Liquid tank, breather device, and exhaust gas purification device for engine

Abstract

In a liquid tank provided with a pressure relief vent hole, a shielding member surrounding the vent hole is disposed. The shielding member forms an isolated chamber communicated with the vent hole. In a portion located to the side of the vent hole, the shielding member allows communication between the isolated chamber and an inner space in the liquid tank excluding the isolated chamber. On the other hand, in a portion located below the vent hole, the shielding member blocks movement of the liquid between the isolated chamber and the inner space.

Description

This application is a continuation of PCT/JP2007/052866, filed on Feb. 16, 2007.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a liquid tank, a breather device therefor, and an exhaust gas purification device for an engine. In more detail, the invention relates to a technology for preventing liquid outflow through a vent hole provided for pressure relief, in a liquid tank installed on a vehicle.

2. Description of the Related Art

A vehicle provided with an internal combustion engine (hereunder, simply referred to as “engine”) serving as a driving source, as disclosed in Japanese Laid-open (Kokai) Patent Application Publication No. H07(1995)-208138 (Paragraphs 0024-0027), is equipped with a liquid tank for storing lubricating oil, fuel, and so forth to be used when operating the engine. Moreover, development of an exhaust gas purification device for an engine that uses the urea SCR (Selective Catalytic Reduction) has progressed in recent years, and is already being put to practical use. In a type of exhaust gas purification device disclosed in Japanese Laid-open (Kokai) Patent Application Publication No. 2000-027627 (Paragraph 0013), there is installed a liquid tank for storing urea aqueous solution that serves as a liquid reducing agent. In the liquid tank, in addition to an opening for suctioning/discharging the stored liquid, there is provided a pressure relief vent hole that communicates between the interior of the liquid tank and the exterior thereof. This vent hole is generally constructed so as to open the interior of the liquid tank to the atmosphere. When the liquid is suctioned from the liquid tank, outside air flows in via the vent hole, thereby maintaining the pressure inside the liquid tank at a constant level.

However, in a liquid tank having such a vent hole, there is a problem in that vibrations of the engine or vehicle body when traveling cause the stored liquid to flow out to the outside via the vent hole.

When the vehicle is traveling, vibrations of the engine or vehicle body are transmitted to the liquid tank, so that the wall face of the liquid tank is vibrated, then vibrations of the wall face are transmitted to and vibrate air inside the liquid tank, and cause the inside air to intermittently flow out from the liquid tank via the vent hole. Such a phenomena becomes significant if resonance occurs in the wall face of the liquid tank due to the frequency of the vibrations. In this case, sloshing or waving occurs in the liquid inside the liquid tank due to vibrations of the engine or acceleration/deceleration of the vehicle, and if the liquid is attached to the surroundings of the vent hole, this attached liquid together with the inside air flows out to the outside via the vent hole.

SUMMARY OF THE INVENTION

The present invention addresses the above problems, and provides a structure that makes attachment of liquid to the surroundings of the vent hole unlikely to occur, thereby preventing liquid outflow through the vent hole.

The present invention provides a liquid tank, a breather device therefor, and an exhaust gas purification device for an engine.

The liquid tank according to the present invention includes: a tank main body configured to store a liquid therein, and provided with a vent hole that enables an interior of the tank main body to communicate with an exterior thereof; and a shielding member attached to the tank main body so as to surround the vent hole within the tank main body, and to form an isolated chamber communicated with the vent hole. The shielding member includes a first portion that is located to the side of the vent hole in the horizontal direction, and that forms an opening that communicates between the isolated chamber and an inner space of the tank main body excluding the isolated chamber, and in a second portion other than the first portion, the shielding member blocks movement of the liquid between the isolated chamber and the inner space.

The exhaust gas purification device for an engine according to the present invention includes: the above liquid tank configured to be appropriate for storing a liquid reducing agent as the above liquid; a NOx reducing catalytic converter installed in an exhaust gas passage of the engine; and a device arranged to be capable of supplying a liquid reducing agent stored in the liquid tank, to exhaust gas on an upstream of the reducing catalytic converter.

Moreover, the breather device according to the present invention is a device that relieves the pressure inside a liquid tank, and includes: a breather pipe forming a vent hole that enables an interior of the liquid tank to communicate with an exterior thereof; and a shielding member configured to be disposed with respect to the breather pipe, within the liquid tank so as to surround the vent hole, and to form an isolated chamber communicated with the vent hole. The shielding member includes, a first portion and a second portion. Here, the first portion is located to the side of the vent hole in the horizontal direction to enclose the vent hole, and forms an opening that communicates between the isolated chamber and an inner space within the liquid tank excluding the isolated chamber, and the second portion is located below the vent hole so as to block movement of liquid between the isolated chamber and the inner space.

According to the present invention, inside the liquid tank, the shielding member is disposed so as to surround the vent hole. In the first portion of the shielding member located to the side of the vent hole in the horizontal direction, while air circulation is allowed between the isolated chamber and the inner space of the liquid tank excluding the isolated chamber (“inner space of the liquid tank” and “space inside the liquid tank main body” excludes the isolated chamber unless otherwise stated), while in the second portion, movement of the liquid between the isolated chamber and the inner space is blocked. Consequently, even if sloshing or waving occurs in the liquid inside the liquid tank due to vibrations of the engine or the like when traveling, attachment of the liquid to the surroundings of the vent hole is suppressed by the first portion (excluding the opening) and the second portion, so that liquid outflow via the vent hole can be prevented. The pressure inside the liquid tank is relieved via; the vent hole, the isolated chamber formed by the shielding member, and the opening of the first portion.

As such, those skilled in the art will appreciate that other objects and features of the present invention can be understood from the following description, with reference to the appended drawings.

The entire contents of Japanese Patent Application No. 2006-085019 on which the priority of this application is based, are incorporated herein by reference.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic block diagram of an exhaust gas purification device for an engine, according to a first embodiment of the present invention.

FIG. 2 is a front perspective view of a liquid tank according to the embodiment.

FIG. 3 is a front sectional view of the liquid tank.

FIG. 4 is a side sectional view of the liquid tank.

FIG. 5 is a front sectional view of a liquid tank according to a second embodiment of the present invention.

FIG. 6 is a side sectional view of the liquid tank.

FIG. 7 is an enlarged perspective view of a mounting portion for a shielding plate.

FIG. 8 is a front view of an L-shaped member that constitutes the shielding plate.

FIG. 9 is a plan view of the L-shaped member.

FIG. 10 is a bottom view of the mounting portion for the shielding plate constituted using the L-shaped member.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Hereunder is a description of embodiments of the present invention, with reference to the drawings.

FIG. 1 is a schematic block diagram of an exhaust gas purification device for an engine, according to a first embodiment of the present invention.

In the present embodiment, an engine 1 is a diesel engine, and is employed to constitute a driving source of a vehicle (here, a large vehicle such as truck).

In an exhaust gas passage 2 of the engine 1, there is interposed a reducing catalytic converter 3 for nitrogen oxides (hereunder, referred to as “NOx”), and this reducing catalytic converter 3 accelerates reductive purification of NOx in engine exhaust gas. In the present embodiment, urea aqueous solution serving as a liquid reducing agent is supplied to the exhaust gas for NOx purification, and a urea aqueous solution injection nozzle 4 (hereunder, simply referred to as “injection nozzle”) is provided on the upstream of the reducing catalytic converter 3. The injection nozzle 4 is inserted into the exhaust gas passage 2 in a manner of passing through the pipe wall of the exhaust gas passage 2 from the outside, and the tip end thereof is directed to the end face on the upstream side of the reducing catalytic converter 3.

Urea aqueous solution to be supplied into the exhaust gas is stored in a liquid tank 7. In consideration if simplifying use on a vehicle, urea, which is an ammonia precursor, has previously prepared in aqueous solution state. The liquid tank 7 is connected, via a reducing agent supply pipe 8, to a reducing agent supply device 6. The reducing agent supply pipe 8 forms a delivery passage for the urea aqueous solution towards the reducing agent supply device 6. A member constituting this supply pipe 8 corresponds to a “pipe member” according to the present embodiment. A feed pump (not shown in the drawing) feeds the urea aqueous solution in the liquid tank 7, via the reducing agent supply pipe 8, to the reducing agent supply device 6. The reducing agent supply device 6 is connected, via a reducing agent supply pipe 5, to the injection nozzle 4, and the urea aqueous solution that has been fed into the reducing agent supply device 6 is supplied together with compressed air, via the reducing agent supply pipe 5, to the injection nozzle 4. The urea supplied to the exhaust gas is hydrolyzed by exhaust heat, to generate ammonia and is then supplied to the reducing catalytic converter 3 as a NOx reducing agent. The reducing agent supply device 6 is connected to the liquid tank 7 not only via the reducing agent supply pipe 8, but also via a reducing agent return pipe 9. A surplus portion of the urea aqueous solution supplied from the liquid tank 7 to the reducing agent supply device 6 that is not supplied to the injection nozzle 4 is returned to the liquid tank 7 via this return pipe 9.

The operation of the reducing agent supply device 6 is controlled by signals from an electronic control unit 10 (also serving as a control unit for the engine 1; hereunder simply referred to as “control unit”). The control unit 10 performs, based on the operating state of the engine 1, a predetermined calculation related to a reducing agent supply operation, and outputs a command signal to the reducing agent supply device 6. In the present embodiment, for detecting the operating state, there are provided: an accelerator sensor 101 that detects an amount of operation of the accelerator pedal by a driver; a crank angle sensor 102 that detects a rotating angle of the crank shaft; and a temperature sensor 103 that detects the temperature of engine coolant. The engine rotating speed can be calculated based on signals from the crank angle sensor 12.

FIG. 2 is a front perspective view showing an overall configuration of the liquid tank 7 according to the present embodiment.

The liquid tank 7 is formed overall in a rectangular in cross-section with a depth D shorter than a width W (and height H), and is mounted on a vehicle in a state where the direction of the depth D coincides with the traveling direction of the vehicle. In an upper part of a left side wall 7a of the liquid tank 7, there is provided a refilling opening 11 for refilling urea aqueous solution.

FIG. 3 and FIG. 4 show an internal structure of the liquid tank 7 according to the present embodiment. FIG. 3 is a sectional view of the liquid tank 7 viewed from the front, and FIG. 4 is a sectional view of the liquid tank 7 viewed from the right side.

In an upper wall 7b of the liquid tank 7, there is provided an opening for inserting the reducing agent supply pipe 8 and a heat exchange pipe 21 described later into the liquid tank 7, and a top lid 20 is fastened on the upper wall 7b so as to close up this opening. The reducing agent supply pipe 8, the heat exchange pipe 21, and the reducing agent return pipe 9 pass through and are fixed on the top lid 20. In the state shown in the drawing with the top lid fastened, the reducing agent supply pipe 8 extends to the bottom part of the liquid tank 7 (in FIG. 3 the tip end is denoted by reference symbol 8a). The reducing agent return pipe 9 ends in close proximity to the underside face of the top lid 20, and opens above the fluid level Hf at which the liquid tank is fully filled (in FIG. 4 the tip end is denoted by reference symbol 9a).

The heat exchange pipe 21 is disposed inside the liquid tank 7. The heat exchange pipe 21 is formed by bending a rod shaped pipe, and constitutes a heat exchanger that circulates engine coolant to thereby exchange heat between the engine coolant and the urea aqueous solution inside the liquid tank 7. Opposite ends of the heat exchange pipe 21 pass through the top lid 20 so as to extend to the outside of the liquid tank 7. One opening 22 forms a supply port for engine coolant and another opening 23 forms a discharge port for the engine coolant. The heat exchange pipe 21 constitutes a part of an engine coolant circulation passage. The engine coolant heated by the engine 1 travels through this heat exchange pipe 21, thereby heating urea aqueous solution stored in the liquid tank 7. In a cold state of operation, even though the urea aqueous solution inside the liquid tank 7 is frozen at the time of starting the engine 1, heated engine coolant travels through the heat exchange pipe 21, thereby promoting thawing out of the frozen urea aqueous solution. Moreover, when the urea aqueous solution inside the liquid tank 7 is excessively heated, the engine coolant acts as a coolant for cooling down the urea aqueous solution, thereby preventing precipitation of urea.

Furthermore, on the top lid 20 there is attached a breather pipe 24 hollowed therethrough in the axial direction. By means of this breather pipe 24, the interior of the liquid tank 7 is communicated with the exterior thereof, and a vent hole 25 is formed for relieving the pressure inside the liquid tank 7. The breather pipe 24 extends upward beyond the top lid 20, and to the top end of the breather pipe 24, there is connected one end 26a of a breather hose 26. The breather hose 26 extends sideways beyond the right side wall of the liquid tank 7, and another end 26b of the breather hose 26 faces downward at a position in close proximity to the fluid level Hf at which the liquid tank 7 is fully filled.

Furthermore, on the top lid 20, there is attached a shielding plate 30 for suppressing attachment of the urea aqueous solution to the surroundings of the vent hole 25. In the present embodiment, the shielding plate 30 is constituted by a member 31 made by bending a rectangular thin plate in a U-shape, and is fixed on the underside face of the top lid 20 in a condition with a bent part 31b (that corresponds to a “second portion” of the shielding member) of the U-shaped member 31 directed downward below the vent hole 25. The bent part 31b is located above the fluid level Hf at which the liquid tank 7 is fully filled. Moreover, the shielding plate 30 is disposed so as to straddle the opening (that is, the vent hole 25) of the breather pipe 24 in the depth D direction of the liquid tank 7, that is, the vehicle traveling direction. In front and rear of the vent hole 25 in the traveling direction and below the vent hole 25, the shielding pate 30 partitions the interior of the liquid tank 7 so as to form an isolated chamber 32 that communicates with the vent hole 25. In a portion of the shielding plate 30 continuing from the inner wall of the liquid tank 7 (that corresponds to the “first portion” and is formed by flat face parts 31 a of the U-shaped member 31), there are provided opposite U-shaped openings 33 at positions on the left and right sides of the vent hole 25 in the vehicle widthwise direction, and the isolated chamber 32 and the inner space of the liquid tank 7 excluding this chamber 32 are communicated via these openings 33. The shielding plate 30 is formed with a wide width, and has a dimension in the width W direction that is greater than that in the depth D direction, in a state of being installed inside the liquid tank 7. In the present embodiment, the shielding plate 30 is in direct contact with the heat exchange pipe 21. However, the shielding plate 30 may be in contact with the heat exchange pipe 21 via a heat transfer body. The shielding plate 30 and the heat exchange pipe 21 may be joined together by welding. In this case, the welding bead acts as a heat transfer body.

According to the present embodiment, the following effects can be achieved.

That is to say, in the present embodiment, inside the liquid tank 7, the U-shaped shielding plate 30 is installed so as to straddle the vent hole 25 in the vehicle traveling direction, and movement of the urea aqueous solution to the front and rear of the vent hole 25 in the traveling direction and below the vent hole 25 is thereby blocked. Therefore, even if sloshing or waving occurs in the urea aqueous solution in the liquid tank 7 due to vibrations of the engine 1 and acceleration/deceleration of the vehicle, the shielding plate 30 suppresses attachment of the urea aqueous solution to the surroundings of the vent hole 25, so that outflow of the urea aqueous solution through the vent hole 25 can be prevented. In the present embodiment, in particular, the liquid tank 7 is formed in a rectangular in cross-section that is long in the width W direction with respect to the depth D direction, and the front and rear wall faces have an area that is greater than that of the left and right wall faces. Therefore, in the case where vibrations occur in the wall faces of the liquid tank 7 due to vibrations of the engine 1 during operation, in the liquid tank 7, waves are likely to occur between the front and rear wall surfaces, in other words, they are likely to occur in the depth D direction. In the present embodiment, as described above, the shielding plate 30 is formed with a wide width, and has a larger dimension in the width W direction in a state of being installed inside the liquid tank 7. Therefore, waves that occur between the front and rear wall faces can be reliably stopped by the shielding plate 30, so that attachment of the urea aqueous solution to the surroundings of the vent hole 25 can be suppressed. Moreover, by making the shielding plate 30 have a greater dimension in the width W direction, then when the vehicle body sways left and right due to traveling course changes, a situation where the urea aqueous solution goes around the first portion 31 a of the shielding plate 30 and reaches the vent hole 25 via the openings 33 can be suppressed. Moreover, by making the depth D direction of the liquid tank 7 coincide with the traveling direction of the vehicle, then even if waves occur in the urea aqueous solution due to acceleration/deceleration of the vehicle, attachment of the urea aqueous solution can be suppressed.

Furthermore, in the present embodiment, the shielding plate 30 is in contact with the heat exchange pipe 21 and the engine coolant is circulated through this pipe 21, so that heat of the engine coolant is directly transferred to the shielding plate 30. Therefore, in a cold state of operation, even though the urea aqueous solution is frozen, and lumps of ice are formed in the liquid tank 7 and block up the openings 33 of the shielding plate 30, this ice lumps can be quickly thawed out so that the function of the vent hole 25 can be maintained. On the other hand, when the urea aqueous solution is excessively heated, this is cooled by the engine coolant. Therefore, precipitation of urea from the urea aqueous solution can be prevented.

Hereunder, another embodiment of the present invention will be described.

FIG. 5 and FIG. 6 show an internal structure of a liquid tank 7 according to a second embodiment of the present invention. FIG. 5 is a sectional view viewed from the front, and FIG. 6 is a sectional view viewed from the right side. Moreover, FIG. 7 is an enlarged perspective view showing a configuration of a mounting portion for a shielding plate 40 according to the present embodiment. In the present embodiment, the configuration of components or parts other than the liquid tank 7 may be similar to those in the first embodiment. Moreover, in FIG. 5 and FIG. 6, components or parts having functions or effects similar to in the first embodiment are denoted by the same reference symbols, and detailed descriptions thereof are omitted.

The liquid tank 7 according to the present embodiment, compared to that in the first embodiment, is characterized in the configuration of the shielding plate 40. As shown enlarged in FIG. 7, in the present embodiment, the shielding plate 40 is formed by joining an L-shaped member 41 and side plates 44 and 45 into a box shape by means of welding, soldering or the like. The shielding plate 40 is attached to the underside face of the top lid 20 so as to surround the vent hole 25, thereby partitioning the interior of the liquid tank 7 in front and to the rear and left side of the vent hole 25 in the vehicle traveling direction, and below the vent hole 25 so as to form an isolated chamber 42 communicating with the vent hole 25. In a portion of the shielding plate 40 continuing from the inner wall of the liquid tank 7 (that corresponds to the “first portion” and is formed by a side part 41 a of the L-shaped member 41 and the side plates 44 and 45), there is formed a rectangular shaped opening 43 at a position on the right side of the vent hole 25 in the vehicle widthwise direction, and the isolated chamber 42 and the inner space within the liquid tank 7 excluding this chamber 42 are communicated via the opening 43. In the present embodiment, the “second portion” of the shielding member is formed by a bottom part 41b of the L-shaped member.

FIG. 8 and FIG. 9 show a configuration of the L-shaped member 41 that constitutes the shielding plate 40 according to the present embodiment. FIG. 8 is a front view and FIG. 9 is a plan view.

The L-shaped member 41 is formed by bending a flat thin plate in a substantial L-shape. The side part 41a forms the “first portion” of the shielding member, and the bottom part 41b forms the “second portion” thereof.

FIG. 10 is a bottom view of the mounting portion for the shielding plate 40 according to the present embodiment. As shown in FIG. 10, the side part 41a of the L-shaped member 41 is disposed to the side of the vent hole 25 in the horizontal direction (on the left side with respect to the vehicle traveling direction), and the bottom part 41b is disposed below the vent hole 25, thereby partitioning the interior of the liquid tank 7 at their respective positions.

The side plates 44 and 45 are both formed in a flat plate shape, and one side plate 44 in front of the vent hole 25 in the traveling direction, and another side plate 45 to the rear of the vent hole 25 in the traveling direction, respectively partition the interior of the liquid tank 7. In the present embodiment, the side plate 44 disposed on the front side also serves as a heat transfer plate that connects the heat exchange pipe 21 and the reducing agent supply pipe 8. That is to say, the side plate 44 is joined to the bottom part 41 b of the L-shaped member 41, and is also disposed so as to be in contact with both of the heat exchange pipe 21 and the reducing agent supply pipe 8. When the engine coolant heated by the engine 1 travels through the heat exchange pipe 21, heat of the engine coolant is transferred to the reducing agent supply pipe 8 via the side plate 44, and the urea aqueous solution in the reducing agent supply pipe 8 is heated.

According to the present embodiment, since the side part 41a of the L-shaped member 41 is disposed on the left side of the vent hole 25 in relation to the vehicle traveling direction, attachment of the urea aqueous solution from this left side can be prevented. In particular, according to the present embodiment, since the side plate 44 prevents attachment of urea aqueous solution and this side plate 44 also serves a function of the heat transfer plate that connects the heat exchange pipe 21 and the reducing agent supply pipe 8, it is possible to promote thawing out of the urea aqueous solution that is frozen within the reducing agent supply pipe 8, while reducing the number and weight of required components.

In the above description, the shielding plate is formed such that the sectional shape thereof is of a U-shape or L-shape (overall box shape). However, the shape of the shielding plate is not limited to these shapes, and may be any shape that can surround the vent hole within the liquid tank. The shape of the shielding plate may be appropriately selected according to the direction of sloshing or waving of the liquid that occurs inside the liquid tank.

Moreover, in the second embodiment, a portion of the shielding plate also serves a function of the heat transfer plate. However, additional functions of the shielding plate are not limited to this. It is possible to constitute the shielding plate using other components provided in the liquid tank than the heat transfer plate.

Furthermore, the shape of the liquid tank is not limited to the rectangular shape described above, and it is possible to adopt various shapes. The direction of waves that occur in the liquid tank due to vibrations of the engine during operation is pre-checked, and the shape of the shielding plate (in other words, the position of the opening) is set so that waves occurring in this direction are blocked.

The present invention is not limited to a liquid tank for storing urea aqueous solution, and may also be applied to a liquid tank for storing other types of liquids, including other liquid reducing agents such as aqueous ammonia and fuel of hydrocarbon, lubricating oil, fuel and so forth.

The present invention has been described above by the preferred embodiments. However, the scope of the present invention is not limited by this description, and is to be judged in accordance with applicable provisions, based on the disclosure of the claims.

Claims

1. A liquid tank comprising:

a tank main body configured to store a liquid therein, the tank main body including a vent hole enabling an interior of the tank main body to communicate with an exterior thereof; and

a shielding member attached to the tank main body so as to surround the vent hole within the tank main body, and to form an isolated chamber communicated with the vent hole, wherein

the shielding member includes a first portion located to the side of the vent hole in the horizontal direction and a second portion other than the first portion, the first portion forming an opening that communicates between the isolated chamber and an inner space of the tank main body excluding the isolated chamber, and in the second portion, the shielding member blocks movement of the liquid between the isolated chamber and the inner space.

2. A liquid tank comprising:

a tank main body configured to store a liquid therein, the tank main body including a vent hole enabling an interior of the tank main body to communicate with an exterior thereof; and

a shielding member attached to the tank main body so as to surround the vent hole within the tank main body, and form an isolated chamber communicated with the vent hole, wherein

the shielding member includes;

a first portion disposed at the side of the vent hole in the horizontal direction to enclose the vent hole, the first portion forming an opening that communicates between the isolated chamber and an inner space of the tank main body excluding the isolated chamber, and

a second portion located below the vent hole so as to block movement of the liquid between the isolated chamber and the inner space.

3. The liquid tank according to claim 1, wherein the shielding member is constituted by a single member with a cross-section formed in a U-shape.

4. The liquid tank according to claim 1, wherein the vent hole is provided in a lid part of the tank main body.

5. The liquid tank according to claim 1, wherein

the tank main body is of a rectangular in cross-section with the depth less than the width, and

the shielding member is longer in the width direction of the tank main body than in the depth direction thereof.

6. The liquid tank according to claim 5 provided for a vehicle, wherein

the tank main body is fixed with respect to the vehicle, with the widthwise direction thereof aligned with the left to right direction of the vehicle.

7. A liquid tank according to claim 1 provided for a vehicle having an engine, further comprising a heat exchange pipe located inside the tank main body, and configured to circulate an coolant of the engine.

8. The liquid tank according to claim 7, wherein the heat exchange pipe is located inside the tank main body, in contact with the shielding member.

9. The liquid tank according to claim 8, wherein the heat exchange pipe is contacted with the shielding member via a heat transfer body.

10. The liquid tank according to claim 7 further comprising a pipe member forming a delivery passage for the liquid, and

the heat exchange pipe is thermally contacted with the pipe member via the shielding member.

11. The liquid tank according to claim 10, wherein

the liquid is a urea aqueous solution, and

the pipe member is arranged to constitute a passage for delivering the urea aqueous solution stored in the tank main body, towards an exterior of the tank main body.

12. The liquid tank according to claim 1, wherein the liquid is a urea aqueous solution.

13. An exhaust gas purification device for an engine, comprising:

the liquid tank according to claim 1, configured to be appropriate for storing a liquid reducing agent as the liquid;

a NOx reducing catalytic converter installed in an exhaust gas passage of the engine; and

a device configured to be capable of supplying the liquid reducing agent stored in the liquid tank, to exhaust gas on the upstream of the reducing catalytic converter.

14. A breather device for relieving the pressure inside a liquid tank, comprising:

a breather pipe forming a vent hole that enables an interior of the liquid tank to communicate with an exterior thereof; and

a shielding member configured to be disposed with respect to the breather pipe, within the liquid tank so as to surround the vent hole, and to form an isolated chamber communicated with the vent hole, wherein

the shielding member includes a first portion and a second portion, and wherein

the first portion locates to the side of the vent hole in the horizontal direction to enclose the vent hole, and forms an opening that communicates between the isolated chamber and an inner space within the liquid tank excluding the isolated chamber, and

the second portion locates below the vent hole so as to block movement of liquid between the isolated chamber and the inner space.