JP4483758B2 - Inhaler - Google Patents

Description

  The present invention relates to an inhaler used for inhalation of a chemical spray for the purpose of treating inflammation of the respiratory system of a human body.

2. Description of the Related Art Conventionally, in order to treat inflammation of the human respiratory system, a spray of a chemical solution or water is generated and the spray is inhaled. An inhaler is a device that generates and inhales such a spray. The general configuration of the apparatus is configured to suck up the chemical liquid and water with a negative pressure generated by the jetted steam blown from the nozzle and spray it to the throat and nose (see, for example, Patent Document 1). ).
JP-A-5-245202

  However, in the inhaler as shown in Patent Document 1 described above, it is possible to change the amount of spray liquid or change the spray direction to the direction of the throat or nose, but these changes are not linked to each other. Annoying adjustment operations were necessary.

  An object of the present invention is to solve the above-mentioned problems, and to provide an inhaler that can easily adjust the spray direction and the amount of the spray liquid with a simple operation.

In order to achieve the above object, the invention of claim 1 is directed to a water supply tank for pouring and storing water, a heater for boiling water drawn from the water supply tank, and water vapor obtained by boiling with the heater. In addition, a jet nozzle that generates a negative pressure, a chemical cup that stores chemical liquid, and a chemical liquid that is disposed in the vicinity of the jet nozzle and sucks the chemical liquid in the chemical cup at a negative pressure generated by the jet nozzle and sprays the chemical liquid in a mist form. In an inhaler comprising a chemical nozzle and an attachment that guides the water vapor from the ejection nozzle and the spray liquid from the chemical nozzle to the mouth and / or the nose, the direction for guiding the water vapor and the spray liquid is switched inside the attachment. A switching plate; and a chemical liquid adjusting unit that adjusts the amount of chemical liquid sprayed from the chemical nozzle. Work in conjunction and a liquid adjuster, the chemical adjusting unit is used to adjust the chemical amount while fixing the switch plate in a predetermined direction.

According to a second aspect of the present invention, in the inhaler according to the first aspect, the attachment has an outside air circulation port that allows the outside air to flow between the inside and the outside, and the outside air circulation port is the chemical solution adjusting unit. The opening amount is adjusted in conjunction with the operation.

According to a third aspect of the present invention, in the inhaler according to the second aspect , a plurality of different combinations are set in advance by combining predetermined states that can be taken by each of the drug solution adjusting unit, the switching plate, and the outside air circulation port that are linked to each other. A mode selection unit that selects a desired usage mode from the usage mode, and an automatic adjustment unit that automatically realizes the state of the usage mode selected using the mode selection unit. .

A fourth aspect of the present invention, in the inhaler according to claim 3, using course formed by setting a plurality of multiple modes of use selected from the use mode in advance different combinations so as to sequentially repeat at predetermined time intervals A course selecting means for selecting a desired used course, and a course executing means for operating the selected course using the course selecting means by operating the automatic adjusting means.

  According to the first aspect of the present invention, since the switching plate and the chemical liquid adjustment unit that operate in conjunction with each other are provided, the adjustment of the spray direction and the adjustment of the amount of the spray liquid can be easily performed with a simple operation. Normally, the spray particle size can be switched by adjusting the amount of the chemical solution.For example, the chemical solution adjustment unit is operated so as to have a spray particle size according to the use of the nose and throat, and in conjunction with this, The switching plate can be operated in an interlocked manner so that the spraying direction is in accordance with the above, and the usability of the inhaler is improved as compared with the prior art.

In addition, for example, since the spray particle size can be switched while the switching plate is switched to either the nose or the throat, the user of the inhaler can easily adjust to the intended use and symptoms. An inhaler can be used.

According to the invention of claim 2 , for example, it is possible to automatically prevent the spray temperature from becoming high when the amount of the chemical solution is limited.

According to the invention of claim 3 , the user can use the inhaler in a desired mode by selecting the use mode from preset use modes, and the operation is easy.

According to the invention of claim 4, in the case of repeated use while sequentially switching a plurality of use modes at a predetermined time interval, a complicated mode switching operation or interruption for switching is unnecessary, which is more than conventional. Usability of the inhaler is improved.

  Hereinafter, an inhaler according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows an inhaler 1 according to this embodiment, FIG. 2 shows a block configuration of the inhaler 1, and FIGS. 3 (a) and 3 (b) show the appearance of the inhaler 1. FIG. The inhaler 1 generates water vapor and sprays a chemical solution with the water vapor. The inhaler 1 introduces water supply tank 11 for pouring and storing water, a heater 12 for boiling water W drawn from the water supply tank 11, and water vapor V obtained by boiling by the heater 12 via a steam path 13 a. The liquid ejecting nozzle 13 that generates a negative pressure while being ejected, the chemical liquid cup 14 that stores the chemical liquid P, and the negative pressure generated by the ejecting nozzle 13 absorbs the chemical liquid P that is disposed near the ejection nozzle 13. A chemical nozzle 15 that sucks up the liquid via the tube 15a and sprays the chemical P in a mist form, and an attachment 2 that guides the water vapor from the ejection nozzle 13 and the spray from the chemical nozzle 15 to the mouth and / or the nose. .

  Further, the inhaler 1 is a chemical liquid adjustment that adjusts the amount of chemical sprayed from the chemical liquid nozzle 15 and the switching plate 3 that switches the direction in which the water vapor and the spray liquid are guided inside the attachment 2 to, for example, the directions of arrows a and b. 4 is further provided. For example, the state of the switching plate 3 changes in conjunction with the operation of the chemical liquid adjusting unit 4. The states of the switching plate 3 and the chemical solution adjusting unit 4 are switched according to the intended use. The user of the inhaler 1 operates the chemical liquid adjusting unit 4 by rotating the switching knob 41 (FIGS. 3A and 3B). The user brings his face close to the attachment 2 from the upper left in FIG. 1 and inhales the spray from his mouth or nose. Therefore, the direction of arrow a is generally the direction of the mouth (throat), and the direction of arrow b is generally the direction of the nose.

  Further, the attachment 2 has an outside air circulation port 21 that enables the circulation of outside air between the inside and the outside, and the outside air circulation port 21 is provided by an opening / closing plate 22 that operates in conjunction with the operation of the chemical liquid adjusting unit 4. The opening amount is adjusted. The temperature of the vapor reaching the mouth and nose is adjusted by adjusting the opening amount. 1 and 3A show a state in which the outside air circulation port 21 is closed, and FIG. 3B shows a state in which the outside air circulation port 21 is fully opened. In FIG. 2, the white arrow indicates the movement of the liquid or vapor, and the black arrow indicates that the operation result of the chemical liquid adjusting unit 4 reaches the destination of the arrow, that is, the chemical liquid adjusting unit 4 and the destination of the arrow. Indicates that is linked.

  FIGS. 4, 5A and 5B show a state where the attachment 2 of the inhaler 1, the upper cover of the main body portion of the inhaler 1, and the chemical liquid suction tube 15a are removed. In these drawings, a partial appearance of the chemical liquid adjusting unit 4 and a link mechanism 30 that links the chemical liquid adjusting unit 4 and the switching plate 3 are shown. 4 and FIG. 5A, the switching plate 3 is switched in the direction of the arrow b1, and as a result, the state of the “nasal direction” where the switching plate 3 is raised is shown. In FIG. 5B, the switching plate 3 As a result of switching 3 in the direction of the arrow a1, the state of the “throat direction” in which the switching plate 3 lies is shown.

  Next, a mechanism for switching the switching plate 3 will be described with reference to FIGS. 6 (a), 6 (b), 7 and 8. FIG. The switching plate 3 switches the direction in which the direction is switched in conjunction with the operation of the chemical liquid adjusting unit 4 to guide the water vapor or the spray liquid. The switching plate 3 is fixed to the switching plate rotating shaft 31. The rotating shaft 31 is rotatably fixed to a predetermined position (not shown) of the main body portion of the inhaler 1. The rotating shaft 31 is connected to the switching knob shaft 42 by the link mechanism 30. The switching knob shaft 42 has a rotation axis parallel to the rotation axis 31. The link mechanism 30 is configured by connecting a shaft fixing link 33, a connecting pin 34, a free link 35, a connecting pin 36, and a shaft fixing link 37 in order from the switching knob shaft 42 side. The link mechanism 30 in this example constitutes a crank.

  The above-described switching knob shaft 42 is a part of the chemical liquid adjusting unit 4 and is rotated using a switching knob 41 (not shown). The rotation of the knob 41 and the switching knob shaft 42 is 1: 1, and the rotation angle and the rotation angle of the switching plate 3 are not 1: 1 but have a relationship as shown in Table 1, for example. Such a relationship can be set variously depending on, for example, the configuration of the link mechanism 30 (for example, the configuration of the crank).

  Next, the structure and operation of the chemical liquid adjusting unit 4 will be described with reference to FIGS. The figure shown here has shown the part except the switching board 3 and the link mechanism 30 from FIG. 7, FIG. 8 mentioned above, for example. In the following, description will be given mainly with reference to FIGS. The chemical liquid adjusting unit 4 adjusts the amount of the chemical liquid P sucked up through the suction tube 15a by the negative pressure generated by the ejection nozzle 13 by opening and closing the needle valve. Such a chemical liquid adjusting unit 4 includes a switching knob 41, a switching knob shaft 42, a needle valve body 43, and a needle valve seat body 44.

  At the tip of the needle valve seat body 44, the chemical nozzle 15 is disposed in the vicinity of the ejection nozzle 13. The ejection nozzle 13 is provided on the needle valve seat body 44 by, for example, integral molding. The ejection nozzle 13 is sealed by an O-ring 13b and fixedly connected to the steam passage 13a by an engaging portion 13c (see FIG. 1).

  As described above, the shaft knob link 42 is provided with the shaft fixing link 33. The switching knob shaft 42 can be rotated with respect to the needle valve seat body 44 in a coaxial state with the needle valve seat body 44 so that the engagement flange portion 42b of the switching knob shaft 42 and the needle valve seat body 44 are engaged with each other. It is fixed by the part 44a.

  The needle valve body 43 includes a spiral rib 43a and a rotation prevention protrusion 43b formed on the outer periphery, and an O-ring 43c disposed in the vicinity of the distal needle portion 43d. The rotation preventing projection 43b is fitted into a linear groove 44b provided on the inner surface of the needle valve seat body 44 and slides linearly. The spiral rib 43a is screwed into a spiral groove 42a provided on the inner surface of the switching knob shaft 42, and converts the rotational movement of the switching knob shaft 42 into an axial linear movement.

  A chemical liquid supply opening 15 b is provided in the vicinity of the chemical liquid nozzle 15 in the needle valve seat body 44. The chemical liquid supply opening 15b introduces the chemical liquid P into the needle valve space from the upper end of the chemical liquid suction tube 15a. Therefore, when the switching knob 41 is rotated, the needle valve is opened and closed, and the amount of chemical liquid supplied from the chemical liquid supply opening 15b to the chemical nozzle 15 is increased or decreased. The state shown in FIG. 13 is a state in which the needle valve body 43 has moved to the left limit and the supply of the chemical liquid has been shut off.

  Next, the operation of the inhaler 1 configured as described above will be described in relation to the operation of the switching plate 3 interlocked with the chemical solution adjusting unit 4 and the chemical solution adjusting unit 4. In the inhaler 1, when water vapor is ejected from the ejection nozzle 13, the nozzle tip portion becomes negative pressure, the chemical liquid sucked up by the chemical liquid suction tube 15 a is ejected from the chemical liquid nozzle 15, and this chemical liquid and water vapor are mixed. To become a spray solution. As described above, when the chemical liquid is atomized by the negative pressure generated by the vapor, the particle size of the spray varies depending on the mixing ratio of the chemical liquid and water vapor. Usually, when the amount of chemical liquid is large with respect to the same amount of vapor, the particle size of the spray becomes large, and when the amount of chemical liquid is small, the particle size of the spray becomes small. The spray particle size also changes depending on the angle at which the water vapor from the ejection nozzle 13 strikes the switching plate 3. For example, when the angle is shallow, the particle size becomes large, and when the angle is deep, the particle size becomes small. The smaller the spray particle size, the easier it is for the spray to reach the back of the nose and throat.

  The rotation angle of the switching plate 3 is changed by the link mechanism 30 (crank mechanism) in accordance with the rotation angle of the switching knob 41 of the chemical liquid adjusting unit 4, and at the same time, the position of the needle valve element 43, that is, the chemical liquid supply by the spiral rib 43 a. The throttle amount of the valve for adjusting the amount continuously changes. Thereby, three use modes as shown in Table 2 are realized by three regions of the rotation angle of the switching knob 41.

Table 2 shows the use mode of the inhaler 1, the state of the chemical liquid adjusting unit 4 that realizes each use mode (the state of the switching knob and the amount of chemical liquid supply), and the state of the switching plate 3. “Switching knob” in the table indicates the rotation angle of the switching knob 41 from the initial position. When the position of the switching knob 41 changes from 0 ° to 45 °, the state of the switching plate 3 changes from “throat direction” to “nose direction”, but the spray particle size remains “normal” and does not change. When the position of the switching knob 41 changes from 45 ° to 90 °, the state of the switching plate 3 remains “nose direction” and does not change, but the spray particle size changes from “normal” to “small diameter”.

  Note that when the position of the switching knob 41 is in the vicinity of 90 °, the content of the spray is in a state where “a little spray of the chemical liquid is mixed with water vapor or only steam”. Further, typical dimensions of the spray particle diameter are about 15 μm to about 8 μm in the “throat mode” to “nose mode” and about 4 μm in the “nose clean mode”.

  By the way, the relationship between the rotation angle of the switching knob 41 and the switching plate 3, that is, the relationship between the switching knob 41 and the direction in which the spray liquid is guided is almost arbitrary depending on how the link mechanism 30 is configured as described above. Can be set to Therefore, as a modified example of the inhaler 1 described above, for example, in a structure in which only the water vapor can be sprayed by blocking the path of the chemical liquid by switching the switching knob 41, water vapor or chemical liquid spray (spray liquid) is guided. Without changing the direction of the switching plate 3 for switching the direction, it is possible to block only the path of the chemical solution and spray only the water vapor.

  In the above-described case, for example, when the switching plate 41 is switched so that the spray liquid is directed in the “throat” direction, the chemical liquid is maintained while the switching plate 3 is maintained in the “throat mode” direction. It is possible to switch to the “noble mode” state in which only the water vapor is sprayed. Thus, it can be said that “the spray particle size is switched” in the “state in which the direction in which the spray liquid is guided is fixed to any state of the nose or the nose”.

  As described above, in order to be able to set a plurality of states of the chemical liquid adjustment unit 4 for each state of the switching plate 3, when performing mechanically, for example, a plurality of link mechanisms may be switched. For example, if the link mechanism is switched by an operation of pushing the switching knob, various use modes can be selected by operating one switching knob. That is, in the inhaler 1, the one-touch operation in which the chemical liquid adjusting unit 4 and the switching plate 3 are interlocked can be realized, and the improved operability of the inhaler 1 can be realized.

  Furthermore, operation | movement of the inhaler 1 comprised as mentioned above is demonstrated in relation to the opening amount of the external air circulation port 21. FIG. As described above, the inhaler 1 can spray only water vapor while blocking the path of the chemical solution. By the way, spraying temperature rises when a chemical | medical solution is interrupted | blocked. Therefore, in order to suppress an increase in the spray temperature, the outside air circulation port 21 (see FIG. 5) that allows the outside air to flow between the inside and the outside of the attachment 2 that is a guide portion of the spray to the user's throat and nose. 1) is provided, and the opening amount of the outdoor air circulation port 21 is adjusted in conjunction with the operation of the chemical solution adjusting unit 4. As a result, when the chemical liquid is blocked by the operation of the switching knob 41, the outside air circulation port 21 opens in conjunction with the introduced outside air, and the temperature rise of the spray can be suppressed.

  The above-mentioned operation of the switching knob 41 and the opening / closing operation of the outside air circulation port 21 can be linked using, for example, an urging spring and a wire. That is, by using an urging spring, the opening / closing plate 22 for opening and closing the outside air circulation port 21 is held at the initial position, and when the opening amount of the outside air circulation port 21 is increased, one end is connected to the opening / closing plate 22. The other end of the wire is wound in cooperation with the operation of the switching knob 41. Thereby, the opening / closing plate 22 can be moved to perform the opening operation. Further, by rewinding the wire, the opening / closing plate 22 can be returned to the initial position by the biasing force of the biasing spring.

  Next, an inhaler 1 according to another embodiment of the present invention will be described with reference to FIGS. 14 and 15. Since the basic structure of the inhaler 1 of this embodiment is the same as that of the inhaler 1 shown in FIG. 1, FIG. 1 is also referred to. The inhaler 1 can be used in a desired mode from a usage mode in which a plurality of different combinations are set in advance by combining predetermined states that can be taken by the chemical liquid adjusting unit 4, the switching plate 3, and the outside air circulation port 21 that are linked to each other. In addition to the inhaler 1 shown in FIG. 1, mode selection means 5 for selecting a mode and automatic adjustment means 6 for automatically realizing the state of the use mode selected using the mode selection means 5 I have.

  The mode selection means 5 includes, for example, buttons 51, 52, and 53 for the user to select a use mode and a circuit that outputs a selection result to the automatic adjustment means 6. The automatic adjustment means 6 includes various actuators (not shown) that realize predetermined states that can be taken by the chemical liquid adjustment unit 4, the switching plate 3, and the outside air circulation port 21 in order to automatically realize the state of each mode. And it is comprised using the control apparatus which processes a signal. As the actuator, a conductive motor, an ultrasonic motor, or the like can be used. In addition to this, for example, the automatic adjustment means 6 is configured by combining a shape memory alloy, a relay, a sensor and the like.

  In such an inhaler 1, as shown in FIG. 15, the user selects a mode (S 1), and the automatic adjustment means 6 automatically executes the selected mode (S 2), and spraying in the selected mode occurs. The procedure of (S3) is repeatedly used in sequence. According to the inhaler 1, the user can use the inhaler in a desired mode by selecting the use mode sequentially from the preset use modes, and the operation is easy.

  Next, inhaler 1 according to still another embodiment of the present invention will be described with reference to FIGS. 16 and 17 in addition to FIG. The inhaler 1 of this embodiment is a further automation of the inhaler 1 shown in FIG. Therefore, since the basic structure of the inhaler 1 is the same as that of the inhaler 1 shown in FIG. 1, FIG. 1 is also referred to. This inhaler 1 selects a desired course of use from a course of use in which a plurality of different modes are set in advance so that a plurality of usage modes selected from a plurality of types of usage modes are sequentially repeated at a predetermined time interval. In addition to the inhaler 1 shown in FIG. 14, there are provided means 7 and course execution means 8 for operating the automatic adjustment means 6 to execute the use course selected using the course selection means 7. .

  The course selection means 7 includes, for example, buttons 71, 72, 73 for the user to select a course to be used, and a circuit that outputs a selection result to the course execution means 8. The course execution unit 8 causes the automatic adjustment unit 6 to sequentially execute the use modes included in the selected course. For example, the course execution unit 8 stores a combination of use modes for each course, the automatic adjustment unit 6 and the course selection unit 7. It is configured with equipment that inputs and outputs.

  In such an inhaler 1, as shown in FIG. 17, the user selects a use course (S 11), and the course execution means 8 operates the automatic adjustment means 6 to automatically execute the selected use course. (S12) The spray mode is generated while the selection modes are sequentially switched (S13), and the operation is finished when the series of selection modes of the selection course is completed.

  According to the inhaler 1, the user can use the inhaler in a series of desired modes without selecting a sequential use mode by selecting a desired use course from preset use courses. This is easier to operate than the inhalers 1 of other embodiments described above.

  The present invention is not limited to the above-described configuration, and various modifications can be made. In all the inhalers 1 described above, the chemical liquid stored in the chemical liquid cup 14 is appropriately selected and used according to the purpose of use of the inhaler 1. For example, an aqueous solution in which a chemical is dissolved in water or other liquids can be used, or water alone can be used. Further, the inhaler 1 operates by supplying operating energy from, for example, a commercial power source, a battery, or both. Further, the inhaler 1 is provided with a remote control device, and the user can change the operation of the inhaler 1 by using the remote control device while the inhaler 1 is being used with the mouth or nose facing the attachment 2. You may do it. Further, the opening / closing plate 22 of the outside air circulation port 21 may be automatically operated according to the temperature of the spray liquid using a shape memory alloy, bimetal, or the like.

1 is a cross-sectional view of an inhaler according to an embodiment of the present invention. The block diagram which shows typically the structure of an inhaler same as the above. (A) is a side view of the same inhaler, (b) is an upper plan view of the inhaler. The perspective view from the upper direction except the attachment and cover of an inhaler same as the above. (A) is the perspective view from the upper direction except an attachment and cover of an inhaler same as the above, (b) is a perspective view in the state where the direction of the change board in (a) was changed. (A) is a perspective view of the switching plate of the same inhaler and its peripheral portion, and (b) is an upper plan view of the same portion. The upper top view of the switching plate of the inhaler same as the above, and its peripheral part. The side view of the switching plate of an inhaler same as the above, and its peripheral part. The perspective view of the chemical | medical solution adjustment part of an inhaler same as the above. (A) is a top plan view of the drug solution adjusting portion of the inhaler, and (b) is a cross-sectional view taken along line AA of (a). (A) is a side view of the chemical | medical solution adjustment part of an inhaler same as the above, (b) is the BB sectional drawing of Fig.10 (a). The disassembled perspective view of the chemical | medical solution adjustment part of an inhaler same as the above. Sectional drawing of the chemical | medical solution adjustment part of an inhaler same as the above. The side view of the inhaler which concerns on other embodiment of this invention. The flowchart which shows the usage pattern of an inhaler same as the above. The side view of the inhaler which concerns on other embodiment of this invention. The flowchart which shows the usage pattern of an inhaler same as the above.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Inhaler 2 Attachment 3 Switching plate 4 Chemical liquid adjustment part 5 Mode selection means 6 Automatic adjustment means 7 Course selection means 8 Course execution means 11 Water supply tank 12 Heater 13 Jet nozzle 14 Chemical liquid cup 15 Chemical liquid nozzle 21 Outside air circulation port A Outside air P Chemical liquid V water vapor W water

Claims (4)

A water supply tank for pouring and storing water, a heater for boiling water drawn from the water supply tank, a water jet obtained by boiling by the heater and a jet nozzle for generating negative pressure, and a chemical for storing chemical A cup, a chemical liquid nozzle disposed near the ejection nozzle and sucking up the chemical liquid in the chemical liquid cup at a negative pressure generated by the ejection nozzle and spraying the chemical liquid in a mist, water vapor from the ejection nozzle and the chemical liquid nozzle An inhaler comprising an attachment for directing the spray of
A switching plate for switching a direction for guiding the water vapor and the spray liquid inside the attachment, and a chemical liquid adjusting unit for adjusting the amount of the chemical liquid sprayed from the chemical liquid nozzle,
The switching plate and the chemical solution adjusting unit operate in conjunction with each other ,
The inhaler, wherein the medicinal solution adjusting unit can adjust the medicinal solution amount in a state where the switching plate is fixed in a predetermined direction . The attachment has an outside air circulation port that allows outside air to flow between the inside and the outside, and the opening amount of the outside air circulation port is adjusted in conjunction with the operation of the chemical liquid adjusting unit. The inhaler according to claim 1 . Mode selection means for selecting a desired use mode from a use mode in which a plurality of different combinations are set in advance by combining predetermined states that can be taken by each of the chemical liquid adjustment unit, the switching plate, and the outside air circulation port that are linked to each other. The inhaler according to claim 2 , further comprising: an automatic adjustment unit that automatically realizes the state of the use mode selected using the mode selection unit. Course selection means for selecting a desired course of use from use courses that are set in advance in different combinations so that a plurality of use modes selected from the use modes are sequentially repeated at predetermined time intervals, and the course selection means, The inhaler according to claim 3 , further comprising course execution means for executing the use course selected by using the automatic adjustment means.

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