JP2022054756A - Agent diffuser - Google Patents

Abstract

To improve the effect of an agent in a fan-type agent diffuser.SOLUTION: An agent diffuser has a fan casing 13 having a first air intake and a second air intake disposed on both sides of a centrifugal fan in the rotation axis direction, a first agent cartridge 20 connected to the first air intake, and a second agent cartridge 30 connected to the second air intake.SELECTED DRAWING: Figure 2

Description

The present invention relates to a drug dissipating device that dissipates, for example, a pest control agent or the like into the air.

Conventionally, as disclosed in Patent Documents 1 and 2, for example, a drug dissipating device using a fan driven by a motor has been known. In the drug dissipating device of Patent Document 1, impregnated bodies impregnated with a volatile drug are arranged on the upstream side and the downstream side in the air flow direction, respectively. The airflow formed by rotating the fan passes through the impregnated body on the upstream side to contain the drug, and then further contains the drug as it passes through the impregnated body on the downstream side. After that, the drug can be released by flowing out to the outside.

Further, the drug dissipating device of Patent Document 2 includes a centrifugal fan. A cylindrical drug container containing a drug is connected to the suction side of the centrifugal fan, and air sucked from the outside of the drug container by the action of the centrifugal fan contains the drug in the drug container. The drug can be released by flowing out to the outside.

Japanese Unexamined Patent Publication No. 2013-70654 Japanese Unexamined Patent Publication No. 2004-229852

By the way, in Patent Document 1, the member constituting each impregnated body is a pleated non-woven fabric. The efficacy of the drug can be improved by setting the pleated pitch of the impregnated body and the separation distance between the impregnated body arranged on the upstream side and the impregnated body arranged on the downstream side to a specific value.

However, when a plurality of impregnated bodies are arranged side by side in the air flow direction, the pressure loss when the airflow passes through the plurality of impregnated bodies in order becomes large, and as a result, the amount of air passing through the impregnated body per unit time decreases. There is. That is, the arrangement of two impregnated bodies does not necessarily mean that the amount of the drug emitted can be increased, and the setting of the pitch of the pleats and the separation distance of the impregnated bodies becomes severe, and the two impregnated bodies are used. It may be assumed that it cannot be used effectively.

Further, in Patent Document 2, a cylindrical drug container long in the air suction direction is used, but even when a drug container having such a shape is used, the efficacy of the drug is further improved. There was a request to want.

The present invention has been made in view of this point, and an object of the present invention is to improve the efficacy of a fan-type drug dissipator by a drug.

In order to achieve the above object, the first invention is in a drug dissipator comprising a fan driven by a motor and a drug cartridge through which air flow formed by the fan passes and has a drug cartridge having a volatile drug. The fan is a centrifugal fan, and is sucked from the first air suction port and the second air suction port arranged on both sides in the rotation axis direction of the fan, and the first air suction port and the second air suction port, respectively. The drug is provided with a fan casing having a discharge port for discharging the discharged air, a first connection port connected to the first air suction port, and a first air intake port for taking in air from the outside. It has a first drug cartridge containing a first drug holder to be held, a second connection port connected to the second air suction port, and a second air intake port for taking in air from the outside. It is characterized by comprising a second drug cartridge containing a second drug holder for holding the drug.

According to this configuration, the first drug cartridge and the second drug cartridge are arranged on both sides in the rotation axis direction of the fan, respectively. Then, when the fan rotates, the outside air is taken in from the first air intake port of the first drug cartridge, so that the air containing the drug held in the first drug holder can be obtained. The air containing the chemical is sucked into the fan casing from the first air suction port of the fan casing. Further, when the fan rotates, the external air is also taken in from the second air intake port of the second drug cartridge, so that the air containing the drug held in the second drug holder can be obtained. The air containing the chemical is sucked into the fan casing from the second air suction port of the fan casing.

The air containing the drug sucked into the fan casing from the first drug cartridge and the air containing the drug sucked into the fan casing from the second drug cartridge are both discharged to the outside from the discharge port of the fan casing. This dissipates the drug over a wide area.

In this configuration, the first drug cartridge and the second drug cartridge are not arranged in series in the air flow direction and are connected to the first air suction port and the second air suction port of the fan casing, respectively. The air flowing through the cartridge is not affected by each other. As a result, adverse effects (for example, pressure loss) when arranged in series are reduced, and the amount of air discharged from the discharge port of the fan casing per unit time is increased.

In the second invention, the first drug holder and the second drug holder are formed in a tubular shape, and the axes of the first drug holder and the second drug holder are the rotation axes of the fan. It is characterized in that it is arranged on an extension line of.

That is, as a method of increasing the holding amount of the drug, it is conceivable to lengthen the tubular drug holding body in the axial direction, but in the configuration in which air is sucked from one end thereof, the other end is far from the fan, and in particular, the other The amount of volatilization of the drug held at the end is reduced, and as a result, the efficacy of the drug may not be significantly improved.

On the other hand, according to this configuration, the first drug cartridge and the second drug cartridge can be arranged on both sides in the rotation axis direction on the extension line of the rotation axis of the fan, so that the axial dimension of one drug cartridge is doubled. The amount of volatilization of the drug in each drug carrier is larger than in the case of the above, and as a result, the efficacy of the drug can be improved.

A third aspect of the invention is characterized in that the rotation axis of the fan extends in the horizontal direction, and the first drug cartridge, the fan, and the second drug cartridge are arranged in the horizontal direction.

That is, if the first drug cartridge and the second drug cartridge are arranged on both sides in the rotation axis direction of the fan, the dimensions of the drug dissipator in the rotation axis direction are expanded, and the device is installed in a posture in which the rotation axis direction extends in the vertical direction. Then, the drug dissipator may become unstable. According to this configuration, since the first drug cartridge, the fan, and the second drug cartridge are arranged in the horizontal direction, it is possible to stabilize the drug in a state where the drug dissipating device is installed.

In the fourth aspect of the invention, the fan has a plurality of first blade portions arranged on the first drug cartridge side and a plurality of second blade portions arranged on the second drug cartridge side. The second drug cartridge side of the first blade portion and the first drug cartridge side of the second blade portion are connected and integrated.

According to this configuration, by integrating the first blade portion and the second blade portion, it can be driven by a common motor, and the drive structure can be simplified.

According to a fifth aspect of the present invention, in the drug dissipating device, the discharge port of the fan casing is open toward a direction away from the installation surface of the device, and the first drug cartridge, the fan, and the second drug cartridge are opened. The housing includes a first opening that opens in a portion facing the discharge port, and a second opening that opens in a portion closer to the installation surface than the first opening. It is characterized in that and is formed.

According to this configuration, the air containing the chemicals discharged from the discharge port of the fan casing is blown out toward the direction away from the installation surface through the first opening of the housing, so that the chemicals can be efficiently dissipated over a wide range. On the other hand, air is sucked from the second opening closer to the installation surface than the first opening and supplied to the first air intake port of the first drug cartridge and the second air intake port of the second drug cartridge. Therefore, the air flow can be divided between the discharge side and the intake side, and the air flow becomes smooth.

In the sixth aspect of the invention, the housing is provided with a battery accommodating portion for accommodating a battery for supplying electric power to the motor, and the arrangement direction of the first drug cartridge, the fan, and the second drug cartridge. Is in the width direction of the housing, and the fan and the battery accommodating portion are arranged in the depth direction of the housing.

That is, since the first drug cartridge, the fan, and the second drug cartridge are arranged in the width direction of the housing, the width of the housing is widened. Therefore, if the battery accommodating portions are also arranged in the width direction of the housing, The width of the drug dissipator may become too wide, reducing the degree of freedom during installation. On the other hand, according to this configuration, since the battery accommodating portion and the fan are arranged in the depth direction of the housing, it is possible to suppress the expansion of the width of the drug dissipating device and increase the degree of freedom at the time of installation.

In a seventh aspect of the invention, the first drug cartridge includes a cylindrical main body portion for accommodating the first drug holder, and the axis of the main body portion is arranged on an extension of the rotation axis of the fan. (1) The connection port is formed on one end surface of the main body portion in the axial direction, and a plurality of the first air intake ports are provided on the peripheral wall portion of the main body portion at intervals in the circumferential direction. It is characterized by.

According to this configuration, air can be taken in from a wide range of the peripheral wall part of the main body of the first medicine cartridge, and the medicine is contained in the air in the process of flowing the taken-in air toward one of the axial directions of the main body. Can be done. Then, the air containing the chemicals flows into the fan casing from the first connection port and is discharged from the discharge port. The second drug cartridge can also be configured in the same manner.

According to the present invention, the first drug cartridge and the second drug cartridge are arranged on both sides of the centrifugal fan in the rotation axis direction, and the air containing the drug in each drug cartridge is separately taken into the fan casing and then discharged to the outside. Therefore, it is possible to increase the amount of air discharged from the discharge port per unit time and the amount of volatilization of the drug to enhance the efficacy of the drug.

It is a perspective view which looked at the drug-dissipating apparatus which concerns on embodiment of this invention from above. It is a perspective view which looked at the state which removed the cover of a drug dissipating apparatus from above. It is a top view of the state which the cover of the drug dissipating apparatus is removed. FIG. 2 is a view corresponding to FIG. 2 showing a state in which the right side plate of the fan casing and the right side medicine cartridge are removed. FIG. 3 is a sectional view taken along line VV in FIG. FIG. 3 is a sectional view taken along line VI-VI in FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. It should be noted that the following description of the preferred embodiment is essentially merely an example and is not intended to limit the present invention, its application or its use.

FIG. 1 is a perspective view of a drug dissipating device 1 according to an embodiment of the present invention. The drug dissipating device 1 is a device for dissipating a volatile drug into the air to obtain the effect of the drug. The place where the drug dissipating device 1 is used is not particularly limited, but it can be used in various stores, offices, factories, homes, etc., and may be used outdoors. Examples of the chemicals include pest control agents, pest repellents, insecticides, fragrances, deodorants, disinfectants and the like, but other than these, various chemicals having volatile properties at room temperature (for example, 20 ° C). May be.

As shown in FIGS. 2 and 3, the drug dissipating device 1 includes a blower unit 10, a right drug cartridge (first drug cartridge) 20, a left drug cartridge (second drug cartridge) 30, and a casing for accommodating them. It has a body 40 (shown in FIG. 1). A battery accommodating case portion (battery accommodating portion) 50 is provided inside the housing 40. In each figure, the left-right direction and the depth direction of the drug dissipating device 1 are defined, but this is for convenience of explanation only, and does not limit the actual usage state, the posture at the time of manufacturing, and the like. In this specification, the front side is simply referred to as "front", and the back side may be simply referred to as "rear".

As shown in FIG. 1, the drug dissipating device 1 has a shape that is long in the left-right direction as a whole. That is, the dimension in the left-right direction of the drug dissipating device 1 is set longer than the dimension in the depth direction, and is set longer than the dimension in the height direction. Further, the width direction of the drug dissipating device 1 is the left-right direction. Although not shown, the drug dissipating device 1 may have a long shape in the vertical direction. In this case, the lower drug cartridge, the blower unit, and the upper drug cartridge are arranged in this order in the vertical direction.

The housing 40 includes a lower member 41 constituting the lower portion of the housing 40 and a cover 42 constituting the upper portion of the housing 40. As shown in FIG. 4, the lower member 41 includes a bottom wall portion 41a and a peripheral wall portion 41b extending upward from the peripheral edge portion of the bottom wall portion 41a, and is open upward. On the right side of the bottom wall portion 41a, a plurality of right lower lower openings (second openings) 41c are formed. On the left side of the bottom wall portion 41a, a plurality of left lower lower openings (second openings) are formed as in the case of the right lower lower opening 41c (not shown). The lower right opening 41c and the lower left opening are formed in a slit shape.

In FIG. 1, the floor surface is used as the installation surface. That is, it shows a state in which the drug dissipating device 1 is placed on the floor and the cover 42 is installed so as to face upward. Not limited to this, the cover 42 may be fixed to the ceiling so that the cover 42 faces downward (upside down) with the ceiling surface as the installation surface. Similarly, the wall surface can be used as an installation surface, and the cover 42 can be fixed to the wall so as to project in the horizontal direction. Therefore, the terms "upper", "lower", etc. in this specification are for convenience of explanation only, and do not limit the actual usage state, posture at the time of manufacture, and the like. Regardless of the posture in which the drug dissipating device 1 is installed, it can be said that the lower member 41 is closer to the installation surface than the cover 42.

A plurality of right side opening (second opening) 41e are formed on the right side of the front side portion of the peripheral wall portion 41b. On the left side of the peripheral wall portion 41b, a plurality of left side side openings (second openings) 41f are formed. The right side opening 41e and the left side opening 41f are formed in a slit shape extending in the vertical direction, and are arranged at intervals in the left and right directions.

As shown in FIG. 1, the cover 42 is a member formed so as to cover the open portion of the lower member 41 from above. The lower end of the cover 42 is adapted to fit or engage the upper end of the lower member 41. The cover 42 can be removed from the lower member 41 when the drug cartridges 20 and 30 and the battery 51 described later are replaced.

The shape of the cover 42 is not particularly limited, but for example, it has a shape that bulges upward so that the central portion in the depth direction is located at the top. This is to correspond to the outer shape of the drug cartridges 20 and 30. Further, both the right end portion and the left end portion of the cover 42 extend in the vertical direction, and are located directly above the right side and the left side of the peripheral wall portion 41b of the lower member 41. Both the front end (front end) and the rear end (back end) of the cover 42 extend in the vertical direction, and are located directly above the front and rear sides of the peripheral wall portion 41b of the lower member 41. are doing.

An operation panel 42a is provided on the upper portion of the cover 42 on the front side. The operation panel 42a is provided with a power switch 42b. Further, the operation panel 42a is provided with an operation indicator light 42c that lights up while the blower unit 10 is operating and turns off while the blower unit 10 is not operating.

A plurality of front side openings (first openings) 42d are provided on the front side of the cover 42. The front opening 42d has a long slit shape in the vertical direction, and is arranged at a distance from each other in the left-right direction. The front side opening 42d is provided only in the central portion in the left-right direction of the cover 42, and is arranged so as to correspond between the right side opening 41e and the left side opening 41f.

As shown in FIG. 3, the blower unit 10 is arranged in the central portion in the left-right direction inside the housing 40, and is displaced toward the front side. As shown in FIG. 4, the blower unit 10 has a motor 11, a centrifugal fan 12 driven by the motor 11, and a fan casing 13 that houses the motor 11 and the fan 12. In FIG. 3, the upper part of the fan casing 13 is omitted so that the fan 12 can be seen.

The fan 12 is arranged inside the fan casing 13 in a posture in which the rotation axis extends in the horizontal direction (horizontal direction), and can be configured by, for example, a sirocco fan. Since the rotation axis of the fan 12 extends in the left-right direction, when the fan 12 rotates, air is sucked from the right side and the left side of the fan 12, respectively. The fan 12 causes the sucked air to flow out in the radial direction.

The fan casing 13 includes a scroll-shaped wall portion 13a extending so as to surround the fan 12, a right side plate 13b provided at the right end portion of the scroll-shaped wall portion 13a, and a left side plate 13c provided at the left end portion of the scroll-shaped wall portion 13a. have. The right side plate 13b and the left side plate 13c are detachably configured with respect to the scroll-shaped wall portion 13a, but may be integrally molded with the scroll-shaped wall portion 13a.

The scroll-shaped wall portion 13a, the right side plate 13b, and the left side plate 13c form an air passage 13d in which the air flowing out from the fan 12 in the radial direction collects inside the fan casing 13. As shown in FIG. 5, the starting point of the air passage 13d is near the nose portion 13e, and in this embodiment, it is located in front of the fan 12 below the upper part of the fan 12 and above the lower part. The air passage 13d is formed so as to sequentially pass above, behind, and below the fan 12 from the vicinity of the nose portion 13e, and the downstream side extends diagonally upward toward the front. The downstream end of the air passage 13d is a discharge port 13f for discharging the air sucked into the fan casing 13. That is, the discharge port 13f is formed on the front side of the fan casing 13, and the discharge port 13f opens upward (that is, toward the side away from the installation surface). The front opening 42d of the housing 40 shown in FIG. 1 is open to a portion facing the discharge port 13f, and the air discharged from the discharge port 13f is discharged to the outside from the front opening 42d of the housing 40. Will be done. A plurality of discharge ports 13f may be formed.

As shown in FIG. 3, the fan 12 has a plurality of right side blades (first blades) 12a arranged on the right side medicine cartridge 20 side and a plurality of left side blades (first blades) arranged on the left side medicine cartridge 30 side. It has two blades) 12b. The plurality of right blade portions 12a have a shape extending in the direction of the rotation axis and are arranged at intervals around the rotation axis. The plurality of left blade portions 12b are also shaped to extend in the direction of the rotation axis and are arranged at intervals around the rotation axis. The right side blade portion 12a and the left side blade portion 12b in FIGS. 3 to 5 have the same shape and the same number of blades, but the shape and number of blades may be different on the left and right sides.

The left side medicine cartridge 30 side (left side) in the right side blade portion 12a and the right side medicine cartridge 20 side (right side) in the left side blade part 12b are connected and integrated. Specifically, the right side blade portion 12a and the left side blade portion 12b can be integrally molded with, for example, a resin. As a result, the right side blade portion 12a and the left side blade portion 12b can be rotated around the rotation axis by the common motor 11, so that the drive structure can be simplified. The right side blade portion 12a and the left side blade portion 12b may be configured as separate members and integrated.

The motor 11 is arranged inside the fan 12. As shown in FIG. 4, the motor casing portion of the motor 11 is fixed to the left side of the right side plate 13b, and is fixed to the fan casing 13 in a state of protruding to the left side from the right side plate 13b. The output shaft (not shown) of the motor 11 extends in the horizontal direction (horizontal direction), and the rotation center portion of the fan 12 is fixed to the output shaft. Therefore, the fan 12 is rotatably supported with respect to the right side plate 13b via the motor 11. The motor 11 may be fixed to the left side plate 13c.

As shown in FIG. 4, a right side suction port (first air suction port) 13g is formed in the vicinity of the center of the right side plate 13b. Further, as shown in FIG. 5, a left side suction port (second air suction port) 13h is formed in the vicinity of the center of the left side plate 13c. The right side suction port 13g and the left side suction port 13h are arranged on the same axis and on both sides (right side and left side) in the rotation axis direction of the fan 12, respectively. When the fan 12 rotates, the air outside the fan casing 13 flows into the fan casing 13 from the right suction port 13g due to the airflow formed by the right side blade portion 12a, and the airflow formed by the left side blade portion 12b causes the air outside the fan casing 13 to flow into the fan casing 13. The air outside the fan casing 13 flows into the fan casing 13 from the left suction port 13h.

In this embodiment, the opening shapes of the right side suction port 13g and the left side suction port 13h are slightly different. This is because in the present embodiment, since the motor 11 is fixed to the right side plate 13b, the inside of the fan casing 13 is asymmetrical, so that the bias of the left and right airflow due to the asymmetry is corrected. However, not limited to such circumstances, the right side suction port 13g and the left side suction port 13h may have the same shape.

The right side medicine cartridge 20 and the left side medicine cartridge 30 have a volatile medicine as well as the air flow formed by the fan 12. As shown in FIGS. 2 and 3, the right side medicine cartridge 20 is arranged on the right side of the blower unit 10, and the left side medicine cartridge 30 is placed on the left side of the blower unit 10. The right side medicine cartridge 20, the blower unit 10 (fan 12), and the left side medicine cartridge 30 are arranged in the horizontal direction (left-right direction).

The right-side drug cartridge 20 includes a right-side drug-holding body (first drug-holding body) 21 for holding a drug and a tubular main body 22 for accommodating the right-side drug-holding body 21, and is a ventilation unit in the housing 40. It is housed in the cartridge storage space on the right side of 10. As shown in FIG. 6, the right drug holder 21 is formed in a cylindrical shape. For example, a cylindrical right-side drug holder 21 can be obtained by forming an impregnated body such as a non-woven fabric that can be impregnated with a drug into a pleated shape and then winding the impregnated body into a cylindrical shape. Further, the foaming material having breathability may be held by impregnating it with a chemical agent, and the foaming material may be formed into a cylindrical shape. Further, the resin net-like member may be held by impregnating or applying a chemical, and the net-like member may be formed into a cylindrical shape. The drug carrier can also be referred to as a drug impregnated body.

The main body 22 includes a cylindrical portion 22a into which the right drug holder 21 can be inserted, a closing plate portion 22b that closes the right end surface of the cylindrical portion 22a, and a left end plate portion provided at the left end portion of the cylindrical portion 22a. It has 22c (shown in FIG. 3). A plurality of right air intake ports (first air intake ports) 22d for taking in air from the outside are formed in the cylindrical portion 22a. The plurality of right air intakes 22d are arranged at intervals in the axial direction and also at intervals in the circumferential direction, and are wide from the vicinity of the right end portion to the vicinity of the left end portion of the cylindrical portion 22a. It is formed in the range. As a result, the area where air can be taken in can be expanded.

Although no opening is formed in the block plate portion 22b, an opening may be formed. Further, as shown by a broken line in FIG. 4, the left end plate portion 22c is formed with a right side connection port (first connection port) 22e connected to the right side suction port 13g of the fan casing 13. As shown in FIG. 2, when the right side medicine cartridge 20 is installed at a predetermined position, the right side connection port 22e is connected to the right side suction port 13g of the fan casing 13. As a result, the air flowing into the right side medicine cartridge 20 can flow into the fan casing 13 through the right side connection port 22e and the right side suction port 13g.

Further, the left side medicine cartridge 30 has a symmetrical structure with the right side medicine cartridge 20. For example, the left drug cartridge 30 can be flipped left and right and used as the right drug cartridge 20, or the right drug cartridge 20 can be flipped left and right and used as the left drug cartridge 30. That is, the same drug cartridge can be used as the left drug cartridge 30 and the right drug cartridge 20.

The left-side drug cartridge 30 includes a left-side drug-holding body (second drug-holding body) 31 for holding a drug and a tubular main body portion 32 for accommodating the left-side drug-holding body 31, and is a ventilation unit in the housing 40. It is housed in the cartridge storage space on the left side of 10. Although not shown, the left drug holder 31 is formed in a cylindrical shape.

The main body 32 includes a cylindrical portion 32a into which the left drug holder 31 can be inserted, a closing plate portion 32b that closes the left end surface of the cylindrical portion 32a, and a right end plate portion provided at the right end portion of the cylindrical portion 32a. It has 32c (shown in FIG. 2). A plurality of left air intake ports (second air intake ports) 32d for taking in air from the outside are formed in the cylindrical portion 32a. The plurality of left air intakes 32d are arranged at intervals in the axial direction and also at intervals in the circumferential direction, and are wide from the vicinity of the left end portion to the vicinity of the right end portion of the cylindrical portion 32a. It is formed in the range. As a result, the area where air can be taken in can be expanded.

Although no opening is formed in the block plate portion 32b, an opening may be formed. Further, as shown only partially in FIG. 4, the right end plate portion 32c is formed with a left side connection port (second connection port) 32e connected to the left side suction port 13h of the fan casing 13. As shown in FIG. 2, when the left side medicine cartridge 30 is installed at a predetermined position, the left side connection port 32e is connected to the left side suction port 13h of the fan casing 13. As a result, the air that has flowed into the left side medicine cartridge 30 can flow into the fan casing 13 through the left side connection port 32e and the left side suction port 13h.

In this embodiment, the right side medicine cartridge 20 and the left side medicine cartridge 30 have the same shape and the same structure, but the present invention is not necessarily limited to this. If necessary, the size of the right side medicine cartridge 20 and the left side medicine cartridge 30 can be made different, or different types of medicine holders can be adopted. Further, the right drug cartridge 20 and the left drug cartridge 30 may have different drugs. When the left and right drug cartridges 20 and 30 are different from each other in this way, the optimum airflow may be different on the left and right. In such a case, the right side blade portion 12a and the left side blade portion 12b of the fan 12 may be used. The shape and number of blades can be different from each other. Similarly, the opening area and the opening shape may be different between the right side suction port 13g and the left side suction port 13h. In this way, by making the blades of the fan 12 and the shape of the suction port different on the left and right, different airflows can be realized on the left and right by one fan 12, so that even if the left and right drug cartridges are different, the drug can be used. Optimal emission can be achieved. Further, when the left and right chemicals are different, the left and right chemicals can be mixed and mixed-phase flow by driving the fan 12, and then discharged from the discharge port 13f, which can be expected to create a new effect. ..

When the right side medicine cartridge 20 and the left side medicine cartridge 30 are housed in the cartridge storage space in the housing 40, respectively, the axes of the right side medicine holder 21 and the left side medicine holder 31 are arranged on the extension line of the rotation axis of the fan 12. It has become. As a result, the air in the right side medicine cartridge 20 and the left side medicine cartridge 30 easily flows into the fan casing 13.

As shown in FIGS. 3 and 5, a battery accommodating case portion 50 accommodating a plurality of batteries 51 for supplying electric power to the motor 11 is provided on the inner side of the housing 40. The fan 12 is arranged on the front side of the battery accommodating case portion 50, and therefore, the fan 12 and the battery accommodating case portion 50 are arranged in the depth direction of the housing 40.

The plurality of batteries 51 are arranged in the left-right direction of the housing 40. Corresponding to the arrangement of the batteries 51, the battery accommodating case portion 50 has a long shape in the left-right direction. Further, the longitudinal direction of each battery 51 is a vertical direction in the battery accommodating case portion 50.

(Operation of drug dissipator 1)
When the power switch 42b is pressed, electric power is supplied from the battery 51 to the motor 11 to rotate the motor 11, and power is also supplied to the operation indicator lamp 42c to turn on the operation indicator lamp 42c. When the fan 12 is driven by the motor 11, an air flow is formed in the fan casing 13, and the air flow generates a negative pressure in the vicinity of the right side suction port 13g and the left side suction port 13h. Then, since the right side medicine cartridge 20 is connected to the right side suction port 13g of the fan casing 13 via the right side connection port 22e, a negative pressure also acts in the right side medicine cartridge 20. As a result, air is taken into the right drug cartridge 20 from the right air intake 22d of the right drug cartridge 20. This air is mainly the air that has flowed into the housing 40 from the right lower opening 41c and the right side opening 41e of the housing 40.

The air taken into the right drug cartridge 20 passes through the right drug holder 21. The drug is contained in the air as it passes through the right drug carrier 21. The air containing the drug passes through the right side connection port 22e and the right side suction port 13g of the fan casing 13, passes through the air passage 13d in the fan casing 13, and is discharged from the discharge port 13f.

Further, since the left side medicine cartridge 30 is connected to the left side suction port 13h of the fan casing 13 via the left side connection port 32e, a negative pressure also acts in the left side medicine cartridge 30. As a result, air is taken into the left side medicine cartridge 30 from the left side air intake 32d of the left side medicine cartridge 30. This air is mainly the air that has flowed into the housing 40 from the left lower opening of the housing 40 (the symmetrical position of the 41c: not shown) and the left side opening 41f.

The air taken into the left drug cartridge 30 passes through the left drug holder 31. The drug is contained in the air as it passes through the left drug carrier 31. The air containing the chemicals passes through the left side connection port 32e and the left side suction port 13h of the fan casing 13, passes through the air passage 13d in the fan casing 13, and is discharged from the discharge port 13f.

Since the front opening 42d of the housing 40 is located so as to face the discharge port 13f, the air containing the drug flows out from the front opening 42d and diffuses over a wide range. At this time, the air flow can be divided between the discharge side and the intake side, and the air flow becomes smooth.

(About the airflow flowing through each drug cartridge on the left and right)
As described above, according to this embodiment, since the suction ports 13g and 13h are provided on both sides of the centrifugal fan 12 in the rotation axis direction, the two drug cartridges 20 and 30 are arranged for one fan 13. Can be done. Then, by driving the fan 12, air flows into the drug cartridges 20 and 30 on both sides and the drug volatilizes, but at this time, the air passing through the right drug cartridge 20 does not pass through the left drug cartridge 30. Since the air passing through the left drug cartridge 30 does not pass through the right drug cartridge 20, the airflow flowing through both drug cartridges 20 and 30 is not affected by each other. In this regard, in the prior art in which a plurality of impregnated bodies are stacked and arranged in the air flow direction for one fan as in Patent Document 1, the air that has passed through one impregnated body also passes through another impregnated body. Although there was an adverse effect on the amount of volatilization due to an increase in pressure loss and the like, there is no such adverse effect in the present embodiment.

Since such an effect can be obtained regardless of the shape of the drug cartridge or the type of the impregnated body, it is not limited to the drug cartridges 20 and 30 having a cylindrical drug holder as in the present embodiment, and is not limited to the drug cartridges 20 and 30 as in the present embodiment, for example, as in Patent Document 1. Efficacy can be improved by arranging various types of drug cartridges, such as drug cartridges having various impregnated bodies, on both sides of the centrifugal fan 12.

(About the effect of a cylindrical drug cartridge)
Next, the effect of arranging the drug cartridges 20 and 30 having the cylindrical drug holders on both sides of the fan 12 as in the present embodiment will be specifically described based on the test results.

First, in order to confirm the difference in the amount of drug volatilization in the axial direction of the tubular drug cartridge, the drug holder 21 housed in the right drug cartridge 20 is divided into two at the center portion in the left-right direction, and the right drug cartridge 20 is used. The drug holder is located on the left side of the inside and the drug holder is located on the right side of the right side drug cartridge 20. Similarly, in the left drug cartridge 30, the drug holder 31 housed inside is divided into two at the center in the left-right direction, and the drug holder located on the right side in the left drug cartridge 30 and the left side in the left drug cartridge 30. To be a drug carrier located in. This creates a total of four drug carriers, and each of these drug carriers is impregnated with 3 g (initial amount) of metoflutrin as a volatile drug.

After that, the right side medicine cartridge 20 and the left side medicine cartridge 30 are attached to predetermined positions of the housing 40, and the fan 12 is rotated to volatilize the medicine for a certain period of time. The rotation speed of the fan 12 is about 100 rpm. After a lapse of a certain period of time, the remaining amount of metoflutrin in the four drug carriers is measured, and the amount of volatilization is calculated by subtracting the remaining amount from the initial amount. The environmental temperature is 25 ° C ± 2 ° C, and the above fixed time is about 110 hours. The method for measuring the remaining amount of metoflutrin in the drug carrier is not particularly limited, but for example, the drug carrier is immersed in acetone to extract metoflutrin, and the extract is analyzed by gas chromatography to determine the remaining amount of metoflutrin. There is a way to quantify.

As a result of measurement by the above method, the amount of volatilization on the left side (closer to the fan 12) in the right side drug cartridge 20 was 5.49 mg / hr, whereas the amount of volatilization on the right side (far from the fan 12) in the right side drug cartridge 20 was 5.49 mg / hr. The amount of volatilization on the side) was 0.52 mg / hr. The amount of volatilization on the right side (closer to the fan 12) in the left drug cartridge 30 was 2.86 mg / hr, whereas the amount of volatilization on the left side (far side from the fan 12) in the left drug cartridge 30 was 2.86 mg / hr. It was 0.81 mg / hr. This value is the average value of three times.

That is, the amount of the drug volatilized on the side far from the fan 12 is overwhelmingly smaller than that on the side closer to the fan 12. From this, it can be seen that even if the axial dimension of the drug holder is lengthened, only the portion far from the fan 12 (that is, the portion where the amount of volatilization is small) increases, and the efficacy of the drug does not improve so much. In other words, even if the two drug cartridges 20 and 30 are axially connected and arranged on one side of the fan 12, the efficacy of the drug can hardly be expected to be improved as compared with the case where only one drug cartridge is used. On the other hand, as in the present embodiment, the axial dimension of the drug holder is set to a certain dimension or less, and the drug cartridges 20 and 30 are arranged on the left and right sides of the fan 12, respectively, so that there is only one drug cartridge. It is possible to surely improve the efficacy of the drug as compared with the above.

In the actual drug cartridges 20 and 30, it is considered that the drug on the side far from the fan 12 gradually moves to the side closer to the fan 12 according to the concentration gradient and volatilizes there. Therefore, the drug on the side far from the fan 12 is not wasted. Incidentally, in the above test, there is a difference in the amount of volatilization of the left and right drug cartridges, which is considered to be due to a slight left-right asymmetry in the structure of the drug dissipator 1.
(Drug emission test)
Next, an actual volatilization amount test by the drug dissipating device 1 of this embodiment will be described. The drug-retaining bodies 21 and 31 are formed by forming a non-woven fabric having a basis weight of 40 g / m ² or 60 g / m ² in a pleated shape, and 12 g (initial amount) of metoflutrin as a volatile drug is applied to each to impregnate them. .. Then, the drug holders 21 and 31 were rolled into a cylindrical shape and housed in the drug cartridges 20 and 30, respectively.

After that, the right side medicine cartridge 20 and the left side medicine cartridge 30 are attached to the predetermined positions of the housing 40, the fan 12 is rotated, and after a certain period of time has elapsed, the remaining amount of metoflutrin in the medicine holder is measured, and the remaining amount from the initial amount is measured. Is subtracted to calculate the amount of volatilization. The environmental temperature is 25 ° C ± 2 ° C, and the above-mentioned fixed time is 48 hours. The method for measuring the remaining amount of metoflutrin in the drug carrier is not particularly limited, but for example, the drug carrier is immersed in acetone to extract metoflutrin, and the extract is analyzed by gas chromatography to determine the remaining amount of metoflutrin. There is a way to quantify.

As a result, when a non-woven fabric having a basis weight of 40 g / m ² was used, the total volatilization amount of the two drug cartridges 20 and 30 was 25.09 mg / hr. When a non-woven fabric having a basis weight of 60 g / m ² was used, the total volatilization amount of the two drug cartridges 20 and 30 was 21.16 mg / hr. This value is the average value of three times.

Next, as a comparative example, the same test was performed when there was only one drug cartridge, that is, when only the right drug cartridge 20 was provided for the centrifugal fan 12 (the left suction port 13h was closed). .. As a result, when a non-woven fabric having a basis weight of 40 g / m ² was used, the amount of volatilization of the drug cartridge 20 was 10.56 mg / hr. When a non-woven fabric having a basis weight of 60 g / m ² was used, the amount of volatilization of the drug cartridge 20 was 16.62 mg / hr. This value is the average value of three times.

As described above, it was confirmed that by arranging the drug cartridges 20 and 30 on both sides of the centrifugal fan 12 in the rotation axis direction, the amount of volatilization is improved as compared with the case where only one drug cartridge is used.

(Action and effect of the embodiment)
As described above, according to this embodiment, the right side medicine cartridge 20 and the left side medicine cartridge 30 are arranged on both sides of the centrifugal fan 12 in the rotation axis direction, and the air containing the medicine in each medicine cartridge 20 and 30 is blown. Since the air is separately taken into the fan casing 13 and then discharged to the outside, the amount of air discharged from the discharge port 13f per unit time can be increased to enhance the effectiveness of the drug.

Further, since the right side medicine cartridge 20 and the left side medicine cartridge 30 are arranged on both sides on the extension line of the rotation axis of the fan 12, each medicine holding is performed as compared with the case where the axial dimension of one medicine cartridge is doubled. The amount of volatilization of the drug in the bodies 21 and 31 is increased, and as a result, the efficacy of the drug can be improved.

The above embodiments are merely exemplary in all respects and should not be construed in a limited way. Further, all modifications and modifications belonging to the equivalent scope of the claims are within the scope of the present invention.

As described above, the drug dissipating device according to the present invention can be used, for example, in various stores, offices, factories, homes and the like.

1 Chemical dissipator 10 Blower unit 11 Motor 12 Fan 12a Right blade (first blade)
12b Left blade (second blade)
13 Fan casing 13g Right side suction port (1st air suction port)
13h Left side suction port (second air suction port)
13f Discharge port 20 Right side medicine cartridge (first medicine cartridge)
21 Right drug holder (first drug holder)
22 Main body 22d Right air intake (1st air intake)
22e Right connection port (first connection port)
30 Left drug cartridge (second drug cartridge)
31 Left drug holder (second drug holder)
32 Main body 32d Left air intake (second air intake)
32e Left connection port (second connection port)
40 Housing 41e Right side opening (second opening)
41f Left side opening (second opening)
42d Front opening (first opening)
50 Battery storage case (battery storage)
51 Battery

Claims (7)

With a fan driven by a motor,
In a drug dissipator equipped with a drug cartridge having a volatile drug as the airflow formed by the fan passes through.
The fan is a centrifugal fan.
It has a first air suction port and a second air suction port arranged on both sides in the rotation axis direction of the fan, and a discharge port for discharging air sucked from the first air suction port and the second air suction port. With fan casing,
A first drug cartridge having a first connection port connected to the first air suction port and a first air intake port for taking in air from the outside, and accommodating a first drug holder for holding the drug. When,
A second drug cartridge having a second connection port connected to the second air suction port and a second air intake port for taking in air from the outside, and accommodating a second drug holder for holding the drug. A drug dissipator characterized by being equipped with. In the drug dissipating apparatus according to claim 1,
The first drug holder and the second drug holder are formed in a tubular shape.
A drug dissipating device characterized in that the axes of the first drug holder and the second drug holder are arranged on an extension of the rotation axis of the fan. In the drug dissipating apparatus according to claim 1 or 2.
The axis of rotation of the fan extends horizontally and
A drug dissipating device characterized in that the first drug cartridge, the fan, and the second drug cartridge are arranged in a horizontal direction. In the drug dissipating apparatus according to any one of claims 1 to 3.
The fan has a plurality of first blade portions arranged on the first drug cartridge side and a plurality of second blade portions arranged on the second drug cartridge side.
A drug dissipating device characterized in that the second drug cartridge side of the first blade portion and the first drug cartridge side of the second blade portion are connected and integrated. In the drug dissipating apparatus according to claim 3,
The discharge port of the fan casing is open toward a direction away from the installation surface of the drug dissipating device.
A housing for accommodating the first drug cartridge, the fan, and the second drug cartridge is provided.
The housing is formed with a first opening that opens in a portion facing the discharge port and a second opening that opens in a portion closer to the installation surface than the first opening. Characteristic drug dissipator. In the drug dissipating apparatus according to claim 5.
The housing is provided with a battery accommodating portion for accommodating a battery for supplying electric power to the motor.
The arrangement direction of the first drug cartridge, the fan, and the second drug cartridge is the width direction of the housing.
A drug dissipating device characterized in that the fan and the battery accommodating portion are arranged in the depth direction of the housing. In the drug dissipating apparatus according to any one of claims 1 to 6.
The first drug cartridge includes a cylindrical main body portion for accommodating the first drug holder.
The axis of the main body is arranged on an extension of the rotation axis of the fan.
The first connection port is formed on one end surface of the main body portion in the axial direction.
A drug dissipating device characterized in that a plurality of the first air intake ports are provided on the peripheral wall portion of the main body portion at intervals in the circumferential direction.

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