KR101500751B1 - Inner partition type oil cooler - Google Patents

Abstract

The present invention discloses an internal divided oil cooler. The oil cooler includes a first core portion 4 including a plurality of tubes and radiating fins and an inlet 23 communicating with an upper portion of the first core portion and supplying an operating fluid to one of the longitudinal end portions A first cooler unit 21 including a first upper tank 12 and a first lower tank 15 communicating with a lower portion of the first core unit 4; A second core portion 5 disposed in parallel to the first core portion 4 and including a plurality of tubes and radiating fins, a first guide channel 24 communicating with the upper portion of the second core portion, A second upper tank 13 partially communicating with the first upper tank 12 through the first upper tank 12 and a second upper tank 13 communicating with a lower portion of the second core 5, And a second cooler unit 22 having an outlet 25 and a second lower tank 16 partially communicating with the first lower tank 15 through a second guide channel 26 . INDUSTRIAL APPLICABILITY The present invention makes it possible to ensure the strength of the tank according to the internal pressure of the fluid, to improve the assemblability and maintainability, and to evenly divide and guide the operating oil.

Oil cooler, split type, core part

Description

[0001] INNER PARTITION TYPE OIL COOLER [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an oil cooler for cooling hydraulic oil for operating various actuators in a construction machine such as an excavator and a loader, The present invention relates to an internal split type oil cooler that can ensure the strength of the tank according to the internal pressure of the internal combustion engine and improve the assemblability and maintainability and to divide and guide the operating oil evenly.

Generally, a construction machine such as an excavator, a loader, etc., drives a hydraulic pump by the power of an engine and operates various hydraulic cylinders of the working machine as hydraulic oil generated from the hydraulic pump. Further, as a hydraulic oil generated from a hydraulic pump, For various hydraulic motors. At this time, when the hydraulic cylinder or the hydraulic motor is operated, the heat generated by the friction heats the operating oil. Since such high-temperature operating oil is highly likely to deteriorate various kinds of seals and components in the hydraulic system, the construction machine is provided with an oil cooler capable of cooling high-temperature operating oil. Such an oil cooler must have a heat dissipation effect for cooling the operating oil and a durability against the action of the operating oil pressure.

1 is a schematic perspective view showing a structure of a conventional oil cooler in which core portions are arranged in two rows and one tank is arranged in each of upper and lower portions.

The oil cooler 1 of the prior art according to Fig. 1 comprises upper and lower tanks 2, 3 for taking in and out hydraulic oil, first and second core portions 4, 5 arranged in two rows between the tanks 2, . A portion of the upper tank 2 is provided with an inlet 2a and a portion of the lower tank 3 is provided with an outlet 3a. The first and second core portions 4 and 5 are provided with a plurality of tubes (not shown) communicating with the inside of the upper and lower tanks 2 and 3, (Not shown).

Accordingly, the working oil flows into the upper tank 2 through the inlet 2a and is divided into the first and second core portions 4,5. Subsequently, the hydraulic fluid flowing into the first and second core portions 4 and 5 flows to the lower tank 3 along the corresponding tube (not shown) and flows out through the discharge port 3a while joining . At this time, the operating oil flowing down through the tubes of the first and second core portions (4,5) is cooled through the heat exchange action between the wind blowing from the cooling fan (not shown) and the radiating fins.

However, since the upper tank 2 of the prior art oil cooler 1 as described above covers one of the two core portions, it is inevitably formed into a large elliptical shape. Therefore, the upper tank 2 has a relatively large stress due to the high-temperature, high-pressure operating oil that continuously flows into the upper tank, as compared with the case where the tank is provided in each tank, Concerns about breakage were very high. This problem can be solved by increasing the thickness of the upper tank 2, but there is a problem of waste of material. The lower tank 3 of the prior art oil cooler 1 is less influenced by the high temperature than the upper tank 2 but has a relatively large thickness due to the relatively high stress caused by the high pressure hydraulic oil .

2 is a schematic perspective view showing a structure in which a core portion is arranged in two rows and two tanks are arranged in an upper portion and a lower portion, respectively, according to a conventional oil cooler.

The oil cooler 10 of the prior art according to FIG. 2 includes first and second upper tanks 12 and 13 respectively connected to an oil supply pipe 11 for supplying operating oil, an oil discharge pipe 14 for discharging operating oil, A first core unit 4 connecting the first upper tank 12 and the first lower tank 15 to each other and a second upper tank 15 connected to the second upper tank 15, And a second core portion 5 connecting the first lower tank 16 and the second lower tank 16 to each other. Each of the first and second core units 4 and 5 is provided with a plurality of tubes (not shown) communicating with the inside of the corresponding tanks, and a plurality of radiating fins (not shown) have.

Accordingly, the working oil is divided into two bifurcations through the oil supply pipe 11, and a part thereof flows into the first upper tank 12, the first core portion 4 and the first lower tank 15, 2 upper tank 13, the second core portion 5, and the second lower tank 16, respectively. Subsequently, the hydraulic fluid introduced into the first lower tank 15 and the second lower tank 16 is discharged through the oil discharge pipe 14 to the outside. At this time, the operating oil flowing down through the tubes of the first and second core portions (4, 5) is cooled through a heat exchange action between the wind blowing from the cooling fan (not shown) and the radiating fins.

However, in the oil cooler 10 of the prior art as described above, the operating oil is supplied for each tank, and the flow rate is evenly distributed and discharged. However, the oil supply pipe 11 and the oil discharge pipe 14, So that the piping space for the operation is very narrow, so that the assembly and maintenance are not good. This is because the front or rear of the oil cooler 10 is very close to the engine or radiator grill.

Accordingly, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an internal split type oil cooler which has sufficient durability of a tank against pressure of operating oil and improves assemblability and maintainability of piping .

In order to achieve the above-mentioned object, the present invention provides a heat exchanger comprising a first core portion including a plurality of tubes and a radiating fin, and an introduction port communicating with the upper portion of the first core portion, A first cooler unit having a first upper tank and a first lower tank communicating with a lower portion of the first core unit; A second core portion disposed in parallel to the first core portion and including a plurality of tubes and a radiating fin, and a second core portion communicating with an upper portion of the second core portion and partially communicating with the first upper tank through a first guide channel A second upper tank communicating with the second lower tank and a discharge port communicating with a lower portion of the second core and discharging hydraulic fluid to one of the longitudinal ends of the second upper tank, And a second cooler unit configured as a second lower tank communicated with the first cooler unit.

The present invention further provides the following specific embodiments with respect to the above embodiment of the present invention.

According to an embodiment of the present invention, the first and second upper tanks are integrally provided through a first bridge located in a space between the two upper tanks, and the first guide channel is provided to the first bridge Wherein the first and second lower tanks are integrally provided via a second bridge located in a space between the two lower tanks and the second guide channel is provided to the second bridge.

According to an embodiment of the present invention, the first and second upper tanks may be separately provided, and the first guide channel may include a first guide portion that is disposed over two upper portions of the first and second upper tanks and is sealedly fixed Wherein the first and second lower tanks are provided separately and the second guide channel is provided through a second guide portion which is disposed over two upper portions of the first and second lower tanks and is sealed and fixed. do.

According to an embodiment of the present invention, the first guide unit is divided into a first guide block and a second guide block for each of the first and second upper tanks, A sealing member is provided at the rim and each of the first and second guide blocks is fixed to each other via fixing means, and the second guide portion is divided into a first guide block and a second guide block for each of the first and second lower tanks And a sealing member is provided at a rim between the second guide channels of the first and second guide blocks, and the first and second guide blocks are fixed to each other via fixing means.

According to an embodiment of the present invention, the inlet is connected to one of the longitudinal ends of the first upper tank, the outlet is connected to one of the longitudinal ends of the second lower tank, and both the inlet and outlet Is disposed on one side of the oil cooler.

The present invention is characterized in that four tanks are provided one for each of the core portions and one for the core portions of the two core portions, and the durability of the tank to the pressure of the hydraulic oil relative to the pressure of the hydraulic oil .

Further, according to the present invention, the introduction port and the discharge port for guiding the operating oil are installed in one of the lengthwise end portions of the tank, respectively, so that the piping can be assembled and improved in maintenance by being prevented from being disturbed by the engine or the radiator grill.

The present invention also provides a bifurcated guide channel leading from one inlet to the other outlet so that the operating oil can be evenly split and guided through the two guide channels to the outlet at the inlet.

Hereinafter, an embodiment of the internal split type oil cooler according to the present invention will be described with reference to FIGS. 3 to 5. FIG.

FIG. 3 is a schematic perspective view of an internal split oil cooler according to a first embodiment of the present invention, FIG. 4 is a schematic perspective view of an internal split oil cooler according to a second embodiment of the present invention, and FIG. 3 is a schematic perspective view of an internal split type oil cooler according to a third embodiment.

3 to 5, the internal split oil cooler 20 according to the present invention includes a first core portion 4, a first upper tank 12, and a first lower tank 15, And a second cooler unit 22 including a first cooler unit 21 and a second core unit 5, a second upper tank 13 and a second lower tank 16.

Here, the first core part 4 includes a plurality of known tubes (not shown) and a radiating fin (not shown). The first upper tank 12 is provided to communicate with the upper portion of the first core portion 4 and has an inlet 23 for supplying the hydraulic fluid to one of the longitudinal ends thereof. The first lower tank 15 is connected to the lower part of the first core part 4.

The second core portion 5 includes a plurality of known tubes (not shown) and a radiating fin (not shown) arranged in parallel with the first core portion 4. The second upper tank 13 communicates with the upper portion of the second core portion 5 and partially communicates with the first upper tank 12 through a first guide channel 24. The second lower tank 16 is provided to communicate with the lower portion of the second core portion 5 and has a discharge port 25 for discharging the hydraulic oil to one of the longitudinal end portions. In addition, the second lower tank 16 communicates partially with the first lower tank 15 through the second guide channel 26. The reason why the inlet port 23 is provided in the first cooler unit 21 and the outlet port 25 is provided in the second cooler unit 22 is that the first and second cooler units 21 and 22, Considering the oil flow between each other. That is, as in the present embodiment, sufficient pressure is formed in the first lower tank 15 to allow the oil to flow smoothly from the first upper tank 12 to the second upper tank 13, The efficiency can be improved. When both the inlet 23 and the outlet 25 are provided in the first cooler unit 21, the internal pressure of the first cooler unit 21 is sufficiently low, So that the utilization efficiency of the second cooler unit 22 is lowered, and thus the overall cooling efficiency of the oil may be lowered. On the other hand, when both the inlet 23 and the outlet 25 are formed in the second cooler unit 22, the pressure of the first cooler unit 21 is higher than necessary and the efficiency of the first cooler unit 21 is lowered The cooling efficiency of the whole oil may be lowered.

According to the embodiment of the present invention, the inlet port 23 and the outlet port 25 are disposed on one side of the oil cooler 20. Accordingly, the interference of other components by the connection of the oil cooler 20 and the pipes can be minimized, thereby maximizing the space efficiency around the oil cooler.

Meanwhile, the internal split oil cooler according to the present invention can be further limited to the following specific embodiments in the basic configuration as described above.

3 is a schematic perspective view of an internal split oil cooler according to a first embodiment of the present invention.

Hereinafter, a first embodiment of the present invention will be described with reference to FIG. The first and second upper tanks 12 and 13 are integrally provided through a first bridge 27 located in a space between the two upper tanks, (Not shown). The first and second lower tanks 15 and 16 are integrally provided via a second bridge 28 located in a space between the two lower tanks, (Not shown). Both ends of the first guide channel 24 are preferably located at the center of the first and second upper tanks 12 and 13 for equal distribution of operating fluid. Both side ends of the second guide channel 26 are preferably located at the central portions of the first and second lower tanks 15 and 16 for the even discharge of the operating oil.

4 is a schematic perspective view of an internal divided oil cooler according to a second embodiment of the present invention.

Hereinafter, a second embodiment of the present invention will be described with reference to FIG. The first and second upper tanks 12 and 13 are disposed separately from each other. The first guide channel 24 is disposed over two upper portions of the first and second upper tanks 12 and 13, And the first guide portion 29 is fixed in a sealed manner. The first and second lower tanks 15 and 16 are disposed separately and the second guide channel 26 is disposed over two upper portions of the first and second lower tanks 15 and 16, (Not shown). Both ends of the first guide channel 24 are preferably located at the center of the first and second upper tanks 12 and 13 for equal distribution of operating fluid. Both side ends of the second guide channel 26 are preferably located at the central portions of the first and second lower tanks 15 and 16 for the even discharge of the operating oil. The first and second guide channels 24 and 26 may be curved.

5 is a schematic perspective view of an internal split oil cooler according to a third embodiment of the present invention.

Hereinafter, a third embodiment of the present invention will be described with reference to FIG. The first guide portion 29 is divided into a first guide block 31 and a second guide block 32 for each of the first and second upper tanks. A sealing member 33 is provided on the rim between the first guide channels 24 of the first and second guide blocks 31 and 32 and the first and second guide blocks are fixed Respectively. The second guide unit 30 is divided into a first guide block 31 and a second guide block 32 for each of the first and second lower tanks. A sealing member 33 is provided at the edge between the second guide channels 26 of the first and second guide blocks 31 and 32 and the first and second guide blocks are fixed to each other via fixing means 34 Respectively. Each of the fixing means 34 includes a fixing portion having a through hole 34a formed to be aligned with two points of the first and second guide blocks 31 and 32, And a nut 34c and a bolt 34b for fixing the guide blocks 31 and 32, respectively.

3 to 5, at both upper ends of the first and second upper tanks 12 and 13 and the first and second lower tanks 15 and 16, a boss 35a having a screw hole 35a at a central portion thereof, (35), which are used to secure the oil cooler (20) to the fixed structure of the vehicle.

Operation of the internal split type oil cooler according to the present invention constructed as above will be described with reference to FIGS. 3 to 5. FIG.

First, the case of the oil cooler according to the first embodiment will be described with reference to FIG.

When the vehicle starts to operate, oil flows from the oil filter (not shown) disposed around the oil cooler 20 through the inlet 23 into the first upper tank 12.

Subsequently, a part of the hydraulic oil continuously flowing into the first upper tank 12 descends to the first lower tank 15 along each tube (not shown) of the first core portion 4, 1 bridge 27 into the second upper tank 13 through the first guide channel 24. [ Subsequently, the hydraulic fluid flowing into the second upper tank 13 flows into the second lower tank 16 along each tube (not shown) of the second core portion 5.

At this time, the operating oil descending along the respective tubes (not shown) of the first and second core portions 4 and 5 is blown from a cooling fan (not shown) disposed around the oil cooler 20, And the cooling fins (not shown) of the two core portions (4,5).

The hydraulic fluid flowing into the first lower tank 15 flows into the second lower tank 16 through the second guide channel 26 of the second bridge 28 and flows from the second core portion 5 (Not shown) through the discharge port 25 of the second lower tank 16, and is then supplied to the corresponding actuator (not shown).

The oil cooler according to the first and second embodiments will be described with reference to FIGS. 4 and 5. FIG.

When the vehicle starts to operate, oil flows from the oil filter (not shown) disposed around the oil cooler 20 through the inlet 23 into the first upper tank 12.

Subsequently, a part of the hydraulic oil continuously flowing into the first upper tank 12 descends to the first lower tank 15 along each tube (not shown) of the first core portion 4, The first guide channel 24 of the first guide block 29 or the first guide block 31 or the second guide block 32 into the second upper tank 13. Subsequently, the operating oil flowing into the second upper tank 13 flows into the second lower tank 16 along each tube (not shown) of the second core portion 5.

At this time, the operating oil descending along the respective tubes (not shown) of the first and second core portions 4 and 5 is blown from a cooling fan (not shown) disposed around the oil cooler 20, And the cooling fins (not shown) of the two core portions (4,5).

The hydraulic fluid introduced into the first lower tank 15 is supplied to the second lower tank 16 through the second guide channel 30 of the second guide block 30 or the first and second guide blocks 31, Flows into the actuator (not shown) through the discharge port 25 of the second lower tank 16, and is supplied to the corresponding actuator (not shown).

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and simple substitution, modification and alteration within the technical spirit of the present invention will be apparent to those skilled in the art.

1 is a schematic perspective view of a conventional oil cooler;

2 is a schematic perspective view of another oil cooler according to the prior art;

3 is a schematic perspective view of an internal split type oil cooler according to a first embodiment of the present invention;

4 is a schematic perspective view of an internal divided oil cooler according to a second embodiment of the present invention;

5 is a schematic perspective view of an internal divided oil cooler according to a third embodiment of the present invention.

Description of the Related Art

4: first core part 5: second core part

12: first upper tank 13: second upper tank

15: first lower tank 16: second lower tank

20: Oil cooler 21: First cooler unit

22: second cooler unit 23: inlet port

24: first guide channel 25: outlet

26: second guide channel 27: first bridge

28: second bridge 29: first guide portion

30: second guide portion 31: first guide block

32: second guide block 33: sealing member

34: Fixing means

Claims (5)

A first core portion (4) including a plurality of tubes and a radiating fin, a first core portion (4) provided in communication with an upper portion of the first core portion and having an introduction port (23) A first cooler unit 21 composed of a tank 12 and a first lower tank 15 communicating with a lower portion of the first core unit 4; And A second core part 5 disposed in parallel with the first core part 4 and including a plurality of tubes and radiating fins, a second core part 5 communicating with the upper part of the second core part, A second upper tank 13 partially communicating with the first upper tank 12 and a second lower tank 13 communicating with a lower portion of the second core portion 5 and having a discharge port A second cooler unit 22 having a first lower tank 15 and a second lower tank 16 partially communicating with the first lower tank 15 through a second guide channel 26; / RTI > Wherein the inlet port (23) is provided only in the first upper tank (12), and the outlet port (25) is provided only in the second lower tank (16). The method according to claim 1, The first and second upper tanks 12 and 13 are integrally provided through a first bridge 27 located in a space between the two upper tanks, (27) The first and second lower tanks 15 and 16 are integrally provided via a second bridge 28 located in a space between the two lower tanks, (28). ≪ / RTI > The method according to claim 1, The first and second upper tanks 12 and 13 are separated from each other and the first guide channel 24 is disposed over two upper portions of the first and second upper tanks 12 and 13 to be sealed Is provided through the first guide portion 29, The first and second lower tanks 15 and 16 are separately provided and the second guide channel 26 is disposed over two upper portions of the first and second lower tanks 15 and 16 to be sealed Is provided through the second guide portion (30). The method of claim 3, The first guide portion 29 is divided into a first guide block 31 and a second guide block 32 for each of the first and second upper tanks and the first and second guide blocks 31 and 32 A sealing member 33 is provided at the rim between the first guide channels 24 and the first and second guide blocks are fixed to each other via fixing means 34, The second guide portion 30 is divided into a first guide block 31 and a second guide block 32 for each of the first and second lower tanks and the first guide block 31 and the second guide block 32 Wherein a sealing member (33) is provided at the rim between the second guide channels (26) and the first and second guide blocks are fixed to each other via fixing means (34). 5. The method according to any one of claims 1 to 4, The inlet 23 is connected to one of the lengthwise ends of the first upper tank 12 and the outlet 25 is connected to one of the longitudinal ends of the second lower tank 16, Wherein both the inlet (23) and the outlet (25) are disposed on one side of the oil cooler (20).

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