JP2007307560A - Liquid atomizing apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquid atomizing apparatus for stabilizing atomization and for achieving such operation inexpensively by keeping constant the liquid amount to be supplied to an atomizing. <P>SOLUTION: A fixed amount of a chemical liquid in a primary liquid storage part (10) in which the chemical liquid to be atomized is stored is filled in a secondary liquid storage part (16) through a liquid supply path (18). When sliding a liquid supply button (40) to the left, an operating rod (42) pushes a piston (20) and turns on a power switch (46). When the piston (20) moves to the left, the liquid in the secondary storage part (16) is pushed and then, a value 22 is moved to the left to open a liquid supply path (24). Thereby, the fixed amount of the liquid in the secondary storage part (16) is supplied to the atomizing part which is composed of a horn vibrator (30) and a mesh member (32) through the liquid supply path (24) and a guide groove (26) to perform atomization. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a liquid atomizing apparatus including a liquid feeding mechanism that stably supplies liquid to an atomizing unit by a certain amount.

  For example, a conventional portable ultrasonic liquid atomizing device generally has a liquid storage part for storing a liquid (chemical liquid), and a vibration source (for example, an ultrasonic horn vibrator) in which the liquid in the liquid storage part is supplied to the tip part. And a mesh member having a large number of fine holes arranged in contact with the end face of the tip of the vibration source, and atomizes the liquid in the liquid storage part by the vibration action of the vibration source and the mesh member. .

  That is, the liquid in the liquid storage part enters the gap between the mesh member and the end face of the tip of the vibration source, and the liquid is absorbed by the mesh member by the ultrasonic vibration of the vibration source and the end face of the tip of the vibration source. It is discharged as fine droplets from the fine holes.

  By the way, in order to perform the atomization operation stably, it is necessary to stably supply a certain amount of liquid from the liquid storage unit to the atomization unit. However, in actuality, the degree of tilt when using the device, external vibration, the remaining amount of liquid in the liquid storage unit, etc. affect the supply amount to the atomization unit and the atomization becomes unstable. There are many cases. Such atomization instability is not preferable for a chemical solution suction treatment in which a high concentration of a chemical solution is inhaled at a time, and the quantitative spray is not stable.

  The present invention has been made paying attention to such problems. One object of the present invention is to provide a liquid atomizing apparatus that stabilizes the amount of atomization for each time while keeping the amount of liquid fed to the atomizing section constant and realizes it at low cost.

  Another object of the present invention is to reduce useless power consumption and to shorten the driving time of the vibration means in a no-load state, thereby extending the life of the vibration means.

  Still another object of the present invention is to reduce a loss of inhalation of a medicine by a user.

  In order to achieve the above object, a liquid atomizing apparatus according to one aspect of the present invention includes a primary liquid storage unit that stores a liquid to be atomized, and an atomization unit that atomizes the liquid in the primary liquid storage unit. And a secondary liquid storage part for measuring the amount of liquid sent between the primary liquid storage part and the atomization part and sending the liquid of the primary liquid storage part to the atomization part, and the liquid in the primary liquid storage part A primary liquid feeding part that is sent to the liquid storage part, a secondary liquid feeding part that sends the measured liquid of the secondary liquid storage part to the atomization part, and an operation part that operates the secondary liquid feeding part. Features.

  In this atomization device, the liquid in the primary liquid storage part is not sent to the atomization part as it is, but is once sent to the secondary liquid storage part between the primary liquid storage part and the atomization part. The liquid storage unit measures the amount of liquid fed per time to the atomization unit, and sends the measured liquid to the atomization unit. Therefore, a constant amount of liquid is always supplied to the atomizing unit regardless of the degree of inclination when the apparatus is used, vibration from the outside, the remaining amount of liquid in the liquid storage unit, etc., and the atomization is stabilized. .

  In the liquid atomization apparatus of the present invention, if the primary liquid feeding unit and the secondary liquid feeding unit respectively feed liquid in conjunction with the operation of the operation unit, the liquid in the primary liquid storage unit can be obtained by one operation of the operation unit. Is sent to the secondary liquid storage part, and the liquid in the secondary liquid storage part is sent to the atomization part, and the liquid feeding, metering, and liquid feeding operations can be performed smoothly, and the convenience is enhanced.

  In addition, if the atomizing unit starts the atomizing operation of the liquid simultaneously with the operation of the operation unit, the operation unit also serves as an atomization start switch. The timing of the liquid and the atomization operation is improved.

  In this case, if the atomizing unit starts the atomizing operation before the liquid is supplied to the atomizing unit, the liquid is immediately atomized when the liquid is supplied to the atomizing unit. The rising of the atomizing operation becomes agile and the atomizing operation is stabilized.

  Further, when the liquid feeding operation to the atomization unit by the operation of the operation unit is completed, if the liquid supply from the primary liquid storage unit to the secondary liquid storage unit is performed, the operation of the next operation unit is performed. The liquid feeding to the atomization part can be performed smoothly.

  On the other hand, if the secondary liquid storage part is in a sealed state except when it sends liquid to the atomization part, the liquid in the secondary liquid storage part does not contact the outside air and is sucked into the human body (chemical liquid) Can be kept clean.

  On the other hand, the primary liquid storage unit, the atomization unit, the secondary liquid storage unit, the primary liquid supply unit, and the secondary liquid supply unit are integrally configured as a liquid supply unit, and the primary liquid storage unit is attached to and detached from the liquid supply unit. If possible, cleaning of the primary liquid storage part for storing the liquid becomes easy.

  A liquid atomization apparatus according to another aspect of the present invention is supplied from a liquid storage chamber for storing a liquid, a measuring chamber into which a predetermined amount of liquid is sent from the liquid storage chamber through a liquid supply hole, and a liquid supply hole from the measurement chamber. An atomizing unit for atomizing the liquid, a piston for supplying the liquid to the atomizing unit through the liquid supply hole by opening and closing the liquid feeding hole and pressing the liquid in the measuring chamber, and driving the piston at a constant speed A piston drive unit.

  By providing the piston driving section as described above, the piston can be moved at a constant speed, and a liquid such as a chemical solution can be pressed with a substantially uniform force. Thereby, the speed of the liquid supplied to the atomization part can be made substantially constant, and the liquid can be adhered to the atomization part as initially aimed.

  The liquid atomizing device defines one end of the measuring chamber, is supported by an elastic member, moves by pressing the liquid by a piston, opens a liquid supply hole, and supplies a liquid to the atomizing unit It is preferable to provide.

  The atomizing unit includes a mesh member and a vibrator such as an ultrasonic vibrator, and is supplied with liquid from the measuring chamber. In this case, a predetermined amount of liquid can be supplied to a predetermined position on the mesh member by including the piston drive unit of the present invention.

  The piston drive unit includes at least one element selected from the group consisting of an elastic means such as a spring for applying an elastic force to the piston, a motor, and a solenoid. That is, the piston drive unit of the present invention drives the piston with a substantially constant force such as an elastic force by a spring or the like, or a force obtained by using an electromagnetic force such as a motor or a solenoid.

  The liquid atomizing device includes a locking unit for fixing the piston at a position where the liquid feeding hole is opened and the liquid can be fed from the liquid storage chamber to the measuring chamber, and the fixed state by the locking unit is released and the piston is released. You may provide the release switch for operating a drive part and driving a piston. As a result, the piston can be driven simply by turning on the release switch, and a certain amount of liquid can be supplied to the atomizing section with a simple operation.

  In addition, the liquid atomizing device includes: a lock release detecting means for detecting that the fixed state by the lock means is released by the release switch; and the piston fixed state by the lock means is released by the lock release detecting means. And an atomizing operation starting means for starting the liquid atomizing operation after it is detected that the operation has been performed. In this case, the atomizing portion can be automatically operated after releasing the locked state of the piston. For example, the liquid atomization operation can be started after a predetermined time has elapsed after the piston is unlocked. Thereby, the atomization of the liquid can be started simultaneously with or immediately after the liquid is supplied to the atomization unit. The atomization operation starting means of the present invention is means for starting an operation capable of atomizing a liquid, and when the atomization of the liquid actually starts by starting the atomization operation. And the atomization of the liquid may start after a predetermined time.

  The piston drive unit may include a first rod, a second rod that presses the piston, and a connection member that connects the first and second rods. And the moving direction of a 1st rod and the moving direction of a 2nd rod are varied. Thereby, it is not necessary to arrange a piston drive part and a piston on 1 straight line, and the length of the liquid atomization apparatus in the moving direction of a piston can be reduced. In particular, by arranging the first rod, the piston and the second rod in parallel, and driving the first and second rods in opposite directions, the liquid atomizing device can be made compact.

  The liquid atomizing device includes a housing having a liquid storage chamber therein and a cylinder having a measuring chamber therein and receiving a piston. In this case, it is preferable that the cylinder and the piston driving unit are detachably attached to the housing.

  In the liquid atomizing apparatus, the piston drive unit has a spiral spring as an elastic means for applying an elastic force to the piston. Thereby, by reducing the spring constant of the spiral spring, it is possible to easily realize atomization with a constant amount, to prevent the chemical liquid from being scattered in the atomizing portion, and to reduce the size of the apparatus. .

  A liquid atomization apparatus according to another aspect of the present invention is supplied from a liquid storage chamber for storing a liquid, a measuring chamber into which a predetermined amount of liquid is sent from the liquid storage chamber through a liquid supply hole, and a liquid supply hole from the measurement chamber. An atomizing section for atomizing the liquid, a valve for defining one end of the measurement chamber and opening and closing the liquid supply hole supported by the elastic member, and a valve for opening and closing the liquid supply hole and pressing the liquid in the measurement chamber The piston for supplying the liquid to the atomizing part through the liquid supply hole, the piston driving part for driving the piston, and the liquid supply to the atomizing part are started. A liquid supply detection means for detecting the liquid in advance, and an atomization operation start means for starting the liquid atomization operation when the liquid supply detection means detects that the liquid supply to the atomization unit is started With.

  By providing the liquid supply detection means and the atomization operation start means in this manner, the liquid atomization operation can be automatically started at a desired time before and after the liquid supply to the atomization unit is started. it can.

  The liquid supply detection means includes a position sensor for detecting the position of at least one of the piston and the valve. In this case, the atomization operation start means starts the liquid atomization operation when the position sensor detects that at least one of the piston and the valve has reached a predetermined position.

  By providing the position sensor and the atomization operation start means, the liquid atomization operation can be automatically started when at least one of the piston and the valve reaches a predetermined position. At this time, if the position sensor detects the liquid supply start time to the atomization unit, the liquid atomization operation can be started immediately after or before the liquid is supplied to the atomization unit. .

  The piston drive unit includes a motor and a solenoid. In this case, the atomization operation start means starts the liquid atomization operation after the drive signal of the motor or solenoid is input.

  The atomizing unit includes a mesh member and a vibrator such as an ultrasonic vibrator, and liquid is supplied from the measuring chamber, and the atomizing operation start means includes vibrator driving means for driving the vibrator.

  In the liquid atomizing apparatus, the piston drive unit has a spiral spring as an elastic means for applying an elastic force to the piston. Thereby, by reducing the spring constant of the spiral spring, it is possible to easily realize atomization with a constant amount, to prevent the chemical liquid from being scattered in the atomizing portion, and to reduce the size of the apparatus. .

  A liquid atomization apparatus according to still another aspect of the present invention includes a liquid storage chamber for storing a liquid, a measurement chamber into which a predetermined amount of liquid is sent from the storage chamber through a liquid supply hole, and a supply from the measurement chamber through a liquid supply hole. An atomizing unit including a mesh member and an oscillator for atomizing the collected liquid, and supplying the liquid to the atomizing unit through the liquid supply hole by opening and closing the liquid feeding hole and pressing the liquid in the measuring chamber A piston, a piston driving unit for driving the piston, an impedance detection means for detecting the impedance of the vibrator, and the impedance of the vibrator in response to the impedance detected by the impedance detection means being less than a predetermined value. Vibrator stopping means for stopping the vibration.

  The impedance of the vibrator differs depending on whether or not the liquid is present on the mesh member. Therefore, by detecting the impedance of the vibrator with the above impedance detection means, it is possible to detect whether or not liquid is present on the mesh member. Here, by providing the vibrator stopping means, the vibration of the vibrator can be stopped when the impedance of the vibrator becomes a predetermined value or less. That is, the vibration of the vibrator can be stopped in response to the absence of the liquid to be atomized on the mesh member.

  In the liquid atomizing apparatus, the piston drive unit has a spiral spring as an elastic means for applying an elastic force to the piston. Thereby, by reducing the spring constant of the spiral spring, it is possible to easily realize atomization with a constant amount, to prevent the chemical liquid from being scattered in the atomizing portion, and to reduce the size of the apparatus. .

  A liquid atomization apparatus according to still another aspect of the present invention includes a liquid storage chamber for storing a liquid, a measurement chamber into which a predetermined amount of liquid is sent from the storage chamber through a liquid supply hole, and a supply from the measurement chamber through a liquid supply hole. An atomizing unit for atomizing the liquid, a piston for supplying liquid to the atomizing unit through the liquid supply hole by opening and closing the liquid feeding hole and pressing the liquid in the measuring chamber, and for driving the piston A piston drive unit, an intake port for the user to inhale the liquid atomized by the atomization unit, and an intake air detection means for detecting that the user has inhaled from the intake port.

  By providing the intake air detection means in this manner, it is possible to detect that the user has inhaled from the intake port. Accordingly, the atomization of the liquid or the supply of the liquid to the atomizing unit can be performed according to the user inhaling from the suction port, and the atomization timing of the atomized liquid and the user's intake The deviation from the timing can be reduced.

  The liquid atomization device may include an atomization operation start unit that starts an atomization operation of the liquid in the atomization unit in response to the detection of the intake air by the user by the intake air detection unit. There may be provided liquid supply means for supplying liquid to the atomizing section in response to detection of the intake air by the user by the detection means.

  In the liquid atomizing apparatus, the piston drive unit has a spiral spring as an elastic means for applying an elastic force to the piston. Thereby, by reducing the spring constant of the spiral spring, it is possible to easily realize atomization with a constant amount, to prevent the chemical liquid from being scattered in the atomizing portion, and to reduce the size of the apparatus. .

Hereinafter, the present invention will be described in more detail with reference to embodiments.
(Embodiment 1)
An external perspective view of the liquid atomizing apparatus according to Embodiment 1 is shown in FIG. The liquid atomizing device includes a main body 1 having a battery storage 5 (see FIG. 3), an electric circuit, and the like, and a liquid supply unit 2 detachably attached to the main body 1. .

  In FIG. 2 showing a partially broken perspective view of the liquid supply unit 2 and FIG. 3 showing a longitudinal sectional view of the inside of the apparatus, a primary liquid storage part 10 for storing a liquid (chemical liquid) to be atomized is stored in the apparatus. The movable member 12 that can be displaced in the vertical direction is liquid-tightly attached to the bottom of the primary liquid storage unit 10, and the movable member 12 also serves as the bottom wall of the primary liquid storage unit 10. Pressure is applied to the movable member 12 by a pressing member 14 disposed on the lower side. Accordingly, pressure is applied to the chemical solution in the primary liquid storage unit 10. Here, a primary liquid feeding part is comprised by the movable member 12, the press member 14, etc. FIG. Moreover, the components, the movable member 12, the pressing member 14 and the like constituting the primary liquid storage unit 10 can be attached to and detached from the liquid supply unit 2 and can be easily cleaned.

  A secondary liquid storage unit 16 for measuring the amount of liquid sent to the atomization unit is provided above the primary liquid storage unit 10, and the secondary liquid storage unit 16 communicates with the primary liquid storage unit 10 through a liquid supply path 18. is doing. The secondary liquid storage section 16 is formed of a columnar space (cylinder) extending in the horizontal direction. The piston 20 is movably disposed on one side of the columnar space, and the valve 22 is displaceably disposed on the other side. ing. A coil spring 56 is inserted into the piston 20, and the piston 20 is biased by the coil spring 56 in the right direction in the drawing. Although not shown in FIG. 3, the valve 22 is urged to the right of the drawing by a coil spring 52 (see FIGS. 4 and 10), and one end of the coil spring 52 is a stopper attached to the end of a cylindrical space. 54 is engaged. Here, the secondary liquid feeding section is constituted by the piston 20, the valve 22, the liquid feeding path 24, the coil springs 52 and 56, and the like.

  The secondary liquid storage unit 16 communicates with the liquid feeding path 24, and the liquid feeding path 24 has a discharge port 24 a, and the discharge port 24 a communicates with the guide groove 26. The guide groove 26 is provided with a buffer portion 28 for temporarily storing a part of the sent chemical solution in the upward direction. Here, the guide groove 26 and the buffer part 28 are provided as separate parts from the part provided with the secondary liquid storage part 16 and the liquid feeding path 24, but they may be integrally formed with the same part.

  The secondary liquid storage unit 16 communicates with the liquid supply path 24 when liquid is supplied, but is in a sealed state when the liquid is not supplied. That is, when the chemical liquid is supplied from the primary liquid storage unit 10, the secondary liquid storage unit 16 communicates with the liquid supply path 18, but the liquid supply path 18 is filled with the chemical liquid. The chemical liquid in the portion 16 does not come into contact with air, and the chemical liquid is kept clean.

  On the other hand, the horn vibrator 30 is disposed close to the primary liquid storage part 10, and the tip part thereof faces the guide groove 26. A mesh member 32 having a large number of fine holes is disposed in contact with the end face of the horn vibrator 30, and the mesh member 32 is pressed against the end face of the horn vibrator 30 by a coil spring 34 with an appropriate force. Yes. The atomizing unit is composed of a horn vibrator 30 and a mesh member 32.

  With this configuration, the chemical liquid in the primary liquid storage unit 10 is supplied to the gap between the horn vibrator 30 and the mesh member 32 via the liquid supply path 18, the secondary liquid storage part 16, the liquid supply path 24, and the guide groove 26. Is done.

  On the other hand, a slide-type liquid supply button 40 is provided as an operation unit at the upper part of the main body 1, and the liquid supply button 40 is a horizontal operation rod that operates the piston 20 disposed in the secondary liquid storage unit 16. 42 and an operation shaft 44 for operating a lever 46a of a power switch 46 disposed below the liquid supply button 40. When supplying the chemical liquid to the atomizing section, the liquid supply button 40 is slid to the left in FIG. Then, not only the operating rod 42 of the liquid supply button 40 pushes the piston 20, but also the operating shaft 44 pushes down the lever 46a of the power switch 46, and the power switch 46 is turned on. When the hand is released from the liquid supply button 40, the liquid supply button 40 returns to the state of FIG. 3 as the piston 20 moves to the right side by the coil spring 56, and the power switch 46 is turned OFF.

  The ON timing of the power switch 46 is set earlier than the chemical solution in the secondary liquid storage unit 16 is sent to the atomizing unit, and the horn vibrator 30 is activated before the liquid is supplied to the atomizing unit. The atomization starts simultaneously with the liquid supply to the atomization section. Thereby, the rising of the atomization operation becomes quick and the atomization operation is stabilized.

  Since the liquid supply to the atomizing unit is performed by the operation of the operation unit, the atomization operation is started simultaneously with the operation of the operation unit. Here, the atomizing operation means not only the step of atomizing the chemical solution but also the step of supplying the liquid to the atomizing unit as described below.

  The chemical atomization operation of the liquid atomizer will be described with reference to schematic diagrams of the liquid feeding mechanism shown in FIGS. However, the same elements as those described above are denoted by the same reference numerals. First, in FIG. 4, a cylinder 50 (corresponding to a cylindrical space forming the secondary liquid storage part 16) communicates with the primary liquid storage part 10 (not shown in FIGS. 4 to 9) through the liquid supply path 18. At the same time, it communicates with the guide groove 26 through the liquid feeding path 24.

  On one side of the cylinder 50, a piston 20 having a valve function for opening and closing the liquid feeding path 18 is movably disposed, and on the other side, a valve 22 for opening and closing the liquid feeding path 24 is movably disposed. ing. The piston 20 is urged downward by the coil spring 56 and the valve 22 is also urged downward by the coil spring 52. One end of the coil spring 52 is attached to the valve 22, and the other end is engaged with a stopper 54 attached to the end of the cylinder 50. Inside the cylinder 50, the space between the piston 20 and the valve 22 is a secondary liquid storage part 16, and a chemical solution is supplied from the primary liquid storage part 10. The capacity of the secondary liquid storage unit 16 is obtained by [(φ / 2) 2 π · L] from the inner diameter φ and the length L of the cylinder 50 as shown in FIG. The required amount is set.

  According to the liquid feeding mechanism configured as described above, in the state of FIG. 4 in which the piston 20 opens the liquid feeding path 18 and the valve 22 seals the liquid feeding path 24, the primary liquid storage unit 10 has an arbitrary value. Since the pressure is applied, the chemical liquid in the primary liquid storage section 10 flows into the secondary liquid storage section 16 in the cylinder 50 through the liquid supply path 18 and the secondary liquid storage section 16 is filled with a certain amount of chemical liquid. .

  When the liquid supply button 40 is slid in the state of FIG. 4, the piston 20 is pushed and moves in the direction of the arrow (upward in the drawing), and the pressure from the piston 20 is applied to the chemical liquid filled in the secondary liquid storage unit 16. And the valve 22 starts to move upward. When the piston 20 further moves upward, the liquid supply path 18 is eventually blocked by the piston 20, and the primary liquid storage part 10 and the secondary liquid storage part 16 are shut off (see FIG. 5).

  When the piston 20 moves further upward, the valve 22 also moves upward, so that the liquid feeding path 24 is opened, and the chemical solution in the secondary liquid storage section 16 passes through the liquid feeding path 24 and passes through the discharge port 24a to the guide groove. 26, and is supplied to the atomization part (refer FIG. 6).

  The valve 22 is in a fixed state at an arbitrary position (here, a position at which the liquid supply path 24 is completely opened) by the balance between the pressing force of the piston 20 and the discharge pressure of the chemical liquid from the discharge port 24a. Therefore, the piston 20 moves until it comes into contact with the fixed valve 22, further moves upward together with the valve 22, and finally moves until the valve 22 hits the stopper 54 (see FIG. 7). If it will be in this state, the chemical | medical solution of the secondary liquid storage part 16 will be discharged completely from the discharge outlet 24a.

  Here, when the liquid supply button 40 is released, as the piston 20 is pulled back by the coil spring 56, the liquid supply button 40 returns to the original position, and the valve 22 also returns to the original position by the biasing force of the coil spring 52. At this time, as shown in FIG. 8, the piston 20 and the valve 22 are moved downward as a unit at the beginning, but when the valve 22 returns to a fixed position where the liquid supply path 24 is closed, thereafter, as shown in FIG. 9. Only the piston 20 moves downward.

  In this state, when the piston 20 moves further downward, the secondary liquid storage unit 16 is in a negative pressure state. When the piston 20 moves until the liquid supply path 18 is opened, the chemical solution in the primary liquid storage unit 10 is brought into the secondary liquid storage unit 16 by the negative pressure of the secondary liquid storage unit 16 and the pressure applied to the chemical solution from the primary liquid storage unit 10. (See FIG. 4), and enters a standby state until the next liquid feeding operation. When the liquid supply button 40 is slid again, the above operation is repeated, and a certain amount of chemical liquid is supplied to the atomizing unit.

  Although the liquid feeding mechanism is actually arranged in the horizontal direction in the apparatus shown in FIG. 3, more specific operation will be described with reference to FIGS. 10 to 14. First, in FIG. 10 corresponding to the state of FIG. 4, the chemical solution is filled into the secondary liquid storage unit 16 by a certain amount through the liquid supply path 18 by the pressure applied to the primary liquid storage unit 10. At this time, the lever 46a of the power switch 46 is not operated by the operation shaft 44 of the liquid supply button 40, and the power switch 46 is OFF (see FIG. 15).

  In FIG. 11 corresponding to the state of FIG. 5, when the liquid supply button 40 is slid, the piston 20 is pushed by the operating rod 42 and moves in the direction of the arrow, and accordingly the valve 22 also moves in the direction of the arrow. The path 18 is closed with a piston 20. At this time, as shown in FIG. 16, since the liquid supply button 40 moves to the left side, the lever 46a of the power switch 46 is pushed down by the operation shaft 44, the power switch 46 is turned on, and the supply to the atomizing unit is performed. The horn vibrator 30 starts to operate before the liquid.

  In FIG. 12 corresponding to the state of FIG. 6, the liquid supply path 24 is opened by the movement of the valve 22, the chemical liquid in the secondary liquid storage section 16 flows into the liquid supply path 24, and further through the guide groove 26 to the atomization section. Supplied.

  In FIG. 13 corresponding to the state of FIG. 7, the piston 20 moves until it contacts the valve 22, and a certain amount of the chemical solution in the secondary liquid storage part 16 is completely sent from the liquid supply path 24 to the atomization part. However, the chemical liquid is not all supplied to the atomization section at once, but a part of the chemical liquid is temporarily stored in the buffer section 28 attached to the guide groove 26 as shown in FIG. An appropriate amount of chemical solution is supplied little by little.

  In FIG. 14 corresponding to the state of FIG. 9, the piston 20 is returned by the coil spring 56, and the valve 22 is also returned to the home position by the coil spring 52, and the liquid supply path 24 is closed by the valve 22. Further, when the piston 20 is pulled back, the secondary liquid storage unit 16 is in a negative pressure state, and when the piston 20 opens the liquid feeding path 18, the state returns to the state of FIG. 10 and the chemical solution in the primary liquid storage unit 10 is secondary. The liquid storage unit 16 is filled and preparation for the next liquid feeding operation is performed.

  As described above, according to the present embodiment, the liquid in the primary liquid storage unit 10 is not sent to the atomization unit as it is, but the secondary storage between the primary liquid storage unit 10 and the atomization unit. The liquid is once sent to the liquid part 16, and the secondary liquid storage part 16 measures the amount of liquid delivered to the atomization part once, and the measured liquid is sent to the atomization part. Regardless of the degree of inclination, vibration from the outside, the remaining amount of liquid in the liquid storage unit, etc., a constant amount of liquid is always supplied to the atomization unit, and the atomization is stabilized. In addition, it can be realized with an inexpensive configuration.

(Embodiment 2)
As shown in FIGS. 18 and 19, the liquid atomizing apparatus includes a housing 101, a cylinder 102, a piston driving unit 126, and an atomizing unit 127.

  As shown in FIG. 18, a battery 108 serving as a power supply unit and an atomization unit driving circuit board 107 for driving the atomization unit are provided in the housing 101. As shown in FIG. 19, a recess is provided in the side wall of the housing 101, and an ampoule 104 containing a liquid such as a chemical solution is attached to the recess.

  As shown in FIG. 18, the ampoule 104 includes a liquid storage chamber 105, a piston 106, and a liquid feed passage 104a. A chemical solution (liquid) is stored in the liquid storage chamber 105, and the chemical solution is sent from the liquid storage chamber 105 to the metering chamber 109 described later through the liquid supply passage 104 a and the liquid supply hole 111.

  The cylinder 102 is detachably attached to the housing 101 and receives the piston 112. The cylinder 102 includes a valve cover 103, a measuring chamber 109, a discharge valve 113, a valve spring 118, and a liquid supply hole 110.

  The piston 112 opens and closes the liquid supply hole 111 to supply the chemical liquid from the liquid storage chamber 105 into the measuring chamber 109 and press the chemical liquid in the measuring chamber 109 to the atomizing unit 127 through the liquid supply hole 110. Supply.

  A measuring chamber 109 shown in FIG. 18 is a place for measuring a certain amount of chemical liquid. One wall surface of the measuring chamber 109 is constituted by an end surface of the piston 112, and the other wall surface of the measuring chamber 109 is the discharge valve 113. Consists of end faces.

  The discharge valve 113 is elastically supported by the cylinder 102 via an elastic member such as a valve spring 118 and is movable in the left and right (horizontal) direction in FIG. By pressing the chemical solution in the measuring chamber 109 with the piston 112, pressure is applied to the discharge valve 113, the valve spring 118 is compressed and deformed, and the discharge valve 113 moves to the left in FIG. Thereby, the liquid supply hole 110 can be opened.

  The liquid supply hole 110 opens into the measuring chamber 109, communicates with a liquid supply passage (not shown), and feeds the chemical solution in the measurement chamber 109 into the atomizing unit 127 through the liquid supply passage. The medicinal solution sent to the atomization unit 127 is atomized and then sprayed and inhaled by the patient.

  The piston driving unit 126 drives the piston 112 at a constant speed and is detachably attached to the housing 101. In the present embodiment, the piston drive unit 126 includes a rod 114, a lever 115, a piston spring 116, a release button 117, a rod case 123, and a screw 124.

  The rod 114 extends in the horizontal direction, is connected to the piston 112, and can push the piston 112 to the left in FIG. 18 via the rod 114. The rod 114 has a flange portion 114c, and one end of the piston spring 116 is attached to or brought into contact with the flange portion 114c.

  The piston spring 116 applies a certain elastic force to the piston 112 via the rod 114, and moves the piston 112 in the horizontal direction at a constant speed. Both the piston spring 116 and the rod 114 are accommodated in the rod case 123, and the other end of the piston spring 116 is supported on the wall surface of the rod case 123. The rod case 123 is fixed to the housing 101 with screws 124.

  The lever 115 is attached so as to cover one end side of the rod case 123, and is used when the piston 112 and the rod 114 are pulled back to a predetermined position against the elastic force of the piston spring 116.

  The lever 115 has a pair of engaging claws 115a protruding from the side wall and a protruding portion (operation portion) 115b protruding upward. One end of the piston 112 is received between the engaging claws 115a, and the engaging claw 115a and the flange portion 112a provided at one end of the piston 112 are engaged.

  When the protrusion 115b is pressed by hand and the lever 115 is slid to the right in FIG. 18, the rod 114 is also moved to the right in FIG.

  The release button 117 can be pressed in the vertical direction and has a lock claw 125. The lock claw 125 engages with the flange portion 114c of the rod 114 and restricts the movement of the rod 114 in the left direction. Therefore, when the projecting portion 115b is pressed by hand and the piston 112 and the rod 114 are moved to the right side, a position where the liquid feeding hole 111 is opened and the chemical solution can be fed from the liquid storage chamber 105 into the measuring chamber 109. Thus, the piston 112 and the rod 114 can be locked. At this time, the piston spring 116 is compressed, and an elastic force due to the compression is applied to the rod 114.

  To release the locked state of the piston 112 and the rod 114, the release button 117 is pushed downward. As a result, the engagement state between the lock claw 125 and the flange portion 114c of the rod 114 is released, and at the same time, the piston driving portion 126 is operated, and the piston 112 and the rod 114 are moved to the left side by the elastic force of the compressed piston spring 116. Move to.

  Thus, by providing the lock claw 125 as the locking means and the release button 117 as the release switch, the piston 112 can be driven simply by pressing the release button 117, and the atomization unit 127 can be operated with a simple operation. A certain amount of liquid can be supplied to the.

  The liquid atomizing device preferably includes an unlock detection unit for detecting that the lock claw 125 is released by the release button 117, and the lock claw 125 by the lock claw 125. An atomization operation start unit that starts the atomization operation of the chemical solution after it is detected that the fixed state is released.

  In this case, the atomization unit 127 can be automatically operated after releasing the locked state of the piston 112. For example, the atomizing operation of the chemical solution is performed after the locked state of the piston 112 is released and a predetermined time has elapsed. Can start. Thereby, the atomization of the chemical liquid can be started at the same time or immediately after the chemical liquid is supplied to the atomizing unit 127.

  As shown in FIG. 19, the atomizing unit 127 includes a horn vibrator (ultrasonic vibrator) 119, a mesh member 120, a mesh member holder 121, and a mesh member cap 122.

  The mesh member 120 has a large number of fine holes and is placed on the end face of the tip of the horn vibrator 119. At this time, the mesh member 120 is pressed with an appropriate force against the end face of the horn vibrator 119 by the mesh member holder 121 having a coil spring built therein. A mesh member cap 122 is attached on the mesh member holder 121.

  Next, the operation of the liquid atomizing apparatus according to the second embodiment will be described with reference to FIGS.

  From the initial state shown in FIG. 20, the protrusion 115b of the lever 115 is pushed to the right by hand. Thereby, as shown in FIG. 21, the lever 115 moves to the right side, and accordingly, the piston 112 and the rod 114 also move to the right side. At this time, the piston spring 116 is pressed against the flange portion 114c of the rod 114 and compressed.

  Further, when the piston 112 moves to the right side, the liquid feeding passage 104a and the liquid feeding hole 111 communicate with the measuring chamber 109, and the measuring chamber 109 having a negative pressure is filled with the chemical solution from the liquid storage chamber 105.

  When the lever 115 is moved by a predetermined amount, an extension portion extending from the end of the flange portion 114c of the rod 114 in the longitudinal direction of the rod 114 engages with the lock claw 125 of the release button 117, and the lever 115, piston 112 and rod 114 is locked in place.

  Next, the release button 117 is pushed down. Thereby, the engagement state between the extension portion of the flange portion 114c and the lock claw 125 can be released, and the piston 112 and the rod 114 can be pressed by the elastic force of the compressed piston spring 116. .

  Thus, by pressing the piston 112 and the rod 114 with a substantially constant force such as an elastic force, the piston 112 and the rod 114 can be moved to the left side at a substantially constant speed as shown in FIG. . That is, the chemical liquid in the measuring chamber 109 can be pressed by the piston 112 with a substantially uniform force. As a result, the discharge valve 113 receives pressure from the chemical and moves to the left, and the liquid supply hole 110 is opened.

  And a chemical | medical solution can be supplied to the atomization part 127 through the liquid supply hole 110. FIG. At this time, since the piston 112 is driven at a substantially constant speed, the speed (momentum) of the chemical solution supplied to the atomizing unit 127 can be made substantially constant. That is, it is possible to avoid a situation in which the chemical solution is sent to the atomizing unit 127 with vigorous force or the force of the chemical solution is too weak.

  As a result, the chemical solution can be attached at a desired flow rate at the initial target position in the atomizing unit 127, and the chemical solution can be atomized reliably and efficiently in the atomizing unit 127. The amount of liquid remaining without being atomized can be reduced.

  Thereafter, as shown in FIG. 23, the piston 112 moves to a position where it substantially contacts the discharge valve 113, and a certain amount of the chemical solution in the measuring chamber 109 is all delivered at a desired speed. Thereby, the discharge of the chemical solution from the measuring chamber 109 is completed.

  According to the present embodiment, the piston can be driven at a constant speed as compared with the first embodiment. This will be described below.

  In the first embodiment described above, since the liquid supply button 40 is operated by hand, the force applied to the liquid supply button 40 may vary. If the magnitude | size of the force which pushes the liquid supply button 40 varies, the moving speed of piston 20 will also vary and the speed of the chemical | medical solution sent into the atomization part will also change.

  If the speed of the chemical liquid discharged to the atomizing section is high, the chemical liquid will be scattered in the atomizing section, and if the speed of the chemical liquid discharged to the atomizing section is low, the chemical liquid will not reach the predetermined position of the atomizing section. Therefore, the chemical liquid does not adhere to the atomizing part as initially aimed, and the amount of liquid remaining without being atomized in the atomizing part increases.

  Also, WO00 / 66277 discloses a liquid spraying device having a pushing mechanism for operating a manual operation member to advance a piston in a liquid bottle by a predetermined stroke in order to supply a constant amount of liquid to the spraying chamber with a simple operation. It is disclosed. However, in this case as well, since the piston is driven by manual operation, the chemical liquid does not adhere to the atomizing portion as intended and the amount of liquid remaining without being atomized increases as intended. The problem can arise.

  On the other hand, in this embodiment, since the piston 112 and the rod 114 can be pressed by the elastic force of the piston spring 116, the piston 112 can be driven at a constant speed. Therefore, the above problems can be prevented.

(Embodiment 3)
Next, Embodiment 3 of the present invention will be described with reference to FIGS.

  As shown in FIGS. 24 and 25, in the third embodiment, the configuration of the piston drive unit 126 for driving the piston 112 is mainly different from that in the second embodiment. The other configuration is basically the same as that of the second embodiment.

  As shown in FIGS. 24 and 25, the piston driving unit 126 according to the third embodiment includes rods 114a and 114b, a lever 115, a piston spring 116, a release button 117, an upper lever plate 128, and a lower lever. A plate 129, a lever cover 130, and a screw 134 are provided.

  The rod 114a has a reduced diameter portion and an enlarged diameter portion at one end, and a ring-shaped portion at the other end. Then, the reduced diameter portion is placed on the U-shaped concave portion of the support wall provided on the upper surface of the housing 101. Thereby, the enlarged diameter portion and the support wall can be engaged, and the rod 114 a can be attached to the housing 101.

  A flange portion is provided at the center of the rod 114a, and a piston spring 116 is installed between the flange portion and the support wall. The piston spring 116 can press the flange portion to drive the rod 114a to the right side in FIG.

  The rod 114b has a pin portion protruding upward at one end and a ring-shaped portion at the other end. The pin part is inserted into the ring-shaped part of the piston coupling rod 133. A tubular portion is provided at one end of the piston coupling rod 133, a piston cover 132 is fitted on the tubular portion, and one end of the piston 112 is inserted into the tubular portion via a piston stopper 131.

  The rods 114a and 114b are connected via upper and lower lever plates 128 and 129 which are connecting members. As shown in FIG. 25, the upper and lower lever plates 128 and 129 each have a through hole and a boss portion 129c for receiving a cylindrical portion 101a provided on the upper surface of the housing 101, and are rotatably assembled to the housing 101. .

  The lower lever plate 129 has a pair of pins 129a and 129b on both sides of the boss portion 129c, is connected to the rod 114a via the pin 129a, and is connected to the rod 114b via the pin 129b. More specifically, the rods 114a and 114b can be connected to the lower lever plate 129 by inserting the pins 129a and 129b into the ring-shaped portions of the rods 114a and 114b, respectively.

  As shown in FIGS. 24 and 25, the rods 114a and 114b are arranged substantially in parallel, and the moving direction of the rod 114a is opposite to the moving direction of the rod 114b. Thus, by making the moving directions of the rods 114a and 114b different, it is not necessary to arrange the piston driving unit 126 and the piston 112 on one straight line, and the length of the liquid atomizing device in the moving direction of the piston 112 is reduced. be able to. Further, by arranging the rods 114a and 114b substantially in parallel, the liquid atomizing device can be reduced in the width direction, and the liquid atomizing device can be made compact.

  As shown in FIG. 25, the lever 115 has a through hole that receives the cylindrical portion 101a at the center and a long hole that receives the pin 129b. The lever 115 has a flat plate shape and has a protruding portion (operation portion) 115b protruding in the radial direction. The lever 115 can be rotated by pressing the protruding portion by hand.

  The lever cover 130 is placed on the lever 115, and a screw 134 is screwed onto the cylindrical portion 101 a from above the lever cover 130. Thereby, the lever cover 130, the lever 115, the upper and lower lever plates 128 and 129 can be attached to the housing 101.

  The release button 117 is elastically supported by a release spring 135 housed in a spring case 136 provided on the side surface of the housing 101. The release button 117 has a lock claw 125, and the lock claw 125 is inserted into a through hole provided in the lower lever plate 129. Thereby, the lower lever plate 129 is locked.

  In order to release the locked state, the operation part of the release button 117 is pushed by hand and pushed downward. As a result, the lock claw 125 moves downward and comes out of the through hole of the lower lever plate 129, and the locked state of the lower lever plate 129 is released.

  Next, the operation of the liquid atomizing apparatus in the present embodiment will be described with reference to FIGS.

  26, the protrusion 115b of the lever 115 is rotated counterclockwise (counterclockwise) by hand, and the lever 115 is rotated by a predetermined angle. Thereby, as shown in FIG. 27, the upper and lower lever plates 128 and 129 rotate, the rod 114b moves to the right side, and the piston 112 also moves to the right side. At this time, the rod 114a moves to the left, and the piston spring 116 is pressed and compressed by the flange portion of the rod 114a.

  When the piston 112 moves to the right by a predetermined amount or more, the liquid feeding hole 111 is opened, and the liquid chemical is fed from the liquid storage chamber 105 into the measuring chamber 109 as in the second embodiment. At this time, the liquid supply hole is closed by the discharge valve 113.

  When the lever 115 is rotated by a predetermined amount, the lock claw 125 is inserted into the through hole provided in the lower lever plate 129 as shown in FIG. 27, and the piston 112 and the like can be locked at a predetermined position.

  Next, by depressing the release button 117, the lock claw 125 comes out of the through hole provided in the lower lever plate 129 as shown in FIG. 28, and the engagement state between the lower lever plate 129 and the lock claw 125 is released. Can do. Thereby, the rod 114a, the rod 114b, the upper and lower lever plates 128 and 129 are driven by the elastic force of the compressed piston spring 116, and the piston 112 can be moved to the left side through these.

  By pressing the piston 112 with the elastic force of the spring in this manner, the chemical liquid in the measuring chamber 109 can be pressed with the piston 112 with a substantially uniform force, as in the case of the second embodiment.

  Accordingly, the discharge valve 113 receives pressure from the chemical liquid and moves to the left side to open the liquid supply hole 110, and the chemical liquid can be supplied to the atomizing unit 127 through the liquid supply hole 110. Also in the case of the present embodiment, since the piston 112 can be driven at a substantially constant speed, the same effect as that of the second embodiment can be obtained.

  Thereafter, as shown in FIG. 29, the piston 112 moves to a position where it substantially contacts the discharge valve 113, and a certain amount of the chemical in the measuring chamber 109 is all supplied to the atomizing section 127 at a desired speed. It becomes. Thereby, the discharge of the chemical solution from the measuring chamber 109 is completed.

  In the present embodiment, as in the second embodiment, the piston 112 can be pressed by the elastic force of the piston spring 116, so that the piston 112 can be driven at a constant speed.

(Embodiment 4)
Next, Embodiment 4 of the present invention and its modification will be described with reference to FIGS.

  In the above-described Embodiments 2 and 3, an elastic member such as a spring is used as a driving means for the piston 112. However, the piston 112 is driven with a constant force (speed) using an electromagnetic force such as a motor or a solenoid. May be. In the present embodiment, an example in which the piston 112 is driven using not only a spring but also a motor, a solenoid, or the like will be described.

  As shown in FIG. 30, the liquid atomization apparatus in the present embodiment includes a power supply unit 150, a control unit 151, a chemical solution presence / absence detection unit 152, a constant current booster circuit 153, an oscillation circuit 154, and an atomization unit. 127, current detection unit 155, mesh member cap 122, intake sensor 156, piston drive unit 126, liquid storage chamber 105, liquid feed hole 111, piston 112, metering chamber 109, and discharge valve 113. And a liquid supply hole 110.

  The power supply unit 150 is composed of a dry battery or the like. The control unit 151 controls the operation of each unit. The constant current boosting circuit 153 boosts the output of the power supply unit 150 and drives the oscillation circuit 154 and the atomizing unit 127 with a constant current.

  The atomization unit 127 includes an ultrasonic transducer (horn transducer) and a mesh member, as in the second embodiment. The current detection unit 155 detects the current flowing through the ultrasonic transducer and makes the constant current booster circuit 153 constant.

  The chemical solution presence / absence detection unit 152 detects the presence / absence of the chemical solution in the atomization unit 127, inputs the detection result to the control unit 151, and controls the constant current booster circuit 153 to be turned on / off by the control unit 151.

  Whether or not a chemical is present on the ultrasonic transducer depends on the impedance of the ultrasonic transducer. Specifically, the impedance is high when a chemical is present on the ultrasonic transducer, and the impedance is low when no chemical is present on the ultrasonic transducer.

  When the impedance of the ultrasonic vibrator increases, the input impedance of the oscillation circuit 154 itself increases, and the output voltage of the constant current booster circuit 153 increases. This voltage is input to the control unit, and it is detected whether or not a chemical is present on the ultrasonic transducer.

  The inhalation sensor 156 senses inspiration of the patient (user), and controls the constant current booster circuit 53 by the control unit 151 according to the detection result. The inhalation sensor 156 is installed at or near the mesh cap (mouthpiece: inhalation port) 122 and detects that the patient has inhaled the medicinal liquid atomized by the atomization unit 127 from the inhalation port. In order to sense inhalation, it is only necessary to detect a change in pressure or a change in airflow due to the patient's inspiration.

  By providing the inhalation sensor 156 in this manner, it is possible to detect that the patient has inhaled from the inlet, and in response to the patient inhaling from the inlet, the chemical liquid is atomized, or the chemical liquid is applied to the atomization unit 127. The difference between the spraying timing of the atomized chemical liquid and the patient's inspiration timing can be reduced.

  As the piston drive unit 126, the same configuration as in the second and third embodiments can be adopted, but the one shown in FIGS. 36 to 39 can also be adopted.

  For example, as shown in FIG. 36, the piston 112 may be driven using a solenoid 138. In this case, by passing a current through the solenoid 138, the pin 137 moves to the left, and the piston 112 moves to the left via the rod 114. Thereby, the piston 112 can be driven at a constant speed.

  Also, as shown in FIG. 37, the piston 112 may be driven using a motor 139. In this case, the gear is cut on the rod 114 and the motor 139 and the rod 114 are connected via the pinion gear 140. Thereby, the pinion gear 140 can be rotated by driving the motor 139, and the piston 112 can be moved to the left side at a constant speed via the rod 114.

  As shown in FIG. 38, the gear 142 may be fixed to the rod 114, the gear 141 may be attached to the motor 139 side, and the gear 141 and the gear 142 may be engaged with each other. Thereby, the power from the motor 139 can be transmitted to the rod 114 via the gear 141 and the gear 142, and the piston 112 can be moved to the left side at a constant speed.

  Further, as shown in FIG. 39, the piston 112 may be driven using a rotary solenoid 145. In this case, the arm 143 fixed to the shaft 144 is rotated by the rotation of the rotary solenoid 145, the rod 114 fixed to the arm 143 is pushed, and the piston 112 can be driven. Thereby, the piston 112 can be moved to the left side at a constant speed.

  The mesh member cap 122, the discharge valve 113, the liquid storage chamber 105, the measurement chamber 109, the piston 112, the liquid supply hole 110, and the liquid supply hole 111 can be the same as those in the second and third embodiments. Therefore, explanation is omitted. Further, when the piston driving unit 126 includes a spring, the piston driving unit 126 does not need to be controlled by the control unit 151.

Next, the operation of the liquid atomizing apparatus in the present embodiment will be described.
First, the operation when the intake sensing is not performed will be described with reference to FIGS. 31A to 31D and FIG.

  As shown in FIG. 31A, a predetermined amount of chemical solution is measured in step S10. The method of measuring the chemical solution is the same as in the second and third embodiments. That is, as shown in FIG. 31B, the liquid supply lever is rolled up (step S11), the piston 112 is driven to open the liquid supply hole 111, and the chemical solution is supplied from the liquid storage chamber 105 to the measurement chamber 109 (step S12). At this time, the spring is compressed (step S13), and the extension of the spring is latched by the same method as in the second and third embodiments (step S14).

  Next, in step S20 of FIG. 31A, the chemical solution is sent to the atomizing unit 127. As shown in FIG. 31C, the chemical solution is delivered by operating the release button described in Embodiments 2 and 3 to release the spring latch (step S21) and extend the spring (step S22). . As a result, the piston 112 is pushed by the spring via the rod 114, the chemical liquid in the measuring chamber 109 is pushed by the piston 112, the discharge valve 113 is moved, the liquid supply hole 110 is opened, and the liquid is fed to the atomizing unit 127. (Step S23).

  Next, in step S30 of FIG. 31A, the chemical solution is atomized in the atomizing unit 127 and then sprayed. This chemical solution is sprayed by the following method. First, as shown in FIG. 31D, the rod 114 is moved by the elastic force of the spring (step S31), but the position of the rod 114 is detected (step S32), and it is detected that the rod 114 has reached the specified position. Accordingly, the power supply unit 150 is turned on (step S33).

  The position of the rod 114 can be detected by, for example, a magnet provided at an appropriate position of the rod 114 and a magnetic force sensitive switch (for example, a reed relay or a Hall element) provided in the corresponding housing 101. By detecting the position of the rod 114 in this way, it is possible to detect in advance that the liquid supply to the atomizing unit 127 is started.

  When the rod 114 reaches a predetermined position, the power supply unit 150 is turned on by the control unit (atomization operation start unit) 151 and automatically at a desired time before and after the liquid supply to the atomization unit 127 is started. The atomization operation of the chemical solution can be started.

  It should be noted that other liquid supply detection means may be employed as long as the start of liquid supply to the atomizing unit 127 can be detected in advance. For example, a position sensor for detecting the position of at least one of the piston 112 and the discharge valve 113 may be provided, and this may function as the liquid supply detection means. The position of the discharge valve 113 can be detected by, for example, a magnet provided in the discharge valve 113 and a magnetic force sensitive switch (for example, a reed relay or a Hall element) provided in the corresponding housing 101.

  By providing the position sensor as described above, the chemical liquid atomization operation is automatically started when the position sensor detects that at least one of the piston 112 and the discharge valve 113 has reached the predetermined position. Can do. Thereby, the atomization operation | movement of a chemical | medical solution can be started immediately before or before the chemical | medical solution is supplied to the atomization part 127. FIG.

  When the piston drive unit 126 includes a motor or a solenoid, the atomization operation start means may start the liquid atomization operation after the drive signal of the motor or solenoid is input.

  After the power supply unit 150 is turned on, the battery potential is boosted by the constant current boosting circuit 153 (step S34). Thereafter, in step S35, it is detected whether or not the current flowing through the horn vibrator (ultrasonic vibrator) 119 is a specified value. If the current is greater than or equal to the specified value, the horn vibrator 119 is driven ( Step S36), the chemical liquid atomization operation is performed.

  As shown in FIG. 32B, the impedance is relatively large when there is a chemical solution on the horn vibrator 119, the impedance decreases as the chemical liquid is atomized, and the impedance is most when there is no chemical liquid on the horn vibrator 119. Becomes lower.

  Therefore, in step S37, it is detected whether or not the boosted potential of the horn vibrator 119 is equal to or higher than a specified value. When the boosted potential becomes a predetermined value (threshold voltage V1) or lower as shown in FIG. It is determined that there is no chemical on the child 119 (step S38), and the power is turned off as shown in FIGS. 31D and 32A (step S40).

  That is, the liquid atomizing apparatus of the present invention includes an impedance detection means (step S37) for detecting the impedance of the vibrator, and for stopping the vibration of the vibrator when the impedance becomes a predetermined value or less. Vibrator stop means (step S40). As a result, the vibration of the horn vibrator 119 can be stopped in response to the absence of the chemical liquid to be atomized on the mesh member 120, thereby suppressing unnecessary power consumption and extending the life of the horn vibrator 119. Can be achieved.

  Next, the operation when performing intake sensing will be described with reference to FIGS. 33A to 33D and FIG. 34.

  In the example shown in FIG. 33A, the medicinal solution is measured in step S10 in the same manner as in the above example, and then it is detected in step S20 that the patient has inhaled. Inhalation by the patient is detected by the inhalation sensor 156 described above. Then, as shown in FIG. 33C, the power is turned on in response to the detection of inspiration by the patient (step S21) (step S22), the latch is released by a solenoid or the like (step S23), and the spring is extended ( Step S24), the chemical solution is sent to the atomizing unit 127 (Step S30). That is, the chemical solution is supplied to the atomizing unit 127 in response to the inspiration by the patient detected by the inhalation sensor 156.

  After the chemical liquid is sent to the atomization unit 127, the chemical liquid is atomized, and the chemical liquid atomized in step S40 is sprayed as shown in FIG. 33A. Spraying is performed in the same manner as the example shown in FIGS. 31A to 31D. Specifically, as shown in FIG. 33D, the battery potential is boosted by the constant current boosting circuit 153 (step S41), the current flowing through the horn vibrator 119 is detected (step S42), and the constant flow drive of the horn vibrator 119 is performed. (Step S43) and the detection of the boosted potential (Step S44).

  Then, when the boosted potential becomes equal to or lower than a predetermined value (threshold voltage V1) as shown in FIG. 34A, it is determined that there is no longer any chemical to be atomized on the mesh member 120 (step S45). The power is turned off (step S50). Thereby, the vibration of the horn vibrator 119 can be stopped in response to the absence of the chemical to be atomized on the mesh member 120.

  Next, another operation example when performing intake air sensing will be described with reference to FIGS. 35A to 35D.

  As shown in FIG. 35A, the chemical solution is measured (step S10), and then the chemical solution is sent to the atomizing unit 127 (step S20). The method of measuring the chemical solution is the same as the example shown in FIGS. 33A to 33D, and the method of sending the chemical solution to the atomizing unit 127 is the same as the example shown in FIGS.

  Next, the patient's inspiration is detected (step S30). As shown in FIG. 35D, whether or not the patient has inhaled is detected by the inhalation sensor 156 (step S31), and the power is turned on in response to the patient inhaling (step S32). That is, the atomization operation of the liquid in the atomization unit 127 is started in response to the inhalation by the patient being detected by the inhalation sensor 156.

  Then, similarly to the case shown in FIGS. 33A to 33D, the battery potential is boosted (step S33), the current flowing through the horn vibrator 119 is detected (step S34), and the constant flow drive of the horn vibrator 119 is performed (step S35). Then, when the boosted potential is detected (step S36) and the boosted potential becomes equal to or lower than a predetermined value (threshold voltage V1) as shown in FIGS. Is no longer present (step S37), and the power is turned off (step S50).

  In the present embodiment, the battery life and the life of the vibrator can be increased as compared with JP-A-8-502688, and the drug inhalation loss can be reduced as compared with WO00 / 66277. . This will be described below.

  In Japanese National Patent Publication No. 8-502688, in an apparatus for atomizing a liquid by vibrating a thin film, in order to atomize all of a predetermined amount of liquid, the vibration time required for atomizing the predetermined amount of liquid is An invention is described in which the thin film is vibrated for a long time.

  However, vibrating the thin film for a long time in this way not only shortens the battery life for vibrating the thin film, but also vibrates the vibrator for a long time in a no-load state, thereby shortening the life of the vibrator. There was a problem.

  On the other hand, in this embodiment, since the liquid supply detection means 160 and the atomization operation start means 151 are provided, the liquid is automatically supplied at a desired time before and after the liquid supply to the atomization unit 127 is started. The atomization operation can be started. As a result, when a vibrator is used to atomize the liquid, it is possible to reduce the driving time in a no-load state, thereby suppressing unnecessary power consumption and extending the life of the vibrator. Can do. In addition, by vibrating the vibrator in advance immediately before supplying the liquid to the atomizing unit 127, even when the amount of liquid supplied from the measuring chamber 109 varies, an extreme load increase on the vibrator can be prevented. Spraying can be performed continuously.

  In the present embodiment, since the impedance detecting means (step S37) and the vibrator stopping means (step S40) are provided, the vibrator is vibrated in response to the absence of liquid on the mesh member 120. Can be stopped. Accordingly, wasteful power consumption can be suppressed, and driving of the vibrator in a no-load state can be suppressed to extend the life of the vibrator.

  In addition, in the above-mentioned WO00 / 66277, when supplying a chemical solution to the atomizing unit by manual operation, the chemical solution is manually sprayed to the atomizing unit and sprayed after the chemical solution is inhaled. Will be inhaled. For this reason, there is a problem that the difference between the spraying timing of the atomized chemical liquid and the timing of the user's inhalation becomes large, and the chemical liquid cannot be sucked in well. In particular, when the amount of medicinal solution to be inhaled is very small, the inhalation loss of the medicine increases due to the timing of spraying and inhalation being shifted.

  In contrast, in the present embodiment, since the inhalation detection means (inhalation sensor 156) is provided, the liquid atomization operation, the supply of the liquid to the atomization unit, and the like can be performed according to the patient's inspiration. it can. Thereby, the shift | offset | difference of the spraying timing of the atomized liquid and a user's inhalation timing can be made small, and the inhalation loss of the chemical | medical agent by a user can be reduced.

(Embodiment 5)
Next, a fifth embodiment of the present invention will be described with reference to FIGS.

  As shown in FIGS. 40 and 41, in the fifth embodiment, the configuration of the third embodiment is that a spiral spring is used for the lever spring 216 in the piston drive unit 126 for driving the piston (not shown). And different.

  The piston driving unit 126 includes a push rod 114b, a winding lever 115, a release lever 117, a lever plate 128, a release spring 135, an E-ring 201, a switch lever 202, a lever shaft 214, and a lever spring 216. With.

  The push rod 114b has an engaging projection 114d and a rack 114c, and is slidably supported by a guide 101c provided on the housing 101. The lever plate 128 has a pinion 128 a that meshes with the rack 114 c of the push rod 114 b and is rotatably fitted to a cylindrical portion 101 a provided in the housing 101. The winding lever 115 has an operating portion 115b that can be operated by hand, and an engaging convex portion 115c that can be engaged with the concave portion 128b of the lever plate 128.

  The lever shaft 214 is inserted from the inside of the housing 101 into the through hole of the cylindrical portion 101 a, thereby penetrating through the holes of the lever plate 128 and the winding lever 115 and protruding from the winding lever 115 to the tip of the E-ring 201. Is fitted. The lever shaft 214 also penetrates the switch lever 202, whereby the switch lever 202 rotates together with the lever shaft 214. A lever spring 216 made of a spiral spring is disposed at the lower end of the lever shaft 214.

  As shown in FIG. 42, the lever spring 216 has an inner peripheral end sandwiched between cracked portions 214a of the lever shaft 214, and an outer peripheral end is hooked by a rib portion 101d provided inside the housing 101. Is supported by

  The release lever 117 has a lock claw 125 that can be fitted into a hole provided in the lever plate 128 and is biased upward by a release spring 135.

  The battery unit 108a can be inserted into the housing 101 from below the lever spring 216, and the housing 101 can be closed by the bottom cover unit 101b after the battery unit 108a is inserted into the housing 101.

  The piston driving unit 126 configured as described above can drive the piston when the engaging convex portion 114d of the push rod 114b is engaged with the hole of the coupling rod 133.

  In addition, since it is as substantially the same as the structure of Embodiment 3 mentioned above about the structure other than this, the same code | symbol is attached | subjected about the same member and the description is abbreviate | omitted.

  Next, the operation of the liquid atomization apparatus in the present embodiment will be described with reference to FIGS. 43 and 44.

  From the initial state shown in FIG. 43, the operation portion 115b of the winding lever 115 is rotated counterclockwise by hand, and the winding lever 115 is rotated by a predetermined angle. As a result, the lever plate 128 rotates, the push rod 114b and the coupling rod 133 slide to the right, and the piston (not shown) also moves to the right. At this time, the lever spring 216 formed of a spiral spring is wound up by the rotation of the lever shaft 214, and a biasing force is generated to rotate the winding lever 115 clockwise (clockwise).

  When the piston moves to the right by a predetermined amount or more, the liquid chemical is fed from the liquid storage chamber (not shown) into the measurement chamber (not shown) in the same manner as in the second and third embodiments. At this time, a liquid supply hole (not shown) is closed by a discharge valve (not shown).

  When the winding lever 115 is rotated by a predetermined amount, as shown in FIG. 44, the lock claw 125 is inserted into the hole 128c provided in the lever plate 128 by the urging force of the release spring 135, and the lock that locks the piston or the like at a predetermined position. It becomes a state.

  Next, when the release lever 117 is pushed down, the lock claw 125 comes out of the hole 128c provided in the lever plate 128, and the locked state between the lever plate 128 and the lock claw 125 is released. Accordingly, the lever plate 128 is rotated clockwise (clockwise) by the biasing force of the lever spring 216 that has been wound up, and the push rod 114b and the coupling rod 133 slide to the left.

  By pressing the piston (not shown) with the urging force of the lever spring 216 in this way, the chemical solution in the measuring chamber (not shown) is moved to the piston (not shown) with a substantially uniform force as in the second and third embodiments. (Not shown). Thereby, the chemical solution can be supplied to the atomizing unit 127 in the same manner as in the second and third embodiments.

Note that the mode of the fourth embodiment can be applied to the fifth embodiment.
In the present embodiment, as in the second and third embodiments, the piston can be pressed by the biasing force of the lever spring 216, so that the piston can be driven at a constant speed.

  In addition, the liquid atomization apparatus of the present embodiment can easily realize atomization in a constant amount as compared with the second and third embodiments, and can prevent the chemical liquid from being scattered in the atomization unit 127. There is an advantage that the apparatus can be miniaturized. This will be described below.

  Referring to FIG. 45, normally, in a spring, the force F applied to the spring and the displacement amount X are directly proportional to each other, and the slope of a straight line indicating the relationship is the spring constant. Here, when the spring constant is increased, the force F applied to the spring in the winding state (the spring is in the most contracted state) and the spring in the state in which the piston 112 is fully pressed (the spring is in the most extended state). The difference from the force F is increased. This difference in force F is proportional to the difference in speed at which the spring pushes the piston 112. That is, in the position of the winding state (the state where the spring is most contracted), the speed at which the spring pushes the piston 112 is large, and in the position where the piston 112 is fully pushed (the state where the spring is most extended), the spring is the piston. The speed of pushing 112 is smaller than that, and the rate of change in speed is greater. Thereby, when mass-producing the liquid atomization apparatus of this Embodiment, it becomes difficult to implement | achieve atomization by a fixed quantity by the dispersion | variation by the individual difference of a spring.

  Here, the “degree of change in speed” is sufficiently small compared to the speed change in the case of the manual operation of the first embodiment, and is a change rate that can be regarded as a substantially constant speed.

  Further, the force F applied to the spring when the piston 112 is fully pressed needs to have a minimum force to push down the discharge valve 113 sufficiently against the valve spring 118 and push out the chemical solution in the measuring chamber 109 from the liquid supply hole 110. It is. Therefore, if the spring constant is large, a larger force F is applied to the spring when it is wound, and the speed at which the spring pushes the piston 112 is increased accordingly. As a result, the discharge valve 113 is pushed in a little, and the amount of the chemical flowing backward from the measuring chamber 109 to the ampoule 104 is reduced by the amount pushed, resulting in a phenomenon that the chemical supplied to the atomizing unit increases. This phenomenon varies greatly due to individual differences in springs, deterioration of parts, and the viscosity state of the chemical solution, making it difficult to realize atomization with a constant amount.

  Also, if the spring constant is large, the piston 112 is pushed at a position beyond the liquid feed passage 104 a connected to the ampoule 104, and the speed at which the piston 112 is pushed by the spring becomes faster, so that the chemical moves to the atomization unit 127 at a high speed. The atomization unit 127 is likely to scatter the chemical solution, which also hinders the realization of the atomization with a constant amount.

  Therefore, if a spring with a small spring constant is used, the speed difference of the speed at which the spring pushes the piston 112 becomes small. Therefore, atomization with a constant amount is facilitated, and the chemical liquid splatters at the atomizing section 127. No longer occurs. However, in this case, if an attempt is made to increase the force with which the spring presses the piston 112, the amount of displacement X of the spring increases, so the length of the entire spring needs to be increased. Therefore, when a coil spring is used as the piston spring 116 as in the second and third embodiments, the size of the helical coil spring increases in the longitudinal direction, making it difficult to reduce the size of the device.

  On the other hand, in this embodiment, a spiral spring is used as the lever spring 216. In order to lengthen this spiral spring, it is necessary to lengthen it in the spiral direction. However, when the length is increased in the spiral direction, the length can be ensured in the circumferential direction, so that the size of the spiral spring can be kept smaller than the coil spring that is elongated in the longitudinal direction. Therefore, the liquid atomization apparatus of the present embodiment using a spiral spring is more suitable for miniaturization than the configurations of the second and third embodiments.

  As described above, the liquid atomization apparatus of the present embodiment can easily realize atomization with a constant amount by using a spiral spring having a small spring constant as the lever spring 216, and the chemical liquid in the atomization unit 127 can be realized. It is possible to prevent scattering and to reduce the size of the apparatus.

  Although the embodiments of the present invention have been described as above, the above-described embodiments should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, and includes meanings equivalent to the terms of the claims and all modifications within the scope.

  The present invention can be advantageously applied to a liquid atomizing apparatus for stabilizing the atomization by keeping the amount of liquid fed to the atomizing unit constant and realizing it at a low cost.

It is an external appearance perspective view of the liquid atomization apparatus which concerns on embodiment. It is a partially broken perspective view of the liquid supply unit in the liquid atomization apparatus of the embodiment. It is a longitudinal cross-sectional view of the liquid atomization apparatus of the embodiment. It is a schematic diagram which shows the state which fills a secondary liquid storage part with a chemical | medical solution in the liquid feeding mechanism of the liquid atomization apparatus of the embodiment. It is a schematic diagram which shows the state which presses the chemical | medical solution of a secondary liquid storage part with a piston in the liquid feeding mechanism of the liquid atomization apparatus of the embodiment. It is a schematic diagram which shows the state which liquid-feeds the chemical | medical solution of a secondary liquid storage part to the atomization part in the liquid feeding mechanism of the liquid atomization apparatus of the embodiment. It is a schematic diagram which shows the state which sent the chemical | medical solution of the secondary liquid storage part to the atomization part completely in the liquid delivery mechanism of the liquid atomization apparatus of the embodiment. It is a schematic diagram which shows the state after the chemical liquid feeding of the secondary liquid storage part in the liquid feeding mechanism of the liquid atomization apparatus of the embodiment. It is a schematic diagram which shows the state by which the piston was further pulled back after the chemical liquid feeding of a secondary liquid storage part in the liquid feeding mechanism of the liquid atomization apparatus of the embodiment. FIG. 5 is a longitudinal sectional view showing a state corresponding to the state of FIG. 4 in the liquid feeding mechanism of the liquid atomizing apparatus of the same embodiment. It is a longitudinal cross-sectional view which shows the state corresponding to the state of FIG. 5 in the liquid feeding mechanism of the liquid atomization apparatus of the embodiment. It is a longitudinal cross-sectional view which shows the state corresponding to the state of FIG. 6 in the liquid feeding mechanism of the liquid atomization apparatus of the embodiment. It is a longitudinal cross-sectional view which shows the state corresponding to the state of FIG. 7 in the liquid feeding mechanism of the liquid atomization apparatus of the embodiment. It is a longitudinal cross-sectional view which shows the state corresponding to the state of FIG. 9 in the liquid feeding mechanism of the liquid atomization apparatus of the embodiment. It is a longitudinal cross-sectional view which shows the state in which the power switch is OFF in the principal part of the liquid atomization apparatus of the embodiment. It is a longitudinal cross-sectional view which shows the state in which the power switch is ON in the principal part of the liquid atomization apparatus of the embodiment. It is a partially broken perspective view which shows a state when the chemical | medical solution of a secondary liquid storage part is supplied to the atomization part in the liquid supply unit of the liquid atomization apparatus of the embodiment. It is sectional drawing of the liquid atomization apparatus in Embodiment 2 of this invention. It is a disassembled perspective view of the liquid atomizer shown in FIG. It is a fragmentary sectional perspective view which shows the initial state of the liquid atomizer shown in FIG. It is a fragmentary sectional perspective view which shows the liquid absorption state of the liquid atomizer shown in FIG. It is a fragmentary sectional perspective view which shows the chemical | medical solution discharge state of the liquid atomization apparatus shown in FIG. It is a fragmentary sectional perspective view which shows the chemical | medical solution discharge completion state of the liquid atomization apparatus shown in FIG. It is a perspective view of the liquid atomization apparatus in Embodiment 3 of this invention. It is a disassembled perspective view of the liquid atomization apparatus shown in FIG. It is a fragmentary sectional perspective view which shows the initial state of the liquid atomization apparatus shown in FIG. It is a fragmentary sectional perspective view which shows the liquid absorption state of the liquid atomizer shown in FIG. It is a fragmentary sectional perspective view which shows the chemical | medical solution discharge state of the liquid atomization apparatus shown in FIG. It is a fragmentary sectional perspective view which shows the chemical | medical solution discharge completion state of the liquid atomization apparatus shown in FIG. It is a block diagram which shows schematic structure of the liquid atomization apparatus in Embodiment 4 of this invention. It is a flowchart for demonstrating the operation example when not performing inhalation | air-intake sensing with the liquid atomization apparatus in Embodiment 4 of this invention. It is a flowchart for demonstrating the operation example when not performing inhalation | air-intake sensing with the liquid atomization apparatus in Embodiment 4 of this invention. It is a flowchart for demonstrating the operation example when not performing inhalation | air-intake sensing with the liquid atomization apparatus in Embodiment 4 of this invention. It is a flowchart for demonstrating the operation example when not performing inhalation | air-intake sensing with the liquid atomization apparatus in Embodiment 4 of this invention. (A) is a figure which shows the change of the voltage value of a horn vibrator | oscillator at the time of atomization operation | movement, (B) is a figure which shows the change of the impedance of a horn vibrator | oscillator. It is a flowchart which shows the operation example in the case of performing intake air sensing with the liquid atomization apparatus in Embodiment 4 of this invention. It is a flowchart which shows the operation example in the case of performing intake air sensing with the liquid atomization apparatus in Embodiment 4 of this invention. It is a flowchart which shows the operation example in the case of performing intake air sensing with the liquid atomization apparatus in Embodiment 4 of this invention. It is a flowchart which shows the operation example in the case of performing intake air sensing with the liquid atomization apparatus in Embodiment 4 of this invention. (A) is a figure which shows the change of the voltage value of a horn vibrator | oscillator at the time of atomization operation | movement, (B) is a figure which shows the change of the impedance of a horn vibrator | oscillator. It is a flowchart which shows the other operation example in the case of performing intake air sensing with the liquid atomization apparatus in Embodiment 4 of this invention. It is a flowchart which shows the other operation example in the case of performing intake air sensing with the liquid atomization apparatus in Embodiment 4 of this invention. It is a flowchart which shows the other operation example in the case of performing intake air sensing with the liquid atomization apparatus in Embodiment 4 of this invention. It is a flowchart which shows the other operation example in the case of performing intake air sensing with the liquid atomization apparatus in Embodiment 4 of this invention. It is a schematic diagram which shows the other example of the piston drive part of this invention. It is a schematic diagram which shows the further another example of the piston drive part of this invention. It is a schematic diagram which shows the further another example of the piston drive part of this invention. It is a schematic diagram which shows the further another example of the piston drive part of this invention. It is a disassembled perspective view of the liquid atomization apparatus in Embodiment 5 of this invention. It is a fragmentary sectional perspective view of the liquid atomization apparatus shown in FIG. It is a figure for demonstrating the structure which supports a lever spring. It is a perspective view which shows the initial state of the liquid atomization apparatus shown in FIG. It is a perspective view which shows the winding state of the liquid atomizer shown in FIG. It is a figure which shows the relationship between the displacement amount X of a spring, and the force F concerning a spring.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Main-body part, 2 Liquid supply unit, 10 Primary liquid storage part, 16 Secondary liquid storage part, 18, 24 Liquid supply path, 20 Piston, 22 Valve, 30, 119 Horn vibrator, 32, 120 Mesh member, 40 Supply Liquid button (operating part), 50 cylinder, 52, 56 Coil spring, 101 housing, 102 cylinder, 104a Liquid feed passage, 105 Liquid storage chamber, 106 piston, 109 Measuring chamber, 110 Liquid feed hole, 111 Liquid feed hole, 112 piston 117 release button, 126 piston drive unit, 127 atomization unit, 139 motor, 145 rotary solenoid, 151 atomization operation start unit, 152 chemical presence / absence detection unit, 156 intake sensor, 160 liquid supply detection unit.

Claims (25)

A primary liquid storage part for storing a liquid to be atomized, an atomization part for atomizing the liquid in the primary liquid storage part, and a primary liquid storage part provided between the primary liquid storage part and the atomization part. A secondary storage unit that measures the amount of liquid sent to the atomization unit, a primary liquid supply unit that sends the liquid in the primary storage unit to the secondary storage unit, and a measured liquid in the secondary storage unit A secondary liquid feeding part for sending the liquid to the atomizing part, and an operation part for operating the secondary liquid feeding part,
The liquid atomizing device, wherein the atomizing unit starts the atomizing operation before the liquid is supplied to the atomizing unit by the operation of the operation unit. The liquid atomizing apparatus according to claim 1, wherein the primary liquid feeding unit and the secondary liquid feeding unit feed liquids in conjunction with operation of an operation unit. The liquid atomizing apparatus according to claim 1, wherein the atomizing unit starts a liquid atomizing operation simultaneously with the operation of the operation unit. The liquid supply from the primary liquid storage part to the secondary liquid storage part is performed when the liquid feeding operation to the atomization part by the operation of the operation part is completed. Liquid atomizer. 2. The liquid atomizing apparatus according to claim 1, wherein the secondary liquid storage unit is in a sealed state except when liquid is sent to the atomizing unit. 3. The primary liquid storage part, the atomization part, the secondary liquid storage part, the primary liquid supply part and the secondary liquid supply part are integrally configured as a liquid supply unit, and the primary liquid storage part is attached to and detached from the liquid supply unit. The liquid atomizer according to claim 1, which is possible. A liquid storage chamber for storing liquid;
A measuring chamber into which a predetermined amount of the liquid is fed from the liquid storage chamber through a liquid feeding hole;
An atomizing section for atomizing the liquid supplied from the measuring chamber through the liquid supply hole;
A piston for opening and closing the liquid supply hole and supplying the liquid to the atomizing section through the liquid supply hole by pressing the liquid in the measurement chamber;
A piston drive unit for driving the piston at a constant speed;
One end of the measuring chamber is defined, supported by an elastic member, moved by pressing the liquid by the piston, opens the liquid supply hole, and a valve for supplying the liquid to the atomizing unit A liquid atomizer provided. The liquid atomizing apparatus according to claim 7, wherein the atomizing unit includes a mesh member and a vibrator, and the liquid is supplied from the measuring chamber. The liquid atomizing apparatus according to claim 7, wherein the piston drive unit includes at least one element selected from the group consisting of an elastic means for applying an elastic force to the piston, a motor, and a solenoid. A locking means for fixing the piston at a position where the liquid feeding hole is opened and the liquid can be fed from the liquid storage chamber to the measuring chamber;
A release switch for releasing the fixed state by the locking means and driving the piston by operating the piston driving unit;
The liquid atomizer of Claim 7 provided with these. Unlock detection means for detecting that the fixed state by the lock means has been released by the release switch;
The atomization operation start means for starting the liquid atomization operation after the lock release detection means detects that the fixed state of the piston by the lock means is released. Liquid atomizer. The piston drive unit includes a first rod, a second rod that presses the piston, and a connection member that connects the first and second rods,
The liquid atomizing device according to claim 7, wherein a moving direction of the first rod is different from a moving direction of the second rod. A housing having the liquid storage chamber therein;
A cylinder having the weighing chamber therein and receiving the piston;
The liquid atomizer according to claim 7, wherein the cylinder and the piston driving unit are detachably attached to the housing. The liquid atomizing device according to claim 7, wherein the piston driving unit has a spiral spring as an elastic means for applying an elastic force to the piston. A liquid storage chamber for storing liquid;
A measuring chamber into which a predetermined amount of the liquid is fed from the liquid storage chamber through a liquid feeding hole;
An atomizing section for atomizing the liquid supplied from the measuring chamber through the liquid supply hole;
A valve for defining one end of the measuring chamber, supported by an elastic member, and for opening and closing the liquid supply hole;
A piston for opening and closing the liquid supply hole, pressing the liquid in the measuring chamber to move the valve to open the liquid supply hole, and supplying the liquid to the atomizing section through the liquid supply hole When,
A piston drive for driving the piston;
Liquid supply detection means for detecting in advance that liquid supply to the atomizing unit is started;
In response to the fact that liquid supply to the atomization unit is detected by the liquid supply detection means, the atomization operation start means for starting the liquid atomization operation;
A liquid atomization device comprising: The liquid supply detection means includes a position sensor for detecting the position of at least one of the piston and the valve,
The atomizing operation start means starts the atomizing operation of the liquid in response to detection by the position sensor that at least one of the piston and the valve has reached a predetermined position. Liquid atomizer. The piston drive unit includes a motor and a solenoid,
The liquid atomization apparatus according to claim 15, wherein the atomization operation start means starts the liquid atomization operation after a drive signal of the motor or solenoid is input. The atomization unit includes a mesh member and a vibrator, and the liquid is supplied from the measurement chamber,
The liquid atomizing apparatus according to claim 15, wherein the atomizing operation start means includes vibrator driving means for driving the vibrator. The liquid atomizing device according to claim 15, wherein the piston driving unit includes a spiral spring as elastic means for applying an elastic force to the piston. A liquid storage chamber for storing liquid;
A measuring chamber into which a predetermined amount of the liquid is fed from the liquid storage chamber through a liquid feeding hole;
An atomizing unit including a mesh member and an oscillator for atomizing the liquid supplied from the measuring chamber through the liquid supply hole;
A piston for opening and closing the liquid supply hole and supplying the liquid to the atomizing section through the liquid supply hole by pressing the liquid in the measurement chamber;
A piston drive for driving the piston;
Impedance detection means for detecting the impedance of the vibrator;
Vibration stopping means for stopping the vibration of the vibrator in response to the impedance detected by the impedance detecting means becoming a predetermined value or less;
A liquid atomizing device. 21. The liquid atomizing device according to claim 20, wherein the piston driving unit includes a spiral spring as elastic means for applying an elastic force to the piston. A liquid storage chamber for storing liquid;
A measuring chamber into which a predetermined amount of the liquid is fed from the liquid storage chamber through a liquid feeding hole;
An atomizing section for atomizing the liquid supplied from the measuring chamber through the liquid supply hole;
A piston for opening and closing the liquid supply hole and supplying the liquid to the atomizing section through the liquid supply hole by pressing the liquid in the measurement chamber;
A piston drive for driving the piston;
An inlet for a user to inhale the liquid atomized by the atomization unit;
Inhalation detection means for detecting that the user has inhaled from the inlet;
A liquid atomizing device. The liquid mist according to claim 22, further comprising: an atomization operation start unit that starts an atomization operation of the liquid in the atomization unit in response to detection of intake air by the user by the intake detection unit. Device. 23. The liquid atomizing apparatus according to claim 22, further comprising a liquid supply unit configured to supply the liquid to the atomizing unit in response to the intake air detected by the user by the intake air detection unit. The liquid atomizing apparatus according to claim 22, wherein the piston driving unit includes a spiral spring as an elastic means for applying an elastic force to the piston.

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