JP3159830U - Atomizer - Google Patents

Abstract

An atomization device that detects an inclination angle of a predetermined portion of an apparatus and switches an operation state is provided. An inhaler includes a boiler tank 2 and a heating chamber 6 for boiling water contained therein to change it into steam, a heater 3 disposed for heating water, and an inclination angle of a predetermined portion of the inhaler. And a heater control unit that controls the amount of current supplied to the heater 3. Based on the comparison result between the tilt angle detected by the acceleration sensor 9 and a predetermined angle, the operating state of the inhaler such as the amount of power supplied to the heater 3 is switched. [Selection] Figure 2

Description

  The present invention relates to an atomizer, and more particularly to an atomizer that atomizes and outputs a liquid.

  A humidifier that generates water vapor using a heater incorporates a safety device that turns off the power to the heater when the device falls (Patent Document 1).

  Moreover, as a power disconnection device at the time of a fall, the structure which stops the electric power feeding to a heater when an instrument main body falls in an electric stove is proposed (patent document 2).

Japanese Utility Model Publication No. 5-42944 JP-A-8-298053

  The fall detection function of Patent Document 1 is composed of a movable fall push bar protruding from the bottom of the main body of the humidifier and a safety switch that comes into contact with the opposite end of the fall push bar. When the safety switch is turned on or off by a tipping push bar tilted from a predetermined angle, the heater power is shut off as a tipping detection to ensure safety.

  However, in such a technique, it is not easy to detect a delicate tilt only by arranging a falling push rod and a safety switch in one place. In order to detect tilt in all directions, front and back, left and right, a plurality of overturning push rods and switches are arranged, and each switch needs to be connected in series, and the position of the overturning push rod is fixed due to the configuration of the device. There is a problem in assembling property and cost.

  Moreover, when using it mounted on a carpet with long hair, the fall push rod may not operate | move appropriately.

  In addition, in a device that uses water such as a humidifier, the mechanical portion may be required to be waterproof, which complicates the structure and increases costs.

  SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide an atomization device that can detect an inclination angle of a predetermined portion of the device with a simple configuration and switch an operation state.

  According to an aspect of the present invention, the atomizing device includes an atomizing unit that changes the contained liquid into a mist, a heater disposed in association with the atomizing unit, and an inclination angle of a predetermined portion of the atomizing device. An angle detection sensor that detects the amount of current and a heater control unit that controls the amount of current supplied to the heater. Based on the comparison result between the tilt angle detected by the angle detection sensor and the predetermined angle, the operation state of the atomizer is switched.

Preferably, the heater control unit controls the energization amount to the heater based on the comparison result.
Preferably, the operation state of the atomizer is switched based on a comparison result between the tilt angle detected by the angle detection sensor when the power is turned on and a predetermined angle.

Preferably, the angle detection sensor is an acceleration sensor.
Preferably, the operation state of the atomizer is switched based on a comparison result between the acceleration detected by the acceleration sensor and a predetermined acceleration.

  Preferably, the operation state of the atomizing device is switched when it is detected that a state in which the amount of change in acceleration detected by the acceleration sensor is greater than a predetermined value continues for a predetermined time or longer.

  Preferably, the predetermined portion is a main body, and the acceleration sensor is installed at a portion where the inclination angle changes when an external force that moves the main body acts.

  Preferably, a power switch operated to rotate about the rotation axis is further provided, and the acceleration sensor detects an inclination angle due to rotation of the rotation axis as a predetermined portion.

  Preferably, a spray port that can change the tilt angle is further provided, and the acceleration sensor detects the tilt angle of the spray port that is a predetermined portion.

  Preferably, the bottom surface of the main body of the atomizing device has a plurality of surfaces with different inclination angles, the bottom surface is a predetermined portion, and the main surface is defined with respect to each surface of the plurality of surfaces. Can be installed.

Preferably, a change in the operating state of the atomizer is notified.
Preferably, the atomization device is an inhaler.

  According to this device, by providing the acceleration sensor that detects the tilt angle of the predetermined portion of the atomizing device, switching of the operation state according to the tilt angle of the predetermined portion of the device can be realized with a simple configuration. .

It is an external view of the inhaler by this Embodiment. It is a figure explaining an example of the attachment aspect of the acceleration sensor in the inhaler by this Embodiment. It is a figure explaining the other example of the attachment aspect of the acceleration sensor in the inhaler by this Embodiment. It is a figure explaining the further another example of the attachment aspect of the acceleration sensor in the inhaler by this Embodiment. It is a hardware block diagram of the inhaler by this Embodiment. It is a functional block diagram of the inhaler by this Embodiment. (A)-(C) are the figures explaining the inclination angle detection using an acceleration sensor. It is a figure explaining the peripheral circuit structure of CPU. It is a process flowchart explaining operation | movement of an inhaler. It is a figure which shows typically the inhaler in which a bottom face has a some angle.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, the same reference numerals indicate the same or corresponding parts, and description thereof will not be repeated.

  In the present embodiment, as an example of an atomizing device, a vapor-type inhaler that sucks up and sprays water for inhalation using vapor pressure is shown. In this embodiment, the liquid (water) is atomized by boiling it using a heater, but the atomization may be by ultrasonic vibration. In this case, the heater is ultrasonic vibration. Used to heat the fog produced by

  Referring to FIG. 1, the inhaler according to the present embodiment includes a housing 1, a vent hole 16 formed in advance on the upper surface of the housing 1 for taking air into the inhaler, and a detachable attachment to the housing 1. A suction port 10 that is freely attached is provided. On the side surface of the housing 1, a switch 11 is provided that is operated to switch the power supply of the inhaler ON / OFF and the spray amount. In addition, a power plug 13 is connected to the main body of the inhaler via a power cord 12, and the power plug 13 is inserted into a wall outlet so that a commercial power supply can be obtained via the outlet, the power plug 13 and the power cord 12. Electric power is supplied to the inhaler.

  The internal configuration of the inhaler will be described with reference to FIG. The inhaler includes a water supply cup 4 that stores water for suction, a boiler tank 2 that corresponds to an atomizing section, a heating chamber 6, and a heater 3. The boiler tank 2 stores water for generating steam for sucking up water for suction. The heating chamber 6 and the heater 3 are disposed in advance along the side surface of the boiler tank 2 in order to heat water. Further, the inhaler includes a jet nozzle portion 5 for jetting steam generated by heating of the heater 3 via the upper portion of the water supply cup 4, and a water supply tube 4 a inserted into the water supply cup 4. One end of the water supply tube 4 a is located in the water in the water supply cup 4, and the other end is located in a path through which the steam of the ejection nozzle portion 5 passes.

  The boiler tank 2 is formed in a cylindrical shape having a bottom, and the upper portion of the boiler tank 2 is open. The upper part of the boiler tank 2 is sealed with a lid member. A heating chamber 6 is formed on the side surface on the lower side of the boiler tank 2. A water supply path 4 </ b> B is provided on the lower side of the boiler tank 2. A communication passage 4 </ b> C is provided at substantially the center of the boiler tank 2.

  The boiler tank 2 and the lower side of the heating chamber 6 communicate with each other through the water supply path 4B. The boiler tank 2 communicates with the upper side of the heating chamber 6 through the communication passage 4C. A heater 3 is disposed on the opposite side of the boiler tank 2 across the heating chamber 6. Electric power is supplied to the heater 3 through the power cord 12.

  An ejection nozzle portion 5 is attached to the upper side surface of the boiler tank 2. The nozzle of the ejection nozzle portion 5 communicates with the inside of the boiler tank 2. The nozzle of the ejection nozzle portion 5 extends toward the suction port 10 located obliquely upward. A water supply tube 4a is attached to the nozzle tip side of the ejection nozzle portion 5 so as to hang down. The water supply tube 4 a extends to the vicinity of the bottom of the water supply cup 4.

  The operation of the inhaler will be described. By storing, for example, water as a predetermined liquid in the boiler tank 2 and the water supply cup 4, a small amount of water is supplied to the heating chamber 6 through the water supply path 4 </ b> B (for convenience of illustration, in FIG. 2. And a small amount of water supplied to the heating chamber 6 is not described).

  First, the plug 13 of the power cord 12 is inserted into an outlet, and the switch 11 is turned on to supply power to each part. The heater 3 heats the water supplied into the heating chamber 6. Steam is generated inside the heating chamber 6 by heating. The steam sequentially passes through the communication passage 4 </ b> C and the upper part of the boiler tank 2.

  The steam passes through the nozzle of the ejection nozzle portion 5 and is ejected from the nozzle toward the suction port 10 located in the obliquely upward direction. When the steam is ejected, a vapor pressure (negative pressure) is generated in the vicinity of the steam ejection port of the ejection nozzle portion 5.

  On the other hand, the water supply tube 4a sucks up water from the water supply tank 4 by the vapor pressure (negative pressure) generated by the steam ejected from the ejection nozzle portion 5 (Venturi effect). Water is discharged to the outside from the suction port 10 together with the steam ejected from the ejection nozzle portion 5.

  In the present embodiment, the inhaler includes an angle detection sensor for detecting an inclination angle of a predetermined portion (including the main body) of the inhaler. In the present embodiment, an acceleration sensor is exemplified as the angle detection sensor. However, the present invention is not limited to the acceleration sensor as long as the inclination angle can be detected.

  The acceleration sensor is installed at a predetermined portion where the inclination angle changes when an external force that moves the main body of the inhaler is applied. Based on the comparison result between the tilt angle detected by the acceleration sensor and the predetermined angle, the operating state of the inhaler (such as the amount of power supplied to the heater 3) is switched.

  Referring to FIG. 2, the acceleration sensor 9 is mounted on the substrate 8 in advance, so that the substrate 8 and the acceleration sensor 9 are integrally formed. When the inhaler is placed on the floor surface or the desk surface or the like, the substrate 8 on which the acceleration sensor 9 is mounted is at a position far (distant) from the bottom surface 1b of the housing parallel to the floor surface or the desk surface. And is disposed in a gap (gap) in the inhaler (see FIG. 2).

  In FIG. 2, the water cup 4 is disposed in the space above the water cup 4. Thereby, even if the inclination angle of the bottom surface 1b of the inhaler main body with respect to the floor surface or the desk surface is small, the acceleration sensor 9 can quickly detect the inclination angle of the main body.

  In FIG. 2, when the power cord 12 is pulled in the direction of the right arrow in the figure, the substrate 8 on which the acceleration sensor 9 is mounted is attached at a portion where the main body moves greatly. That is, when the power cord 12 is pulled in the direction of the arrow, for example, when the user hooks his / her foot, the rubber leg 1B for fixing the inhaler attached to the outside of the bottom surface 1b serves as a fulcrum, and the power cord 12 The body part on the opposite side of the connection part moves greatly. Even in this case, according to the attachment position in FIG. 2, the acceleration sensor 9 can quickly detect the tilt angle of the main body.

  If the inclination of the inhaler body can be detected, the mounting position of the substrate 8 on which the acceleration sensor 9 is mounted is not limited to the position shown in FIG. For example, you may arrange | position so that the board | substrate 8 may be mounted on the floor surface 1b in the space | gap on the bottom face 1b like FIG. In FIG. 3, it is arranged in the gap between the water supply cup 4 and the boiler tank 2.

  Alternatively, the substrate 8 on which the acceleration sensor 9 is mounted has a connecting portion between the power cord 12 and the main body of the inhaler as a power point, and a rubber leg 1A for fixing the inhaler attached to the outside of the bottom surface 1b of the inhaler (or When 1B) is assumed to be a fulcrum, it may be arranged at the portion with the largest movement. For example, as shown in FIG. 4, it is disposed in the gap between the boiler tank 2 and the casing near the connection portion of the power cord 12. As a result, even if an external force acts on the main body of the inhaler, for example, someone else hits the power cord 12, and the tilt of the main body of the inhaler is likely to fall on the floor or fall from the desk. Can be detected promptly.

  In addition, the space | gap where the board | substrate 8 which mounts the acceleration sensor 9 in the inside of the inhaler 1 is attached is enclosed with a wall, and is set as waterproof specification.

  With reference to FIG. 5, the functional configuration of the inhaler according to the present embodiment will be described. The inhaler includes a CPU (Central Processing Unit) 50 mounted together with the acceleration sensor 9 on the substrate 8. Further, an operation unit 80 corresponding to the switch 11, a power supply unit 40 for processing an electric signal supplied via the power cord 12, a heater unit 30 for controlling the heater 3, and a display unit provided on the surface of the housing 1 60, an angle detector 70 for detecting the tilt angle of the inhaler body, a timer 51 for timing, a memory 52 for storing a data program, and an alarm output unit 53 for outputting an alarm sound Prepare. The CPU 50 controls each unit while inputting / outputting signals and data to / from other units.

  The power supply unit 40 includes a low voltage circuit unit 41 that converts AC (alternating current) 100 V (input rated voltage) supplied from a commercial power supply via the power cord 12 into a low voltage of DC (direct current) 5 V, and a low voltage circuit unit 41. Includes a step-down unit 43 that receives a DC5V voltage signal output from the power supply and steps down the voltage signal to 3V. In the present embodiment, since the acceleration sensor 9 is driven by a 3V voltage signal, a DC3V voltage signal output from the step-down unit 43 is applied to the acceleration sensor 9. Furthermore, the power supply unit 40 includes a zero cross detection circuit 45 and an AC 220V detection circuit 47 corresponding to a voltage detection circuit.

  The zero cross detection circuit 45 receives a voltage signal based on AC 100 V, compares it with a predetermined reference voltage, detects a zero cross point based on the comparison result, and gives the detection result to the CPU 50. The CPU 50 can detect the frequency of the voltage signal of AC 100V (here, assumed to be either 50 Hz or 60 Hz) based on the input signal from the zero cross detection circuit 45.

  The AC 220V detection circuit 47 detects a voltage signal input via the power cord 12 and gives the detection result to the CPU 50. When the AC 220V detection circuit 47 detects that the voltage signal supplied via the power cord 12 is an AC 220V signal, the AC 220V detection circuit 47 outputs a signal of level “1” to the CPU 50 and other signals (this embodiment) In the embodiment, a signal of level “0” is output to the CPU 50.

  The operation unit 80 has an intensity volume 81 for adjusting the spray amount in relation to the switch 11. The user can switch the power ON / OFF by operating the switch 11 and can switch the spray amount to be either “small” or “large”. When the switch 11 is operated, a signal having a level corresponding to the operation is given to the CPU 50. The CPU 50 compares the given signal level with a predetermined level and detects the instructed spray amount based on the comparison result.

  The display unit 60 uses an LED (Light Emitting Diode) 61 or the like to display information for notifying the operating state of the inhaler to the outside based on data provided from the CPU 50. The notification of the operating state of the inhaler (spray amount, ON / OFF of energization to the heater 3, etc.) is not limited to the alarm sound by the alarm output unit 53 described above, but may be by light using the LED 61.

The angle detector 70 includes an acceleration sensor 9 that detects gravitational acceleration applied to the inhaler.
The heater unit 30 includes an output circuit 3B for supplying current to the heater 3, a heater control circuit 3A for controlling the output of current from the output circuit 3B, and a temperature detection circuit 3C.
In the present embodiment, PTC (Positive Temperature Coefficient) is used for the heater 3. The PTC has a resistance value that rapidly increases at a certain temperature when a current is supplied and the temperature rises. When the temperature exceeds a certain temperature, the resistance value suddenly increases. Therefore, when the temperature is higher than this temperature, the current limit works. Therefore, it is possible to avoid the heater 3 from generating excessive heat.
The temperature detection circuit 3 </ b> C corresponds to a temperature sensor (not shown) attached to the external wall surface of the boiler tank 2. A signal of the wall surface temperature of the boiler tank 2 detected by the temperature detection circuit 3 is given to the CPU 50.

  With reference to FIG. 6, the functional configuration of the inhaler according to the present embodiment will be described. The inhaler includes an input unit 504 that processes a signal of the switch 11, an initial processing unit 505 that is activated when the switch 11 is operated and switched from power OFF to ON, and an inclination angle of the inhaler based on an output signal of the acceleration sensor 9. The inclination measuring unit 508 for detecting (measuring), the acceleration measuring unit 509 for detecting (measuring) the acceleration applied to the inhaler based on the signal output from the acceleration sensor 9, and the operation of the inhaler based on the time data of the timer 51 A timekeeping control unit 510 that monitors time and an airborne detection unit 511 that detects an airing of the boiler tank 2 are provided. The initial processing unit 505 includes a power supply detection unit 506 that detects a voltage (power supply voltage) supplied to the inhaler via the power cord 12. A temperature sensor that detects the wall surface temperature of the boiler tank 2 is provided on the outer bottom surface of the boiler tank 2, and the airborne detection unit 511 determines whether or not the boiler tank 2 is aired based on the temperature detected by the temperature sensor. Detect. Here, the emptying refers to a state where the heater 3 is energized with no water in the boiler tank 2 and the heating chamber 6.

  Furthermore, the inhaler includes an over-detecting unit 501 for detecting inclination and movement exceeding a predetermined level of the inhaler. The over detection unit 501 is based on the measurement result of the inclination measurement unit 508, and the output signal of the angle over detection unit 502 and the acceleration measurement unit 509 for determining (detecting) whether or not the inhaler is inclined by a predetermined angle or more. Based on the above, an over-acceleration detector 503 for detecting whether or not an acceleration exceeding a predetermined speed is applied to the inhaler is included.

  An example of inhaler tilt detection using the acceleration sensor 9 will be described with reference to FIGS. Referring to FIG. 7A, assuming that the two orthogonal axes defining the surface (two-dimensional plane) on which the acceleration sensor 9 of the substrate 8 is placed are the X axis and the Z axis, the two axes are orthogonal to each other. Assume a Y-axis (Y-axis extends in a direction penetrating the paper surface). The acceleration sensor 9 is a gravitational acceleration sensor, and in this embodiment, by detecting gravitational acceleration in three directions (Y direction in which the Y axis extends, X direction in which the X axis extends, and Z direction in which the Z axis extends), Has the function of measuring the tilt of the inhaler. The acceleration sensor 9 is not limited to the detection direction in the three axial directions, and may be in the two axial directions.

The detection of inclination and acceleration using the acceleration sensor 9 will be described. It is assumed that the acceleration sensor 9 outputs numerical data of 340 counts to the CPU 50 when a gravitational acceleration of 1 G (G = 9.8 m / m ² ) is detected in each of the X, Y, and Z directions.
When the acceleration sensor 9 is attached to the substrate 8 as shown in FIG. 7A, in the state of FIG. 7B where the X axis is orthogonal to the ground, 1G gravitational acceleration is detected in the X direction. , A value of 340 counts is output for the X direction, and a value of 0 count is output for each of the Y direction and the Z direction.
For example, when the substrate 8 on which the acceleration sensor 9 is mounted is tilted by θ ° as shown in FIG. 7C, if the output in the X direction is 300 counts, the tilt measuring unit 50 outputs from the acceleration sensor 9. Is detected (calculated) as θ = COS ⁻¹ (300/340). The detected inclination angle is given to the angle over detection unit 502. The angle over detection unit 502 compares the detected inclination angle with a predetermined inclination angle stored in advance in the memory 52, and based on the comparison result, whether or not the detected inclination angle exceeds the predetermined inclination angle (overscore). Whether or not) and output the determination result.
The acceleration measuring unit 509 receives the inclination angle detected by the inclination measuring unit 508, detects a change (difference) in the inclination angle per predetermined unit time based on the time measurement data of the timer 51, and detects the detected change angle as an acceleration over detection. Output to the unit 503. The acceleration over detection unit 503 compares the input change angle with a predetermined angle stored in the memory 52 in advance, and based on the comparison result, whether or not the change angle exceeds the predetermined angle (whether or not it exceeds). And the determination result is output.

  With reference to FIG. 8, the configuration of peripheral circuits of the CPU 50 will be described. The voltage signal of AC100V supplied from the power cord 12 is converted to DC5V by the low voltage circuit 41, and the voltage signal of DC5V is further stepped down to a voltage of DC3V by the step-down unit 43. The 3V voltage signal after the voltage drop is supplied as a drive voltage to the acceleration sensor 9 and the like.

  The ON / OFF of the heater 3 will be described. On the basis of the output signal from the CPU 50, the heater control unit 30 performs ON / OFF control of the photo triac 3X corresponding to the heater control circuit 3A and the triac 3Y corresponding to the output circuit 3B via the transistor Q2 which is a switching element. Thus, energization to the heater 3 is controlled. Specifically, when the CPU 11 detects that the switch 11 is operated and the switch of the power switch circuit 11A corresponding to the switch 11 is turned on (closed) based on the input signal from the power switch circuit 11A, The CU 50 outputs a predetermined current to the base terminal of the transistor Q2. As a result, the transistor Q2 becomes conductive (ON), the phototriac 3X connected to the collector terminal of the transistor Q2 is turned on, and an ON signal is given from the CPU 50 to the triac 3Y via the phototriac 3X. As a result, a voltage signal of 100 VAC is supplied to the heater 3 via the triac 3Y that has been turned on.

  Conversely, when the switch 11 is turned off, the transistor Q2 is controlled to a non-conducting (OFF) state. As a result, the phototriac 3X connected to the collector terminal of the transistor Q2 is turned off, and an OFF signal is given from the CPU 50 to the triac 3Y via the phototriac 3X. Thereby, since the triac 3Y is turned off, the power supply to the heater 3 is stopped.

  The switching of the spray amount using the heater 3 will be described. The heater 3 is supplied with electric power of 100V AC by the full-wave phase control method via the triac 3X. Specifically, the CPU 50 detects the zero cross point of the AC 100V AC waveform based on the input signal from the zero cross detection circuit 45. When the intensity volume 81 is operated by the user and a designation signal indicating that the spray amount is “large” is input, an ON signal is output to the triac 3Y via the photo triac 3X in synchronization with the detected zero cross point. To do. As a result, the heater 3 is supplied with the maximum level of power based on the AC 100V AC waveform, and the heater 3 generates the largest amount of heat and the spray amount increases.

  On the other hand, when the intensity volume 81 is operated and a designation signal indicating that the spray amount is “low” is input, the CPU 50 passes the photo triac 3X to the triac 3Y at a timing delayed by a predetermined time from the zero cross point of the AC 100V AC waveform. To output an ON signal. As a result, the heater 3 is supplied with an amount of electric power that is smaller than the maximum amount of electric power based on the entire waveform, and the amount of heat generated by the heater 3 is reduced and the amount of spray is reduced.

  As described above, the CPU 50 switches the amount of power supplied to the heater 3 via the triac 3Y in accordance with the switching operation of the spray amount by the strength volume 81 interlocked with the switch 11, whereby the unit time from the boiler tank 2 is changed. The amount of generated steam, that is, the spray amount can be switched.

  The operation of the inhaler will be described with reference to FIG. The flowchart of FIG. 9 is stored in advance in the memory 52 as a program. When the CPU 50 reads the program from the memory 52 and executes the read program, the processing according to the flowchart of FIG. 9 is realized.

  First, when the user operates the switch 11 to switch from power OFF to power ON, the CPU 50 detects the switching operation based on an input signal from the input unit 504 and starts processing (step S1).

When the process is started, the CPU 50 activates the initial processing unit 505.
The initial processing unit 505 executes an initial processing routine R1. Specifically, using the power supply detection unit 506, it is determined based on the output signal from the AC220V detection circuit 47 whether the power supply voltage supplied via the power cord 12 is AC220V (step S3). If it is determined that the output signal of the AC220V detection circuit 47 is level “1” (YES in step S3), the supplied power supply voltage is determined to be AC220V, and the atomization OFF processing routine R3 is started.

  In the atomization off routine R3, the CPU 50 controls the power supply unit 40 to turn off the power supply to each unit. As a result, energization of the heater 3 is not started, so that the water in the water supply cup 4 is not atomized and sprayed (step S27). The process ends here.

  On the other hand, when the power supply detection unit 506 determines that the output signal of the AC220V detection circuit 47 indicates “0”, that is, detects that the power supply voltage supplied via the power supply cord 12 is AC100V (NO in step S3). ), The process of step S5 is performed.

  In step S <b> 5, the power source detection unit 506 detects the number of detections of the zero cross point per unit time based on the output signal from the zero cross detection circuit 45. Based on the detection result, it is determined whether the frequency of the supplied power supply voltage signal is 50 Hz or 60 Hz (step S5). When the frequency determination is finished, the CPU 50 sets the value of the timer 51 to (T = 1). Thereby, the initial processing routine R1 ends.

  Subsequently, the CPU 50 activates the atomizing routine R2. When the atomizing routine R2 is started, the timing control unit 510 counts up the value of the timer 51 (step S9). Subsequently, the timing control unit 510 compares the count value T of the timer 51 with a predetermined value MAX read from the memory 52 and determines whether or not a condition of T ≧ MAX is satisfied (step S11). When it is determined that this condition is satisfied (“TIME UP” in step S11), that is, when the operation of the inhaler is continued beyond a specified time, the above-described atomization off routine R3 is started.

  On the other hand, if it is determined that the condition (T ≧ MAX) is not satisfied (“not” in step S11), in step S13, the CPU 50 determines whether or not the boiler tank 2 is in an empty state (step S13). ). That is, the airborne detection unit 511 compares the wall surface temperature of the boiler tank 2 with a predetermined temperature based on the output signal of the temperature detection circuit 3C, and determines that it can be said that the predetermined temperature is exceeded based on the comparison result. The state is detected (YES in step S13), the atomization off routine R3 is started, and the atomization operation is stopped. That is, the CPU 50 controls the triac 3Y to cut off the power applied to the heater 3. Thereby, the heating by the heater 3 is stopped and the generation of steam from the heating chamber 6 is stopped.

  On the other hand, if the airborne detection unit 511 determines that the predetermined temperature has not been exceeded based on the comparison result described above, and detects that the airborne state is not empty (NO in step S13), the angle overdetection unit of the overdetection unit 501 is detected. 502 and the acceleration over detection unit 503 are based on the output signals of the inclination measurement unit 508 and the acceleration measurement unit 509 based on the output signal of the acceleration sensor 9, and the inhaler is inclined beyond a predetermined angle or exceeds a predetermined acceleration. It is determined whether acceleration is applied (step S15).

  If it is determined that the vehicle is tilted beyond a predetermined angle, or that acceleration greater than or equal to the predetermined acceleration is given (YES in step S15), the above-described atomization off routine R3 is started, and atomization and spraying are stopped. To do.

  When the posture of the inhaler (inclination angle / acceleration) in the state where the switch 11 is operated and the power is turned on is thus detected and it is determined that the body posture is not appropriate at the start of spraying, Not done. At this time, the alarm output unit 53 may output an alarm sound.

  If it is determined that the inclination is equal to or less than the predetermined angle or the acceleration is less than the predetermined value (NO in step S15), then the CPU 50 operates the switch 11 based on the input signal from the strength volume 81 to set the spray amount. Whether it is switched to a small amount or a large amount is determined (step S17). If it is determined that the amount has been switched to a small amount (“small” in step S17), the triac 3X is controlled via the heater control unit 507 in step S21 to reduce the amount of power applied to the heater 3. As a result, the amount of steam generated from the heating chamber 6 is reduced and the amount of spray is reduced.

  On the other hand, if it is determined that a large amount has been switched (“multiple” in step S17), in step S19, the triac 3X is controlled via the heater control unit 507 to maximize the amount of power applied to the heater 3. As a result, the amount of steam generated from the heating chamber 6 increases and the amount of spray increases.

  After the process of step S19 or S21, it returns to the process of step S9 again and the subsequent processes are repeated. In the process of the atomizing routine R2, when the power OFF operation of the switch 11 is detected, this is processed as an interrupt signal, the process of the atomizing routine R2 is terminated, and the atomization off routine R3 is started. Stop atomization.

  Thus, when the inclination angle of the inhaler body is detected by the acceleration sensor 9 mounted on the inhaler and the detected inclination angle indicates a predetermined angle or more, the heater 3 is turned off. It is possible to avoid damage to the equipment due to tilting of the inhaler body during use or water outflow when falling.

  Further, according to the present embodiment, the structure can be simplified and the placement of the inhaler can be simplified because the tilt detection unit is not a structure that protrudes to the outside of the housing as in the conventional method using the overturning push rod. The slope can be confirmed even on a carpet with long hairs.

  Further, by detecting the acceleration to the inhaler body, it is possible to detect that the user has lifted the body and turn off the heater 3. As a result, when the inhaler body is suddenly lifted and moved during use, the heater 3 can be automatically turned off and the generation of steam can be stopped.

  Further, the shaking of the main body of the inhaler is detected as acceleration using the acceleration sensor 9 and the power supply to the heater 3 is automatically stopped. As a result, the heater 3 is also turned off when it is detected that a state in which the acceleration change amount detected by the acceleration sensor 9 is greater than a predetermined value continues for a predetermined time (for example, when an earthquake occurs). It is possible to prevent boiling water from overflowing from the main body.

(Other embodiments)
The CPU 50 may output an alarm via the alarm output unit 53 when detecting that the switch 11 is turned on while the inhaler body is tilted beyond a predetermined angle.

  For example, when the main body cannot take a normal posture depending on the inclination angle, when the appropriate amount of water (water in the heating chamber 6) cannot contact the surface of the heater 3, the spray start is started. Be late. If the start of spraying is delayed, the user may open the lid member of the boiler tank 2 in an attempt to check the inside (such as the presence or absence of water). In that case, the temperature in the boiler tank 2 and the heating chamber 6 falls, and the spray start is further delayed. In the present embodiment, when such a state is detected, an alarm sound is output as described above, so that it is possible to prevent the user from inadvertently opening the lid member and delaying the start of spraying. As a result, the user can be encouraged to use the inhaler with an appropriate body posture, and the time required to start spraying can be made constant.

  The predetermined part to which the acceleration sensor 9 is attached may be a rotary shaft of a rotary power ON / OFF switch. In this case, the acceleration sensor 9 detects the tilt angle of the rotation by the switch operation of the rotation axis. The detected angle is switched in conjunction with the operation of the power ON / OFF switch. As a result, it is possible to detect the power ON / OFF operation based on the output signal of the acceleration sensor 9 and switch the operation state to spray start / stop.

  Here, the switching of the spray amount is not limited to the one linked to the operation of the strength volume 81 described above, and may be as follows.

  In other words, when the suction port 10 serving as the spray port is detachable (replaceable) from the main body, the attachment angle (tilt angle) of the suction port 10 to the main body is detected, and the throat is inhaled based on the detected angle. You may make it switch to use (a large spray amount) or nasal inhalation (a small spray amount). Specifically, if the acceleration sensor 9 is attached to a predetermined portion related to the suction port 10, specifically, the portion where the suction port 10 is mounted on the main body, the mounting angle of the suction port 10 detected at the mounting portion is switched. In conjunction with this, the output level of the acceleration sensor 9 changes. Based on the output of the acceleration sensor 9 (inclination angle of the suction port 10), the power supplied to the heater 3 can be switched, and the spray amount can be switched.

  Further, when the suction port 10 that is used for both throat inhalation and nasal inhalation is attached to the main body via the throat / nose switching knob, the ejection nozzle portion 5 is switched by switching the angle of the throat / nose switching knob. The spray amount supplied to the suction port 10 can be switched by the angle of the throat / nose switching knob. The acceleration sensor 9 is attached to the throat / nose switching knob, and the acceleration sensor 9 detects the tilt angle of the throat / nose switching knob, and switches the amount of power supplied to the heater 3 according to the detected angle. Thus, the spray amount can be switched in conjunction with the angle switching operation of the throat / nose switching knob.

  On the other hand, the suction port 10 may be fixedly attached to the main body, and the main body itself may be tilted so that it can be used for throat inhalation and nasal inhalation. As shown in FIG. 10, the bottom surface of the main body has two tapered surfaces. The two surfaces have different inclination angles. The main body is tilted and placed using the tapered bottom surface. By properly using the bottom surface used for mounting, the tilt angle of the main body, that is, the tilt angle of the suction port 10 can be properly used for throat inhalation and nasal inhalation.

  In FIG. 10, using the tapered bottom surface, the inhaler is freely tilted so that the inlet 10 faces the throat or is directed to the nose. The acceleration sensor 9 built in the inhaler detects the tilt angle of the inhaler body. Based on the detection angle, it is detected whether the throat inhalation or the nasal inhalation is installed. Based on the detection result, the power supplied to the heater 3 is switched, and the spray amount can be switched. Note that the number of bottom surfaces with different inclination angles may be three or more, and in that case, it is possible to switch the spray amount to other three or more stages with a large or small spray amount.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is indicated not by the above description but by the scope of the utility model registration request, and is intended to include all modifications within the meaning and scope equivalent to the scope of the utility model registration request.

  2 boiler tank, 3 heater, 4 water supply cup, 4a water absorption tube, 5 ejection nozzle part, 6 heating chamber, 8 substrate, 9 acceleration sensor, 10 suction port, 12 power cord, 30 heater part, 40 power supply part, 50 CPU, 60 display unit, 70 angle detection unit, 80 operation unit.

Claims (12)

An atomizing device,
An atomizing section for changing the contained liquid into a mist,
A heater arranged in association with the atomizing section;
An angle detection sensor for detecting an inclination angle of a predetermined portion of the atomizing device;
A heater control unit for controlling the power of the heater,
An atomization device that switches an operation state of the atomization device based on a comparison result between a tilt angle detected by the angle detection sensor and a predetermined angle.   The atomizer according to claim 1, wherein the heater control unit controls an energization amount to the heater based on the comparison result.   The atomization device according to claim 1 or 2, wherein an operation state of the atomization device is switched based on a comparison result between an inclination angle detected by the angle detection sensor when the power is turned on and a predetermined angle.   The atomization device according to any one of claims 1 to 3, wherein the angle detection sensor is an acceleration sensor.   The atomization device according to claim 4, wherein the operation state of the atomization device is switched based on a comparison result between the acceleration detected by the acceleration sensor and a predetermined acceleration.   The operation state of the atomizing device is switched when it is detected that a state in which the amount of change in acceleration detected by the acceleration sensor is larger than a predetermined value continues for a predetermined time or more. Atomization device. The predetermined portion is a main body portion,
The atomization device according to any one of claims 4 to 6, wherein the acceleration sensor is installed at a portion where an inclination angle changes when an external force that moves the main body is applied. A power switch that is operated to rotate about the rotation axis;
The predetermined portion is the rotating shaft,
The atomization apparatus according to claim 4, wherein the acceleration sensor detects an inclination angle due to rotation of the rotation shaft. In addition, it has a spray port that can change the tilt angle,
The predetermined portion is the spray port,
The atomization apparatus according to claim 4, wherein the acceleration sensor detects an inclination angle of the spray port. The bottom surface of the main body of the atomizer has a plurality of surfaces with different inclination angles,
The predetermined portion is the bottom surface,
The atomization device according to claim 9, wherein the main body can be installed for each of the plurality of surfaces with the surface as a bottom surface.   The atomization apparatus in any one of Claim 1 to 10 which alert | reports the change of the said operation state of the said atomization apparatus.   The atomization apparatus in any one of Claim 1 to 11 which is the inhaler of the said atomization apparatus.

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