KR20210075390A - Cooling water reservoir for urea water injector and working vehicle comprising the reservoir - Google Patents

Abstract

In accordance with an embodiment, a working vehicle comprises: a urea water injector injecting urea water into an exhaust pipe; an auxiliary tank supplying cooling water to a water jacket of the urea water injector, and disposed higher than the urea water injector so that the cooling water is supplied by free fall; a radiator cooling the cooling water circulating inside an engine; a surge tank connected to the radiator, and storing supplemental cooling water therein; and a water pump providing the engine with power for circulating the cooling water. The auxiliary tank is formed so that a first cooling water accommodating chamber in which the cooling water used to cool the urea water injector is accommodated and a second cooling water accommodating chamber in which the cooling water to be supplied to the urea water injector is accommodated are partitioned by a partition wall. In accordance with the embodiment, the working vehicle can rapidly cool the urea water injector under high temperatures when the engine is turned off, thereby ensuring stable injector operation.

Description

An auxiliary tank for cooling an injector and a working vehicle comprising the auxiliary tank {Cooling water reservoir for urea water injector and working vehicle comprising the reservoir}

The present invention relates to an auxiliary tank capable of suppressing an increase in nozzle tip temperature by flowing coolant from a coolant auxiliary tank to an injector even when a vehicle engine is turned off, and a work vehicle including the same.

In general, the exhaust gas discharged from the engine through the exhaust manifold is guided to a catalytic converter formed in the middle of the exhaust pipe to be purified, and after passing through the muffler, noise is attenuated, and then discharged to the atmosphere through the tail exhaust pipe. .

Upstream of the catalytic converter, a filter as a type of Diesel Particulate Filter (DPF) is included to treat soot in the exhaust gas. A selective catalytic reduction (SCR) is one of the types of catalysts applied to the catalytic converter that serves as above. Selective catalytic reduction unit (SCR) is also called 'selective' catalytic reduction in the sense that it allows reducing agents such as THC, CO, etc. to react better with NOx in oxygen and NOx.

Among the selective reduction catalysts, ammonia-SCR uses ammonia as a reducing agent to purify NOx, and not only has excellent selectivity to NOx, but also has the advantage of promoting the reaction between NO and ammonia in the presence of oxygen. It is known to be advantageous for application to diesel exhaust gases.

Urea-SCR (Urea-SCR) is to selectively remove NOx by applying such ammonia-SCR to a vehicle. Since the urea-SCR selectively reduces NOx by using ammonia generated when urea is decomposed by injecting an aqueous urea solution upstream of the SCR catalyst, it can be regarded as ammonia-SCR in terms of the SCR catalyst.

This SCR system consists of a urea water injector, a pump, a controller, a tank, etc., and is configured to inject urea water into the exhaust pipe. It is exposed to high temperatures according to the load conditions of the vehicle. Depending on the cooling method, the injector itself is air cooled or water cooled. is cooling

In the case of work vehicles for agriculture, industry, and construction, etc., due to the characteristic of off-road driving, they do not move in fast driving mode and do high-load work, so a water-cooled cooling method is adopted rather than an air-cooled type, and the after-treatment device is installed inside the engine room. If the engine is stopped after a high-load operation, the coolant circulation is immediately stopped.

In such a hot shutdown condition, the injector is in a state of severe thermal shock, and in a system in which urea water recovery is operated, the nozzle tip of the injector is inevitably exposed to high temperature, and without an appropriate cooling system, the performance of the injector is deteriorated and the injector is clogged. failures such as

An object of the present invention is to propose a work vehicle in which coolant can be supplied to an injector by an auxiliary tank even when the coolant temperature of the water jacket of the injector rises when the work vehicle is stopped at a high temperature.

In addition, even if the coolant inside the water jacket of the injector boils, air can easily escape to the outside of the injector, and it is an object of the present invention to propose an auxiliary tank that allows the coolant to be smoothly supplied to the inside of the injector.

The working vehicle of the embodiment includes a urea water injector configured to inject urea water through an exhaust pipe, and a configuration for supplying cooling water to a water jacket of the urea water injector, so that the cooling water is supplied by free fall. An auxiliary tank disposed at a high position, a radiator for cooling the coolant circulating inside the engine, a surge tank connected to the radiator for storing supplemental coolant therein, and power for circulating coolant into the engine and a water pump providing a, wherein the auxiliary tank has a first cooling water receiving chamber in which the cooling water used for cooling the urea water injector is accommodated, and a second cooling water receiving chamber in which the cooling water to be supplied to the urea water injector is accommodated. It includes an auxiliary tank that is formed to be separated by a bulkhead.

The auxiliary tank of the embodiment is an auxiliary tank for supplying cooling water to a water jacket of the urea water injector when the work vehicle is started off in a work vehicle including a urea water injector, wherein the auxiliary tank forms an exterior a body, a first cooling water accommodating chamber and a second cooling water accommodating chamber separated by a partition wall within the body, a first and second connecting portion for connecting the first cooling water accommodating chamber to an external pipe or hose; a third connection part and a fourth connection part for allowing the cooling water accommodating chamber to be connected to an external pipe or hose, the third connection part being connected to an out hose for supplying cooling water to the water jacket, and the first connection part being the water jacket It is connected to the in-hose from which the coolant used for cooling is recovered from the jacket.

According to the embodiment as proposed, it is possible to quickly cool the high-temperature urea water injector when the engine is turned off, thereby securing a stable injector operation and further preventing clogging of the injector nozzle.

1 is a view showing a partial configuration of a work vehicle equipped with an auxiliary tank of the present embodiment.
Figure 2 is a view showing the coupling position of the auxiliary tank and the urea water injector of this embodiment.
3 is a view showing a cross-section of the urea water injector connected to the auxiliary tank of this embodiment.
4 to 6 are views for explaining the detailed configuration of the auxiliary tank of the present embodiment.

Hereinafter, the present embodiment will be described in detail with reference to the accompanying drawings. However, the scope of the spirit of the present embodiment can be determined from the matters disclosed in this embodiment, and the spirit of the present embodiment is the implementation of addition, deletion, change, etc. of components with respect to the proposed embodiment It will be said to include transformations.

The suffixes "means" and "part" used in the description related to the present invention are given or mixed in consideration of the ease of writing the specification, and do not have distinct meanings or roles by themselves.

1 is a view showing a partial configuration of a work vehicle equipped with an auxiliary tank of the present embodiment.

A cooling system of a work vehicle including an SCR system includes a urea water injector 10 configured to inject urea water through an exhaust pipe, and a water jacket of the urea water injector 10 when the work vehicle is started off. An auxiliary tank 100 disposed at a higher position than the urea water injector 10 so that it can be supplied while falling, a radiator 30 that cools the coolant circulating inside the engine, and an air vent line, etc. It is connected to the radiator 30 and includes a surge tank 20 for storing supplemental coolant therein, and a water pump for providing power for forcibly circulating coolant into the engine.

The surge tank 20 may be connected to the water pump through a coolant replenishment line, and in addition, a configuration such as a thermostat that opens and closes according to the coolant temperature so that the coolant selectively flows into the radiator 30 may also be included.

In this embodiment, the auxiliary tank 100 is disposed at a higher position than the urea water injector 10 so as to be supplied to the water jacket of the urea water injector 10 through free fall when the engine is turned off, and the surge tank 20 ) is arranged at a lower position than, but it is also possible to be installed at a higher position than the surge tank 20 differently from the drawings.

Figure 2 is a view showing the coupling position of the auxiliary tank and the urea water injector of this embodiment, Figure 3 is a view showing a cross section of the urea water injector connected to the auxiliary tank of this embodiment.

2 and 3 , the auxiliary tank 100 is disposed at a higher position than the urea water injector 10 , and the in-hose 101 and the out-hose 102 are respectively connected to the auxiliary tank 100 . . The connecting pipe for allowing the in-hose 101 and the out-hose 102 to freely fall to the urea injector 10 side as the cooling water inside the auxiliary tank 100 is discharged based on the auxiliary tank 100 is out. hose 102 .

The out hose 102 is connected to the coolant inlet 12 of the urea water injector 10 , and the in hose 101 is connected to the inlet and outlet on the other side, not shown. Therefore, the cooling water flowing in through the cooling water inlet 12 of the water jacket 11 of the urea water injector 10 cools the inside of the air jacket 11 and the injector, and then the cooling water whose temperature rises is transferred to the auxiliary tank through another inlet. It is recovered back into the auxiliary tank 100 through the in-hose 101 of the.

That is, when the engine of the work vehicle is turned off, the cooling water inside the auxiliary tank 100 goes down to the water jacket 11 of the urea water injector 10, and the heat exchange continues in which bubbles rise and circulate again by heat. .

At this time, both the in-hose 101 and the out-hose 102 are disposed to have an inclination of at least 10° or more with respect to the horizontal plane, and the coolant supplied to the urea water injector 10 is taken out from the cylinder block rather than the cylinder head, It is desirable to lower the coolant temperature.

In addition, the capacity of the auxiliary tank 100 is preferably 10 times or more compared to the water jacket of the urea water injector 10, and when the water jacket has a capacity of 5 to 10 cc, the capacity is about 50 to 100 cc has

And, as will be described later, the auxiliary tank 100 is also disposed in a direction in which its bottom surface is inclined at a predetermined angle with respect to the horizontal plane, and through this configuration and arrangement, the free fall of the coolant can be made at a high speed.

On the other hand, a urea water inlet 13 into which urea water is introduced is configured on the upper side of the urea water injector 10 , and a urea water nozzle 14 for injecting the introduced urea water into the exhaust pipe is configured on the lower side.

4 to 6 are views for explaining the detailed configuration of the auxiliary tank of the present embodiment.

The auxiliary tank 100 of the embodiment includes a body 110 forming an exterior, and a first cooling water accommodating chamber 120 and a second cooling water accommodating chamber 130 divided by a partition wall 140 in the body 110 . The second coolant accommodating chamber 130 accommodates the water of the auxiliary water tank to be supplied to the urea water injector, and the first coolant accommodating chamber 120 receives the coolant heated through the urea water injector again. It plays the role of supplying water to the water pump.

In detail, a first connection part 161 for connecting the inside of the first coolant accommodating chamber 120 and the in-hose 101 so that the coolant heated by the urea water injector flows into the first coolant accommodating chamber 120; A second connection part 162 for moving the coolant warmed by the water pump, and a third connection part 163 for connection to the out hose 102 for supplying coolant to the urea water injector 10, and the auxiliary water tank and a fourth connection part 164 for supplying water into the second cooling water accommodating chamber 130 .

Inside the auxiliary tank 100 , the first cooling water accommodating chamber 120 and the second cooling water accommodating chamber 130 are separated by a partition wall 140 , and in particular, the temperature accommodated in the first cooling water accommodating chamber 120 . The partition wall 140 is made of a heat insulating material so that the cooling water having a high level can minimize heat transfer to the cooling water of the second cooling water accommodating chamber 130 and forcibly circulate by the driving force of the water pump.

In addition, the body 110 surrounding the first and second cooling water accommodating chambers 120 and 130 of the auxiliary tank 100 is also made of an insulating material, and the temperature of the low-temperature cooling water inside the second cooling water accommodating chamber 130 decreases due to the surrounding heat. prevent it from rising

In particular, as shown in FIG. 6 , the auxiliary tank 100 is disposed at a predetermined angle with respect to the horizontal plane, and the coolant in the second coolant accommodating chamber 130 is a urea water injector (10). The process of being supplied while freely falling to the water jacket 11 of the

According to the auxiliary tank of the embodiment as described above, when the engine is started off, cooling water can be smoothly supplied to the urea water injector remaining in the high-temperature exhaust pipe, and since the cooling water is supplied by free fall of the cooling water, the engine is started for supplying cooling water. There is an advantage in that cooling water can be supplied even when the water pump is not operated when it is off.

10: urea water injector 11: water jacket
100: auxiliary tank 110: body
120: first cooling water accommodating chamber 130: second cooling water accommodating chamber
140: bulkhead 150: insulation

Claims (6)

a urea water injector configured to inject urea water into an exhaust pipe;
A configuration for supplying cooling water to the water jacket of the urea water injector, and an auxiliary tank disposed at a higher position than the urea water injector so that the cooling water is supplied by free fall;
a radiator for cooling the coolant circulating inside the engine;
a surge tank connected to the radiator and storing supplemental cooling water therein;
a water pump providing power for circulating the coolant into the engine;
The auxiliary tank is an auxiliary tank formed such that a partition wall separates a first cooling water receiving chamber in which the cooling water used for cooling the urea water injector is accommodated and a second cooling water receiving chamber in which the cooling water to be supplied to the urea water injector is accommodated. A work vehicle comprising a. The method of claim 1,
The bulkhead and the body forming the outer shape of the auxiliary tank are made of an insulating material. The method of claim 1,
The auxiliary tank is a work vehicle including an auxiliary tank, characterized in that disposed in a state inclined by a predetermined angle with respect to the horizontal plane. In a work vehicle including a urea water injector, an auxiliary tank for supplying cooling water to a water jacket of the urea water injector when the work vehicle is turned off, comprising:
The auxiliary tank is
a body forming an appearance; and
a first cooling water accommodating chamber and a second cooling water accommodating chamber divided by a partition in the body;
a first connection part and a second connection part for connecting the first cooling water accommodating chamber to an external pipe or hose;
a third connection part and a fourth connection part for connecting the second cooling water accommodating chamber to an external pipe or hose;
The third connection part is connected to an out hose for supplying cooling water to the water jacket,
The first connection part is an auxiliary tank connected to an in-hose from which the coolant used for cooling in the water jacket is recovered. 5. The method of claim 4,
The bulkhead is an auxiliary tank, characterized in that made of an insulating material. 5. The method of claim 4,
The auxiliary tank, characterized in that the pipe or hose for moving the cooling water to the water jacket of the urea water injector is disposed in a downwardly inclined state from the auxiliary tank so that the cooling water can freely fall.

Images