JP2021142498A - Spray device - Google Patents

Abstract

To provide a spray device that can generate large quantities of fine particles having a fine particle size enough to cause Brownian motion and can be used easily.SOLUTION: The spray device according to the present invention comprises: an atomizing unit which comprises an atomizing tank that can store liquid formulation, an atomizing device that atomizes the liquid formulation to generate fine particles in the atomizing tank and an air blower that generates carrier-air for carrying the fine particles of the liquid formulation; a tank unit, arranged above the atomizing tank, which supplies the atomizing tank with the liquid formulation; a blast-out unit 30 that blasts out the fine particles generated by the atomizing unit together with the carrier-air; and a top member 63 arranged above the tank unit. The top member, in which the blast-out unit is arranged on a top surface, which comprises a top surface recessed part 63C formed downward from the top surface and an openable/closable door part 63d that covers the top surface recessed part, where a liquid formulation replenishment port 63e communicated with the tank unit is formed in the top surface recessed part.SELECTED DRAWING: Figure 5E

Description

The present invention relates to a technique for producing fine particles in a spraying device that sprays a liquid into a space.

Various spraying devices have been developed that atomize water or an aqueous solution having a predetermined effect and spray it into a space.

In such a spraying device, in order to evenly diffuse the fine particles in a wide area, a fine particle having a desired particle size, particularly a particle size small enough to cause Brownian motion in the air, is used. Stable generation is required.

As an example of such a spraying device, it may be necessary to spray a large amount of a liquid agent having a sterilizing effect in a large space such as a hall of a facility for the elderly or a livestock house such as a barn, a piggery, or a poultry house. .. In such a case, if the particle size of the particles is large, they will fall to the floor or the ground before reaching every corner of the space, and will also moisten the floor, walls, and skin, resulting in slippage, mold, and the like. It is not preferable because it causes a cold. Therefore, it is necessary to generate fine particles having a particle size small enough to cause Brownian motion so as to float in the air for a long time and exert a sterilizing effect.

Generally, in order to atomize and spray a liquid, in an atomization unit in which water or an aqueous solution is stored, a liquid column generated by using an oscillator such as an ultrasonic transducer is made to collide with a separator. A technique has been adopted in which large droplets and small mist droplets are separated, and only the mist droplets are conveyed using a conveying medium supplied from a blower or the like and diffused into the air. (Patent Document 1, Patent Document 2)

Japanese Unexamined Patent Publication No. 8-309248 Jitsukaisho 60-50728

According to the techniques disclosed in Patent Document 1 and Patent Document 2, it is possible to obtain a spraying device capable of selectively spraying mist droplets separated from the droplets. However, in the techniques disclosed in Patent Document 1 and Patent Document 2, since air is directly supplied to the region where the liquid column collides with the separator, the flow is disturbed by the air, and even particles having a relatively large particle size are also air. It is caught in and transported. Therefore, the particle size of the fine particles transported to the air and sprayed is on the order of 10 μm, and it is difficult to generate fine particles (particle size of about 0.1 to 2 μm) small enough to cause Brownian motion.

Further, in order to perform an operation of evenly distributing fine particles over a wide space, it is first necessary to promptly start the spraying device, but when starting the spraying device, atomization equipped with an ultrasonic vibrator is provided. It is necessary to promptly supply the liquid agent into the tank. At that time, it is troublesome to directly supply the liquid agent to the atomization tank one by one. Therefore, although some have a sub-tank, there is a problem that if the sub-tank cannot be efficiently replenished with the liquid agent, the spraying device becomes inconvenient to use.

The present invention has been made in view of such a problem, and is used in a spraying apparatus capable of producing a large amount of fine particles having a fine particle size capable of stably causing Brownian motion. It is an object of the present invention to provide a spraying device capable of promptly replenishing a liquid agent to a chemical tank and stably spraying a large amount of liquid agent over a wide range for a long period of time.

The present invention provides the following solutions.

The invention according to the first feature is an atomization tank capable of storing a liquid agent, an atomization device that atomizes the liquid agent in the atomization tank to generate fine particles, and a blower that generates transport air for transporting the fine particles of the liquid agent. An atomization unit equipped with, a tank unit arranged above the atomization tank and supplying a liquid agent to the atomization tank, a blowout unit for blowing out fine particles generated by the atomization unit together with the conveyed air, and a tank unit. The top member is provided with a top member arranged above, and the top member is provided with the blowout unit on the top surface, and the top surface recess formed downward from the top surface and an openable / closable door covering the top surface recess. Provided is a spraying device, which is provided with a portion and has a liquid agent supply port that communicates with a tank unit and is formed in a recess on the top surface.

According to the invention according to the first feature, since the tank unit is provided with the liquid agent replenishment port for replenishing the liquid agent in the top surface recess provided on the top surface of the top member, the liquid agent is replenished from above at a high position of the device. It becomes possible and it is easy to replenish the liquid agent. Further, since the liquid agent replenishment port is covered with the door portion during the spraying operation, it is possible to provide a spraying device having a clean appearance without a risk of foreign matter being mixed into the tank unit.

According to the present invention, even a human resource who is unfamiliar with the work has a fine particle size capable of stably causing Brownian motion without complicated control using an expensive control device. It is possible to provide a spraying device that can generate a large amount of particles and is easy to use.

FIG. 1A is a perspective view of the spraying device 1 according to the present embodiment. FIG. 1B is a front view of the spray device 1 according to the present embodiment with the cover member 80 removed. FIG. 1C is a right side view of the spray device 1 according to the present embodiment with the cover member 80 removed. FIG. 1D is a rear view of the spray device 1 according to the present embodiment with the cover member 80 removed. FIG. 2A is a partially enlarged perspective view of the atomization unit 10 according to the present embodiment. FIG. 2B is a schematic view of the atomization unit 10 according to the present embodiment in a state when it is used. FIG. 3A is a perspective view of the blowout unit 30 of the spray device 1 according to the present embodiment. FIG. 3B is a plan view of the blowout unit 30 of the spray device 1 according to the present embodiment. FIG. 3C is a front view of the blowout unit 30 of the spray device 1 according to the present embodiment. FIG. 3D is a bottom view of the blowout unit 30 of the spray device 1 according to the present embodiment. FIG. 4A is a front view of the installation unit 60 according to the present embodiment. FIG. 4B is a cross-sectional view taken along the line AA of FIG. 4A. FIG. 4C is a bottom view of the base member 61 according to the present embodiment. FIG. 5A is a plan view of the top member 63 according to the present embodiment in a state where the top member cover 63g is removed. FIG. 5B is a cross-sectional view taken along the line AA of FIG. 4D. FIG. 5C is a bottom view of the top member 63 according to the present embodiment. FIG. 5D is a plan view of the top member cover 63 g according to the present embodiment. FIG. 5E is a perspective view of the top member 63 and the blowout unit 30 when the liquid agent is replenished. FIG. 6 is a flowchart of a liquid agent atomizing method using the atomizing device 1 according to the present embodiment. FIG. 7A shows a schematic view of the atomization unit 10 according to the second modification in a state when it is used. FIG. 7B shows a schematic view of the atomization unit 10 according to the third modification in a state when it is used. FIG. 7C shows a schematic view of the atomization unit 10 according to the third modification in a state when it is used. FIG. 7D shows a schematic view of the atomization unit 10 according to the third modification in a state when it is used.

Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. It should be noted that this is only an example, and the technical scope of the present invention is not limited to this.

[Overall configuration of spraying device]
The overall configuration of the spraying device 1 according to the present embodiment will be described with reference to FIG. 1A shows a perspective view, FIG. 1B shows a front view with the cover member 80 removed, FIG. 1C shows a right side view with the cover member 80 removed, and FIG. 1D shows the cover member 80 removed. The rear view of the state is shown. In FIG. 1B, the liquid level sensor 15, the control unit 50, and the power supply unit 70 are omitted, and in FIG. 1C, the power supply unit 70 is omitted.

As shown in FIGS. 1A to 1D, the spraying device 1 of the present embodiment has an atomization unit 10 that atomizes a liquid agent to generate and conveys fine particles, and a tank unit that stores the liquid agent to be supplied to the atomization unit. 20 and the blowout unit 30 that blows out the fine particles generated by the atomization unit 10, the supply unit 40 that sends out the fine particles generated by the atomization unit 10 and supplies the liquid agent to the atomization unit 10, and each device. It is composed of a control unit 50 for controlling, an installation unit 60 for fixing each unit, a power supply unit 70 for supplying power to each device, and a cover member 80 for covering each unit.

Further, in the present embodiment, it is assumed that a chlorous acid aqueous solution having a sterilizing effect is used as the liquid agent, and the spraying device 1 is used as a sterilizing device for killing viruses and bacteria floating in the air. NS.

[Structure of atomization unit 10]
The atomization unit 10 according to the present embodiment will be described with reference to FIGS. 1 and 2. FIG. 2A is a partially enlarged perspective view of the atomization unit 10, and FIG. 2B is a schematic view showing a state when the atomization unit 10 is used.

As shown in FIG. 2A, the atomization unit 10 has an atomization tank 11 having a predetermined width and capable of storing the liquid agent, and an ultrasonic transducer 12a that atomizes the liquid agent in the atomization tank 11 to generate fine particles. , 12b, 12c ... Are provided with an atomizing device 12 in which a plurality of, 12b, 12c ... Are arranged in the width direction and the depth direction, and a blower member (not shown) capable of holding a predetermined number of revolutions. Is arranged so as to receive the blower 13 that discharges into the atomization tank 11 from the blower port 11b provided in the atomization tank 11 and the liquid column of the liquid agent generated by the ultrasonic vibrators 12a, 12b, 12c ... The two baffle plates 14a and 14b to be formed and a liquid level sensor 15 for detecting the liquid level in the atomization tank 11 are provided.

The atomization tank 11 is for storing and atomizing the liquid agent supplied from the tank unit 20, and exhibits a substantially rectangular parallelepiped shape having a predetermined width. A supply port 11a is formed on the top surface 11d of the atomization tank 11, and the liquid agent supplied from the tank unit 20 via the liquid agent supply pump 41 of the supply unit 40 described later is atomized through the supply port 11a. It flows into 11. Further, a blower port 11b is formed on the top surface 11d of the atomization tank 11, and the conveyed air from the blower 13 flows into the atomization tank 11 through the blower port 11b. Further, a delivery port 11c is formed on the top surface 11d of the atomization tank 11, and the fine particles atomized in the atomization tank 11 are sent out from the delivery port 11c together with the conveyed air. The atomization tank 11 is fixed to the lower base 61 of the installation unit 60, which will be described later, by a well-known means such as screwing. At this time, the atomization tank 11 is arranged inside the region defined by the six columnar members 62 of the installation unit 60. The atomization tank 11 is formed of polyethylene terephthalate (PET). Further, in the present embodiment, the top surface 11d of the atomization tank 11 is formed by a top surface member mounted on the main body portion of the atomization tank 11.

The atomizing device 12 is a device including a plurality of ultrasonic vibrators 12a, 12b, 12c ... Arranged at the bottom of the atomizing tank 11, and is operated by the electric power supplied from the power supply unit 70. It emits sound waves. In the atomization device 12 according to the present embodiment, two rows of ultrasonic vibrators 12a, 12b, 12c, 12d, 12e, and 12f are arranged in a plane in the depth direction and three rows in the width direction of the atomization tank 11. The liquid agent is atomized over a wide area in the atomization tank 11 to generate fine particles. When the atomizing device 12 is operated, each of the ultrasonic vibrators 12a, 12b, 12c ... Arranged from the liquid surface is directed upward of the respective ultrasonic vibrators 12a, 12b, 12c ... A liquid column is generated.

The blower 13 is provided with a blower member (not shown) capable of controlling the rotation speed in response to a signal from the control unit 50, and transports air for transporting the atomized liquid agent into the atomization tank 11 through the blower port 11b. A discharge port (not shown) for discharging the conveyed air is connected to the air outlet 11b of the atomization tank 11 and is arranged so as to be able to blow downward. In the present embodiment, the blower 13 is driven by the electric power supplied from the power supply unit 70, and controls the rotation speed by changing the applied voltage according to the signal from the control unit 50.

Next, the two baffle plates 14a and 14b will be described. The baffle plates 14a and 14b are flat plate-shaped members made of stainless steel, and their basic function is to divide the droplets generated by the ultrasonic vibration of the atomizing device 12 into large droplets and small fine particles. be. That is, when a liquid column is generated above the respective ultrasonic vibrators 12a, 12b, 12c ..., the droplets having a large particle size contained in the liquid column collide with the baffle plates 14a, 14b and flow downward to mist. It returns to the liquid layer stored in the conversion tank 11. On the other hand, the mist droplets having a small particle size contained in the liquid column are suspended in the vicinity of the baffle plates 14a and 14b, and are conveyed to the outlet 11c along with the conveyed air supplied by the blower 13. In this way, the baffle plates 14a and 14b can separate the droplets having a large particle size and the mist droplets having a small particle size generated by the ultrasonic vibration.

In addition to such basic functions, the baffle plates 14a and 14b according to the present embodiment are further arranged as follows so as to be able to exert the functions described later.

The baffle plate 14a (first baffle plate in the present invention) according to the present embodiment is an ultrasonic wave arranged below the air outlet 11b and on one end side of the atomizing tank 11 in the width direction of the ultrasonic vibrator. It is arranged above the vibrators 12a and 12d.

Further, the baffle plate 14a has a connection portion 14ac (first connection portion in the present invention) connected to the top surface 11d of the atomization tank 11 at one end, and the other end is on one end side in the width direction of the atomization tank 11. The atomizing tank 11 is inclined diagonally downward toward one end in the width direction so as to have an edge portion 14ae (first edge portion in the present invention) arranged at a predetermined distance from the side surface. ..

The baffle plate 14b (second baffle plate in the present invention) is an ultrasonic wave arranged below the supply port 11a and the delivery port 11c and on the other end side of the atomizing tank 11 in the width direction of the ultrasonic vibrator. It is arranged above the vibrators 12c and 12f.

Further, the baffle plate 14b has a connection portion 14bc (second connection portion in the present invention) having one end connected to the top surface of the atomization tank 11, and the other end is the other end side in the width direction of the atomization tank 11. That is, it is opposite to the baffle plate 14a so as to have an edge portion 14be (second edge portion in the present invention) arranged at a predetermined distance from the side surface opposite to the side on which the baffle plate 14a is arranged. It is arranged so as to be inclined diagonally downward in the direction, that is, toward the other end side in the width direction of the atomization tank 11.

That is, the end portion of the baffle plate 14a is arranged so as to be separated from the side surface on one end side in the width direction of the atomization tank 11 at a predetermined distance, and the end portion of the baffle plate 14b is the side surface on the other end side in the width direction of the atomization tank 11. And are arranged so as to be separated by a predetermined interval.

The air outlet 11b is provided on one end side in the width direction with respect to the connecting portion 14ac of the baffle plate 14a, and the air outlet 11c is provided on the other end side in the width direction with respect to the connecting portion 14bc of the baffle plate 14b.

The liquid level sensor 15 is for detecting the liquid level of the liquid agent stored in the atomization tank 11, and in the present embodiment, a float type sensor arranged outside the atomization tank 11 is used. Will be done. In this case, the atomization tank 11 is provided with a flow hole (not shown) at an appropriate height, and the liquid agent flows into the liquid level sensor 15 through the flow hole. Since the atomization tank 11 and the liquid level sensor 15 connected through the flow hole are placed under the same pressure, the liquid level in the liquid level sensor 15 and the liquid level in the atomization tank 11 have the same value. In this way, the liquid level of the atomization tank 11 is detected by the external liquid level sensor 15, but the liquid level is not limited to this as long as it can be measured. The liquid level sensor 15 in the present embodiment is used to detect a predetermined first liquid level h1 and a second liquid level h2 higher than the first liquid level h1.

Like the liquid level sensor 15, the stop sensor 16 is for detecting the liquid level of the liquid agent stored in the atomization tank 11, but as will be described later, the operation of the spray device 1 is forced. It detects the liquid level for determining that it stops at.

As described above, the atomization tank 11 is arranged inside the region defined by the six columnar members 62 of the installation unit 60, but similarly, each device constituting the atomization unit 10 also has six. It is arranged inside the region defined by the columnar member 62 of the. In other words, when viewed in a plane, the plurality of columnar members 62 are arranged so as to be located on the outermost side, and each device is located inside the region surrounded by the plurality of columnar members 62.

[Structure of tank unit 20]
The tank unit 20 is for temporarily storing the liquid agent to be supplied to the atomization tank 11, and is arranged above the atomization unit 10. The tank unit 20 has a substantially rectangular parallelepiped shape, and an inflow port communicating with a liquid agent supply port 63e of a top member 63, which will be described later, opens on the upper surface. Further, a connection port connected to the liquid agent supply pipe 42 of the supply unit 40 opens on the bottom surface. The tank unit 20 is fixed to the columnar member 62 by a well-known means such as screwing so as to be arranged inside the region defined by the six columnar members 62 of the installation unit 60 described later. At this time, a flange portion may be provided on the outer surface of the tank unit 20 so as to connect to the columnar member 62 at the flange portion. A recess 20a is formed in the substantially central portion of the tank unit 20 in the vertical direction so that the supply pipe 43 for supplying fine particles and transport air from the atomization tank 11 to the blowout unit 30 can pass through the recess 20a. It is composed. The capacity of the tank unit 20 is larger than the capacity of the atomization tank 11, and the liquid agent can be supplied to the atomization tank 11 a plurality of times by supplying the liquid agent to the tank unit 20 once. It is possible to continue driving over time. The tank unit 20 is formed of polyethylene terephthalate (PET) like the atomization tank 11.

[Structure of blowout unit 30]
The balloon unit 30 will be described with reference to FIG. 3A is a perspective view of the blowout unit 30, FIG. 3B is a plan view of the blowout unit 30, FIG. 3C is a front view of the blowout unit 30, and FIG. 3D is a bottom view of the blowout unit 30.

The blowing unit 30 is for blowing out the fine particles generated by the atomizing unit 10 together with the conveyed air, and is installed so as to project upward from the top member 63 arranged at the uppermost portion of the installation unit 60. The blowout unit 30 is formed of a bottomless, substantially tubular blowout member 31 having a predetermined width, depth and height, and is inclined diagonally upward at the upper end and is formed in a slit shape in the width direction. Has. At the lower end of the blowout member 31, a plurality of locking claws (not shown) that can be inserted into the locking recess 63b of the top member 63, which will be described later, are formed.

A partition wall 33 is projected from the inside of the top surface inside the blowout member 31, and by connecting the supply pipe 43 of the supply unit 40 to the area surrounded by the partition wall 33, fine particles from the atomization unit 10 are formed. Conveyed air flows into the blowout unit 30. This point will be described with reference to a plan view of the top member 63 shown in FIG. 5A in a state where the top member cover 63g is removed. The top surface of the top member 63 is connected to the supply pipe 43 of the supply unit 40. Connection port 63a opens. At the same time, a locking recess 63b is formed on the top surface of the top member 63 to which a locking claw portion (not shown) formed at the lower end portion of the blowout unit 30 is locked. Then, when the locking claw portion of the blowout unit 30 is locked in the locking recess 63b of the top member 63, the lower end of the partition wall 33 is sealed and adhered to the periphery of the connection port 63a of the top member 63, and the partition wall 33 is brought into close contact with the partition wall 33. The inner region of 33 and the supply pipe 43 of the supply unit 40 are connected via the connection port 63a.

A slit-shaped spray port 32 inclined diagonally upward is formed at the upper end of the inner region of the partition wall 33, and the fine particles and the conveyed air that have flowed into the inner region of the partition wall 33 from the connection port 63a are sprayed into the spray port 32. Is sprayed from.

[Configuration of supply unit 40]
Returning to FIG. 1, the configuration of the supply unit 40 will be described.

As shown in FIGS. 1B to 1D, the supply unit 40 includes a liquid agent supply pump 41 for supplying the liquid agent stored in the tank unit 20 to the atomization unit 10, and a tank unit 20 connected to the liquid agent supply pump 41. It is composed of a liquid agent supply pipe 42 for flowing a liquid agent between the atomization units 10 and a supply pipe 43 for supplying the fine particles generated by the atomization unit 10 and the conveyed air to the spray unit.

The liquid agent supply pipe 42 connects a connection port (not shown) formed on the bottom surface of the tank unit 20 to the inlet of the liquid agent supply pump 41, and is formed on the outlet of the liquid agent supply pump 41 and the top surface of the atomization tank 11. Connect to the supply port 11a.

That is, by using the liquid agent supply pump 41 and the liquid agent supply pipe 42, the liquid agent stored in the tank unit 20 can be supplied into the atomization tank 11 from the supply port 11a as needed.

In the present embodiment, the tube pump is used as the liquid agent supply pump 41, but the present invention is not limited to this.

The supply pipe 43 connects the delivery port 11c formed on the top surface of the atomization tank 11 with the connection port 63a of the top member 63.

That is, the fine particles generated in the atomization tank 11 are sent out from the delivery port 11c together with the transport air, flow through the supply pipe 43, and are inside the partition wall 32 formed in the blowout unit 30 from the connection port 63a of the top member 63. After flowing into the region, it is sprayed from the spray port 31.

In the present embodiment, the supply pipe 43 is composed of a bellows-shaped flexible tube, but the present invention is not limited to this. Further, the supply pipe 43 passes through a recess in the vertical direction formed in a substantially central portion of the tank unit 20 to connect the delivery port 11c and the connection port 63a.

[Configuration of control unit 50]
The control unit 50 controls the drive of the blower 13 and the drive of the liquid agent supply pump 41, and is composed of a well-known circuit, switch, or the like.

[Configuration of installation unit 60]
The installation unit 60 will be described with reference to FIG. 4A shows a front view of the installation unit 60, FIG. 4B shows a sectional view taken along the line AA of FIG. 4A, and FIG. 4C shows a bottom view of the base member 61.

The installation unit 60 is for fixing each of the above units and members, and is composed of a lower base 61, a plurality of columnar members 62, a top member 63, and a plurality of legs 64.

The lower base 61 is a flat rectangular plate-shaped member located at the lower end of the installation unit 60, and fixes the atomization tank 11 and a plurality of columnar members 62 lower ends. In the present embodiment, the lower base 61 is provided with rising portions 61a protruding upward on the four sides, and at each rising portion 61a, the lower ends of the plurality of columnar members 62 are fixed by screws (not shown). Further, at the four corners of the lower base 61, connection ports 61b for connecting the legs 64 for installing the spray device 1 on the floor surface are provided. A female screw is formed in the connection port 61b, and a male screw portion formed in the leg portion 64 is rotatably connected.

The columnar member 62 is a plurality of columnar members arranged in a substantially vertical direction, and a region inside a region defined by the plurality of columnar members is defined as a region in which each unit is arranged, and each unit is defined. It is a member for fixing. As shown in FIG. 4B, in the present embodiment, six columnar members 62 are used to define an inner region in which each unit is arranged. The lower end of each columnar member 62 is fixed to the rising portion 61a of the lower base 61, and the upper end is fixed to the top member 63 by screwing (not shown). That is, the six columnar members 62 connect the lower base 61 and the top member 63. In addition, in FIG. 4A and FIG. 4B, the thickness of the rising portion 61a and the columnar member 62 is drawn large in order to assist understanding.

Then, in the intermediate portion of the columnar member 62, a fixing portion (not shown) for fixing the tank unit 20, the control unit 50, and the like is arranged.

In particular, above the columnar member 62, a plurality of insertion holes (not shown) into which bolts functioning as one of the fixing portions for fixing the tank unit 20 can be inserted are arranged at the same height, and the tank unit 20 has a plurality of insertion holes. The tank unit 20 can be fixed to the columnar member 62 by screwing the bolt to the female screw portion arranged at a predetermined height.

In this way, by arranging each device in the region surrounded by the plurality of columnar members 62 arranged in the vertical direction, the devices are arranged so as to be stacked in the vertical direction. Since the columnar member 62 is the outermost member when viewed on a flat surface, the cover member 80 described later can be arranged so as to be wound around the columnar member 62. At this time, since the cover member 80 has a shape without unevenness, the spraying device 1 equipped with the cover member 80 can obtain an appearance that gives a neat impression suitable for various environments.

Next, the top member 63 will be described with reference to FIG. 5A is a plan view of the top member 63 with the top member cover 63g removed, FIG. 5B is a sectional view taken along the line AA of FIG. 5A, FIG. 5C is a bottom view of the top member 63, and FIG. 5D is a top member. A plan view of the cover 63 g is shown, and FIG. 5E shows a perspective view of the top member 63 and the blowout unit 30 when the liquid agent is replenished.

The top member 63 is a member located at the uppermost portion of the installation unit 60, and is a member fixed to the upper end portion of each columnar member 62 and also fixes the blowout unit 30 at the uppermost portion of the entire spraying device 1. As shown in FIGS. 5B and 5E, the top member 63 is composed of a bottomless, substantially rectangular tubular member having side walls and rounded corners.

As shown in FIGS. 5A and 5C, a connection port 63a connected to the supply pipe 43 of the supply unit 40 opens on the top surface of the top member 63. At the same time, a locking recess 63b is formed on the top surface of the top member 63 to which a locking claw portion (not shown) formed at the lower end portion of the blowout member 31 is locked.

Further, the top surface of the top member 63 is provided with a top surface recess 63c whose height is locally lowered downward and a door portion 63d that can be opened and closed to cover the top surface recess 63c, and the top surface recess 63c. Is provided with a liquid agent supply port 63e connected to an inflow port (not shown) formed on the upper surface of the tank unit 20. A female screw is formed on the inner surface of the liquid agent supply port 63e, and a cap member (not shown) having a male screw portion is screwed into the liquid agent supply port 63e.

To connect the top member 63 and the plurality of columnar members 62, bolts (not shown) are inserted through a plurality of screw holes 63f provided on the top surface, and the bolts are inserted into the female screw portions (not shown) provided at the upper ends of the columnar members 62. It is done by screwing to. Alternatively, instead of providing the female thread portion on the columnar member 62, a bolt and a nut may be used for connection. After connecting the top member 63 and the columnar member 62, the top surface of the top member 63 is covered with the top member cover 63g shown in FIG. 5D, as shown in FIG. 5E.

[Configuration of power supply unit 70]
The power supply unit 70 is a unit that connects to a household or commercial power source and supplies electric power to each device. Specifically, the power supply unit 70 includes a cable connected to the power strip, a power switch 71 of the spraying device 1 itself, and the like.

[Structure of cover member 80]
The cover member 80 is a member that is arranged around a plurality of columnar members 62 and covers each device.

Specifically, as shown in FIG. 1A, the top member 63 is wound around the plurality of columnar members 62 so as to cover the height from the lower side to the lower base 61. The cover member 80 is formed by bending an elastic stainless steel plate-shaped member by bending.

Here, in configuring the spraying device 1, since each device such as the atomizing unit 10 and the tank unit 20 is arranged in the area surrounded by the plurality of columnar members 62 arranged in the vertical direction, it is flat. When viewed, the columnar member 62 is arranged on the outermost side. Therefore, the cover member 80 can be arranged so as to be wound around the columnar member 62. At this time, since the cover member 80 has a shape without unevenness, the spraying device 1 equipped with the cover member 80 can obtain an appearance that gives a neat impression suitable for various environments.

[Spraying method using spraying device 1]
Next, a method of atomizing the liquid agent using the atomizing device 1 according to the present embodiment will be described with reference to the flowchart shown in FIG.

[Step S100: Replenishment of liquid agent]
First, prior to starting the atomizing device 1, the tank unit 20 is replenished with a liquid agent (step S100).

When replenishing the liquid agent to the tank unit 20, the user opens the openable / closable door portion 63d provided on the top surface of the top member 63, removes the cap (not shown) attached to the liquid agent replenishment port 63e, and replenishes the top surface recess. The liquid agent is poured into the liquid agent supply port 63e formed in 63c. After replenishing the liquid, close the cap and close the door 63d.

In this way, since the liquid agent supply port 63e is covered with the door portion 63d that can be opened and closed, the liquid agent supply port 63e can be covered with the door portion 63 when not in use, and a neat appearance can be maintained. In particular, since the liquid agent supply port 63e is formed in the top surface recess 63c, when the door portion 63d is closed, the top surface of the top member 63 has the same plane except for the blowout unit 30, so that the appearance is particularly excellent. can.

[Step S110: Start of supply of liquid agent]
When the tank unit 20 is replenished with the liquid in step S100, the user connects a power cord (not shown) constituting the power supply unit 70 to a general household or commercial power supply, and similarly, a power supply constituting the power supply unit 70. Turn on the switch 71. When the power switch 71 is turned on, the control unit 50 operates the liquid agent supply pump 41 and starts supplying the liquid agent charged into the tank unit 20 to the atomization tank 11 (step S110).

The liquid agent stored in the tank unit 20 is supplied to the atomizing tank 11 as follows. That is, the liquid agent supply pump 41 is driven by the signal from the control unit 50, and the liquid agent flows out from the connection port (not shown) formed on the bottom surface of the tank unit 20 accordingly, and passes through the liquid agent supply pipe 42 and the liquid agent supply pump 41. It flows into the atomization tank 11 from the supply port 11a formed on the upper surface of the atomization tank 11.

[Steps S120 to S130: Judgment of the second liquid level-Stopping the supply of the liquid agent]
At the same time when the supply of the liquid agent is started in step S110, the control unit 50 starts determining the liquid level by the liquid level sensor 15, and has the liquid level in the atomization tank 11 reached a predetermined second liquid level h2? Is determined (step S120).

When the liquid level detected by the liquid level sensor 15 does not reach the second liquid level h2, that is, when N in step S120, the control unit 50 continues the supply by the liquid agent supply pump 41 and reaches the second liquid level h2. In the case, that is, when it becomes Y in step S120, the control unit 50 stops the supply by the liquid agent supply pump 41 (step S130).

[Step S140: Atomization of liquid agent]
When the supply of the liquid agent is stopped in step S130, the control unit 50 starts atomization of the liquid agent in the atomization unit 10 (step S140). The start of the atomization operation in step S140 may be controlled so that the liquid level detected by the liquid level sensor 15 reaches the first liquid level h1 as a trigger. In that case, the atomization operation and the supply of the liquid agent are performed at the same time, but it is preferable that the atomization operation can be started at an early stage.

When atomizing the liquid agent in the atomizing unit 10, the control unit 50 starts blowing the conveyed air by the blower 13 and also starts atomizing the liquid agent by the atomizing device 12.

As the atomizing device 12 operates, as shown in FIG. 2B, a liquid column rises above the ultrasonic vibrators 12a, 12b, 12c ... The liquid column contains particles having various particle sizes, and the liquid is opposed to the baffle plates 14a and 14b which are arranged so as to be inclined diagonally downward above the ultrasonic vibrator so that the liquid column comes into contact with the liquid column. Large-sized droplets contained in the column come into contact with each other and flow downward to return to the stored liquid layer, and only small-sized mist droplets float in the air.

Further, as the blower 13 operates, the conveyed air is supplied downward from the blower port 11b, and the mist droplets having a small particle size floating in the air are conveyed and sent out from the outlet 11c.

At this time, the baffle plate 14a provided on one end side in the width direction of the atomization tank 11 is arranged below the air outlet 11b and above the ultrasonic vibrators 12a and 12d on one end side in the width direction. Therefore, the conveyed air supplied from the blower 13 is prevented from directly reaching the liquid level or the liquid column, and the liquid column or the droplet rising from the liquid surface flows in from the blower port 11b and directly reaches the blower 13. Is prevented. Therefore, the atomization of the liquid agent and the supply of the conveyed air function without interfering with each other, thereby ensuring the performance of selecting the particle size of the particles.

Further, the conveyed air supplied from the blower 13 collides with one side surface of the baffle plate 14a and flows along the one side surface of the baffle plate 14a, so that a pressure loss occurs at that time and the particles are conveyed. The pressure to do is reduced. Since the pressure of the transport air decreases, from the liquid agent separated into droplets and small particles by colliding with the baffle plates 14a and 14b, only fine particles smaller than the particles that are normally large enough to be transported are transferred air. Transported by.

Further, when the conveyed air flowing along one side surface of the baffle plate 14a flows out from between the edge portion 14ae and one end side surface of the atomization tank 11, the other side surface of the baffle plate 14a, that is, A negative pressure region is formed in the region where the liquid column contacts, but since the pressure of the transport air is further reduced in the negative pressure region, only fine particles having a very small particle size cannot be transported. It will fall to the lower liquid level. Therefore, only fine particles having a particle size small enough to cause Brownian motion are transported to the downstream side by the transport air.

With such a mechanism, fine particles can be transported by transport air rather than simply receiving a liquid column on a baffle plate, and only fine particles small enough to cause Brownian motion can be selectively sprayed. A spraying device can be provided.

Further, the baffle plate 14a has a connection portion 14ac (first connection portion) having one end connected to the top surface 11d of the atomization tank 11, and the other end is defined as a side surface on one end side in the width direction of the atomization tank 11. It is arranged so as to be inclined diagonally downward so as to have an edge portion 14ae (first edge portion) that separates the above. Then, the conveyed air supplied from the blower 13 is arranged so as to project from the inside to the outside so as to pass through the outer peripheral side in the atomization tank 11.

Due to such a structure of the baffle plate 14a, the conveyed air supplied downward from the air outlet 11b changes the flow direction diagonally downward according to the arrangement direction of the baffle plate 14a, and is located on one end side of the atomization tank 11. It passes through the gap formed between the side surface and the edge portion 14ae of the baffle plate 14a and reaches the bottom portion near the liquid layer of the atomization tank 11. The conveyed air that has reached the bottom changes direction toward the side surface on the other end side, and circulates in the vicinity of the liquid level toward the side surface on the other end side of the atomization tank 11. Then, the direction is changed upward near the side surface on the other end side of the atomization tank 11, and the flow is directed toward the delivery port 11c formed on the top surface 11d. Further, a part of the conveyed air passes through the gap formed between the side surface on one end side of the atomization tank 11 and the other end portion of the baffle plate 14a, and then reaches the surface on the side receiving the liquid column of the baffle plate 14a. After wrapping around, a swirling flow is formed in the atomization tank 11 and flows out from the delivery port 11c.

In this way, the conveyed air supplied downward from the air outlet 11b forms a gentle swirling flow inside the atomization tank 11 according to the arrangement direction of the baffle plate 14a, and a part of the conveyed air is on the side that receives the liquid column. After wrapping around the surface of the surface, a part of the liquid passes through the outer peripheral side of the atomization tank 11 and is sent out from the delivery port 11b.

Then, the conveyed air supplied from the air outlet 11b passes through the outer peripheral side of the atomization tank 11 to form a gentle swirling flow, so that fine particles and further fine particles are further affected by the effect of centrifugal force accompanying the generation of the swirling flow. It is separated into fine particles, and only the fine particles are transported to the transport air.

Further, in the present embodiment, the air outlet 11b and the air outlet 11c are provided on the top surface 11d of the atomization tank 11 and on opposite sides of the baffle plate 14a.

Therefore, a swirling flow sandwiching the baffle plate 14a can be formed, and the effect of centrifugation by the swirling flow can be enhanced.

In this way, the atomization unit 10 in the present embodiment selectively generates and sends out only fine particles small enough to cause Brownian motion by the cooperation of the blower 13 and the baffle plate 14a. Can be done.

Further, in the present embodiment, one end of the baffle plate 14b has a connecting portion 14bc (second connecting portion) connected to the top surface of the atomizing tank 11, and the other end is in the width direction of the atomizing tank 11 and the like. Diagonally downward in the direction opposite to the baffle plate 14a so as to have an edge portion 14be (second edge portion) that separates a predetermined distance from the side surface on the end side, that is, the side opposite to the side on which the baffle plate 14a is arranged. It is arranged so that it faces.

The baffle plate 14b is arranged below the delivery port 11c and above the ultrasonic vibrators 12c and 12f on the other end side in the width direction. Therefore, droplets having a large particle size contained in the liquid column generated by the ultrasonic vibrators 12c and 12f come into contact with the lower surface of the baffle plate 14b and flow downward, return to the stored liquid layer, and have a particle size. Only small fog droplets float in the air.

At this time, since the pressure of the transport air is lowered by the contact with the baffle plate 14a, only fine particles smaller than the particles having a size that can be normally transported are transported by the transport air. In this way, even for the particles generated in the vicinity of the baffle plate 14b, only the fine particles having a small particle size can be selected and conveyed.

Further, the air outlet 11b is provided on the top surface 11d of the atomization tank 11 on one end side in the width direction with respect to the connection portion 14ac of the baffle plate 14a, and the air outlet 11c is the other end in the width direction with respect to the connection portion 14bc of the baffle plate 14b. By being provided on the side, the swirling flow formed in the atomization tank 11 becomes a large one formed over the entire inside of the atomization tank 11 with the baffle plate 14a and the baffle plate 14b interposed therebetween. Therefore, the selection of fine particles by the centrifugal force of the transport air is further strengthened, and only fine particles that are fine enough to cause Brownian motion can be reliably selected and sprayed.

[Steps S150 to S160: Judgment of First Liquid Level-Start of Replenishment of Liquid Agent]
Return to the flowchart of FIG. When atomization of the liquid agent is started in step S140, the control unit 50 starts determining the liquid level by the liquid level sensor 15, and determines whether the liquid level in the atomization tank 11 is lower than the first liquid level h1. Determine (step S150).

When the liquid level detected by the liquid level sensor 15 can secure the first liquid level h1, that is, when N in step S150, the control unit 50 continues atomization as it is and falls below the first liquid level h1. That is, when it becomes Y in step S150, the control unit 50 starts replenishing the liquid agent by the liquid agent supply pump 41 (step S160).

The replenishment of the liquid agent in step S160 is performed by operating the liquid agent supply pump 41 in the same manner as in step S110. In this case, the atomizing tank 11 can be replenished with the liquid agent by the liquid agent supply pump 41 at the same time while continuing the atomization operation.

In particular, since the supply port 11a is formed above the baffle plate 11b, the liquid agent supplied from the supply port 11a falls on the liquid layer stored in the atomization tank 11 in a liquid state along the baffle plate 11b. do. That is, the liquid agent supplied from the supply port 11a is replenished in the liquid layer without being affected by the ultrasonic vibration. Therefore, the liquid agent can be replenished without affecting the sorting performance of the fine particles in the present embodiment.

[Steps S170 to S180: Judgment of the second liquid level-Stopping the supply of the liquid agent]
At the same time when the replenishment of the liquid agent is started in step S160, the control unit 50 starts determining the liquid level by the liquid level sensor 15, and the liquid level in the atomization tank 11 is higher than the predetermined first liquid level h1. It is determined whether the two-liquid level h2 has been reached (step S170).

When the liquid level detected by the liquid level sensor 15 does not reach the second liquid level h2, that is, when N in step S170, the control unit 50 continues the supply by the liquid agent supply pump 41 and reaches the second liquid level h2. In the case of Y, that is, in the case of Y in step S170, the control unit 50 stops the supply by the liquid agent supply pump 41 (step S180).

After that, the process may be returned to step S150 again until the power switch 71 is turned off by the user, and control may be performed so that the process from the determination of the first liquid level to the supply of the liquid agent is repeated.

By doing so, the liquid level of the liquid agent in the atomization tank 11 can be maintained between the first liquid level h1 and the second liquid level h2, and the user does not have to worry about the increase or decrease of the liquid level. , It is possible to automatically continue the operation for a long time.

Further, the control unit 50 may be configured to constantly use the stop sensor 16 to determine whether or not the temperature falls below the third liquid level h3, which is lower than the first liquid level h1. When the stop sensor 16 detects that the liquid level has fallen below the third liquid level h3, the control unit 50 immediately stops the operation of the blower 13 and the atomizing device 12.

By doing so, it is possible to suppress the operation of the atomizing device 12 in a situation where the amount of the liquid agent is extremely low, and to prevent so-called dry heating.

Further, at this time, the control unit 50 may be configured to notify the user that the heating state has been reached by sounding an alarm sound or turning on the warning light at the same time as stopping the operation. By doing so, the user can recognize that the heating state has been reached.

[Adjustment of particle size using spraying device 1]
Next, a method of adjusting the particle size of the fine particles to be sprayed using the spraying device 1 in the present embodiment to a desired value will be described.

As described above, the control unit 50 can control the rotation speed of the blower member of the blower 13 by controlling the voltage applied to the blower 13. Then, by increasing the rotation speed of the blower member, the particle size of the fine particles sprayed from the spray port 32 can be reduced. On the contrary, by lowering the rotation speed of the blower member, the particle size of the fine particles sprayed from the spray port can be increased. The mechanism capable of changing the particle size of the sprayed particles according to the change in the rotation speed of the blower member will be described below.

Generally, when the rotation speed of the blower member is controlled, the air volume changes as the rotation speed changes. For example, increasing the rotation speed of the blower member increases the air volume, and decreasing the rotation speed decreases the air volume. However, since the wind pressure itself does not change, the transport capacity of the transport air does not change, and the particle size of the transportable particles cannot be changed by changing the rotation speed.

On the other hand, in the present invention, since the air outlet 11b of the conveyed air supplied from the blower 13 is arranged above the baffle plate 14a, the conveyed air supplied from the air outlet 11b is on one side of the baffle plate 14a. It collides with the surface and causes pressure loss.

If the rotation speed of the blower member is controlled in a state where the pressure loss of the transport air is caused, the change in the wind pressure can be made larger with respect to the change in the air volume of the transport air. For example, when the rotation speed of the blower member is increased, the air volume of the conveyed air increases, so that the pressure loss generated by the contact with the baffle plate 14a increases, so that the pressure of the conveyed air decreases and the particles are conveyed. The ability to do is reduced. Therefore, particles having a smaller particle size are transported than before the rotation speed is changed.

On the contrary, when the rotation speed of the blower member is lowered, the air volume of the conveyed air is reduced and the pressure loss generated by the contact with the baffle plate 14a is reduced, so that the pressure of the conveyed air is increased and the particles are conveyed. Ability improves. Therefore, particles having a larger particle size are transported than before the rotation speed is changed.

In this way, the particle size of the particles that can be transported can be changed by utilizing the increase or decrease in the pressure loss.

Further, in the present embodiment, the conveyed air passes through the gap formed between the edge portion 14ae of the baffle plate 14a and the atomization tank 11, and then wraps around the surface of the baffle plate 14a on the side receiving the liquid column. Since the air reaches the outlet 11c, a gentle swirling flow of the conveyed air toward the outlet is formed around the baffle plate 14a.

Then, by controlling the rotation speed of the blower member, the air volume changes, so that the centrifugal force applied to the atomized particles changes, that is, the particle size of the particles that can be conveyed can be changed. For example, when the rotation speed of the blower member is increased, the air volume of the conveyed air is increased, so that the centrifugal force applied to the particles accompanying the swirling flow is increased and the particles having a relatively small particle size are separated. , Only particles with very small particle size will be transported.

On the contrary, when the rotation speed of the blower member is lowered, the air volume of the conveyed air is reduced and the centrifugal force applied to the particles accompanying the swirling flow is reduced, so that the ability to separate the particles is weakened and the particle size is large. Particles can also be transported.

In this way, by controlling the rotation speed of the blower member of the blower 13 by the control unit 50, it is possible to spray fine particles having a desired particle size from the spray port 32.

<Modification example 1>
In step S110 of the flowchart shown in FIG. 6, the liquid agent is supplied from the tank unit 20 to the atomization tank 11 by using the liquid agent supply pump 41, but the liquid agent is supplied by using a solenoid valve instead of the liquid agent supply pump 41. It can also be configured to supply.

That is, an electromagnetic valve that can be opened and closed by a signal from the control unit 50 is arranged in the middle of the liquid agent supply pipe 42, and when an open signal is emitted from the control unit 50, the solenoid valve is opened to supply the liquid agent. At this time, since the tank unit 20 is arranged above the atomization tank 11, the liquid agent can be supplied by gravity, which is faster than using the liquid agent supply pump 41 and consumes less power. The liquid agent can be supplied without need. In particular, by supplying the liquid agent to the atomization tank 11 at the time of starting by using gravity, the time from turning on the power switch 71 to the start of atomization can be shortened, which is a convenient spraying device. 1 can be provided.

<Modification 2>
A modified example of the configuration of the atomization unit 10 will be described with reference to FIG. 7. Instead of arranging the baffle plates 14a and 14b so as to be inclined diagonally downward, they can be arranged vertically downward from the top surface and then bent horizontally toward the side surface of the atomization tank 11. ..

In particular, as shown in FIG. 7A, the baffle plate 14a is hung vertically downward from the top surface 11d and then bent horizontally toward the side surface of the atomization tank 11 on one end side in the width direction to atomize the edge portion 14ae. The tank 11 is arranged at a predetermined distance from the side surface on one end side in the width direction. By doing so, similarly to the above, the conveyed air from the blower 13 can be brought into contact with the one side surface of the baffle plate 14a to cause a pressure loss. As a result, a spraying device capable of transporting only fine particles from a liquid column in contact with the other surface of the baffle plate 14a and selectively spraying only fine particles small enough to cause Brownian motion. 1 can be provided.

Further, even if the baffle plate 14a has such a configuration, the conveyed air passes between the edge portion 14ae and the side surface on one end side in the width direction of the atomization tank 11 and passes below the baffle plate 14a, so that the atomization tank 11 A swirling flow can be formed inside. As a result, by utilizing the effect of separation by centrifugal force, only fine particles can be transported from the liquid column in contact with the other surface of the baffle plate 14a, and only fine particles small enough to cause Brownian motion can be transported. It is possible to provide a spraying device 1 capable of selectively spraying.

<Modification example 3>
The air outlet 11b and the air outlet 11c can be arranged on the side surface of the atomization tank 11 instead of the top surface 11d.

As shown in FIG. 7B, even when the air outlet 11b is arranged on the side surface of the atomization tank 11 on one end side in the width direction, if it is arranged above the position of the edge portion 14ae, the air outlet 11b Since the transfer air flowing in from the baffle plate 14a comes into contact with the baffle plate 14a, a pressure loss of the transfer air can be caused, and the same effect as described above can be obtained.

Further, as shown in FIG. 7C, even when the delivery port 11c is arranged on the side surface on the other end side in the width direction of the atomization tank 11, if it is arranged above the position of the edge portion 14bc, it is sufficient. A swirling flow can be formed in the atomization tank 11, and the same effect as described above can be obtained.

Further, as shown in FIG. 7D, the position where the air blower port 11b is arranged may be arranged at a position where the blown air is not in contact with the baffle plate 14a. Even in such a case, the conveyed air passes between the side surface of the atomization tank 11 on one end side in the width direction and the edge portion 14ae and passes under the baffle plate 14a, so that a swirling flow is generated in the atomization tank 11. It can be formed and the same effect as described above can be obtained.

In this way, even if the arrangement and shape of the baffle plates 14a and 14b are changed, or the arrangement of the air outlet 11b and the outlet 11c is changed, the phenomenon described in the present invention can occur. If it is, it is included in the scope of the present invention.

The effects of the present invention described above can be summarized as follows.

A baffle plate 14a arranged so as to receive a liquid column of a liquid agent generated by the ultrasonic vibrators 12a and 12d arranged on one end side in the width direction of the ultrasonic vibrator, and a baffle plate 14a arranged on the other end side in the width direction. In order to provide a baffle plate 14b arranged so as to receive a liquid column of the liquid agent generated by the ultrasonic vibrators 12c and 12f, the baffle plates 14b are arranged above the ultrasonic vibrators 12a, 12b, 12c ... When the liquid column comes into contact with the baffle plates 14a and 14b, droplets having a large particle size contained in the liquid column come into contact with the baffle plates 14a and 14b and flow downward to return to the stored liquid layer. Only small-sized mist droplets float in the air in large quantities and are transported to the transport air.

At this time, the baffle plate 14a includes an edge portion 14ae arranged at a predetermined distance from the inner surface on one end side in the width direction of the atomization tank 11, and a connection portion 14ac connected to the inside of the atomization tank 11. The air outlet 11b is arranged closer to one end side in the width direction of the atomization tank 11 than the connection portion 14ac, and the baffle plate 14b is arranged at a predetermined distance from the inner surface of the other end side in the width direction of the atomization tank 11. The edge portion 14be and the connection portion 14bc connected to the inside of the atomization tank 11 are provided, and the outlet 11c is arranged closer to the other end side in the width direction of the atomization tank 11 than the connection portion 14bc. A large swirling flow is formed in the atomization tank 11 with the baffle plate 14a and the baffle plate 14b interposed therebetween. Therefore, due to the effect of centrifugal force accompanying the generation of swirling flow, it is separated into fine particles and finer fine particles, and only fine fine particles that can cause Brownian motion are surely selected and sprayed in large quantities. It is possible to provide a spraying device 1 capable of capable.

Further, since the baffle plate 14a is arranged so that the transport air supplied from the air outlet 11b comes into contact with one side surface of the baffle plate 14a, a pressure loss occurs at that time, and the pressure for transporting the particles decreases. do. Since the pressure of the transport air decreases, only fine particles smaller than the particles that are normally large enough to be transported are transported by the transport air from the liquid agent separated into droplets and small particles by colliding with the baffle plate 14a. can do.

Further, since the outlet 11c is arranged on the opposite side of the air outlet 11b with respect to the connection portion 14ac of the baffle plate 14a, the conveyed air in contact with the baffle plate 14a is atomized with the edge portion 14ae of the baffle plate 14a. It reaches the delivery port 11c through a gap formed between the tank 11 and the inner surface. At that time, a negative pressure region is formed on the back side of the surface of the baffle plate 14a where the transport air contacts, that is, a region where the liquid column contacts, and the pressure of the transport air further decreases in the negative pressure region. Only fine particles with a very small diameter can be transported and fall to the liquid surface below. Therefore, only fine particles having a particle size small enough to cause Brownian motion can be conveyed to the outlet 11c side by the conveying air.

Further, after the conveyed air supplied from the air outlet 11b passes through the gap formed between the edge portion 14ae of the baffle plate 14a and the atomization tank 11, it wraps around the surface on the side receiving the liquid column. Since it reaches the delivery port 11c, a gentle swirling flow of the conveyed air toward the delivery port 11c is formed around the baffle plate 14a. When the fine particles separated from the droplets by the liquid column colliding with the baffle plate 14a are transported to the transport air, due to the effect of the centrifugal force accompanying the generation of the swirling flow, the fine particles and the finer fine particles are separated. And only the fine particles are transported to the transport air. In this way, it is possible to provide a spraying device capable of sending only fine particles together with the conveying air from the delivery port 11c by the effect of the baffle plate 14a and the effect of the swirling flow.

Further, since the air outlet 11b and the air outlet 11c are provided on the top surface 11d on opposite sides of the baffle plate 14a, respectively, a swirling flow sandwiching the baffle plate 14a can be formed, and centrifugation by the swirling flow can be formed. Since the effect of separation can be enhanced, it is possible to provide a spraying device 1 capable of spraying only fine particles having a smaller particle size.

Further, the direction in which the baffle plate 14a blocks the liquid column generated by the ultrasonic vibrators 12a and 12d and the conveyed air supplied from the air outlet 11b above the ultrasonic vibrators 12a and 12d and below the air outlet 11b. Since it is arranged in, it is possible to prevent the liquid column generated by the action of the ultrasonic vibrators 12a and 12d from being directly blown into the blower 13, and the conveyed air from the blower 13 is directly blown onto the liquid column. Can be prevented. Therefore, it is possible to provide the spraying device 1 capable of transporting only fine particles by transport air without impairing the particle sorting effect of the baffle plate 14a.

Further, when the liquid level in the atomization tank 11 falls below the predetermined first liquid level h1, the supply of the liquid agent stored in the tank unit 20 is controlled to start, and when the liquid level reaches the predetermined second liquid level h2. Since the supply is stopped, the liquid level in the atomization tank 11 is maintained between the first liquid level h1 and the second liquid level h2 even if the liquid agent in the atomization tank 11 is consumed according to the atomization operation. be able to. Therefore, even when a large amount of liquid agent is sprayed over a wide range, it is possible to stably and automatically continue spraying for a long period of time. Since the size of the atomizing tank 11 can be suppressed, the capacity of the blower 13 can be reduced, and only fine particles having a smaller particle size, that is, fine particles small enough to cause Brownian motion can be produced. It is possible to provide a spraying device 1 that can be selectively conveyed.

Further, a stop sensor 16 for detecting a third liquid level h3 lower than the first liquid level h1 is provided, and when it is detected that the stop sensor 16 has fallen below the third liquid level h3, the blower 13 and the atomizing device 12 are operated. Since it is stopped, in the unlikely event that the liquid level falls below the first liquid level h1 and reaches the third liquid level h3, it is possible to prevent empty heating. Further, since the stop sensor 16 is provided separately from the liquid level sensor 15, even if the liquid level sensor 15 fails, the stop sensor 16 can be used to prevent a dangerous empty heating state. can.

Further, since the liquid level sensor 15 is connected to the outside of the atomization tank 11, the influence of the local fluctuation of the liquid level in the atomization tank 11 due to the operation of the ultrasonic vibrator is reduced and the liquid is accurate. The position can be measured.

Further, by supplying the liquid agent from the tank unit 20 arranged above the atomization tank 11 via the solenoid valve, the liquid agent can be supplied by utilizing gravity, and the liquid agent can be supplied only by controlling the opening and closing of the solenoid valve. Since control can be performed, it is possible to provide the spray device 1 capable of supplying the liquid agent to the atomization tank 11 more quickly than using the liquid agent supply pump 41.

Further, since the blowout unit 30 is formed of a substantially cylindrical blowout member having a predetermined width, depth and height, it is possible to prevent the generated fine particles from adhering to the wall surface of the blowout member. Further, since the slit-shaped spray port 31 is provided at the upper end of the blowout unit 30 and is inclined diagonally upward, pressure loss during spraying can be suppressed, and spraying can be performed over a wide range even if the pressure for spraying is low. Can be done. In this way, it is possible to provide the spraying device 1 capable of spraying a sufficient amount of fine particles over a wide range even when the rotation speed of the blower 13 is low.

Further, by fixing the atomization tank 11 to the lower base 61, fine particles are generated at the lowermost part of the spray device 1. Further, since the blowout unit 30 is arranged at the uppermost part above the tank unit 20 arranged above the atomization tank 11, the generated fine particles rise from the lowermost part of the apparatus and are blown out from the uppermost part. It will be. Therefore, even when the rotation speed of the blower member is lowered and the pressure of the blower 13 is lowered, it is possible to provide the spray device 1 capable of spraying fine particles over a wide range by utilizing the chimney effect.

Further, since the liquid agent replenishment port 63e for replenishing the liquid agent to the tank unit 20 is provided in the top surface recess 63c provided on the top surface of the top member 63, it is possible to replenish the liquid agent from above at a high position of the device. Easy to replenish liquid. Further, since the liquid agent supply port 63e is covered with the door portion 63d that can be opened and closed during the spraying operation, there is no risk of foreign matter being mixed into the tank unit 20 if the door portion 63d is closed, and the spraying has a neat appearance. Device 1 can be provided.

Further, since the cover member 80 formed of the stainless steel plate covers the periphery of the columnar member 62, the atomizing unit 10 and the tank unit 20 can be covered and protected from the external environment, and a neat impression is given. A spraying device 1 can be provided. Further, since the cover member 80 is formed of an elastic plate-shaped member, it can be wound around the columnar member by using elastic force and arranged, and even a person who is unfamiliar with the work can easily attach and detach the cover member 80. be able to. Further, since it is resistant to corrosion by acid, it is possible to provide a spraying device 1 that can be used in various environments by using various liquid agents.

Further, by atomizing the chlorous acid aqueous solution using an ultrasonic vibrator, it is possible to generate fine particles small enough to cause Brownian motion. Further, since the fine particles produced by using the chlorous acid aqueous solution are not easily inactivated even after a long period of time, the effect of sterilization can be continued for a long period of time. At this time, since the atomizing tank 11 and the tank unit 20 are formed of polyethylene terephthalate having a strong property against chlorous acid, the spraying device 1 capable of continuing the operation without the need for long-term maintenance. Can be provided. Similarly, since the installation unit 60 is made of stainless steel, corrosion is unlikely to occur, and replacement of members due to the occurrence of rust can be avoided, so that stable operation is possible for a longer period of time.

Although the embodiments of the present invention have been described above, the present invention is not limited to these embodiments described above. In addition, the effects described in the embodiments of the present invention merely list the most preferable effects arising from the present invention, and the effects according to the present invention are limited to those described in the embodiments of the present invention. is not it.

Further, the above-described embodiment has been described in detail in order to explain the present invention in an easy-to-understand manner, and is not necessarily limited to the one including all the described configurations.

The spraying device of the present invention can be applied to various spraying devices that spray various kinds of liquids.

<Appendix 1>
The spraying device 1 of Appendix 1 is as follows.

〔Technical field〕
The present invention relates to a technique for producing fine particles in a spraying device that sprays a liquid into a space.
[Background technology]

Various spraying devices have been developed that atomize water or an aqueous solution having a predetermined effect and spray it into a space.

In such a spraying device, in order to evenly diffuse the fine particles in a wide area, a fine particle having a desired particle size, particularly a particle size small enough to cause Brownian motion in the air, is used. Stable generation is required.

As an example of such a spraying device, it may be necessary to spray a large amount of a liquid agent having a sterilizing effect in a large space such as a hall of a facility for the elderly or a livestock house such as a barn, a piggery, or a poultry house. .. In such a case, if the particle size of the particles is large, they will fall to the floor or the ground before reaching every corner of the space, and will also moisten the floor, walls, and skin, resulting in slippage, mold, and the like. It is not preferable because it causes a cold. Therefore, it is necessary to generate fine particles having a particle size small enough to cause Brownian motion so as to float in the air for a long time and exert a sterilizing effect.

Generally, in order to atomize and spray a liquid, in an atomization unit in which water or an aqueous solution is stored, a liquid column generated by using an oscillator such as an ultrasonic transducer is made to collide with a separator. A technique has been adopted in which large droplets and small mist droplets are separated, and only the mist droplets are conveyed using a conveying medium supplied from a blower or the like and diffused into the air. (Japanese Patent Laid-Open No. 8-309248, Japanese Patent Application Laid-Open No. 60-50728)

[Outline of Invention]
[Problems to be solved by the invention]
According to the techniques disclosed in Japanese Patent Application Laid-Open No. 8-309248 and Japanese Patent Application Laid-Open No. 60-50728, it is possible to obtain a spraying device capable of selectively spraying mist droplets separated from the droplets. However, in the techniques disclosed in Japanese Patent Application Laid-Open No. 8-309248 and Japanese Patent Application Laid-Open No. 60-50728, air is directly supplied to the region where the liquid column collides with the separator, so that the flow is disturbed by the air. Particles with a relatively large particle size are also entrained in the air and transported. Therefore, the particle size of the fine particles transported to the air and sprayed is on the order of 10 μm, and it is difficult to generate fine particles (particle size of about 0.1 to 2 μm) small enough to cause Brownian motion.

Further, in order to evenly distribute the fine particles over a wide space, it is necessary to supply a large amount of transport air for transporting the fine particles. In that case, not only the fine particles having a small particle size but also the particles having a large particle size It is difficult to transport only fine particles small enough to cause Brownian motion.

In order to generate and convey only small fine particles, it is necessary to accurately control the voltage applied to the vibrator and the rotation speed of the feeder at the same time, which is difficult without specialized knowledge.

The present invention has been made in view of such a problem, and even a human resource who is unfamiliar with the work can stably cause Brownian motion without using an expensive control device for complicated control. It is an object of the present invention to provide a spraying device capable of producing a large amount of fine particles having a particle size as fine as possible.

[Means to solve problems]
The present invention provides the following solutions.

The invention according to the first feature is an atomization tank capable of storing a liquid agent, an atomization device provided with an ultrasonic transducer that atomizes the liquid agent to generate fine particles in the atomization tank, and a predetermined rotation. A blower that is equipped with a blower member capable of holding the number and discharges transport air for transporting fine particles of the liquid agent into the atomization tank from an air outlet provided in the atomization tank, and a blower provided in the atomization tank to convey the fine particles. The baffle plate is provided with an outlet for sending the air together with the conveyed air and a baffle plate arranged in the atomization tank. It is connected to the inside of the atomization tank and is arranged so as to receive the conveyed air from the air outlet on one side and the liquid column of the liquid agent generated by the ultrasonic transducer on the other side. A spraying device, is provided.

According to the invention according to the first feature, since the transport air supplied from the air outlet comes into contact with one side surface of the baffle plate, a pressure loss occurs at that time, and the pressure for transporting the particles decreases. .. Since the pressure of the transport air decreases, only fine particles smaller than the particles that are normally large enough to be transported are transported by the transport air from the liquid agent separated into droplets and small particles by colliding with the baffle plate. NS.

The invention according to the second feature is the invention according to the first feature, in which the outlet is arranged at a position opposite to the position where the air outlet is arranged with respect to the connection portion of the baffle plate. A spraying device, is provided.

According to the invention according to the second feature, since the air outlet is arranged on the opposite side of the air outlet with respect to the connection portion of the baffle plate, the conveyed air in contact with the baffle plate is with one end of the baffle plate. It reaches the outlet through the gap formed between it and the inner surface of the atomization tank. At that time, a negative pressure region is formed on the back side of the baffle plate where the transport air contacts, that is, a region where the liquid column contacts, and the pressure of the transport air further decreases in the negative pressure region. Only very small particles can be transported and will fall to the liquid surface below. Therefore, only fine particles having a particle size small enough to cause Brownian motion are transported to the outlet side by the transport air.

In this way, finer particles than simply receiving the liquid column on the baffle plate can be conveyed by the transfer air, and only fine particles small enough to cause Brownian motion can be selectively sprayed. A spraying device can be provided.

The invention according to the third feature is a step of bringing the conveyed air into contact with the upper surface of the baffle plate projecting laterally or diagonally downward, and the liquid column of the liquid agent generated by the ultrasonic vibrator collides with the lower surface of the baffle plate. Provided is a spraying method including a step of causing the transfer air to flow to the lower surface side of the baffle plate, and a step of sending out the transfer air that has collided with the upper surface of the baffle plate.
I will provide a.

According to the invention according to the third feature, the transfer air is brought into contact with the upper surface of the baffle plate and then flowed to the lower surface of the baffle plate, so that the transfer air is atomized from the liquid column in a state where a pressure loss is generated. Transport the particles. Since transporting is performed using transport air having a reduced pressure, it is possible to provide a spraying device capable of separating and transporting only fine particles having a particularly small particle size. Therefore, even if a relatively large flow rate is secured, it is possible to provide a spraying method capable of transporting and spraying only particles having a particularly small particle size.

The invention according to the fourth feature is the invention according to the third feature, and further includes a step of controlling the rotation speed of the blower member for supplying the conveyed air.

According to the invention according to the fourth feature, by controlling the rotation speed of the blower member in a state where the pressure loss of the transport air is caused, the change in the wind pressure can be increased with respect to the change in the air volume of the transport air. , It is possible to provide a spraying method capable of changing the particle size without changing the spray amount.

<Appendix 2>
The spraying device 1 of Appendix 2 is as follows.

〔Technical field〕
The present invention relates to a technique for producing fine particles in a spraying device that sprays a liquid into a space.
[Background technology]

Various spraying devices have been developed that atomize water or an aqueous solution having a predetermined effect and spray it into a space.

In such a spraying device, in order to evenly diffuse the fine particles in a wide area, a fine particle having a desired particle size, particularly a particle size small enough to cause Brownian motion in the air, is used. Stable generation is required.

As an example of such a spraying device, it may be necessary to spray a large amount of a liquid agent having a sterilizing effect in a large space such as a hall of a facility for the elderly or a livestock house such as a barn, a piggery, or a poultry house. .. In such a case, if the particle size of the particles is large, they will fall to the floor or the ground before reaching every corner of the space, and will also moisten the floor, walls, and skin, resulting in slippage, mold, and the like. It is not preferable because it causes a cold. Therefore, it is necessary to generate fine particles having a particle size small enough to cause Brownian motion so as to float in the air for a long time and exert a sterilizing effect.

Generally, in order to atomize and spray a liquid, in an atomization unit in which water or an aqueous solution is stored, a liquid column generated by using an oscillator such as an ultrasonic transducer is made to collide with a separator. A technique has been adopted in which large droplets and small mist droplets are separated, and only the mist droplets are conveyed using a conveying medium supplied from a blower or the like and diffused into the air. (Japanese Patent Laid-Open No. 8-309248, Japanese Patent Application Laid-Open No. 60-50728)

[Outline of Invention]
[Problems to be solved by the invention]
According to the techniques disclosed in Japanese Patent Application Laid-Open No. 8-309248 and Japanese Patent Application Laid-Open No. 60-50728, it is possible to obtain a spraying device capable of selectively spraying mist droplets separated from the droplets. However, in the techniques disclosed in Japanese Patent Application Laid-Open No. 8-309248 and Japanese Patent Application Laid-Open No. 60-50728, air is directly supplied to the region where the liquid column collides with the separator, so that the flow is disturbed by the air. Particles with a relatively large particle size are also entrained in the air and transported. Therefore, the particle size of the fine particles transported to the air and sprayed is on the order of 10 μm, and it is difficult to generate fine particles (particle size of about 0.1 to 2 μm) small enough to cause Brownian motion.

Further, in order to evenly distribute the fine particles over a wide space, it is necessary to supply a large amount of transport air for transporting the fine particles. In that case, not only the fine particles having a small particle size but also the particles having a large particle size It is difficult to transport only fine particles small enough to cause Brownian motion.

In order to generate and convey only small fine particles, it is necessary to accurately control the voltage applied to the vibrator and the rotation speed of the feeder at the same time, which is difficult without specialized knowledge.

The present invention has been made in view of such a problem, and even a human resource who is unfamiliar with the work can stably cause Brownian motion without using an expensive control device for complicated control. It is an object of the present invention to provide a spraying device capable of producing a large amount of fine particles having a particle size as fine as possible.

[Means to solve problems]
The present invention provides the following solutions.

The invention according to the first feature is an atomization tank capable of storing a liquid agent, an atomization device provided with an ultrasonic transducer that atomizes the liquid agent to generate fine particles in the atomization tank, and a predetermined rotation. A blower that is provided with a blower member capable of holding a number and discharges transport air for transporting fine particles of the liquid agent into the atomization tank from a blower port provided in the atomization tank, and a blower provided in the atomization tank. The transport air supplied from the air outlet is provided with an outlet that sends out fine particles together with the transport air and a baffle plate that is arranged to receive the liquid column of the liquid agent generated by the ultrasonic transducer in the atomization tank. A spraying device in which the distance and the outlet are arranged so as to pass through the gap between one end of the baffle plate and the atomization tank, wrap around to the surface side on the side receiving the liquid column, and then reach the outlet. offer.

According to the invention according to the first feature, the surface on the side that receives the liquid column after the conveyed air supplied from the air outlet passes through the gap formed between one end of the baffle plate and the atomization tank. Since it reaches the outlet after wrapping around the baffle plate, a gentle swirling flow of the conveyed air toward the outlet is formed around the baffle plate. The fine particles separated from the droplets by the liquid column colliding with the baffle plate are carried to the transport air, but at this time, due to the effect of the centrifugal force accompanying the generation of the swirling flow, the fine particles and finer particles are obtained. It is separated into fine particles, and only the fine particles are transported to the transport air. In this way, it is possible to provide a spraying device capable of sending only fine particles together with the conveyed air from the inlet by the effect of the baffle plate and the effect of the swirling flow.

The invention according to the second feature is the invention according to the first feature, in which the end portion of the baffle plate is connected to the inside of the top surface of the atomization tank, and the air outlet and the outlet are of the atomization tank. Provided is a spraying device provided on the top surface at locations on opposite sides of the baffle plate.

According to the invention according to the second feature, since the air outlet and the air outlet are provided on the top surfaces on opposite sides of the baffle plate, respectively, it is possible to form a swirling flow sandwiching the baffle plate and swirl. Since the effect of centrifugation by the flow can be enhanced, it is possible to provide a spraying device capable of spraying only fine particles having a smaller particle size.

The invention according to the third feature is a step of generating a downward transfer air flow in the atomization tank to generate a swirling flow of transfer air in the entire atomization tank, and a liquid column of a liquid agent generated by an ultrasonic vibrator. Provided is a spraying method including a step of bringing the swirl flow into contact with the lower surface of the baffle plate, a step of flowing a swirling flow on the lower surface of the baffle plate, and a step of transmitting the swirling flow by the conveyed air from above.

According to the invention according to the third feature, particles having a small particle size generated by generating a swirling flow of conveyed air in the entire atomization tank and bringing a liquid column by an ultrasonic vibrator into contact with a baffle plate are produced. It is possible to provide a spraying method capable of separating by using centrifugal force due to a swirling flow and extracting only smaller fine particles.

The invention according to the fourth feature is the invention according to the third feature, and further includes a step of controlling the rotation speed of the blower member for supplying the conveyed air.

According to the invention according to the fourth feature, the swirling strength of the swirling flow can be controlled by controlling the rotation speed of the blower member, so that the change in the transport capacity is made large with respect to the change in the air volume of the transport air. It is possible to provide a spraying method capable of changing the particle size without changing the spray amount.

<Appendix 3>
The spraying device 1 of Appendix 3 is as follows.

〔Technical field〕
The present invention relates to a technique for producing fine particles in a spraying device that sprays a liquid into a space.
[Background technology]

Various spraying devices have been developed that atomize water or an aqueous solution having a predetermined effect and spray it into a space.

In such a spraying device, in order to evenly diffuse the fine particles in a wide area, a fine particle having a desired particle size, particularly a particle size small enough to cause Brownian motion in the air, is used. Stable generation is required.

As an example of such a spraying device, it may be necessary to spray a large amount of a liquid agent having a sterilizing effect in a large space such as a hall of a facility for the elderly or a livestock house such as a barn, a piggery, or a poultry house. .. In such a case, if the particle size of the particles is large, they will fall to the floor or the ground before reaching every corner of the space, and will also moisten the floor, walls, and skin, resulting in slippage, mold, and the like. It is not preferable because it causes a cold. Therefore, it is necessary to generate fine particles having a particle size small enough to cause Brownian motion so as to float in the air for a long time and exert a sterilizing effect.

Generally, in order to atomize and spray a liquid, in an atomization unit in which water or an aqueous solution is stored, a liquid column generated by using an oscillator such as an ultrasonic transducer is made to collide with a separator. A technique has been adopted in which large droplets and small mist droplets are separated, and only the mist droplets are conveyed using a conveying medium supplied from a blower or the like and diffused into the air. (Japanese Patent Laid-Open No. 8-309248, Japanese Patent Application Laid-Open No. 60-50728)

[Outline of Invention]
[Problems to be solved by the invention]
According to the techniques disclosed in Japanese Patent Application Laid-Open No. 8-309248 and Japanese Patent Application Laid-Open No. 60-50728, it is possible to obtain a spraying device capable of selectively spraying mist droplets separated from the droplets. However, in the techniques disclosed in Japanese Patent Application Laid-Open No. 8-309248 and Japanese Patent Application Laid-Open No. 60-50728, air is directly supplied to the region where the liquid column collides with the separator, so that the flow is disturbed by the air. Particles with a relatively large particle size are also entrained in the air and transported. Therefore, the particle size of the fine particles transported to the air and sprayed is on the order of 10 μm, and it is difficult to generate fine particles (particle size of about 0.1 to 2 μm) small enough to cause Brownian motion.

Further, in order to evenly distribute the fine particles over a wide space, it is necessary to supply a large amount of transport air for transporting the fine particles. In that case, not only the fine particles having a small particle size but also the particles having a large particle size It is difficult to transport only fine particles small enough to cause Brownian motion.

In order to generate and convey only small fine particles, it is necessary to accurately control the voltage applied to the vibrator and the rotation speed of the feeder at the same time, which is difficult without specialized knowledge.

The present invention has been made in view of such a problem, and even a human resource who is unfamiliar with the work can stably cause Brownian motion without using an expensive control device for complicated control. It is an object of the present invention to provide a spraying device capable of producing a large amount of fine particles having a particle size as fine as possible.

[Means to solve problems]
The present invention provides the following solutions.

The invention according to the first feature is an atomization tank capable of storing a liquid agent, an atomization device provided with an ultrasonic transducer that atomizes the liquid agent to generate fine particles in the atomization tank, and a predetermined rotation. A blower that is equipped with a blower member that can hold the number and discharges the transport air for transporting the fine particles of the liquid agent into the atomization tank from the air outlet provided on the top surface of the atomization tank, and the atomization tank. The baffle plate is provided with an outlet for sending out the fine particles together with the conveyed air, and a baffle plate arranged in the atomization tank. Provided is a spraying device, which is arranged so as to block the liquid column generated by the child and the conveyed air supplied from the air outlet.

According to the invention according to the first feature, the baffle plate transfers the liquid column generated by the ultrasonic vibrator and the conveyed air supplied from the air outlet above the ultrasonic vibrator and below the air outlet. Since it is arranged in a shielding direction, it is possible to prevent the liquid column generated by the action of the ultrasonic vibrator from being directly blown into the blower, and also to prevent the conveyed air from the blower from being directly blown onto the liquid column. Can be done. Therefore, it is possible to provide a spraying device capable of transporting only fine particles by transport air without impairing the effect of selecting particles by the baffle plate.

<Appendix 4>
The spraying device 1 of Appendix 4 is as follows.

〔Technical field〕
The present invention relates to a technique for producing fine particles in a spraying device that sprays a liquid into a space.
[Background technology]

Various spraying devices have been developed that atomize water or an aqueous solution having a predetermined effect and spray it into a space.

In such a spraying device, in order to evenly diffuse the fine particles in a wide area, a fine particle having a desired particle size, particularly a particle size small enough to cause Brownian motion in the air, is used. Stable generation is required.

As an example of such a spraying device, it may be necessary to spray a large amount of a liquid agent having a sterilizing effect in a large space such as a hall of a facility for the elderly or a livestock house such as a barn, a piggery, or a poultry house. .. In such a case, if the particle size of the particles is large, they will fall to the floor or the ground before reaching every corner of the space, and will also moisten the floor, walls, and skin, resulting in slippage, mold, and the like. It is not preferable because it causes a cold. Therefore, it is necessary to generate fine particles having a particle size small enough to cause Brownian motion so as to float in the air for a long time and exert a sterilizing effect.

Generally, in order to atomize and spray a liquid, in an atomization unit in which water or an aqueous solution is stored, a liquid column generated by using an oscillator such as an ultrasonic transducer is made to collide with a separator. A technique has been adopted in which large droplets and small mist droplets are separated, and only the mist droplets are conveyed using a conveying medium supplied from a blower or the like and diffused into the air. (Japanese Patent Laid-Open No. 8-309248, Japanese Patent Application Laid-Open No. 60-50728)

[Outline of Invention]
[Problems to be solved by the invention]
According to the techniques disclosed in Japanese Patent Application Laid-Open No. 8-309248 and Japanese Patent Application Laid-Open No. 60-50728, it is possible to obtain a spraying device capable of selectively spraying mist droplets separated from the droplets. However, in the techniques disclosed in Japanese Patent Application Laid-Open No. 8-309248 and Japanese Patent Application Laid-Open No. 60-50728, air is directly supplied to the region where the liquid column collides with the separator, so that the flow is disturbed by the air. Particles with a relatively large particle size are also entrained in the air and transported. Therefore, the particle size of the fine particles transported to the air and sprayed is on the order of 10 μm, and it is difficult to generate fine particles (particle size of about 0.1 to 2 μm) small enough to cause Brownian motion.

In addition, in order to continue the operation of evenly distributing fine particles over a wide space, the atomization tank equipped with the ultrasonic transducer is enlarged and a large amount of liquid agent is atomized using a plurality of ultrasonic transducers. It was necessary to transport the fine particles using a large amount of transport air. In that case, not only fine particles having a small particle size but also particles having a large particle size are transported by a large amount of transport air, and it is difficult to transport only fine particles small enough to cause Brownian motion.

In order to generate and convey only small fine particles, it is necessary to accurately control the voltage applied to the vibrator and the rotation speed of the feeder at the same time, which is difficult without specialized knowledge.

The present invention has been made in view of such a problem, and even a human resource who is unfamiliar with the work can apply a large amount of liquid agent over a wide range without complicated control using an expensive control device. A spraying device that can stably and automatically continue spraying for a long period of time and can generate a large amount of fine particles having a fine particle size that can stably cause Brownian motion. The purpose is to provide.

[Means to solve problems]
The present invention provides the following solutions.

The invention according to the first feature includes an atomization tank capable of storing a liquid agent, an atomization device that atomizes the liquid agent in the atomization tank to generate fine particles, and a blower member capable of holding a predetermined rotation speed. , Atomizer equipped with a blower that discharges the conveyed air for transporting the fine particles of the liquid agent into the atomization tank from the air outlet provided in the atomization tank, and a liquid level sensor that measures the liquid level of the atomization tank. A spraying device including a unit, a tank unit that supplies the liquid agent to the atomization tank, and a control unit that controls the supply of the liquid agent from the tank unit to the atomization tank. The control unit is a liquid level sensor. When the liquid level measured in 1 is lower than the predetermined first liquid level, the tank unit starts supplying the liquid agent to the atomizing tank, and the liquid level measured by the liquid level sensor is higher than the first liquid level. Provided is a spraying device, which stops the supply of the liquid agent from the tank unit to the atomizing tank when a predetermined second liquid level is reached.

According to the invention according to the first feature, when the liquid level in the atomization tank falls below the predetermined first liquid level, the supply of the liquid agent stored in the tank unit is controlled to be started, and the predetermined second liquid agent is started. Since the supply is stopped when the liquid level is reached, the liquid level in the atomization tank is maintained between the first liquid level and the second liquid level even if the liquid agent in the atomization tank is consumed according to the atomization operation. can do. Therefore, even when a large amount of liquid agent is sprayed over a wide range, it is possible to stably and automatically continue spraying for a long period of time. Since the size of the atomizing tank can be suppressed, the capacity of the blower can be reduced, and only fine particles having a smaller particle size, that is, fine particles small enough to cause Brownian motion, are selected. It is possible to provide a spraying device capable of transporting the particles.

The invention according to the second feature is an invention according to the first feature, in which the control unit can further control the operation of the atomizing device and the operation of the blower, and the atomizing tank has the first liquid level. Further equipped with a stop sensor that detects a predetermined lower third liquid level, the control unit stops the operation of the blower and the atomizing device when it detects that the stop sensor has fallen below the third liquid level. The device, provided.

According to the invention according to the second feature, when it is detected that the liquid level has fallen below the third liquid level, the operation of the blower and the atomizing device is stopped. Therefore, in the unlikely event that the liquid level falls below the first liquid level and reaches the third liquid level. , Can prevent empty burning. Further, since the stop sensor is provided separately from the liquid level sensor, even if the liquid level sensor fails, it is possible to prevent a dangerous empty heating state by using the stop sensor.

The invention according to the third feature is the invention according to the first or second feature, wherein the liquid level sensor provides a spray device which is a float type sensor connected to the outside of the atomization tank.

According to the invention according to the third feature, since the liquid level sensor for measuring the liquid level is connected to the outside of the atomization tank, the liquid level in the atomization tank is localized due to the operation of the ultrasonic vibrator. It is possible to measure the liquid level accurately by reducing the influence of various fluctuations.

<Appendix 5>
The spraying device 1 of Appendix 5 is as follows.

〔Technical field〕
The present invention relates to a technique for producing fine particles in a spraying device that sprays a liquid into a space.
[Background technology]

Various spraying devices have been developed that atomize water or an aqueous solution having a predetermined effect and spray it into a space.

In such a spraying device, in order to evenly diffuse the fine particles in a wide area, a fine particle having a desired particle size, particularly a particle size small enough to cause Brownian motion in the air, is used. Stable generation is required.

As an example of such a spraying device, it may be necessary to spray a large amount of a liquid agent having a sterilizing effect in a large space such as a hall of a facility for the elderly or a livestock house such as a barn, a piggery, or a poultry house. .. In such a case, if the particle size of the particles is large, they will fall to the floor or the ground before reaching every corner of the space, and will also moisten the floor, walls, and skin, resulting in slippage, mold, and the like. It is not preferable because it causes a cold. Therefore, it is necessary to generate fine particles having a particle size small enough to cause Brownian motion so as to float in the air for a long time and exert a sterilizing effect.

Generally, in order to atomize and spray a liquid, in an atomization unit in which water or an aqueous solution is stored, a liquid column generated by using an oscillator such as an ultrasonic transducer is made to collide with a separator. A technique has been adopted in which large droplets and small mist droplets are separated, and only the mist droplets are conveyed using a conveying medium supplied from a blower or the like and diffused into the air. (Japanese Patent Laid-Open No. 8-309248, Japanese Patent Application Laid-Open No. 60-50728)

[Outline of Invention]
[Problems to be solved by the invention]
According to the techniques disclosed in Japanese Patent Application Laid-Open No. 8-309248 and Japanese Patent Application Laid-Open No. 60-50728, it is possible to obtain a spraying device capable of selectively spraying mist droplets separated from the droplets. However, in the techniques disclosed in Japanese Patent Application Laid-Open No. 8-309248 and Japanese Patent Application Laid-Open No. 60-50728, air is directly supplied to the region where the liquid column collides with the separator, so that the flow is disturbed by the air. Particles with a relatively large particle size are also entrained in the air and transported. Therefore, the particle size of the fine particles transported to the air and sprayed is on the order of 10 μm, and it is difficult to generate fine particles (particle size of about 0.1 to 2 μm) small enough to cause Brownian motion.

Further, in order to perform an operation of evenly distributing fine particles over a wide space, it is first necessary to promptly start the spraying device, but when starting the spraying device, atomization equipped with an ultrasonic vibrator is provided. It is necessary to promptly supply the liquid agent into the tank. At that time, if the atomization tank is large, it takes time to supply the liquid agent, so it takes time to start up.

The present invention has been made in view of such a problem, and is activated in a spraying device capable of producing a large amount of fine particles having a fine particle size capable of stably causing Brownian motion. It is an object of the present invention to provide a spraying device capable of promptly spraying a large amount of a large amount of liquid agent over a wide range in a stable manner for a long period of time.

[Means to solve problems]
The present invention provides the following solutions.

The invention according to the first feature is an atomization tank capable of storing a liquid agent, an atomization device that atomizes the liquid agent in the atomization tank to generate fine particles, and a blower that generates transport air for transporting the fine particles of the liquid agent. A atomization unit including the above, a tank unit arranged above the atomization unit to supply the liquid agent to the atomization tank, and a control unit for controlling the supply of the liquid agent from the tank unit to the atomization tank. The atomizing device is connected to the tank unit via an electromagnetic valve, and the control unit controls the supply of liquid agent from the tank unit to the atomizing tank by opening and closing the electromagnetic valve. A spraying device, is provided.

According to the invention according to the first feature, since the liquid agent is supplied from the tank unit arranged above the atomization tank via the solenoid valve, the liquid agent can be supplied by utilizing gravity and the electromagnetic valve is opened and closed. Since the supply of the liquid can be controlled only by control, it is possible to provide a spraying device capable of supplying the liquid to the atomization tank more quickly than using a pump.

<Appendix 6>
The spraying device 1 of Appendix 6 is as follows.

〔Technical field〕
The present invention relates to a technique for producing fine particles in a spraying device that sprays a liquid into a space.

〔Technical field〕
The present invention relates to a technique for producing fine particles in a spraying device that sprays a liquid into a space.
[Background technology]

Various spraying devices have been developed that atomize water or an aqueous solution having a predetermined effect and spray it into a space.

In such a spraying device, in order to evenly diffuse the fine particles in a wide area, a fine particle having a desired particle size, particularly a particle size small enough to cause Brownian motion in the air, is used. Stable generation is required.

As an example of such a spraying device, it may be necessary to spray a large amount of a liquid agent having a sterilizing effect in a large space such as a hall of a facility for the elderly or a livestock house such as a barn, a piggery, or a poultry house. .. In such a case, if the particle size of the particles is large, they will fall to the floor or the ground before reaching every corner of the space, and will also moisten the floor, walls, and skin, resulting in slippage, mold, and the like. It is not preferable because it causes a cold. Therefore, it is necessary to generate fine particles having a particle size small enough to cause Brownian motion so as to float in the air for a long time and exert a sterilizing effect.

Generally, in order to atomize and spray a liquid, in an atomization unit in which water or an aqueous solution is stored, a liquid column generated by using an oscillator such as an ultrasonic transducer is made to collide with a separator. A technique has been adopted in which large droplets and small mist droplets are separated, and only the mist droplets are conveyed using a conveying medium supplied from a blower or the like and diffused into the air. (Japanese Patent Laid-Open No. 8-309248, Japanese Patent Application Laid-Open No. 60-50728)

[Outline of Invention]
[Problems to be solved by the invention]
According to the techniques disclosed in Japanese Patent Application Laid-Open No. 8-309248 and Japanese Patent Application Laid-Open No. 60-50728, it is possible to obtain a spraying device capable of selectively spraying mist droplets separated from the droplets. However, in the techniques disclosed in Japanese Patent Application Laid-Open No. 8-309248 and Japanese Patent Application Laid-Open No. 60-50728, air is directly supplied to the region where the liquid column collides with the separator, so that the flow is disturbed by the air. Particles with a relatively large particle size are also entrained in the air and transported. Therefore, the particle size of the fine particles transported to the air and sprayed is on the order of 10 μm, and it is difficult to generate fine particles (particle size of about 0.1 to 2 μm) small enough to cause Brownian motion.

Further, in order to evenly distribute the fine particles over a wide space, it is necessary to supply a large amount of transport air for transporting the fine particles. In that case, not only the fine particles having a small particle size but also the particles having a large particle size It is difficult to transport only fine particles small enough to cause Brownian motion.

In order to generate and convey only small fine particles, it is necessary to accurately control the voltage applied to the vibrator and the rotation speed of the feeder at the same time, which is difficult without specialized knowledge.

In particular, in order to selectively generate fine particles having a small particle size, it is necessary to reduce the rotation speed of the blower. By lowering the rotation speed of the blower, it is possible to lower the draft of the air and prevent the transport of large and heavy particles, so that fine particles having a small particle size can be selectively transported. However, when the rotation speed of the blower is lowered, the air volume is also lowered at the same time, so that it is not possible to spray over a wide range, and it is difficult to spray on a hall or a livestock barn.

The present invention has been made in view of such a problem, and even a human resource who is unfamiliar with the work can stably cause Brownian motion without using an expensive control device for complicated control. It is an object of the present invention to provide a spraying device capable of producing a large amount of fine particles having a particle size as fine as possible.

[Means to solve problems]
The present invention provides the following solutions.

The invention according to the first feature includes an atomizing tank capable of storing a liquid agent, an atomizing device for atomizing the liquid agent in the atomizing tank to generate fine particles, and a blower member capable of holding a predetermined rotation speed. , An atomization unit equipped with a blower that discharges the transfer air for conveying the fine particles of the liquid agent into the atomization tank from the air outlet provided in the atomization tank, and the transfer air for the fine particles generated by the atomization unit. A spraying device including a blowing unit that blows out together with, and the blowing unit is formed of a substantially tubular blown member having a predetermined width, depth, and height, and a slit-shaped spraying port that is inclined diagonally upward at the upper end. To provide a spraying device, which has.

According to the invention according to the first feature, since the blowout unit is formed of a substantially cylindrical blowout member having a predetermined width, depth and height, it is possible to prevent the generated fine particles from adhering to the wall surface. can. Further, since the upper end of the blowout unit is provided with a slit-shaped spray port that is inclined diagonally upward, pressure loss during spraying can be suppressed, and even if the pressure for spraying is low, it is possible to spray over a wide range. .. In this way, it is possible to provide a spraying device capable of spraying a sufficient amount of fine particles over a wide range even when the rotation speed of the blower is low.

<Appendix 7>
The spraying device 1 of Appendix 7 is as follows.

〔Technical field〕
The present invention relates to a technique for producing fine particles in a spraying device that sprays a liquid into a space.
[Background technology]

Various spraying devices have been developed that atomize water or an aqueous solution having a predetermined effect and spray it into a space.

In such a spraying device, in order to evenly diffuse the fine particles in a wide area, a fine particle having a desired particle size, particularly a particle size small enough to cause Brownian motion in the air, is used. Stable generation is required.

As an example of such a spraying device, it may be necessary to spray a large amount of a liquid agent having a sterilizing effect in a large space such as a hall of a facility for the elderly or a livestock house such as a barn, a piggery, or a poultry house. .. In such a case, if the particle size of the particles is large, they will fall to the floor or the ground before reaching every corner of the space, and will also moisten the floor, walls, and skin, resulting in slippage, mold, and the like. It is not preferable because it causes a cold. Therefore, it is necessary to generate fine particles having a particle size small enough to cause Brownian motion so as to float in the air for a long time and exert a sterilizing effect.

Generally, in order to atomize and spray a liquid, in an atomization unit in which water or an aqueous solution is stored, a liquid column generated by using an oscillator such as an ultrasonic transducer is made to collide with a separator. A technique has been adopted in which large droplets and small mist droplets are separated, and only the mist droplets are conveyed using a conveying medium supplied from a blower or the like and diffused into the air. (Japanese Patent Laid-Open No. 8-309248, Japanese Patent Application Laid-Open No. 60-50728)

[Outline of Invention]
[Problems to be solved by the invention]
According to the techniques disclosed in Japanese Patent Application Laid-Open No. 8-309248 and Japanese Patent Application Laid-Open No. 60-50728, it is possible to obtain a spraying device capable of selectively spraying mist droplets separated from the droplets. However, in the techniques disclosed in Japanese Patent Application Laid-Open No. 8-309248 and Japanese Patent Application Laid-Open No. 60-50728, air is directly supplied to the region where the liquid column collides with the separator, so that the flow is disturbed by the air. Particles with a relatively large particle size are also entrained in the air and transported. Therefore, the particle size of the fine particles transported to the air and sprayed is on the order of 10 μm, and it is difficult to generate fine particles (particle size of about 0.1 to 2 μm) small enough to cause Brownian motion.

Further, in order to evenly distribute the fine particles over a wide space, it is necessary to supply a large amount of transport air for transporting the fine particles. In that case, not only the fine particles having a small particle size but also the particles having a large particle size It is difficult to transport only fine particles small enough to cause Brownian motion.

In order to generate and convey only small fine particles, it is necessary to accurately control the voltage applied to the vibrator and the rotation speed of the feeder at the same time, which is difficult without specialized knowledge.

In particular, in order to selectively generate fine particles having a small particle size, it is necessary to reduce the rotation speed of the blower. By lowering the rotation speed of the blower, it is possible to lower the draft of the air and prevent the transport of large and heavy particles, so that fine particles having a small particle size can be selectively transported. However, when the rotation speed of the blower is lowered, the air volume is also lowered at the same time, so that it is not possible to spray over a wide range, and it is difficult to spray on a hall or a livestock barn.

In view of these problems, the present invention has fine particles capable of stably causing Brownian motion even for a human resource who is unfamiliar with the work, without using an expensive control device for complicated control. An object of the present invention is to provide a spraying device capable of producing a large amount of fine particles having a diameter.

[Means to solve problems]
The present invention provides the following solutions.

The invention according to the first feature includes an atomization tank capable of storing a liquid agent, an atomization device for atomizing the liquid agent in the atomization tank to generate fine particles, and a blower member capable of holding a predetermined rotation speed. An atomization unit including a blower that discharges transport air for transporting fine particles of the liquid agent into the atomization tank from an air outlet provided in the atomization tank, and a tank unit that supplies the liquid agent to the atomization tank. , A spraying device including a blowout unit that blows out fine particles generated by the atomization unit together with conveyed air, and an installation unit that fixes the atomization unit, tank unit, and blowout unit, and the installation unit is located at the lower end. The atomizing tank is fixed to the lower base and has a lower base, a plurality of columnar members fixed to the lower base and arranged upward, and a top member fixed to the upper end of the columnar members. The unit is fixed to a columnar member above the atomization tank, and the blowout unit provides a spraying device, which is disposed on the top member.

According to the invention according to the first feature, the atomizing tank is fixed to the lower base to generate fine particles at the lowermost part of the spraying device. Further, since the blowout unit is arranged at the uppermost part above the tank unit arranged above the atomization tank, the generated fine particles rise from the lowermost part of the apparatus and are blown out from the uppermost part. .. Therefore, it is possible to provide the spraying device 1 capable of spraying fine particles over a wide range by utilizing the chimney effect even when the rotation speed of the blower member is lowered and the pressure of the blower is lowered.

<Appendix 8>
The spraying device 1 of Appendix 8 is as follows.

〔Technical field〕
The present invention relates to a technique for producing fine particles in a spraying device that sprays a liquid into a space.
[Background technology]

Various spraying devices have been developed that atomize water or an aqueous solution having a predetermined effect and spray it into a space.

In such a spraying device, in order to evenly diffuse the fine particles in a wide area, a fine particle having a desired particle size, particularly a particle size small enough to cause Brownian motion in the air, is used. Stable generation is required.

As an example of such a spraying device, it may be necessary to spray a large amount of a liquid agent having a sterilizing effect in a large space such as a hall of a facility for the elderly or a livestock house such as a barn, a piggery, or a poultry house. .. In such a case, if the particle size of the particles is large, they will fall to the floor or the ground before reaching every corner of the space, and will also moisten the floor, walls, and skin, resulting in slippage, mold, and the like. It is not preferable because it causes a cold. Therefore, it is necessary to generate fine particles having a particle size small enough to cause Brownian motion so as to float in the air for a long time and exert a sterilizing effect.

Generally, in order to atomize and spray a liquid, in an atomization unit in which water or an aqueous solution is stored, a liquid column generated by using an oscillator such as an ultrasonic transducer is made to collide with a separator. A technique has been adopted in which large droplets and small mist droplets are separated, and only the mist droplets are conveyed using a conveying medium supplied from a blower or the like and diffused into the air. (Japanese Patent Laid-Open No. 8-309248, Japanese Patent Application Laid-Open No. 60-50728)
[Outline of Invention]
[Problems to be solved by the invention]

According to the techniques disclosed in Japanese Patent Application Laid-Open No. 8-309248 and Japanese Patent Application Laid-Open No. 60-50728, it is possible to obtain a spraying device capable of selectively spraying mist droplets separated from the droplets. However, in the techniques disclosed in Japanese Patent Application Laid-Open No. 8-309248 and Japanese Patent Application Laid-Open No. 60-50728, air is directly supplied to the region where the liquid column collides with the separator, so that the flow is disturbed by the air. Particles with a relatively large particle size are also entrained in the air and transported. Therefore, the particle size of the fine particles transported to the air and sprayed is on the order of 10 μm, and it is difficult to generate fine particles (particle size of about 0.1 to 2 μm) small enough to cause Brownian motion.

Further, in order to evenly distribute the fine particles over a wide space, it is necessary to supply a large amount of transport air for transporting the fine particles. In that case, not only the fine particles having a small particle size but also the particles having a large particle size It is difficult to transport only fine particles small enough to cause Brownian motion.

In order to generate and convey only small fine particles, it is necessary to accurately control the voltage applied to the vibrator and the rotation speed of the feeder at the same time, which is difficult without specialized knowledge.

The present invention has been made in view of such a problem, and even a human resource who is unfamiliar with the work can stably cause Brownian motion without using an expensive control device for complicated control. It is an object of the present invention to provide a spraying device capable of producing a large amount of fine particles having a particle size as fine as possible.
[Means to solve problems]

The inventors of the present invention have a fine particle size capable of causing Brownian motion by disposing a blower, an ultrasonic vibrator, a baffle plate and a separator at a specific position in the atomization unit. We have found that a large amount of fine particles can be produced, and have reached the present invention.

The present invention provides the following solutions.

In the invention according to the first feature, a plurality of atomizing tanks having a predetermined width and capable of storing the liquid agent and a plurality of ultrasonic transducers for atomizing the liquid agent to generate fine particles in the atomization tank are arranged in the width direction. A blower equipped with a atomizing device and a blower member capable of holding a predetermined number of revolutions, and discharging conveyed air for conveying fine particles of a liquid agent into the atomization tank from an air outlet provided in the atomization tank. And, it is arranged so as to receive the outlet which is provided in the atomization tank and sends out the fine particles together with the conveyed air, and the liquid column of the liquid agent generated by the ultrasonic vibrator arranged on one end side in the width direction of the ultrasonic vibrator. A first baffle plate to be installed and a second baffle plate arranged to receive a liquid column of a liquid agent generated by the ultrasonic vibrator arranged on the other end side in the width direction of the ultrasonic vibrator are provided. The first baffle plate includes a first edge portion arranged at a predetermined distance from the inner surface on one end side in the width direction of the atomization tank, and a first connection portion connected to the inside of the atomization tank, and blows air. The mouth is arranged closer to one end side in the width direction of the atomization tank than the first connection portion, and the second baffle plate is arranged at a predetermined distance from the inner surface on the other end side in the width direction of the atomization tank. Provides a spraying device comprising two edges and a second connection connected to the inside of the atomization tank, the outlet being located closer to the other end of the atomization tank in the width direction than the second connection. do.

According to the invention according to the first feature, the first baffle plate arranged so as to receive the liquid column of the liquid agent generated by the ultrasonic vibrator arranged on one end side in the width direction of the ultrasonic vibrator. A baffle arranged above each ultrasonic vibrator is provided with a second baffle plate arranged to receive a liquid column of a liquid agent generated by the ultrasonic vibrator arranged on the other end side in the width direction. When a plurality of liquid columns come into contact with the plate, droplets having a large particle size contained in the liquid columns come into contact with the baffle plate and flow downward, return to the stored liquid layer, and mist with a small particle size. Only a large amount of droplets float in the air and are transported to the transport air.

At this time, the first baffle plate includes a first edge portion arranged at a predetermined distance from the inner surface on one end side in the width direction of the atomization tank, and a first connection portion connected to the inside of the atomization tank. The air outlet is arranged closer to one end side in the width direction of the atomization tank than the first connection portion, and the second baffle plate is arranged at a predetermined distance from the inner surface of the other end side in the width direction of the atomization tank. The second edge portion and the second connection portion connected to the inside of the atomization tank are provided, and the outlet is arranged closer to the other end side in the width direction of the atomization tank than the second connection portion. A large swirling flow is formed in the atomization tank so as to sandwich the first baffle plate and the second baffle plate throughout the atomization tank. Therefore, due to the effect of centrifugal force accompanying the generation of swirling flow, fine particles are separated into finer fine particles, and only fine fine particles that can cause Brownian motion can be reliably selected and sprayed. A possible atomizer can be provided.

That is, according to the present invention, it is possible to generate a large amount of fine particles having a fine particle size capable of stably causing Brownian motion without complicated control.

The invention according to the second feature is the invention according to the first feature, and provides a spray device further including a control unit for controlling the rotation speed of the blower member.

According to the invention according to the second feature, since the control unit for controlling the rotation speed of the blower member of the blower is provided, the fine particles to be sprayed by controlling the rotation speed and changing the strength of the centrifugal force applied to the fine particles. It is possible to provide a spraying device capable of adjusting the particle size.

<Appendix 9>
The spraying device 1 of Appendix 9 is as follows.

〔Technical field〕
The present invention relates to a technique for producing fine particles in a spraying device that sprays a liquid into a space.
[Background technology]

Various spraying devices have been developed that atomize water or an aqueous solution having a predetermined effect and spray it into a space.

In such a spraying device, in order to evenly diffuse the fine particles in a wide area, a fine particle having a desired particle size, particularly a particle size small enough to cause Brownian motion in the air, is used. Stable generation is required.

As an example of such a spraying device, it may be necessary to spray a large amount of a liquid agent having a sterilizing effect in a large space such as a hall of a facility for the elderly or a livestock house such as a barn, a piggery, or a poultry house. .. In such a case, if the particle size of the particles is large, they will fall to the floor or the ground before reaching every corner of the space, and will also moisten the floor, walls, and skin, resulting in slippage, mold, and the like. It is not preferable because it causes a cold. Therefore, it is necessary to generate fine particles having a particle size small enough to cause Brownian motion so as to float in the air for a long time and exert a sterilizing effect.

Generally, in order to atomize and spray a liquid, in an atomization unit in which water or an aqueous solution is stored, a liquid column generated by using an oscillator such as an ultrasonic transducer is made to collide with a separator. A technique has been adopted in which large droplets and small mist droplets are separated, and only the mist droplets are conveyed using a conveying medium supplied from a blower or the like and diffused into the air. (Japanese Patent Laid-Open No. 8-309248, Japanese Patent Application Laid-Open No. 60-50728)

[Outline of Invention]
[Problems to be solved by the invention]
According to the techniques disclosed in Japanese Patent Application Laid-Open No. 8-309248 and Japanese Patent Application Laid-Open No. 60-50728, it is possible to obtain a spraying device capable of selectively spraying mist droplets separated from the droplets. However, in the techniques disclosed in Japanese Patent Application Laid-Open No. 8-309248 and Japanese Patent Application Laid-Open No. 60-50728, air is directly supplied to the region where the liquid column collides with the separator, so that the flow is disturbed by the air. Particles with a relatively large particle size are also entrained in the air and transported. Therefore, the particle size of the fine particles transported to the air and sprayed is on the order of 10 μm, and it is difficult to generate fine particles (particle size of about 0.1 to 2 μm) small enough to cause Brownian motion.

Further, considering the installation in various places, it is preferable that the device itself is not provided with protrusions or the like and has a neat design. In addition, even if the device is enlarged in consideration of spraying a large amount of fine particles, even a person who is unfamiliar with the work can remove the surrounding cover and remove the inside without the help of an expert. It is desirable to be able to confirm.

The present invention has been made in view of such a problem, and even when the device is enlarged due to spraying a large amount of liquid agent over a wide range, even a person who is unfamiliar with the work can easily attach / detach the cover. It is an object of the present invention to provide a highly-designed spraying device that can be installed in any place without discomfort.

[Means to solve problems]
The present invention provides the following solutions.

The invention according to the first feature is an atomization tank capable of storing a liquid agent, an atomization device that atomizes the liquid agent in the atomization tank to generate fine particles, and a blower that generates transport air for transporting the fine particles of the liquid agent. An atomization unit equipped with the above, a tank unit that is arranged above the atomization unit and supplies a liquid agent to the atomization tank, a blowout unit that blows out fine particles generated by the atomization unit together with transport air, and an atomization unit. A spraying device including an installation unit for fixing the tank unit and a atomizing unit, a tank unit, and a cover member for covering the installation unit. The installation unit is fixed to a lower base located at the lower end and a lower base. Provided is a spraying device, which comprises a plurality of columnar members arranged upward, the cover member is formed of an elastic stainless steel plate, and is arranged around the plurality of columnar members so as to cover the installation unit. do.

According to the invention according to the first feature, since the cover member formed of the stainless steel plate covers the periphery of the columnar member, it is possible to cover the atomizing unit, the tank unit, etc. and protect it from the external environment, and it is neat. It is possible to provide a spraying device that gives an impression of. Further, since the cover member is formed of an elastic plate-shaped member, it can be wound around the columnar member by using elastic force and can be easily attached and detached even by a person who is unfamiliar with the work. Can be done. Further, since it is resistant to corrosion by acid, it is possible to provide a spraying device that can be used in various environments by using various liquid agents.

<Appendix 10>
The sterilization device 1 of Appendix 10 is as follows.

〔Technical field〕
The present invention relates to a technique for producing fine particles in a sterilizing device that sprays a sterilizing liquid into a space.
[Background technology]

Various sterilizing devices have been developed that atomize a sterilizing liquid and spray it into the space.

In such a sterilization device, in order to evenly diffuse the fine particles in a wide area, the fine particles have a desired particle size, particularly a particle size small enough to cause Brownian motion in the air. Is required to be stably generated.

As an example of such a sterilizing device, it may be necessary to spray a large amount of a liquid agent having a sterilizing action in a large space such as a hall of a facility for the elderly or a livestock house such as a cowshed, a piggery, or a poultry house. be. In such a case, if the particle size of the particles is large, they will fall to the floor or the ground before reaching every corner of the space, and will also moisten the floor, walls, and skin, resulting in slippage, mold, and the like. It is not preferable because it causes a cold. Therefore, it is necessary to generate fine particles having a particle size small enough to cause Brownian motion so as to float in the air for a long time and exert a sterilizing effect.

Generally, in order to atomize and spray a liquid, in an atomization unit in which water or an aqueous solution is stored, a liquid column generated by using an oscillator such as an ultrasonic transducer is made to collide with a separator. A technique has been adopted in which large droplets and small mist droplets are separated, and only the mist droplets are conveyed using a conveying medium supplied from a blower or the like and diffused into the air. (Japanese Patent Laid-Open No. 8-309248, Japanese Patent Application Laid-Open No. 60-50728)

[Outline of Invention]
[Problems to be solved by the invention]
According to the techniques disclosed in Japanese Patent Application Laid-Open No. 8-309248 and Japanese Patent Application Laid-Open No. 60-50728, it is possible to obtain a spraying device capable of selectively spraying mist droplets separated from the droplets. However, in the techniques disclosed in Japanese Patent Application Laid-Open No. 8-309248 and Japanese Patent Application Laid-Open No. 60-50728, air is directly supplied to the region where the liquid column collides with the separator, so that the flow is disturbed by the air. Particles with a relatively large particle size are also entrained in the air and transported. Therefore, the particle size of the fine particles transported to the air and sprayed is on the order of 10 μm, and it is difficult to generate fine particles (particle size of about 0.1 to 2 μm) small enough to cause Brownian motion.

Further, when spraying particles having a sterilizing action, the liquid agent used is generally an aqueous solution of sodium hypochlorite. In the sodium hypochlorite aqueous solution, it is difficult to generate particles small enough to cause Brownian motion because the fine particles as described above are easily inactivated.

Further, the liquid agent having a sterilizing action is generally acidic, which causes a problem of corrosion of the members constituting the apparatus.

The present invention has been made in view of such a problem, and a large amount of fine particles having a fine particle size capable of stably causing Brownian motion without using an aqueous solution of sodium hypochlorite is used. It is an object of the present invention to provide a sterilizing device that can be produced in a stable manner, is less likely to cause corrosion, and can be operated stably for a long period of time.

[Means to solve problems]
The present invention provides the following solutions.

The invention according to the first feature is to convey an atomization tank capable of storing a chloric acid aqueous solution which is a liquid agent, an atomization device which atomizes the liquid agent to generate fine particles in the atomization tank, and fine particles of the liquid agent. It is generated by an atomization unit equipped with a blower that discharges the conveyed air for the purpose from a blower port provided in the atomization tank into the atomization tank, a tank unit that supplies a liquid agent to the atomization tank, and an atomization unit. It is a sterilization device equipped with a blowout unit that blows out fine particles together with transport air, and an atomization unit, a tank unit, and an installation unit that fixes the blowout unit. The atomization tank and the tank unit are formed of polyethylene terephthalate. Together, the installation unit provides a disinfectant, which is made of stainless steel.

According to the invention according to the first feature, by atomizing an aqueous solution of chlorous acid using an ultrasonic vibrator, fine particles small enough to cause Brownian motion can be generated. Further, since the fine particles produced by using the chlorous acid aqueous solution are not easily inactivated even after a long period of time, the effect of sterilization can be continued for a long period of time. At this time, since the atomization tank and the tank unit are formed of polyethylene terephthalate having strong properties against chlorous acid, a sterilization device capable of continuing operation without the need for long-term maintenance is provided. can do. Similarly, since the installation unit is made of stainless steel, corrosion is unlikely to occur, and replacement of members due to the occurrence of rust can be avoided, so that stable operation is possible for a longer period of time.

1 Atomizer 10 Atomizer unit 11 Atomizer tank 11a Inlet 11b Blower 11c Outlet 11d Top surface 12 Atomizer device 12a, b ... Ultrasonic transducer 13 Blower 14a, b Baffle plate 15 Liquid level sensor 16 Stop Sensor 20 Tank unit 30 Blow-out unit 31 Blow-out member 32 Spray port 40 Supply unit 50 Control unit 60 Installation unit 61 Lower base 62 Columnar member 63 Top member 64 Leg 70 Power supply unit 80 Cover member

Claims (1)

An atomization unit including an atomization tank capable of storing the liquid agent, an atomization device for atomizing the liquid agent in the atomization tank to generate fine particles, and a blower for generating transport air for transporting the fine particles of the liquid agent. ,
A tank unit disposed above the atomization tank and supplying the liquid agent to the atomization tank,
A blowout unit that blows out the fine particles generated by the atomization unit together with the transport air, and
A top member disposed above the tank unit is provided.
The top member includes the blowout unit installed on the top surface, a top surface recess formed downward from the top surface, and an openable / closable door portion that covers the top surface recess.
A liquid supply port that communicates with the tank unit is formed in the top recess.
Atomizer.

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