CN217813678U - Engine intercooler constant temperature equipment - Google Patents

Abstract

The utility model discloses an engine intercooler constant temperature equipment, including first pressure storage funnel, be provided with the air inlet of being connected with automobile turbo charger on the first pressure storage funnel, first pressure storage funnel one side is connected with the dispersion breather pipe, and the dispersion breather pipe other end is connected with second pressure storage funnel, is provided with the gas outlet of being connected with automobile engine on the second pressure storage funnel, the utility model discloses a setting of snakelike cooling runner, snakelike cooling runner are snakelike winding distribution between two adjacent dispersion breather pipes, wrap up dispersion breather pipe trilateral to at the three face department sharing pipe wall with dispersion breather pipe contact, make snakelike cooling runner great with the area of dispersion breather pipe contact, thereby can make the coolant liquid in the snakelike cooling runner and the abundant heat exchange of high temperature high-pressure air that flows through in the dispersion breather pipe, make the radiating efficiency of high temperature air in the dispersion breather pipe higher.

Description

Engine intercooler constant temperature equipment

Technical Field

The utility model relates to a relevant technical field of auto-parts specifically is an engine intercooler constant temperature equipment.

Background

The intercooler is turbocharged's accessory spare, its effect lies in reducing the high temperature air temperature after the pressure boost, in order to reduce the heat load of engine, improve the air input, and then increase the power of engine, its temperature can rise by a wide margin after the air gets into turbo boost, density also correspondingly diminishes, and the intercooler just plays the effect of cooling air, high temperature air is through the cooling of intercooler, in the reentrant engine, if lack the intercooler and let the high temperature air after the pressure boost directly get into the engine, then can lead to engine knock or even damage flame-out phenomenon because of air temperature is too high.

The traditional intercooler generally adopts an air cooling mode, the intercooler and a water tank radiator are installed in front of an engine together, the automobile is cooled by an air suction fan and through surface air of running of the automobile, the temperature of compressed air blown out by a turbine can reach hundreds of degrees, the cooling mode of air cooling is insufficient when the automobile runs at low speed or is blocked, the air through surface air of the automobile is insufficient, the air suction of a simple fan is far insufficient to meet the cooling requirement, the air cooling is greatly influenced by the outside air temperature, the cooling box is poor in hot summer, the intercooler adopting water cooling is adopted, but the water cooling amplitude is lower than that of air cooling, and the temperature of cooling water can also be influenced by the outside environment, so that an engine intercooler constant temperature device is provided, and the problems provided in the above are solved.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an engine intercooler constant temperature equipment to solve the intercooler on the existing market that above-mentioned background art provided and adopt air-cooled or water-cooled mode can receive external environment's influence easily and cause the unstable problem of cooling effect.

In order to achieve the above purpose, the utility model provides a following technical scheme: the utility model provides an engine intercooler constant temperature equipment, includes first pressure accumulation funnel, be provided with the air inlet of being connected with car turbo charger on the first pressure accumulation funnel, first pressure accumulation funnel one side is connected with the dispersion breather pipe, the dispersion breather pipe other end is connected with second pressure accumulation funnel, be provided with the gas outlet of being connected with automobile engine on the second pressure accumulation funnel.

Preferably, the dispersion breather pipe is flat tubular metal resonator, and parallel arrangement has the multiunit, the dispersion breather pipe is provided with snakelike cooling runner outward, snakelike cooling runner upper end is provided with the cooling channel entry, the cooling channel entry is connected with first cooling funnel, snakelike cooling runner's lower extreme is provided with the cooling channel export, cooling channel export department is connected with second cooling funnel, communicate through the electronic pump between first cooling funnel and the second cooling funnel.

Preferably, the driving flow direction of the electronic pump is from bottom to top, and the air inlet and the air outlet on the first pressure accumulating funnel and the second pressure accumulating funnel are respectively positioned at the upper parts of the first pressure accumulating funnel and the second pressure accumulating funnel.

Preferably, the coolant liquid has been held in the snakelike cooling runner, snakelike cooling runner is snakelike winding distribution between two adjacent dispersion breather pipes, snakelike cooling runner parcel is lived dispersion breather pipe trilateral to at the three face department sharing pipe wall with dispersion breather pipe contact, just snakelike cooling runner's turn is the arc.

Preferably, a plurality of groups of intensive first heat exchange separation pieces are arranged in the inlet of the cooling channel, a plurality of groups of first semiconductor refrigeration pieces are tightly attached to the upper side of the inlet of the cooling channel, and first cooling fins are tightly attached to the outer side of the first semiconductor refrigeration pieces.

Preferably, a plurality of groups of intensive second heat exchange spacers are arranged in the outlet of the cooling channel, a plurality of groups of second semiconductor refrigeration pieces are tightly attached to the upper side of the outlet of the cooling channel, and second cooling fins are tightly attached to the outer side of each second semiconductor refrigeration piece.

Compared with the prior art, the beneficial effects of the utility model reside in that:

1. through the arrangement of the snake-shaped cooling flow channel, the snake-shaped cooling flow channel is distributed between two adjacent dispersion vent pipes in a snake-shaped winding manner, wraps three surfaces of the dispersion vent pipes, and shares a pipe wall at three surfaces in contact with the dispersion vent pipes, so that the contact area of the snake-shaped cooling flow channel and the dispersion vent pipes is larger, heat can be fully exchanged between cooling liquid in the snake-shaped cooling flow channel and high-temperature and high-pressure air flowing through the dispersion vent pipes, and the heat dissipation efficiency of the high-temperature air in the dispersion vent pipes is higher;

2. through the heat exchange spacer, the setting of semiconductor refrigeration piece and fin, the entrance and exit department at snakelike cooling flow channel, the semiconductor refrigeration piece all can be fast and invariable reduces the temperature of heat exchange spacer, when the radiating coolant flow of the thermal coolant flow of high temperature air flows through the heat exchange spacer of snakelike cooling flow channel entrance and exit department in the absorption dispersion breather pipe, the heat can be absorbed fast, and the fin from the semiconductor refrigeration piece another side is effluvium, the refrigeration cooling of semiconductor refrigeration piece receives the influence of external environment lower, no matter how the external environment changes, all can invariable its temperature, and refrigerated temperature can be less than external environment temperature, cooling effect and cooling range are bigger.

Drawings

FIG. 1 is a front view of the present invention;

FIG. 2 is a schematic view of the back side of the present invention;

FIG. 3 is a schematic view of the structure of the dispersed vent pipe orifice of the present invention;

FIG. 4 is a schematic cross-sectional view of the serpentine cooling channel of the present invention;

FIG. 5 is a schematic view of a first heat exchange structure of the present invention;

fig. 6 is a schematic view of a second heat exchange structure of the present invention.

In the figure: 1. a first pressure accumulation funnel; 2. an air inlet; 3. dispersing the vent pipe; 4. a second pressure accumulation funnel; 5. an air outlet; 6. a serpentine cooling channel; 7. a cooling channel inlet; 8. a first cooling funnel; 9. an outlet of the cooling passage; 10. a second cooling funnel; 11. an electronic pump; 12. a first heat exchange spacer; 13. a first semiconductor chilling plate; 14. a first heat sink; 15. a second heat exchange spacer; 16. a second semiconductor refrigeration chip; 17. and a second heat sink.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and the detailed description, and it should be noted that the embodiments or technical features described below can be arbitrarily combined to form a new embodiment without conflict.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When a component is referred to as being "connected" to another component, it can be directly connected to the other component or intervening components may also be present. When a component is referred to as being "disposed on" another component, it can be directly on the other component or intervening components may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for purposes of illustration only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1-6, the present invention provides the following solutions:

an engine intercooler constant temperature device comprises a first pressure accumulation funnel 1, wherein an air inlet 2 connected with an automobile turbocharger is formed in the first pressure accumulation funnel 1, a dispersion vent pipe 3 is connected to one side of the first pressure accumulation funnel 1, the other end of the dispersion vent pipe 3 is connected with a second pressure accumulation funnel 4, an air outlet 5 connected with an automobile engine is formed in the second pressure accumulation funnel 4, the dispersion vent pipe 3 is a flat metal pipe and is provided with a plurality of groups in parallel, the surface area of the dispersion vent pipe 3 is larger than that of the circular pipe, the heat dissipation efficiency is higher, a snake-shaped cooling flow passage 6 is arranged outside the dispersion vent pipe 3, cooling liquid is contained in the snake-shaped cooling flow passage 6, the snake-shaped cooling flow passage 6 is distributed between two adjacent dispersion vent pipes 3 in a snake-shaped winding mode, three surfaces of the dispersion vent pipe 3 are wrapped by the snake-shaped cooling flow passage 6, the shared pipe wall is arranged at three surfaces in contact with the dispersion vent pipe 3, the turning position of the snake-shaped cooling flow passage 6 is arc-shaped, the contact area between the snake-shaped cooling flow passage 6 and the dispersion vent pipe 3 is larger, and heat in high-shaped gas flowing through the dispersion vent pipe 3 can be quickly conducted to the cooling liquid in the snake-shaped cooling flow passage 6;

a cooling channel inlet 7 is formed in the upper end of the serpentine cooling channel 6, a first cooling funnel 8 is connected to the cooling channel inlet 7, a cooling channel outlet 9 is formed in the lower end of the serpentine cooling channel 6, a second cooling funnel 10 is connected to the cooling channel outlet 9, the first cooling funnel 8 is communicated with the second cooling funnel 10 through an electronic pump 11, and the turning part of the serpentine cooling channel 6 is arc-shaped, so that cooling liquid flows more smoothly in the serpentine cooling channel 6, the flow speed is higher, and the cooling effect is better;

a plurality of groups of intensive first heat exchange spacers 12 are arranged in the cooling passage inlet 7, a plurality of groups of first semiconductor refrigerating sheets 13 are tightly attached above the cooling passage inlet 7, first radiating fins 14 are tightly attached to the outer sides of the first semiconductor refrigerating sheets 13, when cooling liquid absorbs a large amount of heat in the snake-shaped cooling passage 6 and flows out from the cooling passage outlet 9 below, the cooling liquid passes through a passage separated by a plurality of intensively-arranged second heat exchange spacers 15 at the cooling passage outlet 9, the second semiconductor refrigerating sheets 16 are cooled on one surface close to the second heat exchange spacers 15 after being electrified, so that the cooling liquid flowing through the second heat exchange spacers 15 is primarily cooled, and the heat generated on the other surface of the second heat exchange spacers 15 is radiated through second radiating fins 17;

a plurality of groups of intensive second heat exchange spacers 15 are arranged in the cooling channel outlet 9, a plurality of groups of second semiconductor refrigerating sheets 16 are tightly attached to the upper part of the cooling channel outlet 9, second radiating fins 17 are tightly attached to the outer sides of the second semiconductor refrigerating sheets 16, the primarily cooled cooling liquid passes through a second cooling funnel 10, is intensively pumped into the cooling channel inlet 7 through a first cooling funnel 8 by an electronic pump 11, and when passing through a first heat exchange spacer 12 in the cooling channel inlet 7, the temperature of the cooling liquid is further reduced by a first semiconductor refrigerating sheet 13;

the driving flow direction of the electronic pump 11 is from bottom to top, and the air inlet 2 and the air outlet 5 on the first pressure accumulating funnel 1 and the second pressure accumulating funnel 4 are respectively positioned at the upper parts of the first pressure accumulating funnel 1 and the second pressure accumulating funnel 4, because the air inlet 2 and the air outlet 5 on the first pressure accumulating funnel 1 and the second pressure accumulating funnel 4 are respectively positioned at the upper parts of the first pressure accumulating funnel 1 and the second pressure accumulating funnel 4, the air circulation path in the dispersed vent pipe 3 close to the top is shortest, the flow speed is the highest, the cooling liquid flowing out from the cooling channel outlet 9 is cooled by the second cooling semiconductor sheet 16 and the first semiconductor sheet 13 successively, the temperature when reaching the top of the serpentine cooling channel 6 is the lowest, and the air with higher temperature in the dispersed vent pipe 3 close to the top can be cooled more preferably and rapidly.

The working principle is as follows: when the engine intercooler thermostat is used, high-pressure and high-temperature air in a turbocharger firstly enters a first pressure accumulation funnel 1 through a connecting hose via an air inlet 2 and is dispersed in the first pressure accumulation funnel 1 to enter different dispersion vent pipes 3, and meanwhile, an electronic pump 11 can drive the cooling liquid to circularly flow in a serpentine cooling flow channel 6;

the snakelike cooling flow channel 6 is distributed between the two adjacent dispersed vent pipes 3 in a snakelike winding manner, the snakelike cooling flow channel 6 wraps three surfaces of the dispersed vent pipes 3, and the three surfaces in contact with the dispersed vent pipes 3 share the pipe wall, so that the contact area between the snakelike cooling flow channel 6 and the dispersed vent pipes 3 is larger, heat in high-temperature gas flowing through the dispersed vent pipes 3 can be quickly conducted to cooling liquid in the snakelike cooling flow channel 6, and the turning part of the snakelike cooling flow channel 6 is arc-shaped, so that the cooling liquid can flow more smoothly in the snakelike cooling flow channel 6, the flow speed is higher, and the cooling effect is better;

the electronic pump 11 can drive the coolant flow to flow from bottom to top, so that the coolant can enter from a cooling channel inlet 7 above the serpentine cooling channel 6 and flow out from a cooling channel outlet 9 below the serpentine cooling channel 6, when the coolant absorbs a large amount of heat in the serpentine cooling channel 6 and flows out from a cooling channel outlet 9 below, the coolant can pass through a channel partitioned by a large number of densely-arranged second heat exchange spacers 15 at the cooling channel outlet 9, the second semiconductor chilling plates 16 can refrigerate and cool on one surface close to the second heat exchange spacers 15 after being electrified, so that the coolant flowing through the second heat exchange spacers 15 is primarily cooled, the heat generated on the other surface of the second heat exchange spacers 15 can be dissipated through the second cooling fins 17, then the primarily cooled coolant passes through the second cooling funnel 10 and is concentrated through the electronic pump 11, then is pumped into the cooling channel inlet 7 through the first cooling funnel 8 by the electronic pump 11, when the coolant passes through the first spacers in the cooling channel inlet 7, the first semiconductor chilling air in the serpentine cooling channel inlet 7 can further reduce the temperature of the coolant, and flows out from a second cooling air outlet 4 on the serpentine cooling channel inlet 3, and flows out through the second air storage and flows into the second air vent pipe 5;

because the air inlet 2 and the air outlet 5 on the first pressure accumulating funnel 1 and the second pressure accumulating funnel 4 are respectively arranged at the upper parts of the first pressure accumulating funnel 1 and the second pressure accumulating funnel 4, the air circulation path in the dispersion vent pipe 3 close to the upper part is shortest, the flow speed is the highest, the temperature is the highest, the cooling liquid flowing out from the cooling channel outlet 9 is cooled by the second semiconductor refrigerating sheet 16 and the first semiconductor refrigerating sheet 13, the temperature is the lowest when the cooling liquid reaches the upper part of the snakelike cooling channel 6, the air with higher temperature in the dispersion vent pipe 3 close to the upper part can be cooled rapidly, and a series of work is completed. Those not described in detail in this specification are within the skill of the art.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (6)

1. The utility model provides an engine intercooler constant temperature equipment, includes first pressure accumulation funnel (1), its characterized in that: be provided with air inlet (2) of being connected with the car turbo charger on first pressure accumulation funnel (1), first pressure accumulation funnel (1) one side is connected with dispersion breather pipe (3), dispersion breather pipe (3) other end is connected with second pressure accumulation funnel (4), be provided with gas outlet (5) of being connected with automobile engine on second pressure accumulation funnel (4).

2. The engine intercooler thermostat device of claim 1, wherein: the dispersion breather pipe (3) is flat tubular metal resonator, and parallel arrangement has the multiunit, dispersion breather pipe (3) are provided with snakelike cooling runner (6) outward, snakelike cooling runner (6) upper end is provided with cooling channel entry (7), cooling channel entry (7) department is connected with first cooling funnel (8), the lower extreme of snakelike cooling runner (6) is provided with cooling channel export (9), cooling channel export (9) department is connected with second cooling funnel (10), communicate through electronic pump (11) between first cooling funnel (8) and the second cooling funnel (10).

3. The engine intercooler thermostat device of claim 2, wherein: the driving flow direction of the electronic pump (11) is from bottom to top, and the air inlet (2) and the air outlet (5) on the first pressure accumulation funnel (1) and the second pressure accumulation funnel (4) are respectively positioned at the upper parts of the first pressure accumulation funnel (1) and the second pressure accumulation funnel (4).

4. The thermostat device for an engine intercooler as claimed in claim 2, wherein: the cooling liquid has been accommodated in snakelike cooling runner (6), snakelike cooling runner (6) are snakelike winding and distribute between two adjacent dispersion breather pipe (3), snakelike cooling runner (6) parcel is lived the trilateral of dispersion breather pipe (3) to with the three face department sharing pipe wall of dispersion breather pipe (3) contact, just the turn of snakelike cooling runner (6) is the arc.

5. The engine intercooler thermostat device of claim 2, wherein: be provided with the intensive first heat exchange spacer (12) of multiunit in cooling duct entry (7), cooling duct entry (7) top is hugged closely has multiunit first semiconductor refrigeration piece (13), first semiconductor refrigeration piece (13) outside is hugged closely has first fin (14).

6. The thermostat device for an engine intercooler as claimed in claim 2, wherein: the cooling channel outlet (9) is internally provided with a plurality of groups of intensive second heat exchange spacers (15), a plurality of groups of second semiconductor refrigerating pieces (16) are tightly attached to the upper part of the cooling channel outlet (9), and second radiating fins (17) are tightly attached to the outer sides of the second semiconductor refrigerating pieces (16).

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