JP6840888B1 - Circulator and cleaning equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a circulation device capable of miniaturizing and simplifying a cleaning device. SOLUTION: This is a circulation device that circulates a cleaning fluid in a cleaning tank by using a pump, and includes a tank provided in the cleaning tank and a nozzle provided in the tank, and the tank has an overflow part and a supply part. The nozzle has a driving fluid port, a suction fluid port, and a discharge port. The overflow portion of the tank is provided at the water level at which the cleaning liquid in the cleaning tank overflows, and the supply portion of the tank is located above the water level. It is characterized in that it is provided at a low position and at a position facing the discharge port of the nozzle, the drive fluid port of the nozzle is connected to the pump, and the suction fluid port of the nozzle is immersed in the cleaning liquid in the tank. Circulation device. [Selection diagram] Fig. 1

Description

The present invention relates to a circulation device and a cleaning device including the circulation device.

Japanese Unexamined Patent Publication No. 2005-341926 (hereinafter referred to as Patent Document 1) describes a food cleaning device. In this food cleaning device, a washing chamber for accommodating washing water is formed inside, and a washing water tank in which a collecting portion for collecting the washing water overflowing from the upper edge of the washing chamber is formed and a collecting pipe in the collecting portion It is equipped with a filtered water tank connected via.

JP-A-2005-341926 (Claim 1, FIG. 1)

In the cleaning device as described in Patent Document 1, in addition to the cleaning tank for cleaning the object to be cleaned, it is necessary to provide a filtered water tank outside the cleaning tank. Further, the cleaning tank needs to be provided with a collection unit for collecting the cleaning water overflowing from the cleaning chamber in addition to the cleaning chamber. Therefore, the size of the cleaning device as a whole becomes large. In addition, it is necessary to provide a recovery pipe between the recovery unit and the filtered water tank. Therefore, the configuration of the cleaning device becomes complicated.

An object of the present invention is to provide a circulation device capable of miniaturizing and simplifying a cleaning device.

(Solution 1)
A circulation device that circulates the cleaning liquid in the cleaning tank using a pump.
A tank provided in the washing tank and
The nozzle provided in the tank and
With
The tank has an overflow section and a supply section.
The nozzle has a drive fluid port, a suction fluid port, and a discharge port.
The overflow portion of the tank is provided at a water level at which the cleaning liquid in the cleaning tank overflows.
The supply unit of the tank is provided at a position lower than the water level and at a position facing the discharge port of the nozzle.
The drive fluid port of the nozzle is connected to the pump and
The suction fluid port of the nozzle is immersed in the cleaning liquid in the tank.
A circulation device characterized by that.

(Solution 2)
The tank has a mounting portion that can be mounted on the edge of the cleaning tank.
The tank is provided with a filtration device that filters the cleaning liquid that overflows from the cleaning tank.
The circulatory device according to Solution 1.

(Solution 3)
The nozzle takes in the cleaning liquid flowing in from the driving fluid port and the cleaning liquid around the nozzle from the suction fluid port, mixes these cleaning liquids, and ejects them from the discharge port.
The circulation device according to the first or second solution.

(Solution 4)
The nozzle has a duct portion for taking in gas, and the gas is mixed with the cleaning liquid ejected by the nozzle.
The circulation device according to any one of solutions 1 to 3.

(Solution 5)
The overflow part of the tank adjusts the opening ratio,
The shape of the supply part of the tank is the same as or similar to the discharge port of the nozzle.
The supply part of the tank and the discharge port of the nozzle are close to each other.
The circulation device according to any one of solutions 1 to 4.

(Solution 6)
The circulation device according to any one of solutions 1 to 5 and the circulation device.
With the washing tank
The pump and the like.
A cleaning device characterized by that.

According to one solution of the present invention, the cleaning device can be miniaturized and simplified.

It is a schematic side view of the cleaning apparatus by one Embodiment of this invention. It is a schematic perspective view of a tank. It is a schematic diagram of the nozzle shown in FIG. It is sectional drawing of the nozzle shown in FIG. It is a schematic side view of the cleaning apparatus by another embodiment of this invention. It is a schematic diagram of the nozzle shown in FIG. It is sectional drawing of the nozzle shown in FIG. It is a schematic side view of the cleaning apparatus by another embodiment of this invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The arrows in the figure represent the flow of fluid.

FIG. 1 is a schematic side view of a circulation device according to an embodiment of the present invention and a cleaning device 10 including the circulation device.
The cleaning device 10 is a cleaning device that immerses products, materials, and the like produced by agriculture and fisheries in the cleaning tank 20 for cleaning.
The cleaning device 10 is provided with a tank 30 (chamber) and a pump P that can be easily attached.
The pump P takes the cleaning liquid stored in the cleaning tank 20 into the water intake pipe 40 connected to the lower part of the cleaning tank 20 and sends it to the supply pipe 50. The supply pipe 50 passes through the wall of the cleaning tank 20 and is connected to the nozzle 100 provided in the tank 30 to supply the cleaning liquid to the nozzle 100. As a result, the nozzle 100 can eject the cleaning liquid into the cleaning tank 20.
Further, the cleaning liquid in the cleaning tank 20 overflows due to the cleaning liquid ejected from the nozzle 100 and flows into the tank 30. After that, the cleaning liquid is filtered by the filtration device 60 provided in the tank 30, flows in through the suction fluid port 130 (FIG. 3) opened by the nozzle 100, and is ejected from the nozzle 100 into the cleaning tank 20 again. ..

FIG. 2 is a schematic perspective view of the tank 30.

The tank 30 includes a mounting portion 70 that can be easily mounted by hooking it on the inside of the edge of the cleaning tank 20 or mounting it with bolts or the like.
Further, since the tank 30 provided with the mounting portion 70 can be easily mounted, it can be mounted on a commercially available resin-based cleaning tank 20 for, for example, agriculture and industry.
The tank 30 has a rectangular parallelepiped shape, and the side surface to which the mounting portion 70 is connected is formed along the side surface of the cleaning tank 20 (so as to have the same shape).
Further, the tank 30 includes an overflow unit 80 for collecting the overflow liquid and a supply unit 90 for discharging the cleaning liquid ejected from the nozzle 100 provided in the tank 30 to the cleaning tank 20.

The tank 30 is provided with a filtration device 60 and collects the overflow liquid flowing out from the cleaning tank 20.
Since the overflow liquid contains foreign substances such as leaves, wood chips, and insects adhering to the object to be cleaned in the cleaning tank 20, the foreign substances are removed by the filtration device 60.
The filtration device 60 may be in the form of a mesh or a punch, and is provided according to the size and shape of the foreign matter adhering to the object to be cleaned in the cleaning tank 20.

The overflow portion 80 of the tank 30 is provided above the filtration device 60 and has a hole shape so as to collect the overflow liquid flowing out from the cleaning tank 20. In addition, it prevents the object to be cleaned from flowing into the tank 30 together with the overflow liquid.
The number of holes in the overflow portion is adjusted by the ratio of the opening area to the surface (area) above the filtration device 60 (hereinafter referred to as the opening ratio), and a water level difference occurs between the cleaning tank 20 and the tank 30. The aperture ratio is adjusted, and the number of holes and the size (diameter) of the holes are adjusted.
Further, although holes are provided in the present embodiment, if the opening ratio is adjusted so that the water level is generated in the washing tank 20 and the tank 30, the shape, the size, shape, and quantity of the holes are cut out so as to cut out the upper part of the tank 30. May be changed.
Further, in the present embodiment, the position of the overflow portion 80 is the side surface of the tank 30 facing the mounting portion 70, but any of the side surfaces of the tank 30 may be used as long as it is above the filtration device 60 and the aperture ratio is adjusted.

Further, the supply unit 90 of the tank 30 is provided at a position facing the discharge port 160 of the nozzle 100 provided in the tank 30, and is provided at a position of being immersed in the cleaning liquid stored in the tank 30. Further, the supply unit 90 has a function of discharging the cleaning water ejected from the nozzle 100 to the cleaning tank 20.
Further, the shape of the supply unit 90 is the same as or similar to the shape of the discharge port 160 of the nozzle 100, and when the cleaning liquid is discharged from the nozzle 100, the cleaning liquid in the cleaning tank 20 flows into the tank 30 (backflow). ) Is prevented.
Further, by keeping the distance between the discharge port 160 of the nozzle 100 and the supply unit 90 close to each other and keeping a predetermined distance so that the nozzle 100 does not come into contact with the supply unit 90 even if the nozzle 100 vibrates, the nozzle 100 ejects from the discharge port 160. The cleaning liquid to be used is discharged to the cleaning tank 20.
Further, even if a predetermined distance is maintained between the nozzle 100 and the supply unit 90, the cleaning liquid stored in the cleaning tank 20 flows into the supply unit 90 due to the ejection of the cleaning liquid from the nozzle 100 when the pump P is in operation. The effect of backflow) is small.
That is, since the nozzle 100 and the supply unit 90 are not connected by a connecting body (packing or the like), the trouble of connecting them is saved, and by keeping a predetermined distance, the members are prevented from coming into contact with each other and being damaged. ..

FIG. 3 is a schematic view of the nozzle 100 shown in FIG. 1, and FIG. 4 is a cross-sectional view of the nozzle 100 shown in FIG.
The nozzle 100 is immersed in the cleaning liquid stored in the tank 30, connected to the supply pipe 50, and the cleaning liquid supplied from the pump P is discharged to the tank 20.
Further, the nozzle 100 is an ejector nozzle provided with a drive fluid port 110 and a discharge port 160, and converges from the drive fluid port 110 by a converging portion 150 in the middle of the discharge port 160.

The drive fluid port 110 of the nozzle 100 is provided apart from the converging portion 150, but is connected by a bridge 140.
A space (suction fluid port 130) is provided by the bridge 140, and the overflow liquid (cleaning liquid) flowing into the tank 30 can be taken in.
Further, in the suction fluid port 130, the nozzle 100 is converged by the converging portion 150 in the middle of taking in the cleaning liquid (overflow liquid) around the nozzle and then discharging the cleaning liquid (overflow liquid) to the discharge port 160.
The cleaning water supplied from the pump P is taken into the driving fluid port 110 as a driving liquid and flows into the flow generating unit 120. After that, it is discharged from the discharge port 160, passes through the supply unit 90, and is ejected into the cleaning tank 30.

The drive fluid port 110 of the nozzle 100 has a shape that narrows in a conical shape toward the flow generating portion 120. The cleaning liquid flowing toward the flow generating unit 120 has a Venturi effect caused by squeezing the flow of the fluid, and the flow velocity increases. Then, the pressure around the suction fluid port 130 becomes low, and the cleaning liquid around the open suction fluid port 130 flows in. Then, the cleaning liquid flowing in from the suction fluid port 130 is mixed with the cleaning liquid flowing out from the flow generating unit 120. Further, the mixed cleaning liquid is ejected from the discharge port 160 after the flow velocity is increased again by the converging portion 150 of the nozzle 100. Therefore, it is possible to supply and discharge the cleaning water that exceeds the discharge capacity of the pump P.

In the cleaning device 10, the nozzle 100 and the supply unit 90 have a predetermined distance before the operation of the pump P, and the supply unit 90 is open, so that the cleaning liquid stored in the cleaning device is the cleaning tank 20. The water levels are equal in the tank 30.
When the pump P starts to operate, the cleaning liquid supplied from the pump P becomes a driving liquid, and the nozzle 100 starts discharging the cleaning liquid.
The cleaning liquid in the tank 30 is sucked into the nozzle 100 from the suction fluid port 130, the cleaning liquid is discharged from the discharge port 160 to the cleaning tank 20, and the water level in the cleaning tank 20 gradually rises.
Then, the overflow portion 80 opens above the filtration device 60 of the tank 30, and the holes are adjusted by the opening ratio. Therefore, the overflow portion 80 limits the overflow liquid flowing into the tank 30, and the overflow liquid is more than the overflow portion 80. Since more cleaning liquid is ejected to the cleaning tank 20, the water level in the cleaning tank 20 rises. Further, as for the cleaning liquid in the tank 30, the water level in the tank 30 drops because the nozzle 100 takes in the cleaning liquid through the suction fluid port 130. Therefore, a water level difference is created between the cleaning tank 20 (water level 200a) and the tank 30 (water level 200b).
After that, as the water level of the cleaning tank 20 rises, the amount of the cleaning liquid stored in the cleaning tank 20 in contact with the overflow portion 80 provided on the side surface of the tank 30 increases. Therefore, since the overflow liquid amount is increased by the overflow portion 80, the discharge amount of the pump P and the overflow liquid amount are the same, and the cleaning tank 20 (water level 200a) and the tank 30 (water level 200b) keep the water level difference.
That is, the nozzle 100 in the tank 30 can circulate the cleaning liquid in the cleaning device 10 while constantly immersing in the cleaning liquid.

According to the configuration of the present invention, the nozzle 100 can generate a swirling flow in the cleaning tank 20, and the cleaning liquid in the cleaning tank 20 can overflow into the tank 30. Then, the overflow liquid (cleaning liquid) is collected in the tank 30, and the filtration device 60 removes foreign substances adhering to the object to be cleaned such as leaves, wood chips, and insects mixed in the overflow liquid, filters the overflow liquid, and sucks the nozzle 100 again. It flows into the fluid port 130.
As a result, according to the configuration of the present invention, the cleaning device can be miniaturized and simplified by generating a swirling flow that exceeds the discharge capacity of the pump regardless of the structure and size of the cleaning tank. Further, the tank 30 can be adapted to various tanks by the mounting portion 70 that can be easily mounted, and the cleaning and maintenance of the tank can be easily performed.

Next, other embodiments of the present invention will be described.
FIG. 5 is a schematic side view of the cleaning device 10A according to another embodiment of the present invention.
The tank 30 has a mounting portion 70 that can be easily mounted on the edge of the cleaning tank 20.
Further, in FIG. 1, the pump P is installed outside the cleaning tank 20, but in the schematic side view according to another embodiment of the present invention, it is installed inside the cleaning tank 20.

6 is a schematic view of the nozzle 100A shown in FIG. 5, and FIG. 7 is a cross-sectional view of the nozzle 100A shown in FIG.

The nozzle 100A of the present embodiment is an ejector nozzle including a drive fluid port 110 for taking in the drive liquid, a converging portion 150, a duct portion 170, and a discharge port 160 for discharging the taken-in cleaning liquid.
The drive fluid port 110 of the nozzle 100 is provided apart from the converging portion 150, but is connected by a bridge 140.
A space (suction fluid port 130) is provided by the bridge 140, and the overflow liquid (cleaning liquid) flowing into the tank 30 can be taken in.
Further, in the suction fluid port 130, the nozzle 100 is converged by the converging portion 150 in the middle of taking in the cleaning liquid (overflow liquid) around the nozzle and then discharging the cleaning liquid (overflow liquid) to the discharge port 160.

The cleaning liquid taken from the pump P flows into the drive fluid port 110 connected to the supply pipe 50. The drive fluid port 110 has a shape that narrows in a conical shape toward the flow generating portion 120. Therefore, the flow velocity of the cleaning liquid increases due to the Venturi effect. Then, since the pressure in the flow generating unit 120 drops, the cleaning liquid around the nozzle 100A is taken in from the suction fluid port 130.
Further, in the nozzle 100A, the inside of the converging portion is narrowed by the converging portion 150, and the converging portion 150 has a duct portion 170 communicating with the upper surface. One end of the duct portion 170 communicates with the converging portion 150, and the other bias extends above the liquid level of the tank 30.
Therefore, when the cleaning liquid flows from the flow generating unit 120 to the converging unit 150, the gas is taken into the converging unit 150 from the duct unit 170, mixed with the cleaning liquid circulating in the nozzle 100, and the cleaning liquid containing bubbles is mixed with the cleaning liquid in the cleaning tank. It can be ejected to 20.

The cleaning liquid taken in from the pump P in the cleaning tank 20 flows into the nozzle 100A connected from the supply pipe 50.
When the cleaning liquid flows into the drive fluid port 110 of the nozzle 100A, the cleaning liquid flows toward the flow generating unit 120. Then, the flow velocity of the cleaning liquid increases due to the ejection from the flow generating unit 120, and the pressure around the cleaning liquid is reduced. At this time, since the pressure around the area ejected from the flow generating unit 120 is lower than the pressure around the outside of the suction fluid port 130, the cleaning liquid around the area is likely to be drawn into the suction fluid port 130. As a result, the cleaning liquid around the nozzle 100A and the cleaning liquid flowing in from the drive fluid port 110 are mixed and flow into the inside of the converging portion 150.

Further, in the nozzle 100A, when the cleaning liquid flows through the converging portion 150 in which the inside of the pipe is narrowed, the pressure around the cleaning liquid is reduced. At this time, since the pressure in the converging portion 150 is lower than the pressure (atmospheric pressure) on the upper surface side of the duct portion 170, air is drawn into the converging portion 150 through the duct portion 170. As a result, air can be supplied from the duct portion 170 to the inside of the converging portion 150. At this time, cavitation is likely to occur, the liquid and the gas are mixed, and a cleaning liquid containing bubbles is generated.

Even if foreign substances such as leaves, wood chips, and insects are attached to the object to be cleaned, the surface dirt of the object to be cleaned can be cleaned by ejecting a cleaning solution containing minute bubbles from the nozzle 100 due to the cavitation phenomenon. Even if mud adheres to the object to be cleaned, the bubbles collide with each other and split due to the force of the ejection, and mud stains and the like can be cleaned. Further, since the ejected cleaning liquid is composed of air bubbles, it can be gently cleaned without damaging the object to be cleaned.

FIG. 8 is a schematic side view of the cleaning device 10B according to another embodiment of the present invention.

In another embodiment of the present invention, the pump P is installed outside the cleaning tank 20.
Further, in one embodiment of the present invention, the supply pipe 50 penetrates the cleaning tank 20 and is connected to the nozzle 100 in the tank 30, but the supply pipe 50 in FIG. 8 is the cleaning tank 20. It extends along the side wall and is connected to the nozzle 100 in the tank 30.
As a result, it is possible to save the trouble of opening the cleaning tank 20 and the tank 30.
In addition, since a commercially available resin-based washing tank for agriculture and industry generally has a drain plug at the lower part of the side wall of the tank, the opening of the drain plug is used for the water pipe 40. can do.
That is, according to the configuration of another embodiment of the present invention, the cleaning device can be more easily configured without opening a commercially available cleaning tank, and the cleaning device can be miniaturized and simplified. ..

As described above, the configuration of the present invention has been described based on the embodiments.
According to the configuration of the present invention, even if foreign matter adhering to the object to be cleaned is mixed in the overflow liquid, it is filtered by the filtration device 60, but even if fine particle foreign matter such as mud or sand passes through the filtration device 60, the nozzle The suction fluid port 130 of 100 is widely opened, and clogging of the nozzle 100 can be prevented by ejecting the convergence port 150.
Further, according to the configuration of the present invention, a swirling flow can be generated in the cleaning tank 20, whereby the object to be cleaned can be cleaned while rotating (rotating), and the cleaning liquid to be ejected can be evenly applied.

Further, the configuration of the cleaning tank of the present invention has been described as a rectangular parallelepiped, but if the configuration of the present invention is used, the mounting portion of the tank can be easily mounted. It may be the one.
In the embodiment of the present invention, the pump P is installed outside the cleaning tank, and in other embodiments, the pump is installed inside the cleaning tank. However, the present invention is not particular about this configuration, and the cleaning fluid from the pump P is nozzleed. If the pump P flows into the drive fluid ports 110 of 100 and 100 A as a drive liquid, the installation configuration of the pump P does not care about the inside and outside of the cleaning tank.
Further, if a plurality of nozzles 100 and 100A in the tank 30 are used, or if a plurality of nozzles 30 are installed, it is possible to cope with a larger washing tank and to create a complicated water flow.

The present invention is not limited to the above embodiment, and can be modified without departing from the gist thereof.

10, 10A, 10B cleaning equipment, 20 cleaning tanks, 30 tanks, 50 supply pipes,
60 Filtration device, 70 Mounting part, 80 Overflow part, 90 Supply part 100, 100A Nozzle, 110 Drive fluid port, 120 Flow generation part 130 Intake fluid port, 140 Bridge, 150 Convergence part, 160 Discharge port 170 Duct part, 200a, 200b water level, P pump

Claims (6)

A circulation device that circulates the cleaning liquid in the cleaning tank using a pump.
A tank provided in the washing tank and
The nozzle provided in the tank and
With
The tank has an overflow section and a supply section.
The nozzle has a drive fluid port, a suction fluid port, and a discharge port.
The overflow portion of the tank is provided at a water level at which the cleaning liquid in the cleaning tank overflows.
The supply unit of the tank is provided at a position lower than the water level and at a position facing the discharge port of the nozzle.
The drive fluid port of the nozzle is connected to the pump and
The suction fluid port of the nozzle is immersed in the cleaning liquid in the tank.
A circulation device characterized by that. The tank has a mounting portion that can be mounted on the edge of the cleaning tank.
The tank is provided with a filtration device that filters the cleaning liquid that overflows from the cleaning tank.
The circulation device according to claim 1. The nozzle takes in the cleaning liquid flowing in from the driving fluid port and the cleaning liquid around the nozzle from the suction fluid port, mixes these cleaning liquids, and ejects them from the discharge port.
The circulation device according to claim 1 or 2. The nozzle has a duct portion for taking in gas, and the gas is mixed with the cleaning liquid ejected by the nozzle.
The circulation device according to any one of claims 1 to 3. The overflow part of the tank adjusts the opening ratio,
The shape of the supply part of the tank is the same as or similar to the discharge port of the nozzle.
The supply part of the tank and the discharge port of the nozzle are close to each other.
The circulation device according to any one of claims 1 to 4. The circulation device according to any one of claims 1 to 5.
With the washing tank
The pump and the like.
A cleaning device characterized by that.

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