection part 1e. Yes. In addition, the front-end | tip part 1d can be folded to the position in alignment with the main-body part 1b.

  The hair dryer 1 includes a housing 3 that forms an outer wall of the hair dryer 1, and the housing 3 is configured by joining a plurality of divided bodies together. A cavity is formed inside the housing 3, and various electrical components are accommodated in the cavity.

  In the present embodiment, the flow of air flowing from the inlet opening (suction port) 4a on one side (right side) in the longitudinal direction (left-right direction in FIG. 1) to the outlet opening (discharge port) 4b in the housing 3 of the main body 1b. A path 4 is formed. That is, an air flow path 4 having an inlet opening (suction port) 4a and an outlet opening (discharge port) 4b on both sides is provided inside the housing 3 of the main body 1b.

  An air blowing section 5 is arranged on the upstream side (side closer to the inlet opening 4a) in the air flow path 4, and the air introduced from the inlet opening (suction port) 4a is discharged to the outlet opening (discharge port). It is made to discharge from 4b. In the present embodiment, the air blowing unit 5 includes a fan 51 disposed on the upstream side in the air flow path 4 and a motor 52 disposed on the downstream side of the fan 51 to drive the fan 51. Then, when the motor 52 is energized to drive the fan 51 and rotate the fan 51, the air flows into the air flow path 4 from the outside through the inlet opening 4 a, passes through the air flow path 4, and the outlet opening 4 b. An air flow (air blowing) discharged from the outside is formed.

  Moreover, the heating part 6 which heats ventilation is arrange | positioned in the downstream (side closer to the exit opening 4b than the ventilation part 5) of the ventilation part 5. As shown in FIG. When this heating part 6 is operated, the air flow (air blowing) formed by the air blowing part 5 is heated and hot air is blown out from the outlet opening 4b. As the heating part 6, for example, a heater formed by winding and arranging a strip-like and corrugated electric resistor along the inner periphery of the housing 3 of the main body part 1b can be used.

  Furthermore, in this embodiment, the mist production | generation part 10 which produces | generates the mist containing an acidic component in the ventilation flow path 4 is accommodated. In this embodiment, the mist production | generation part 10 which produces | generates the mist containing nitrate ion (acidic component) is provided between the ventilation part 5 in the ventilation flow path 4, and the heating part 6. FIG.

  As the mist generation unit 10, an electrostatic atomization type device can be used. In other words, a high voltage is applied between a pair of electrodes made of a conductive metal material to generate a discharge (corona discharge, etc.), and a nanometer-size mist containing nitrate ions is generated by the discharge action. Can be used.

  In addition, a detection unit 11 that detects the acidity of the mist (mist containing nitrate ions) generated by the mist generation unit 10 is housed in the air flow path 4. In the present embodiment, the detection unit 11 is made of a conductive substance, and is disposed on the downstream side of the mist generation unit 10. And the pH (acidity) of the mist produced | generated by the mist production | generation part 10 by the detection part 11 is detected.

  Specifically, mist is applied to the detection unit 11 in a state where the detection unit 11 is positively charged by supplying power to the hair dryer 1. In this way, when the positively charged detection unit 11 hits the mist, nitrate ions contained in the mist adhere to the detection unit 11 and the charge amount of the detection unit 11 changes. The amount of nitrate ions contained in the mist is detected from the change in the amount of charge per unit time of the detection unit 11. The detection unit 11 may be a metal or a plastic as long as it is a conductive substance. In addition, the shape of the detection unit 11 may be spherical, rectangular parallelepiped, or elliptical. Further, the arrangement position of the detection unit 11 is not limited to the vicinity of the outlet opening (discharge port) 4 b, and the detection unit 11 may be arranged anywhere in the air flow path 4.

  A push-type power switch 7 is provided on the side surface of the grip portion 1a. When the power switch 7 is operated to turn on the power, power is supplied to the hair dryer 1 through the power cord 2 extending from the base end portion of the gripping portion 1a, and the motor 52 of the blower portion 5 is driven to rotate the fan 51. Then, air is taken into the air flow path 4 from the inlet opening (suction port) 4a. When the power is turned on, the heating unit 6 generates heat and the air sent from the blower unit 5 is heated. And the heated air turns into warm air and is discharged from the exit opening (discharge port) 4b.

  At this time, the mist containing nitrate ions generated by the mist generation unit 10 is discharged from the outlet opening (discharge port) 4b together with air, and the detection unit 11 detects the amount of nitrate ions included in the mist.

  The hair is dried by applying warm air blown from the outlet opening (discharge port) 4b to the hair. Furthermore, the mist containing nitrate ions discharged from the outlet opening (discharge port) 4b is applied to the hair or skin so that the acidity of the hair or skin is in the range of 3.5 to 6.0 pH. , Hair and skin (scalp, face, etc.) are not damaged.

  Moreover, in this embodiment, the control part 8 which controls each output of the ventilation part 5, the heating part 6, the mist production | generation part 10, and the detection part 11 is provided in the cavity part of the housing 3 of the holding part 1a. The control unit 8 controls the ON / OFF timing of the air blowing unit 5 (motor 52) and the ON / OFF timing of the heating unit 6. Further, the ON / OFF timing of the mist generating unit 10 and the ON / OFF timing of the detecting unit 11 are controlled. In the present embodiment, electronic parts such as the control unit 8 and a timer 81 described later are arranged in a hollow portion of the grip portion 1a that is a space defined by the air flow path 4.

  Furthermore, in the present embodiment, a charging unit 9 is provided that charges the user to the opposite pole of the charge of ions generated in the mist generation unit 10 (negative charge in the present embodiment). The charging unit 9 is formed of a conductive resin (conductive member) exposed on the outer surface of the holding unit 1a, and is connected to the control unit 8 through a conductive wire.

  As described above, the hair dryer 1 according to this embodiment releases mist containing nitrate ions (acidic components). Therefore, when the hair dryer 1 is continuously used, the charge (negative charge) of nitrate ions is accumulated in the user, and the nitrate ions are not easily released toward the user. However, by providing the charging unit 9, the user can be charged to the opposite electrode (positive electrode) of the charge of ions generated in the mist generating unit 10. As a result, it is possible to suppress the charge of ions generated in the mist generation unit 10 from being accumulated in the user and making it difficult for the ions to reach the user.

  By the way, the surfactant contained in shampoos and soaps used in daily life brings the acidity of hair and skin to an alkali range of 7.5 to 10.0 pH, and weakens the binding of proteins constituting the hair and skin. It is something to do. Therefore, when hair is washed using normal shampoo or soap, the acidity of the hair or skin becomes weakly alkaline. However, the condition of hair and skin is generally normal when the acidity is in the range of 3.5 to 6.0 pH. In view of this, a hair dryer has been devised in which an acidic mist (mist containing nitrate ions) that acts gently on the hair and skin is applied to the hair and skin so that the state of the hair and skin is returned to a more normal state.

  However, if the amount of discharged acidic mist is not controlled, the acidic component is excessively applied to hair damaged by bleach or perm or dry skin, and the dehydration reaction by the acidic component is promoted. There is a risk of damaging hair and skin.

  Here, when an acidic component is excessively applied to hair damaged by bleaching, a case where the dehydration reaction by the acidic component is accelerated and the hair is damaged will be described based on FIG.

  FIG. 4 is a graph showing the concentration of mist containing an acidic component on the horizontal axis and the average friction coefficient of hair on the vertical axis.

  In this experiment, a sample with 30 bleached hairs arranged at intervals of 0.5 mm was created, and the average friction coefficient of the sample was measured after 10 seconds of mist containing acidic components were applied from a distance of 10 cm. did. In addition, in this experiment, each sample when the concentration of acidic mist was given mists of 0 mg / L (pure water), 7 mg / L, 8 mg / L, 9 mg / L, 10 mg / L, and 11 mg / L. The average coefficient of friction was measured. The concentration of the acidic mist is indicated by the amount dissolved in a certain amount of liquid, which is generated for 10 minutes from a distance of 3 cm. The measurement was performed in an environment of 25 ° C. and 50% RH, and a friction feeling tester manufactured by Kato Tech Co., Ltd. was used for measurement of the average friction coefficient.

  It can be seen from FIG. 4 that the average friction coefficient is the lowest when the concentration of acidic mist is 9 mg / L. In general, the lower the average friction coefficient of hair, the better the cuticle adhesion of the hair. Therefore, it is understood that when the concentration of the acidic mist is 9 mg / L, the hair is kept in a state in which the cuticle has good adhesion. And when FIG. 4 is seen, even if it is 9 mg / L or less or 9 mg / L or more, the average friction coefficient gradually increases as the concentration of acidic mist decreases or increases. That is, when any mist of 7 to 11 mg / L is applied, the concentration of acidic mist is 9 mg / L, which is optimal for maintaining the hair cuticle adhesion in a good state. It is understood that it is a value. From this experiment, it is understood that when an acidic component is added excessively, the dehydration reaction by the acidic component is promoted and the hair is damaged.

  As described above, if an acidic component is excessively applied to the hair or skin, the dehydration reaction by the acidic component is promoted, and there is a possibility that the hair or skin is damaged.

  Therefore, in the present embodiment, the control unit 8 controls the generation amount of mist containing nitrate ions generated by the mist generation unit 10.

  In the present embodiment, the control unit 8 controls the generation amount of mist including nitrate ions generated by the mist generation unit 10 according to the acidity (nitrate ion concentration) of the mist detected by the detection unit 11. I am doing so.

  Specifically, when the blower 5 is driven, the controller 8 drives the mist generator 10. And the control part 8 was made to control the mist production | generation part 10 so that the acidity (nitrate ion density | concentration) of the mist detected by the detection part 11 might become below a predetermined value.

  At this time, in this embodiment, the control unit 8 controls the mist generation unit 10 so that the pH (acidity) of the mist detected by the detection unit 11 is constant within a predetermined value or less. Yes.

  Next, an example of a control method of the mist generating unit 10 by the control unit 8 will be described based on the timing chart of FIG.

  First, when the power is turned on by operating the push-type power switch 7, power is supplied to the motor 52, the heating unit 6, the mist generation unit 10, and the detection unit 11 of the blower unit 5 through an outlet (not shown). Is done. When the fan 51 of the blower 5 is rotated, air is taken into the blower flow path 4 from the inlet opening (suction port) 4a, and warm air heated by the heating unit 6 from the outlet opening (discharge port) 4b. Is discharged. At this time, mist containing nitrate ions generated by the mist generating unit 10 is also discharged from the outlet opening (discharge port) 4b.

  Further, when the power is turned on, electricity flows through the detection unit 11 and the detection unit 11 is positively charged. And since the acidic component (nitrate ion) contained in mist is negatively charged, nitrate ion adheres to the detection part 11 charged positively, and the charge amount of the detection part 11 changes. Then, the amount of nitrate ions contained in the mist is detected from the change in the amount of charge per unit time of the detection unit 11. For example, by using the timer 81, the change in the charge amount of the detection unit 11 can be measured every 10 seconds, and the amount of nitrate ions can be obtained from the difference from the charge amount of the detection unit 11 10 seconds ago. .

  Control by the control unit 8 of the mist generating unit 10 is started several seconds after power is supplied to the motor 52, the heating unit 6, the mist generating unit 10, and the detecting unit 11 of the blower unit 5. The time until the control is started is preferably about 10 seconds.

  That is, as shown in the timing chart of FIG. 2, if the time when the power switch 7 of the hair dryer 1 is operated to turn on the power is T0 seconds, the control of the mist generating unit 10 is started after (T0 + 10) seconds. ing.

  Then, after the start of control, the detection unit 11 detects the concentration of nitrate ions (acidic component) at any time, preferably about once every 3 seconds. When the acidity (nitrate ion concentration) of the mist containing nitrate ions reaches a predetermined amount (threshold value) x0, the control unit 8 determines a predetermined magnification at which the nitrate ion concentration of the mist containing nitrate ions is the threshold value x0. The amount of mist generated by the mist generating unit 10 is controlled so as to be kept constant at y.

  Incidentally, as shown in FIG. 3, the detected acidity (nitrate ion concentration) and the current A flowing through the mist generation unit 10 are in a proportional relationship. Therefore, it is possible to keep the detected acidity (nitrate ion concentration) constant at the predetermined magnification y of the threshold value x0 by controlling the current A flowing through the mist generation unit 10 to be a predetermined value. .

  Therefore, in the present embodiment, the mist generation unit 10 generates acid so that the acidity (nitrate ion concentration) of mist containing nitrate ions is kept constant at a predetermined magnification y of a predetermined amount (threshold value) x0. After the amount of mist is controlled (after T1 in FIG. 4), power supply to the detection unit 11 is stopped. Note that the power supply to the detection unit 11 may not be stopped. When power supply to the detection unit 11 is stopped, nitrate ions attached to the detection unit 11 are separated from the detection unit 11 after the power supply is stopped.

  In the present embodiment, as shown in the timing chart of FIG. 2, when the detection unit 11 detects that the acidity (nitrate ion concentration) of mist containing nitrate ions has reached a predetermined amount (threshold value) x0, The current A flowing through the generation unit 10 is gradually decreased, and the detected acidity (nitrate ion concentration) is gradually decreased.

  When the acidity (nitrate ion concentration) of the mist containing nitrate ions reaches a predetermined magnification y of a predetermined amount (threshold value) x0 (T1 in FIG. 2), the current A flowing in the mist generating unit 10 Is controlled to be constant so that the acidity (nitrate ion concentration) of mist containing nitrate ions is kept constant at a predetermined magnification y of a predetermined amount (threshold) x0. At this time, power supply to the detection unit 11 is stopped.

  Finally, when the power source is turned off by operating the push-type power switch 7 (T2 in FIG. 2), power supply to the motor 52, the heating unit 6, and the mist generating unit 10 of the blower unit 5 is stopped.

  The predetermined amount (threshold value) x0 is a concentration of about 9 mg / L when acid mist is continuously generated for 10 minutes from a distance of 3 cm and expressed in an amount dissolved in a certain amount of liquid. It is desirable. Specifically, the predetermined amount (threshold) x0 is desirably about 30 to 40 mg / L, more preferably about 36 mg / L. At this time, the current A flowing through the mist generation unit 10 is preferably about 5 to 15 μA, more preferably about 8 to 10 μA. The predetermined magnification y is desirably set to 3/4 to 1/2, and more preferably about 2/3.

  In this way, by controlling the amount of mist generated by the mist generating unit 10, the state of the hair after using the hair dryer 1 is separated by 10 cm from the mist containing an acidic component having a concentration of 9 mg / L. It becomes possible to approach the state of the hair applied for 10 seconds from the distance.

  In addition, when the electric power feeding to the motor 52 of the ventilation part 5, the heating part 6, and the mist production | generation part 10 is small, the acidic component contained in mist may not exceed a predetermined value. In this case, for example, when the acidity (nitrate ion concentration) of mist containing nitrate ions exceeds a predetermined magnification y of a predetermined amount (threshold value) x0, control is performed so as to be kept constant. You can do it.

  As described above, in the present embodiment, the control unit 8 of the hair dryer (heating air blower) 1 is generated by the mist generation unit 10 according to the acidity (nitrate ion concentration) of the mist detected by the detection unit 11. The amount of mist generated is controlled.

  In the present embodiment, the control unit 8 drives the mist generation unit 10 when the blower unit 5 is driven, and the acidity (nitrate ion concentration) of the mist detected by the detection unit 11 is a predetermined value x0 or less. Thus, the mist generating unit 10 is controlled. Therefore, excessive discharge of mist containing nitrate ions (acidic components) can be suppressed. As a result, it becomes possible to discharge mist containing nitrate ions (acidic components) in an amount suitable for the hair quality and skin quality, and it is possible to suppress damage to the hair and skin.

  Moreover, in this embodiment, since the detection part 11 is arrange | positioned in the downstream of the mist production | generation part 10, the quantity of nitrate ion (acidic component) which actually adheres to hair or skin is more correctly detected by the detection part 11. Can be detected.

  In the present embodiment, the control unit 8 controls the mist generation unit 10 so that the acidity (nitrate ion concentration) of the mist detected by the detection unit 11 is constant within a predetermined value x0 or less. ing. Therefore, it can suppress more reliably that the mist containing nitrate ion (acidic component) will be discharged excessively.

  Next, a modification of this embodiment will be described.

(First modification of the first embodiment)
The hair dryer 1A according to this modification basically has the same configuration as that of the first embodiment. That is, the hair dryer 1 </ b> A includes an air flow path 4 provided in the housing 3 and having an inlet opening (suction port) 4 a and an outlet opening (discharge port) 4 b on both sides. An air blowing unit 5 that introduces air from the inlet opening (suction port) 4 a and discharges it from the outlet opening (discharge port) 4 b is disposed on the upstream side of the air flow path 4. A heating unit 6 that heats the air is provided.

  Furthermore, in the air flow path 4, the mist production | generation part 10 which produces | generates the mist containing nitrate ion (acidic component), and the detection which detects the acidity (nitrate ion concentration) of the mist produced | generated by the mist production | generation part 10 Part 11 is provided. And the control part 8 which controls the production amount of the mist produced | generated by the mist production | generation part 10 is provided in the cavity part of the housing 3 of the holding part 1a.

  Also in the present modification, the control unit 8 performs the control shown in the timing chart of FIG.

  That is, the control unit 8 controls the generation amount of mist including nitrate ions generated by the mist generation unit 10 according to the acidity (nitrate ion concentration) of the mist detected by the detection unit 11. Yes.

  Specifically, when the blower 5 is driven, the controller 8 drives the mist generator 10. The control unit 8 controls the mist generation unit 10 so that the acidity (nitrate ion concentration) of the mist detected by the detection unit 11 is equal to or less than a predetermined value.

  The control unit 8 controls the mist generation unit 10 so that the acidity (nitrate ion concentration) of the mist detected by the detection unit 11 is constant within a predetermined value or less.

  Here, the hair dryer 1A according to the present modification is mainly different from the first embodiment in that the air flow path 4 of the hair dryer 1A is branched from the downstream side of the air blowing unit 5 and the upstream side of the heating unit 6. There exists in the point provided with the branch path 4c to which the ventilation which does not go through via the heating part 6 is supplied.

  Then, at least a part of the mist generated by the mist generation unit 10 is supplied to the branch path 4c, and the detection unit 11 is provided on the downstream side of the branch path 4c.

  Specifically, by providing the partition plate 3a inside the housing 3 of the main body 1b, the sending flow path 4 to which the air that passes through the heating unit 6 is supplied and the air that does not pass through the heating unit 6 are supplied. A branch path 4c is formed.

  In addition, an inner cylinder may be provided inside the housing 3 of the main body 1b so as to surround the heating unit 6 to form the branch path 4c.

  Also according to the above modification, it is possible to obtain substantially the same operations and effects as in the first embodiment.

  Moreover, according to this modification, the ventilation flow path 4 is provided with the branched path 4c branched from the downstream of the ventilation part 5 and the upstream of the heating part 6, and the ventilation which does not go through the heating part 6 is supplied. . Then, at least a part of the mist generated by the mist generation unit 10 is supplied to the branch path 4c, and the detection unit 11 is provided on the downstream side of the branch path 4c. As a result, the amount of nitrate ions (acidic component) can be detected without being affected by the wind flowing through the main flow of the air flow path 4, and the amount of nitrate ion (acidic component) is detected by the detection unit 11. Can be detected more accurately.

(Second modification of the first embodiment)
The hair dryer 1B according to the present modification basically has the same configuration as that of the first modification of the first embodiment. That is, the hair dryer 1 </ b> B includes an air flow path 4 provided in the housing 3 and having an inlet opening (suction port) 4 a and an outlet opening (discharge port) 4 b on both sides. An air blowing unit 5 that introduces air from the inlet opening (suction port) 4 a and discharges it from the outlet opening (discharge port) 4 b is disposed on the upstream side of the air flow path 4. A heating unit 6 that heats the air is provided.

  Furthermore, in the air flow path 4, the mist production | generation part 10 which produces | generates the mist containing nitrate ion (acidic component), and the detection which detects the acidity (nitrate ion concentration) of the mist produced | generated by the mist production | generation part 10 Part 11 is provided. And the control part 8 which controls the production amount of the mist produced | generated by the mist production | generation part 10 is provided in the cavity part of the housing 3 of the holding part 1a.

  Further, the air flow path 4 is provided with a branch path 4 c that is branched from the downstream side of the air blowing unit 5 and the upstream side of the heating unit 6 and supplied with air that does not pass through the heating unit 6.

  Specifically, by providing the partition plate 3a inside the housing 3 of the main body 1b, the sending flow path 4 to which the air that passes through the heating unit 6 is supplied and the air that does not pass through the heating unit 6 are supplied. A branch path 4c is formed.

  In addition, an inner cylinder may be provided inside the housing 3 of the main body 1b so as to surround the heating unit 6 to form the branch path 4c.

  Also in the present modification, the control unit 8 performs the control shown in the timing chart of FIG.

  That is, the control unit 8 controls the generation amount of mist including nitrate ions generated by the mist generation unit 10 according to the acidity (nitrate ion concentration) of the mist detected by the detection unit 11. Yes.

  Specifically, when the blower 5 is driven, the controller 8 drives the mist generator 10. The control unit 8 controls the mist generation unit 10 so that the acidity (nitrate ion concentration) of the mist detected by the detection unit 11 is equal to or less than a predetermined value.

  The control unit 8 controls the mist generation unit 10 so that the acidity (nitrate ion concentration) of the mist detected by the detection unit 11 is constant within a predetermined value or less.

  Here, the hair dryer 1B according to the present modification is mainly different from the first modification of the first embodiment in that the mist generation unit 10 is disposed in the branch path 4c.

  Also according to the above modification, substantially the same operations and effects as those of the first modification of the first embodiment can be achieved.

(Second Embodiment)
The hair dryer 1 according to the present embodiment has the same configuration as the hair dryer 1 of the first embodiment. Here, in the present embodiment, the control performed by the control unit 8 is different from that in the first embodiment.

  Hereinafter, control in the present embodiment will be described based on the timing chart of FIG.

  The control by the control unit 8 of the present embodiment is basically the same as the control by the control unit 8 of the first embodiment, but the main difference from the control in the first embodiment is the detection unit 11. The control unit 8 controls the mist generation unit 10 so that the acidity (nitrate ion concentration) of the detected mist repeatedly increases and decreases within a predetermined value or less.

  That is, the control unit 8 controls the generation amount of mist including nitrate ions generated by the mist generation unit 10 according to the acidity (nitrate ion concentration) of the mist detected by the detection unit 11. Yes.

  Specifically, when the blower 5 is driven, the controller 8 drives the mist generator 10. The control unit 8 controls the mist generation unit 10 so that the acidity (nitrate ion concentration) of the mist detected by the detection unit 11 is equal to or less than a predetermined value.

  At this time, in the present embodiment, the control unit 8 controls the mist generation unit 10 so that the acidity (nitrate ion concentration) detected by the detection unit 11 repeatedly increases and decreases within a predetermined value or less. I have to.

  Next, an example of a control method of the mist generation unit 10 by the control unit 8 will be described based on the timing chart of FIG.

  First, when the power is turned on by operating the push-type power switch 7, power is supplied to the motor 52, the heating unit 6, the mist generation unit 10, and the detection unit 11 of the blower unit 5 through an outlet (not shown). Is done. When the fan 51 of the blower 5 is rotated, air is taken into the blower flow path 4 from the inlet opening (suction port) 4a, and warm air heated by the heating unit 6 from the outlet opening (discharge port) 4b. Is discharged. At this time, mist containing nitrate ions generated by the mist generating unit 10 is also discharged from the outlet opening (discharge port) 4b.

  Further, when the power is turned on, electricity flows through the detection unit 11 and the detection unit 11 is positively charged. And since the acidic component (nitrate ion) contained in mist is negatively charged, nitrate ion adheres to the detection part 11 charged positively, and the charge amount of the detection part 11 changes. Then, the amount of nitrate ions contained in the mist is detected from the change in the amount of charge per unit time of the detection unit 11. For example, by using the timer 81, the change in the charge amount of the detection unit 11 can be measured every 10 seconds, and the amount of nitrate ions can be obtained from the difference from the charge amount of the detection unit 11 10 seconds ago. .

  Control by the control unit 8 of the mist generating unit 10 is started several seconds after power is supplied to the motor 52, the heating unit 6, the mist generating unit 10, and the detecting unit 11 of the blower unit 5. The time until the control is started is preferably about 10 seconds.

  That is, as shown in the timing chart of FIG. 7, when the time when the power switch 7 of the hair dryer 1 is operated and the power is turned on is T0 seconds, the control of the mist generating unit 10 is started after (T0 + 10) seconds. ing.

  Then, after the start of control, the detection unit 11 detects the concentration of nitrate ions (acidic component) at any time, preferably about once every 3 seconds. When the acidity (nitrate ion concentration) of the mist containing nitrate ions reaches a predetermined amount (threshold value) x0, the control unit 8 detects the acidity (nitrate ion concentration) of the mist detected by the detection unit 11. Is controlled so as to repeat the increase / decrease within the range of the predetermined value x0 or less.

  Specifically, by controlling the current A flowing through the mist generating unit 10 to increase and decrease repeatedly within a predetermined value x0 or less, the mist acidity (nitrate ion concentration) is within a predetermined value x0 or less. In order to repeat the increase and decrease.

  In the present embodiment, the mist acidity (nitrate ion concentration) is repeatedly increased and decreased within a range of a predetermined value x0 that is equal to or less than a predetermined magnification y.

  Specifically, as shown in the timing chart of FIG. 7, when the detection unit 11 detects that the acidity (nitrate ion concentration) of the mist containing nitrate ions has reached a predetermined amount (threshold value) x0, The current A flowing through the generation unit 10 is gradually decreased, and the detected acidity (nitrate ion concentration) is gradually decreased.

  When the acidity (nitrate ion concentration) of the mist containing nitrate ions reaches a predetermined magnification y of a predetermined amount (threshold value) x0 (T1 in FIG. 7), the current A flowing in the mist generating unit 10 Is controlled to repeat increase / decrease within a range of a predetermined value x0 within a predetermined magnification y, and the acidity (nitrate ion concentration) of the mist containing nitrate ions is equal to or lower than a predetermined magnification y of a predetermined amount (threshold) x0. The increase and decrease are repeated in the range of.

  Finally, when the power source is turned off by operating the push-type power switch 7 (T2 in FIG. 7), the power supply to the motor 52, the heating unit 6, the mist generating unit 10 and the detecting unit 11 of the blower unit 5 is stopped. Is done.

  The predetermined amount (threshold value) x0 is a concentration of about 9 mg / L when acid mist is continuously generated for 10 minutes from a distance of 3 cm and expressed in an amount dissolved in a certain amount of liquid. It is desirable. Specifically, the predetermined amount (threshold) x0 is desirably about 30 to 40 mg / L, more preferably about 36 mg / L. At this time, the current A flowing through the mist generation unit 10 is preferably about 5 to 15 μA, more preferably about 8 to 10 μA. The predetermined magnification y is desirably set to 3/4 to 1/2, and more preferably about 2/3.

  In this way, by controlling the amount of mist generated by the mist generating unit 10, the state of the hair after using the hair dryer 1 is separated by 10 cm from the mist containing an acidic component having a concentration of 9 mg / L. It becomes possible to approach the state of the hair applied for 10 seconds from the distance.

  Also according to this embodiment described above, the same operations and effects as those of the first embodiment can be achieved.

  Further, according to the present embodiment, the control unit 8 controls the mist generation unit 10 so that the acidity (nitrate ion concentration) detected by the detection unit 11 repeatedly increases and decreases within a predetermined value or less. ing. That is, when the acidity (nitrate ion concentration) of mist containing nitrate ions (acidic components) reaches a predetermined value (threshold value), the acidity (nitrate ions) of mist containing nitrate ions (acidic components) The mist generating unit 10 is controlled so that the density is generated within a range that does not exceed a predetermined magnification of the threshold value. As a result, it is possible to suppress the deposition of nitrate ions (acidic components) locally only on a part of the hair.

  It should be noted that as a method of controlling so as to be generated with strength and weakness, it is conceivable to perform control so as to have a sin wave shape other than the method shown in FIG. It is also conceivable to control the waveform to be pulsed. It is also conceivable to control the waveform so as to gradually attenuate.

  Moreover, it is also possible to apply the control of this embodiment to the hair dryers 1A and 1B shown in the modified example of the first embodiment.

(Third embodiment)
The hair dryer 1 according to the present embodiment has the same configuration as the hair dryer 1 of the first embodiment. Here, in the present embodiment, the control performed by the control unit 8 is different from that in the first embodiment.

  Hereinafter, control in the present embodiment will be described based on the timing chart of FIG.

  The control by the control unit 8 of the present embodiment is basically the same as the control by the control unit 8 of the first embodiment, but the main difference from the control in the first embodiment is the detection unit 11. The point is to control the mist generation unit 10 so that the detected acidity (nitrate ion concentration) of the mist is simply within a predetermined value or less.

  That is, the control unit 8 controls the generation amount of mist including nitrate ions generated by the mist generation unit 10 according to the acidity (nitrate ion concentration) of the mist detected by the detection unit 11. Yes.

  Specifically, when the blower 5 is driven, the controller 8 drives the mist generator 10. The control unit 8 controls the mist generation unit 10 so that the acidity (nitrate ion concentration) of the mist detected by the detection unit 11 is equal to or less than a predetermined value.

  Next, an example of a control method of the mist generation unit 10 by the control unit 8 will be described based on the timing chart of FIG.

  First, when the power is turned on by operating the push-type power switch 7, power is supplied to the motor 52, the heating unit 6, the mist generation unit 10, and the detection unit 11 of the blower unit 5 through an outlet (not shown). Is done. When the fan 51 of the blower 5 is rotated, air is taken into the blower flow path 4 from the inlet opening (suction port) 4a, and warm air heated by the heating unit 6 from the outlet opening (discharge port) 4b. Is discharged. At this time, mist containing nitrate ions generated by the mist generating unit 10 is also discharged from the outlet opening (discharge port) 4b.

  Further, when the power is turned on, electricity flows through the detection unit 11 and the detection unit 11 is positively charged. And since the acidic component (nitrate ion) contained in mist is negatively charged, nitrate ion adheres to the detection part 11 charged positively, and the charge amount of the detection part 11 changes. Then, the amount of nitrate ions contained in the mist is detected from the change in the amount of charge per unit time of the detection unit 11. For example, by using the timer 81, the change in the charge amount of the detection unit 11 can be measured every 10 seconds, and the amount of nitrate ions can be obtained from the difference from the charge amount of the detection unit 11 10 seconds ago. .

  Control by the control unit 8 of the mist generating unit 10 is started several seconds after power is supplied to the motor 52, the heating unit 6, the mist generating unit 10, and the detecting unit 11 of the blower unit 5. The time until the control is started is preferably about 10 seconds.

  That is, as shown in the timing chart of FIG. 8, when the time when the power switch 7 of the hair dryer 1 is operated and the power is turned on is T0 seconds, the control of the mist generating unit 10 is started after (T0 + 10) seconds. ing.

  Then, after the start of control, the detection unit 11 detects the concentration of nitrate ions (acidic component) at any time, preferably about once every 3 seconds. When the acidity (nitrate ion concentration) of the mist containing nitrate ions reaches a predetermined amount (threshold value) x0, the control unit 8 detects the acidity (nitrate ion concentration) of the mist detected by the detection unit 11. Is controlled so as to change within a predetermined value x0 or less.

  That is, as shown in the timing chart of FIG. 8, when the detection unit 11 detects that the acidity (nitrate ion concentration) of mist containing nitrate ions has reached a predetermined amount (threshold value) x0, the mist generation unit 10 Is changed in a range of a predetermined current A0 or less, and the detected acidity (nitrate ion concentration) is changed in a range of a predetermined value x0 or less.

  Finally, when the power source is turned off by operating the push type power switch 7 (T2 in FIG. 8), the power supply to the motor 52, the heating unit 6, the mist generating unit 10 and the detecting unit 11 of the blower unit 5 is stopped. Is done.

  The predetermined amount (threshold value) x0 is a concentration of about 9 mg / L when acid mist is continuously generated for 10 minutes from a distance of 3 cm and expressed in an amount dissolved in a certain amount of liquid. It is desirable. Specifically, the predetermined amount (threshold) x0 is desirably about 30 to 40 mg / L, more preferably about 36 mg / L. At this time, the current A flowing through the mist generation unit 10 is preferably about 5 to 15 μA, more preferably about 8 to 10 μA.

  In this way, by controlling the amount of mist generated by the mist generating unit 10, the state of the hair after using the hair dryer 1 is separated by 10 cm from the mist containing an acidic component having a concentration of 9 mg / L. It becomes possible to approach the state of the hair applied for 10 seconds from the distance.

  Also according to this embodiment described above, the same operations and effects as those of the first embodiment can be achieved.

  Moreover, it is also possible to apply the control of this embodiment to the hair dryers 1A and 1B shown in the modified example of the first embodiment.

(Fourth embodiment)
The hair dryer 1 </ b> C according to the present embodiment has basically the same configuration as that of the second modification of the first embodiment. That is, as shown in FIG. 9, the hair dryer 1 </ b> C includes an air flow path 4 provided in the housing 3 and having an inlet opening (suction port) 4 a and an outlet opening (discharge port) 4 b on both sides. . An air blowing unit 5 that introduces air from the inlet opening (suction port) 4 a and discharges it from the outlet opening (discharge port) 4 b is disposed on the upstream side of the air flow path 4. A heating unit 6 that heats the air is provided.

  Furthermore, in the air flow path 4, the mist production | generation part 10 which produces | generates the mist containing nitrate ion (acidic component), and the detection which detects the acidity (nitrate ion concentration) of the mist produced | generated by the mist production | generation part 10 Part 11 is provided. And the control part 8 which controls the production amount of the mist produced | generated by the mist production | generation part 10 is provided in the cavity part of the housing 3 of the holding part 1a.

  Further, the air flow path 4 is provided with a branch path 4 c that is branched from the downstream side of the air blowing unit 5 and the upstream side of the heating unit 6 and supplied with air that does not pass through the heating unit 6.

  Specifically, by providing the partition plate 3a inside the housing 3 of the main body 1b, the sending flow path 4 to which the air that passes through the heating unit 6 is supplied and the air that does not pass through the heating unit 6 are supplied. A branch path 4c is formed.

  In addition, an inner cylinder may be provided inside the housing 3 of the main body 1b so as to surround the heating unit 6 to form the branch path 4c.

  And the mist production | generation part 10 is arrange | positioned in the branch path 4c.

  Also in the present embodiment, the control unit 8 generates the amount of mist including nitrate ions generated by the mist generation unit 10 according to the acidity (nitrate ion concentration) of the mist detected by the detection unit 11. To control.

  Specifically, the generation amount of mist containing nitrate ions generated by the mist generation unit 10 is controlled by any one of the control methods described in the first to third embodiments.

  Here, the hair dryer 1 </ b> C according to the present embodiment is mainly different from the second modification of the first embodiment in that the hair dryer 1 </ b> C has an air flow rate switching unit 12 that switches the air flow rate. . The air flow rate switching means 12 is formed on the upper part of the power switch 7 of the grip portion 1a, and is connected to the control portion 8 via a conducting wire. And the amount of ventilation can be changed in two steps.

  Furthermore, the hair dryer 1 </ b> C has a second control unit that controls the mist generation unit 10 so that the mist generation amount is reduced when the blast amount switching unit 12 is driven to reduce the blast amount. In the present embodiment, the control unit 8 also serves as the second control unit. Note that the second control unit may be provided separately from the control unit 8. In this case, the air flow rate switching means 12 is connected to a second control unit provided separately from the control unit 8 via a conducting wire.

  Next, an example of a control method of the mist generation unit 10 by the control unit 8 will be described based on the timing chart of FIG.

First, when the power source is turned on by operating the push-type power switch 7, electric power (for example, to the motor 52, the heating unit 6, the mist generation unit 10, and the detection unit 11 of the blower unit 5 is connected via an outlet (not shown). Power of 1200 W). When the fan 51 of the blower 5 is rotated, air is taken into the blower flow path 4 from the inlet opening (suction port) 4a, and warm air heated by the heating unit 6 from the outlet opening (discharge port) 4b. Is discharged. At this time, mist containing nitrate ions generated by the mist generating unit 10 is also discharged from the outlet opening (discharge port) 4b. In addition, when 1200 W of electric power is supplied, a wind of 1.3 m ² / min is sent out.

  Further, when the power is turned on, electricity flows through the detection unit 11 and the detection unit 11 is positively charged. And since the acidic component (nitrate ion) contained in mist is negatively charged, nitrate ion adheres to the detection part 11 charged positively, and the charge amount of the detection part 11 changes. Then, the amount of nitrate ions contained in the mist is detected from the change in the amount of charge per unit time of the detection unit 11. For example, by using the timer 81, the change in the charge amount of the detection unit 11 can be measured every 10 seconds, and the amount of nitrate ions can be obtained from the difference from the charge amount of the detection unit 11 10 seconds ago. .

  Control by the control unit 8 of the mist generating unit 10 is started several seconds after power is supplied to the motor 52, the heating unit 6, the mist generating unit 10, and the detecting unit 11 of the blower unit 5. The time until the control is started is preferably about 15 seconds.

  That is, as shown in the timing chart of FIG. 10, assuming that the time when the power switch 7 of the hair dryer 1C is operated to turn on the power is T0 seconds, the control of the mist generating unit 10 is started after (T0 + 15) seconds. ing. As shown in the first to third embodiments, the time until the control is started can be set to about 10 seconds.

  Then, after the start of control, the detection unit 11 detects the concentration of nitrate ions (acidic component) at any time, preferably about once every 3 seconds. When the acidity (nitrate ion concentration) of the mist containing nitrate ions reaches a predetermined amount (threshold value) x0, the control unit 8 determines a predetermined magnification at which the nitrate ion concentration of the mist containing nitrate ions is the threshold value x0. The amount of mist generated by the mist generating unit 10 is controlled so as to be kept constant at y.

  Also in the present embodiment, the detected acidity (nitrate ion concentration) is kept constant at a predetermined magnification y of the threshold value x0 by controlling the current A flowing through the mist generating unit 10 to be a predetermined value. I have to.

  The predetermined amount (threshold value) x0 is a concentration of about 9 mg / L when acid mist is continuously generated for 10 minutes from a distance of 3 cm and expressed in an amount dissolved in a certain amount of liquid. It is desirable. Specifically, the predetermined amount (threshold) x0 is desirably about 30 to 40 mg / L, more preferably about 36 mg / L. At this time, the current A flowing through the mist generation unit 10 is preferably about 5 to 15 μA, more preferably about 8 to 10 μA. The predetermined magnification y is desirably set to 3/4 to 1/2, and more preferably about 2/3. FIG. 10 exemplifies a case where the predetermined magnification y is three-quarters (the current A flowing through the mist generation unit 10 is controlled to be 3 / 4A0).

  In this way, by controlling the amount of mist generated by the mist generating unit 10, the state of the hair after using the hair dryer 1C is separated by 10 cm from the mist containing an acidic component having a concentration of 9 mg / L. It becomes possible to approach the state of the hair applied for 10 seconds from the distance.

When the air flow rate switching means 12 is operated to switch the air flow rate while the hair dryer 1C is in use, 600 W of power is supplied (T1 in FIG. 10), and a wind of 0.75 m ² / min is sent out. It becomes.

  At this time, the control part 8 controls the quantity of the mist produced | generated by the mist production | generation part 10 so that only 1/2 of acidic mist is produced | generated at 1200W. That is, the control unit 8 controls the current A flowing through the mist generation unit 10 to be 3 / 8A0. In this way, when the air flow rate switching means 12 is driven and the air flow rate decreases, the control unit 8 as the second control unit controls the mist generation unit 10 so that the mist generation amount decreases. Yes.

When the air flow rate switching means 12 is operated again so that 1200 W of power is supplied (T2 in FIG. 10), a wind of 1.3 m ² / min is sent out. In this case, the control by the control unit 8 is also in the original state. That is, when the acidity (nitrate ion concentration) of the mist containing nitrate ions reaches a predetermined amount (threshold value) x0, the control unit 8 determines that the nitrate ion concentration of the mist containing nitrate ions is the predetermined threshold value x0. The amount of mist generated by the mist generating unit 10 is kept constant at a magnification y (3/4 in FIG. 10) (so that the current A flowing through the mist generating unit 10 becomes 3 / 4A0). Come to control.

  Finally, when the power source is turned off by operating the push-type power switch 7 (T3 in FIG. 10), power supply to the motor 52, the heating unit 6, and the mist generating unit 10 of the blower unit 5 is stopped.

  Also according to the present embodiment described above, the same operations and effects as those of the first to third embodiments and the modifications thereof can be achieved.

  Moreover, in this embodiment, when the control part (2nd control part) 8 of hair dryer (heating air blower) 1C drives the ventilation volume switching means 12, and the ventilation volume falls, mist production amount falls. As described above, the mist generating unit 10 is controlled. That is, the control part (2nd control part) 8 is controlling the mist production | generation part 10 so that it may become the production | generation amount according to the ventilation volume.

  In this way, when the air flow rate is reduced, the mist generation unit 10 is controlled so that the mist generation amount is reduced, so that mist containing nitrate ions (acidic components) is discharged in a high concentration state. It becomes possible to suppress adhesion to hair. As a result, it is possible to discharge mist containing nitrate ions (acidic components) in an amount appropriate for the hair quality and skin quality regardless of increase or decrease in the amount of air flow, and damage the hair and skin. It can be suppressed more.

  In FIG. 10, the control shown in the first embodiment is exemplified as the control of the mist generation unit 10 by the control unit 8 at the normal time, but the control of the mist generation unit 10 by the control unit 8 at the normal time is illustrated. The control shown in the second and third embodiments is also possible.

  Moreover, it is also possible to apply the configuration and control of this embodiment to the hair dryers 1 and 1A shown in the first embodiment and its modifications.

(Fifth embodiment)
The hair dryer 1D according to the present embodiment has basically the same configuration as that of the second modification of the first embodiment. That is, as shown in FIG. 11, the hair dryer 1 </ b> D includes an air flow path 4 provided in the housing 3 and having an inlet opening (suction port) 4 a and an outlet opening (discharge port) 4 b on both sides. . An air blowing unit 5 that introduces air from the inlet opening (suction port) 4 a and discharges it from the outlet opening (discharge port) 4 b is disposed on the upstream side of the air flow path 4. A heating unit 6 that heats the air is provided.

  Furthermore, in the air flow path 4, the mist production | generation part 10 which produces | generates the mist containing nitrate ion (acidic component), and the detection which detects the acidity (nitrate ion concentration) of the mist produced | generated by the mist production | generation part 10 Part 11 is provided. And the control part 8 which controls the production amount of the mist produced | generated by the mist production | generation part 10 is provided in the cavity part of the housing 3 of the holding part 1a.

  Further, the air flow path 4 is provided with a branch path 4 c that is branched from the downstream side of the air blowing unit 5 and the upstream side of the heating unit 6 and supplied with air that does not pass through the heating unit 6.

  Specifically, by providing the partition plate 3a inside the housing 3 of the main body 1b, the sending flow path 4 to which the air that passes through the heating unit 6 is supplied and the air that does not pass through the heating unit 6 are supplied. A branch path 4c is formed.

  In addition, an inner cylinder may be provided inside the housing 3 of the main body 1b so as to surround the heating unit 6 to form the branch path 4c.

  And the mist production | generation part 10 is arrange | positioned in the branch path 4c.

  Also in the present embodiment, the control unit 8 generates the amount of mist including nitrate ions generated by the mist generation unit 10 according to the acidity (nitrate ion concentration) of the mist detected by the detection unit 11. To control.

  Specifically, the generation amount of mist containing nitrate ions generated by the mist generation unit 10 is controlled by any one of the control methods described in the first to third embodiments.

  Here, the hair dryer 1D according to the present embodiment is mainly different from the second modification of the first embodiment in that the hair dryer 1D has a blowing temperature switching means 13 for switching the blowing temperature. . The blower temperature switching means 13 is formed on the upper part of the power switch 7 of the grip part 1a, and is connected to the control part 8 through a conducting wire. In the present embodiment, the air blowing temperature can be switched in two stages by switching the heating unit 6 on and off.

  Furthermore, the hair dryer 1D has a second control unit that controls the mist generation unit 10 so that the mist generation amount decreases when the blast temperature switching means 13 is driven and the blast temperature decreases. Also in the present embodiment, the control unit 8 also serves as the second control unit. Note that the second control unit may be provided separately from the control unit 8. In this case, the blowing temperature switching means 13 is connected to a second control unit provided separately from the control unit 8 via a conducting wire.

  Next, an example of a control method of the mist generation unit 10 by the control unit 8 will be described based on the timing chart of FIG.

  First, when the power source is turned on by operating the push-type power switch 7, electric power (for example, to the motor 52, the heating unit 6, the mist generation unit 10, and the detection unit 11 of the blower unit 5 is connected via an outlet (not shown). Power of 1200 W). When the fan 51 of the blower 5 is rotated, air is taken into the blower flow path 4 from the inlet opening (suction port) 4a, and warm air heated by the heating unit 6 from the outlet opening (discharge port) 4b. Is discharged. At this time, mist containing nitrate ions generated by the mist generating unit 10 is also discharged from the outlet opening (discharge port) 4b. In addition, when measured at a distance of about 15 cm in an environment of 30 ° C., the blowing temperature is about 120 ° C.

  Further, when the power is turned on, electricity flows through the detection unit 11 and the detection unit 11 is positively charged. And since the acidic component (nitrate ion) contained in mist is negatively charged, nitrate ion adheres to the detection part 11 charged positively, and the charge amount of the detection part 11 changes. Then, the amount of nitrate ions contained in the mist is detected from the change in the amount of charge per unit time of the detection unit 11. For example, by using the timer 81, the change in the charge amount of the detection unit 11 can be measured every 10 seconds, and the amount of nitrate ions can be obtained from the difference from the charge amount of the detection unit 11 10 seconds ago. .

  Control by the control unit 8 of the mist generating unit 10 is started several seconds after power is supplied to the motor 52, the heating unit 6, the mist generating unit 10, and the detecting unit 11 of the blower unit 5. The time until the control is started is preferably about 15 seconds.

  That is, as shown in the timing chart of FIG. 12, assuming that the time when the power switch 7 of the hair dryer 1D is operated to turn on the power is T0 seconds, the control of the mist generating unit 10 is started after (T0 + 15) seconds. ing. As shown in the first to third embodiments, the time until the control is started can be set to about 10 seconds.

  Then, after the start of control, the detection unit 11 detects the concentration of nitrate ions (acidic component) at any time, preferably about once every 3 seconds. When the acidity (nitrate ion concentration) of the mist containing nitrate ions reaches a predetermined amount (threshold value) x0, the control unit 8 determines a predetermined magnification at which the nitrate ion concentration of the mist containing nitrate ions is the threshold value x0. The amount of mist generated by the mist generating unit 10 is controlled so as to be kept constant at y.

  Also in the present embodiment, the detected acidity (nitrate ion concentration) is kept constant at a predetermined magnification y of the threshold value x0 by controlling the current A flowing through the mist generating unit 10 to be a predetermined value. I have to.

  The predetermined amount (threshold value) x0 is a concentration of about 9 mg / L when acid mist is continuously generated for 10 minutes from a distance of 3 cm and expressed in an amount dissolved in a certain amount of liquid. It is desirable. Specifically, the predetermined amount (threshold) x0 is desirably about 30 to 40 mg / L, more preferably about 36 mg / L. At this time, the current A flowing through the mist generation unit 10 is preferably about 5 to 15 μA, more preferably about 8 to 10 μA. The predetermined magnification y is desirably set to 3/4 to 1/2, and more preferably about 2/3. FIG. 12 exemplifies a case where the predetermined magnification y is 3/4 (the current A flowing through the mist generation unit 10 is controlled to be 3 / 4A0).

  In this way, by controlling the amount of mist generated by the mist generating unit 10, the state of the hair after using the hair dryer 1D is separated by 10 cm from the mist containing an acidic component having a concentration of 9 mg / L. It becomes possible to approach the state of the hair applied for 10 seconds from the distance.

  Then, when the air temperature is switched by operating the air temperature switching means 13 in the middle of using the hair dryer 1D, the power supply to the heating unit 6 is stopped (T1 in FIG. 12). As described above, when the power supply to the heating unit 6 is stopped, when measured at a distance of about 15 cm in an environment of 30 ° C., the blowing temperature is lowered from about 120 ° C. to about 30 ° C., and the wind of about 30 ° C. is generated. Will be sent out.

  At this time, the control unit 8 controls the amount of mist generated by the mist generating unit 10 so that the acidic mist is generated by half that when the power supply to the heating unit 6 is performed. That is, the control unit 8 controls the current A flowing through the mist generation unit 10 to be 3 / 8A0. In this way, when the blowing temperature switching means 13 is driven and the blowing temperature decreases, the control unit 8 as the second control unit controls the mist generation unit 10 so that the mist generation amount decreases. Yes.

  When the blast temperature switching means 13 is operated again to supply power to the heating unit 6 (T2 in FIG. 12), a wind of about 120 ° C. is sent out. In this case, the control by the control unit 8 is also in the original state. That is, when the acidity (nitrate ion concentration) of the mist containing nitrate ions reaches a predetermined amount (threshold value) x0, the control unit 8 determines that the nitrate ion concentration of the mist containing nitrate ions is the predetermined threshold value x0. The amount of mist generated by the mist generating unit 10 is kept constant at a magnification y (3/4 in FIG. 12) (so that the current A flowing through the mist generating unit 10 becomes 3 / 4A0). Come to control.

  Finally, when the power source is turned OFF by operating the push-type power switch 7 (T3 in FIG. 12), power supply to the motor 52, the heating unit 6, and the mist generating unit 10 of the blower unit 5 is stopped.

  Also according to the present embodiment described above, the same operations and effects as those of the first to third embodiments and the modifications thereof can be achieved.

  Moreover, in this embodiment, when the ventilation temperature switching means 13 is driven and ventilation temperature falls, the control part 8 as a 2nd control part controls the mist production | generation part 10 so that mist production amount may fall. I am doing so.

  By the way, when cold air of about 30 ° C. is applied to the hair, the cuticle is tightened by the cold air, and the acidic component is difficult to enter the hair. For this reason, supplying cold mist of about 30 ° C to the hair and supplying mist containing the same amount of nitrate ion (acidic component) as hot air of about 120 ° C is excessive for the hair. Mist containing a proper amount of nitrate ions (acidic component) is supplied.

  However, as in the present embodiment, when the mist generation unit 10 is controlled so that the mist generation amount decreases when the blast temperature decreases, mist containing an excessive amount of nitrate ions (acidic components) is generated. It becomes possible to suppress being discharged to the hair. As a result, it is possible to discharge mist containing nitrate ions (acidic components) in an amount suitable for the hair quality and skin quality regardless of the air blowing temperature, and damage the hair and skin. It can be suppressed more.

  In FIG. 12, the control shown in the first embodiment is exemplified as the control of the mist generation unit 10 by the control unit 8 at the normal time, but the control of the mist generation unit 10 by the control unit 8 at the normal time is illustrated. The control shown in the second and third embodiments is also possible.

  Moreover, it is also possible to apply the configuration and control of this embodiment to the hair dryers 1 and 1A shown in the first embodiment and its modifications.

(Sixth embodiment)
The hair dryer 1E according to the present embodiment has basically the same configuration as that of the fourth embodiment. That is, as shown in FIG. 13, the hair dryer 1 </ b> E includes an air flow path 4 provided in the housing 3 and having an inlet opening (suction port) 4 a and an outlet opening (discharge port) 4 b on both sides. . An air blowing unit 5 that introduces air from the inlet opening (suction port) 4 a and discharges it from the outlet opening (discharge port) 4 b is disposed on the upstream side of the air flow path 4. A heating unit 6 that heats the air is provided.

  Furthermore, in the air flow path 4, the mist production | generation part 10 which produces | generates the mist containing nitrate ion (acidic component), and the detection which detects the acidity (nitrate ion concentration) of the mist produced | generated by the mist production | generation part 10 Part 11 is provided. And the control part 8 which controls the production amount of the mist produced | generated by the mist production | generation part 10 is provided in the cavity part of the housing 3 of the holding part 1a.

  Further, the air flow path 4 is provided with a branch path 4 c that is branched from the downstream side of the air blowing unit 5 and the upstream side of the heating unit 6 and supplied with air that does not pass through the heating unit 6.

  Specifically, by providing the partition plate 3a inside the housing 3 of the main body 1b, the sending flow path 4 to which the air that passes through the heating unit 6 is supplied and the air that does not pass through the heating unit 6 are supplied. A branch path 4c is formed.

  In addition, an inner cylinder may be provided inside the housing 3 of the main body 1b so as to surround the heating unit 6 to form the branch path 4c.

  And the mist production | generation part 10 is arrange | positioned in the branch path 4c.

  Also in the present embodiment, the control unit 8 generates the amount of mist including nitrate ions generated by the mist generation unit 10 according to the acidity (nitrate ion concentration) of the mist detected by the detection unit 11. To control.

  Specifically, the generation amount of mist containing nitrate ions generated by the mist generation unit 10 is controlled by any one of the control methods described in the first to third embodiments.

  Here, the hair dryer 1E according to the present embodiment is mainly different from the fourth embodiment described above in that the hair dryer 1E not only has the air blowing amount switching means 12 for switching the air blowing amount but also the air blowing temperature switching means 13 for switching the air blowing temperature. It is in having. The air blowing amount switching means 12 and the air blowing temperature switching means 13 are formed on the upper part of the power switch 7 of the grip portion 1a, and are connected to the control portion 8 through a conducting wire. Then, the air volume and the air temperature can be switched in two stages.

  Furthermore, the hair dryer 1E has a second control unit that controls the mist generation unit 10 so that the mist generation amount is reduced when the air supply amount switching unit 12 is driven and the air supply amount is reduced.

  In the present embodiment, the control unit 8 also serves as the second control unit. Note that the second control unit may be provided separately from the control unit 8.

  Next, an example of a method for controlling the mist generation unit 10 by the control unit 8 will be described. Since the change in power consumption (change in the amount of blown air) has a greater effect on the hair and skin than the change in the blower temperature due to turning on / off of the heating unit 6, in the present embodiment, the timing of FIG. Control based on the chart. Specifically, it is as follows.

First, when the power source is turned on by operating the push-type power switch 7, electric power (for example, to the motor 52, the heating unit 6, the mist generation unit 10, and the detection unit 11 of the blower unit 5 is connected via an outlet (not shown). Power of 1200 W). When the fan 51 of the blower 5 is rotated, air is taken into the blower flow path 4 from the inlet opening (suction port) 4a, and warm air heated by the heating unit 6 from the outlet opening (discharge port) 4b. Is discharged. At this time, mist containing nitrate ions generated by the mist generating unit 10 is also discharged from the outlet opening (discharge port) 4b. In addition, when 1200 W of electric power is supplied, a wind of 1.3 m ² / min is sent out. Moreover, when measured at a distance of about 15 cm in an environment of 30 ° C., the blowing temperature is about 120 ° C.

  When the power is turned on, electricity flows through the detection unit 11 and the detection unit 11 is positively charged. And since the acidic component (nitrate ion) contained in mist is negatively charged, nitrate ion adheres to the detection part 11 charged positively, and the charge amount of the detection part 11 changes. Then, the amount of nitrate ions contained in the mist is detected from the change in the amount of charge per unit time of the detection unit 11. For example, by using the timer 81, the change in the charge amount of the detection unit 11 can be measured every 10 seconds, and the amount of nitrate ions can be obtained from the difference from the charge amount of the detection unit 11 10 seconds ago. .

  Control by the control unit 8 of the mist generating unit 10 is started several seconds after power is supplied to the motor 52, the heating unit 6, the mist generating unit 10, and the detecting unit 11 of the blower unit 5. The time until the control is started is preferably about 15 seconds.

  That is, as shown in the timing chart of FIG. 10, assuming that the time when the power switch 7 of the hair dryer 1E is operated to turn on the power is T0 seconds, the control of the mist generating unit 10 is started after (T0 + 15) seconds. ing. As shown in the first to third embodiments, the time until the control is started can be set to about 10 seconds.

  Then, after the start of control, the detection unit 11 detects the concentration of nitrate ions (acidic component) at any time, preferably about once every 3 seconds. When the acidity (nitrate ion concentration) of the mist containing nitrate ions reaches a predetermined amount (threshold value) x0, the control unit 8 determines a predetermined magnification at which the nitrate ion concentration of the mist containing nitrate ions is the threshold value x0. The amount of mist generated by the mist generating unit 10 is controlled so as to be kept constant at y.

  Also in the present embodiment, the detected acidity (nitrate ion concentration) is kept constant at a predetermined magnification y of the threshold value x0 by controlling the current A flowing through the mist generating unit 10 to be a predetermined value. I have to.

  The predetermined amount (threshold value) x0 is a concentration of about 9 mg / L when acid mist is continuously generated for 10 minutes from a distance of 3 cm and expressed in an amount dissolved in a certain amount of liquid. It is desirable. Specifically, the predetermined amount (threshold) x0 is desirably about 30 to 40 mg / L, more preferably about 36 mg / L. At this time, the current A flowing through the mist generation unit 10 is preferably about 5 to 15 μA, more preferably about 8 to 10 μA. The predetermined magnification y is desirably set to 3/4 to 1/2, and more preferably about 2/3. FIG. 10 exemplifies a case where the predetermined magnification y is three-quarters (the current A flowing through the mist generation unit 10 is controlled to be 3 / 4A0).

  In this way, by controlling the amount of mist generated by the mist generating unit 10, the state of the hair after using the hair dryer 1E is separated from the mist containing an acidic component having a concentration of 9 mg / L by 10 cm. It becomes possible to approach the state of the hair applied for 10 seconds from the distance.

And while using the hair dryer 1E, when the air volume switching means 12 is operated to switch the air volume and the air temperature switching means 13 is operated to switch the air temperature, 600 W of electric power is supplied to the heating unit 6. Is stopped (T1 in FIG. 10), and a wind of 0.75 m ² / min is sent out at about 30 ° C.

  At this time, the control part 8 controls the quantity of the mist produced | generated by the mist production | generation part 10 so that only 1/2 of acidic mist is produced | generated at 1200W. That is, the control unit 8 controls the current A flowing through the mist generation unit 10 to be 3 / 8A0. In this way, when the air flow rate switching means 12 is driven and the air flow rate decreases, the control unit 8 as the second control unit controls the mist generation unit 10 so that the mist generation amount decreases. Yes.

Then, when the blast amount switching means 12 is operated again so that 1200 W of power is supplied, and the blast temperature switching means 13 is operated again to supply power to the heating unit 6 ( In FIG. 10, T2), a wind of 1.3 m ² / min is delivered at about 120 ° C. In this case, the control by the control unit 8 is also in the original state. That is, when the acidity (nitrate ion concentration) of the mist containing nitrate ions reaches a predetermined amount (threshold value) x0, the control unit 8 determines that the nitrate ion concentration of the mist containing nitrate ions is the predetermined threshold value x0. The amount of mist generated by the mist generating unit 10 is kept constant at a magnification y (3/4 in FIG. 10) (so that the current A flowing through the mist generating unit 10 becomes 3 / 4A0). Come to control.

  Finally, when the power source is turned off by operating the push-type power switch 7 (T3 in FIG. 10), power supply to the motor 52, the heating unit 6, and the mist generating unit 10 of the blower unit 5 is stopped.

Note that, as described above, the change in power consumption (change in the blowing rate) has a greater effect on the hair and skin than the change in blowing temperature due to turning on and off of the heating unit 6. Therefore, in this embodiment, power supply to the heating unit 6 is stopped in a state where power of 1200 W is supplied and a wind of 1.3 m ² / min is sent, so that a cold wind of about 30 ° C. is sent. Even in this case, since the wind of 1.3 m ² / min is sent, normal control (control from T0 to T1 and T2 to T3 in FIG. 10) is performed by the control unit 8. ing.

In addition, when power is supplied to the heating unit 6 and hot air of about 120 ° C. is being sent out, 600 W of power is supplied and 0.75 m ² / min of wind is sent out. Since the wind of 0.75 m ² / min is sent out, the control unit 8 performs control (a control from T1 to T2 in FIG. 10) that is generated by 1/2 when the acidic mist is 1200 W. I am doing so.

  As described above, the second control unit according to the present embodiment controls the mist generation unit 10 so that the mist generation amount decreases when the blast amount switching unit 12 is driven and the blast amount decreases. Yes.

  It should be noted that the second mist generation amount is reduced not only when the blowing amount switching means 12 is driven and the blowing amount is lowered, but also when the blowing temperature switching means 13 is driven and the blowing temperature is lowered. The control unit may control the mist generating unit 10.

  Also according to the present embodiment described above, the same operations and effects as the fourth and fifth embodiments can be obtained.

  In addition, it is also possible to apply the structure and control of this embodiment to the hair dryers 1 and 1A shown in the said 1st Embodiment and its modification.

  The preferred embodiments of the present invention have been described above. However, the present invention is not limited to the above embodiments, and various modifications can be made.

  For example, in each of the above-described embodiments, an apparatus using an electrostatic atomization apparatus as the mist generation unit has been exemplified. However, a Venturi system that discharges a liquid containing nitrate ions (acidic components) from a Venturi tube. An apparatus may be used.

  Further, in each of the above embodiments, the example of detecting and controlling the concentration of nitrate ion contained in the mist is exemplified, but by detecting other components, the amount of the acidic component to be atomized is predicted, You may make it control. When the generation method of mist containing an acidic component is an electrostatic atomization method and the electrode is Pt, Zn, or the like, the amount of released Pt, Zn, or the like is substantially proportional to the amount of the acidic component. Because.

  Moreover, although what performed only control of the mist production | generation part was illustrated in the said 1st to 3rd embodiment, you may make it combine control of an air volume or a calorie | heat amount.

  Moreover, in the said 4th and 6th embodiment, although the ventilation volume switching means illustrated what switches an ventilation volume to 2 steps | paragraphs, it may be made to enable the ventilation volume switching means to switch an ventilation volume to 3 steps or more. Good.

  Moreover, in the said 5th and 6th embodiment, although the ventilation temperature switching means illustrated what switches a ventilation temperature to 2 steps | paragraphs, it may be made so that a ventilation temperature switching means can switch a ventilation temperature to 3 steps | paragraphs or more. Good.

  In addition, the air flow path, the air blowing unit, the heating unit, and other detailed specifications (shape, size, layout, etc.) can be appropriately changed.

DESCRIPTION OF SYMBOLS 1 Heating blower 3 Housing 4 Air flow path 4a Inlet opening (suction inlet)
4b Outlet opening (discharge port)
4c Branching path 5 Blower part 6 Heating part 8 Control part (a control part and a 2nd control part)
DESCRIPTION OF SYMBOLS 10 Mist production | generation part 11 Detection part 12 Blast volume switching means 13 Blast temperature switching means

Claims (8)

An air flow path provided in the housing and provided with suction ports and outlets on both sides;
A blower unit that is arranged on the upstream side of the blower channel and introduces air from the suction port and discharges it from the blowout port;
A heating unit that is provided on the downstream side of the blowing unit and heats the blowing;
A mist generating unit that generates mist containing an acidic component;
A detection unit for detecting the acidity of the mist generated by the mist generation unit;
A controller that controls the amount of mist generated by the mist generator;
With
The said control part controls the production amount of the mist produced | generated by the said mist production | generation part according to the acidity of the mist detected by the said detection part, The heating air blower characterized by the above-mentioned.   The heated air blower according to claim 1, wherein the mist generating unit is provided in the air flow path, and the detecting unit is disposed on the downstream side of the mist generating unit. The air flow path includes a branch path that is branched from the downstream side of the air blowing unit and the upstream side of the heating unit and is supplied with air that does not pass through the heating unit,
The at least part of the mist produced | generated by the said mist production | generation part is supplied to the said branch path, and the said detection part is provided in the downstream of the said branch path, The Claim 1 or Claim 2 characterized by the above-mentioned. Heating air blower.   The control unit drives the mist generation unit when the air blowing unit is driven, and controls the mist generation unit so that the acidity of the mist detected by the detection unit is equal to or less than a predetermined value. The heating air blower of any one of Claims 1-3 characterized by the above-mentioned.   The control unit drives the mist generation unit when the air blowing unit is driven, and generates the mist so that the acidity of the mist detected by the detection unit is constant within a predetermined value or less. The heating air blower according to any one of claims 1 to 3, wherein the heating air blower is controlled.   The control unit drives the mist generating unit when the air blowing unit is driven, and repeats increase and decrease within a range where the acidity of the mist detected by the detecting unit is equal to or less than a predetermined value. The heating air blower according to any one of claims 1 to 3, wherein the air blower is controlled. The heating air blower includes air flow switching means for switching the air flow, and a second control unit that controls the amount of mist generated by the mist generating unit,
The said 2nd control part controls the said mist production | generation part so that a mist production | generation amount may fall, when the said ventilation | gas_flowing amount switching means is driven and the ventilation | gas_flowing amount falls. 6. The heating air blower according to claim 1. The heating air blower includes air blowing temperature switching means for switching the air blowing temperature, and a second control unit that controls the amount of mist generated by the mist generating unit,
The said 2nd control part controls the said mist production | generation part so that when the said ventilation temperature switching means is driven and ventilation temperature falls, mist production amount falls. The heating air blower according to any one of 7.

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