JP7216959B2 - dust filter - Google Patents

Description

Application of Article 30, Paragraph 2 of the Patent Act On January 30, 2019, Hidetsune Kosugi orally explained to his customers the contents of a dust filtration filter having a truncated cone shape and made of non-woven fabric. On March 11, 2019, Hidetsune Kosugi made public by sending a prototype of the dust filtration filter to the customer by home delivery.

TECHNICAL FIELD The present invention relates to a dust filtration filter that is attached to the spout of a tank that stores a liquid reducing agent that reduces nitrogen oxides contained in exhaust gas.

Diesel engine exhaust gases contain particulate matter (PM) and nitrogen oxides (NOx). Increasing the combustion temperature of light oil reduces the amount of PM contained in the exhaust gas and increases the amount of NOx. A technology that burns light oil at a high temperature to reduce the concentration of PM and injects a liquid reducing agent such as urea into the exhaust gas to reduce the increased NOx is widely used.

The liquid reducing agent is temporarily stored in a tank, pressurized by a pump, and sprayed against the exhaust gas. If the liquid reducing agent contains dust, it causes wear and tear on systems such as pumps, pipes, and injection nozzles that supply the liquid reducing agent. For this reason, for the purpose of filtering the dust contained in the liquid reducing agent, for example, a dust filtering filter as disclosed in Patent Document 1 has been proposed.

The dust filter of Patent Literature 1 has a bag-like filter portion having an opening for allowing liquid to flow thereinto and a plurality of pleats. The plurality of pleats have free ends such that the inside diameter of the bag expands when liquid flows into the bag through the openings.

Also, as a device for removing dust contained in a liquid reducing agent, for example, a strainer as disclosed in Patent Document 2 has been proposed. The strainer of Patent Document 2 is cylindrical and has a frame having a plurality of through-holes arranged on the side surface of the cylinder and a screen stretched over the through-holes. The screen is said to be woven from nylon wires.

JP 2018-1065 A JP 2016-196846 A

The dust filtering filter of Patent Document 1 needs to be sewn in a state in which the filtering material constituting the filtering portion is folded into a predetermined shape. For this reason, an extremely thin and delicate filter medium is used in the filtering section. For this reason, the dust filtration filter may be damaged by friction, stress, or the like.

In a strainer such as that of Patent Document 2, if the opening of the screen that plays the role of straining the dust is made small and it is designed so that dust with a small particle size can be filtered out, the shape of the strainer is cylindrical and the filtration area is small. , the liquid reducing agent flowed into the strainer sometimes blew out of the tank from the spout of the tank.

An object of the present invention is to provide a dust filtration filter for a liquid reducing agent that is less likely to be damaged by friction or the like and less likely to overflow when the liquid reducing agent is poured.

It is a dust filtration filter that is attached to the spout of a tank that stores a liquid reducing agent that reduces nitrogen oxides contained in exhaust gas. It has an opening through which liquid flows in and a bag-like filtering part, and the filtering part is made of woven fabric or non-woven fabric with a thickness of 0.3 to 3.0 mm, and its shape is the attachment part. The above problem is solved by a dust filtration filter having a shape including a tapered portion in which the inner diameter gradually increases from the base end where the is located toward the tip. Since this dust filter includes a tapered portion whose inner diameter gradually increases from the base end where the mounting portion is located toward the tip, the filtration area for the liquid reducing agent increases. Therefore, when the liquid reducing agent is poured, it is possible to prevent the liquid reducing agent from blowing over. Furthermore, since the filtration portion of the above-described dust filtration filter is made of woven fabric or non-woven fabric with a thickness of 0.3 to 3.0 mm, it is less likely to be damaged by friction or the like.

According to the present invention, it is possible to provide a dust filtration filter for a liquid reducing agent that is less likely to be damaged by friction or the like and less likely to overflow when the liquid reducing agent is poured.

1 is a schematic diagram showing an example of a system for reducing nitrogen oxides contained in exhaust gas; FIG. 2 is an enlarged sectional view of the tank of FIG. 1; FIG. 3 is an enlarged cross-sectional view of the periphery of the spout of FIG. 2; FIG. It is a perspective view showing a dust filtration filter according to the first embodiment. It is a perspective view showing a dust filtration filter according to a second embodiment. It is a perspective view showing a dust filtration filter according to a third embodiment. It is a perspective view showing a dust filtration filter according to a fourth embodiment. It is a perspective view showing a dust filtration filter according to a fifth embodiment.

An example of a system for reducing nitrogen oxides contained in exhaust gas will be described below with reference to the drawings. After that, examples of the dust filtering filter of the present invention will be given and explained.

[An example of a system that reduces nitrogen oxides]
FIG. 1 shows an example of a system for reducing nitrogen oxides contained in exhaust gas. The system of FIG. 1 includes a tank 11 that stores a liquid reducing agent, a supply pipe 41 that sucks up the liquid reducing agent from the tank 11 and supplies the liquid reducing agent to an exhaust pipe 52, and a tip of the supply pipe 41. It has a nozzle 53 that injects a liquid reducing agent supplied from a supply pipe into an exhaust pipe 52, an engine 51, and an exhaust pipe 52 through which exhaust gas discharged from the engine 51 passes. The supply pipe 41 is provided with a second filter 42 for filtering out dust contained in the liquid reducing agent, and a pump 43 for sucking up the reducing agent in the tank 11 and pumping it to the tip of the supply pipe 41 . there is

In the example of FIG. 1, an aqueous solution containing urea (hereinafter referred to as urea water) is used as the liquid reducing agent. By operating the pump 43 , the urea water stored in the tank 11 is sucked up from one end of the supply pipe 41 and supplied to the nozzle 53 through the second filter. The exhaust gas discharged from the engine 51 to the exhaust pipe 52 contains NOx. This NOx is reduced by the urea water injected from the nozzle 53, becomes ammonia, and is released into the atmosphere.

If the urea water stored in the tank 11 contains dust, it causes the pump 43, the nozzle 53, and the supply pipe 41 to wear. Therefore, a second filter 42 is arranged in the supply pipe 41 . However, since it is complicated to replace the second filter 42, the system in FIG. A strainer 14 is arranged at the spout 12 . Since the area around the spout 12 of the tank 11 is easily accessible, the dust filter 13 can be replaced more easily than when the second filter 42 is replaced.

As described above, the tank 11 is provided with the urea water spout 12 . An example of the spout 12 is shown in FIG. The spout 12 includes a tubular first receiving member 122 fitted in a tubular opening 121 protruding toward the inside of the tank 11 , and a tubular second receiving member 122 fitted inside the first receiving member 122 . A second receiving member 123, a hollow rod-shaped strainer 14 fitted inside the second receiving member 123, and a threaded portion provided on the cylindrical inner wall of the upper end portion of the second receiving member 123. and cap 15 . The strainer 14 is covered with coarse mesh. The tip of the first receiving member 122 has a shape protruding from the tubular opening 121 . In the spout 12 shown in FIG. 2, the mounting portion of the dust filtering filter 13 can be attached to and detached from the projecting outer peripheral surface of the first receiving member 122 by fastening with a fastener 16 such as a jubilee clip or a binding band. can be fixed to

The spout 12 can be fitted with a dust filtering filter, for example, as shown in the following first to fifth embodiments.

[First Embodiment]
FIG. 4 shows one embodiment of a dust filter attached to the spout of the tank. The dust filtering filter 13a has an attachment portion 131a for the spout 12, an opening portion 132a into which the liquid poured into the spout 12 flows, and a bag-like filtering portion 135a. The filtering portion 135a has a shape including a tapered portion 133a whose inner diameter gradually increases from the proximal end where the mounting portion 131a is located toward the distal end.

As shown in FIG. 4, the attachment portion 131a has a tubular shape extending along the extending direction of the filtering portion. The inner diameter of the mounting portion 131 a is configured to be able to be fitted onto the outer peripheral surface of the first receiving member 122 that functions as a mounting portion for the filter provided on the spout 12 . In the example of FIG. 4, the base end of the mounting portion 131a functions as an opening 132a through which the liquid poured into the spout 12 flows. The tapered portion 133a has a truncated cone shape, and its base end portion is joined to the tip end portion of the mounting portion 132a, and its tip end portion is joined to the base end portion of the storage portion 134a. The storage portion 134a has a tubular shape with an outer diameter larger than that of the attachment portion 131a in the radial direction, and its distal end is closed to form a cylindrical bag. In the dust filtration filter 13a of FIG. 4, the tapered portion 133a and the storage portion 134a constitute a bag-like filtering portion. The tapered portion 133a serves to connect the attachment portion 131a with a relatively small diameter and the storage portion 134a with a relatively large diameter. The storage unit 134a increases the filtration area of the dust filtration filter 13a, temporarily stores the urea water when a large amount of urea water is injected into the dust filtration filter 13a, and prevents blowing back to the outside. .

[Second embodiment]
FIG. 5 shows one embodiment of a dust filter attached to the spout of the tank. The dust filtering filter 13b has a mounting portion 131b for the spout 12, an opening 132b for allowing the liquid poured into the spout 12 to flow in, and a bag-like filtering portion 135b. The filtering portion 135b has a shape including a tapered portion 133b whose inner diameter gradually increases from the proximal end where the mounting portion 131b is located toward the distal end.

As shown in FIG. 5, the attachment portion 131b has a tubular shape extending along the extending direction of the filtering portion. The inner diameter of the mounting portion 131b is configured to be able to be fitted onto the outer peripheral surface of the first receiving member 122 functioning as a cylindrical mounting portion provided on the spout 12 . The tapered portion 133b has a truncated cone shape, and has its proximal end joined to the distal end of the attachment portion, and its distal end joined to the proximal end of the storage portion. The storage portion 134b has a tubular shape with a larger outer diameter at its proximal end than the outer diameter of the mounting portion 131b and a gradually smaller inner diameter toward its distal end. The tip of the reservoir 134b is closed and constitutes a bag. In the dust filtration filter 13b of FIG. 5, the tapered portion 133b and the storage portion 134b constitute a bag-like filtering portion.

[Third Embodiment]
FIG. 6 shows one embodiment of a dust filter attached to the spout of the tank. The dust filtering filter 13c has an attachment portion 131c for the spout 12, an opening 132c for allowing the liquid poured into the spout 12 to flow in, and a bag-like filtering portion 135c. The filtering portion 135c has a shape including a tapered portion 133c whose inner diameter gradually increases from the proximal end where the mounting portion 131c is located toward the distal end.

As shown in FIG. 6, the attachment portion 131c has a tubular shape extending along the extending direction of the filtering portion. The inner diameter of the mounting portion 131c is configured to be able to be fitted onto the outer peripheral surface of the first receiving member 122 that functions as a filter mounting portion provided in the spout 12 . The tapered portion 133c has a truncated conical shape, the proximal end of which is joined to the distal end of the mounting portion, and the distal end of which is closed to form a bag. In the dust filtering filter 13c of FIG. 6, the tapered portion 133c and the closed tip portion 136c constitute a bag-like filtering portion.

[Fourth embodiment]
FIG. 7 shows one embodiment of a dust filter attached to the spout of the tank. This dust filtering filter 13d has an attachment portion 131d for the spout 12, an opening 132d for allowing the liquid poured into the spout 12 to flow in, and a bag-like filtering portion 135d. The filter portion 13 has a shape including a tapered portion 133d whose inner diameter gradually increases from the base end where the mounting portion 131d is located toward the tip.

As shown in FIG. 7, the edge of the opening 132d located at the proximal end of the tapered portion 133d functions as the mounting portion 131d. The inner diameter of the opening 132 d is configured to be fitted to the outer peripheral surface of the first receiving member 122 that functions as a mounting portion for the filter provided in the spout 12 . The tapered portion 133d has a truncated conical shape and is closed at its distal end 136d to form a bag. In the dust filtering filter 13d of FIG. 7, the tapered portion 133d and the closed tip portion 136d constitute a bag-like filtering portion.

[Fifth Embodiment]
FIG. 8 shows one embodiment of a dust filter attached to the spout of the tank. The dust filtering filter 13e has a mounting portion 131e for the spout 12, an opening 132e for allowing the liquid poured into the spout 12 to flow in, and a bag-like filtering portion 135e. The filtering portion 135e has a shape including a tapered portion 133e in which the inner diameter of the filtering portion 135e gradually increases from the proximal end where the mounting portion 131e is located toward the distal end.

As shown in FIG. 8, the attachment portion 131e has a tubular shape extending along the extending direction of the filtering portion. The inner diameter of the mounting portion 131 e is configured to be able to be fitted to the outer peripheral surface of the first receiving member 122 that functions as a cylindrical mounting portion for the filter provided in the spout 12 . The tapered portion 133e has a truncated pyramidal shape with a square bottom surface, the base end of which is joined to the tip of the mounting portion, and the tip of which is closed to form a bag. In the dust filtering filter 13e of FIG. 8, the tapered portion 133e and the closed tip portion 136e constitute a bag-like filtering portion. The ridgeline of the tapered portion 133e has a shape in which the ends of the filter material are joined.

In the dust filtration filters of the first to fifth embodiments, the entire filter including the mounting portion is made of filter cloth or non-woven fabric with a thickness of 0.3 to 3.0 mm. Therefore, it is less likely to be damaged by external stress or friction. When the thickness of the filter cloth is increased, generally, the drainage of the filtrate becomes poor, and the urea water injected from the spout tends to flow back. However, the dust filtration filters of the first embodiment to the fifth embodiment all have a tapered portion, and from the base end where the opening of the dust filtration filter is located toward the tip, the filtration portion The inner diameter of the inner diameter gradually increases. As a result, the filtration area is increased, and the drainage of the filtrate is improved. In addition, since a space in which the urea water is temporarily stored is formed in the dust filter, the urea water is prevented from blowing back to the outside of the tank.

In the above system, as shown in FIG. 3, the spout is configured as follows. The tubular opening 121 arranged in the tank 11 has a first flange 611 protruding radially inward. The first receiving member 122 has a first stepped portion 612 that abuts against the first brim portion 611 and protrudes radially outward, and a second brim portion 613 that is disposed at the base end portion and protrudes radially outward. . The second receiving member 123 has a second step portion 614 protruding radially outward. The strainer 14 has a third brim portion 615 arranged at its proximal end portion and protruding radially outward. In the first receiving member 122 , the first stepped portion 612 of the first receiving member 122 abuts the first brim portion 611 of the cylindrical opening 121 , and the second brim portion 613 of the first receiving member 122 contacts the opening portion 121 . It is fixed inside the cylindrical opening 121 by abutting on the edge of the tube. The second receiving member 123 is fixed inside the first receiving member 122 by abutting the second step portion 614 of the second receiving member 123 against the second flange portion 613 of the first receiving member 122. be. The strainer 14 is fixed to the inside of the second receiving member 123 by bringing the third collar portion 615 of the strainer 14 into contact with the second stepped portion 614 of the second receiving member 123 . With the above configuration, the first receiving member 122, the second receiving member 123, the strainer 14, and the cap 15 are fixed to the opening 121 of the tank. The strainer 14 is hollow and rod-shaped, and urea water flows through the inside of the strainer 14, and large-diameter dust is filtered out by the mesh arranged on the side wall portion.

The shape of the spout provided in the tank is not limited to the configuration shown in FIG. The shape of the mounting portion of the dust filtration filter may also be changed according to the shape of the spout. For example, an opening is provided as a spout in the tank, a plurality of claw-shaped projections are provided at the edge of the opening, and the following claw-shaped A configuration in which a plurality of through-holes that can be hooked to the projections of is provided. By making through-holes of the dust filter filter engage with a plurality of hook-like projections on the tank side, the dust filter filter can be hung and fixed to the spout of the tank. In addition, it may be fixed using fasteners such as a male button and a female button. Further, for example, the dust filtration filter may be fixed to a cylindrical mounting member having a configuration different from that of the first receiving member 122 .

In the dust filtration filter according to the above embodiment, a tubular member is shown as an example of the mounting portion. The mounting portion may be provided with a slit extending along the extending direction of the filtering portion for the purpose of facilitating mounting of the dust filtering filter to the spout by opening and closing the mounting portion. By opening and closing the attachment portion at the slit portion of the attachment portion, it is possible to easily attach the dust filtering filter to the spout.

The filtering portion may have a shape including a tapered portion. The shape of the filtering part can be, for example, a truncated cone shape, or a truncated pyramid shape whose bottom surface is a polygon such as a square or a pentagon. The filtering section is not limited to a three-dimensional shape, and may be configured to have a planar bag-like tapered portion like an envelope.

The reservoir is not essential and may be provided or omitted. The shape of the reservoir may be, for example, cylindrical, prismatic, truncated cone, truncated pyramid, or spherical. The storage portion is not limited to a three-dimensional shape, and may be a planar bag shape as described above.

It is preferable that the filter section is made of a filter material such as woven fabric or non-woven fabric. The attachment part is not particularly limited as long as the dust filtering filter can be attached to the spout. However, if the mounting portion is also made of the same material as that of the filtering portion, the configuration and manufacturing process can be simplified, which is preferable.

The method of manufacturing the dust filtration filter is not particularly limited, and it may be formed into the above shape by sewing nonwoven or woven fabric, or may be formed into the above shape by welding by heating. In the case of thermal welding, the nonwoven fabric or woven fabric is preferably made of a thermoplastic resin such as polypropylene.

13a dust filtration filter 131a mounting portion 132a opening 135a filtration portion 133a tapered portion 13b dust filtration filter 131b mounting portion 132b opening 135b filtration portion 133b tapered portion 13c dust filtration filter 131c mounting portion 132c opening 135c filtration portion 133c tapered shape Part 13d Dust filtration filter 131d Mounting part 132d Opening 135d Filtering part 133d Tapered part 13e Dust filtering filter 131e Mounting part 132e Opening 135e Filtering part 133e Tapered part

Claims (1)

A dust filtration filter attached to the spout of a tank that stores a liquid reducing agent that reduces nitrogen oxides contained in exhaust gas,
The dust filtration filter has a mounting portion for the spout, an opening for allowing the liquid poured into the spout to flow in, and a bag-like filtering portion,
The filter part is made of nonwoven fabric with a thickness of 0.3 to 3.0 mm, and has a tapered shape in which the inner diameter gradually increases from the base end where the attachment part is located toward the tip end. including the part
The dust filtering filter has a shape in which the filtering part expands when a liquid flows into the filtering part and does not have folds .

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