Integrated controller heat dissipation shell for automatic driving intelligent equipment
Technical Field
The utility model relates to the field of integrated controllers, in particular to an integrated controller heat dissipation shell for an automatic driving intelligent device.
Background
With the continuous development of the automobile industry, the functions of an Electronic Control Unit (ECU) for an automobile, which is a brain of the automobile, are deepened, and the ECU collects sensors on the automobile: for example, the temperature sensor, the pressure sensor, the rotation sensor, the flow sensor, the position sensor, the oxygen sensor, the liquid level sensor, the knocking sensor and other data are calculated, and then the result is converted into a control signal to brake the controlled object to perform corresponding actions, thereby playing a great role in the normal and safe operation of the automobile.
Publication No.: CN210899896U discloses ECU intelligent driving controller casing, including controller box body, lid fixed ear and fixed orifices, controller box body top is provided with the lid, be provided with on the controller box body both sides wall the fixed ear, the shaping has on the fixed ear the fixed orifices, fixed orifices one side is provided with the installation locating pin.
The existing shell is poor in heat dissipation effect, and air convection cannot be formed in the shell, so that circulation efficiency of air flow in the shell is low, the shell cannot be sealed when the shell is not used, and external dust easily enters the shell to pollute the inside.
Disclosure of Invention
The utility model aims to provide an integrated controller heat dissipation shell for an automatic driving intelligent device, which solves the defects in the background art.
In order to achieve the above-mentioned purpose, provide an integrated controller heat dissipation casing for autopilot smart machine, including integrated controller shell, integrated controller shell installs the mounting panel surface at autopilot smart machine, and fixes through the bolt between integrated controller shell and the mounting panel, integrated controller shell's top cover apron, and the apron evenly fixes through four sets of hexagon socket head cap bolts on integrated controller shell, and integrated controller shell's right side spiro union installs right side radiator unit simultaneously to integrated controller shell's left side spiro union installs left side radiator unit, and multiunit louvre has evenly been seted up on the surface of apron, and the transverse cross section of louvre is "L" shape setting.
Preferably, the left heat dissipation assembly and the right heat dissipation assembly have the same composition structure, and the left heat dissipation assembly and the right heat dissipation assembly have symmetrical structures with respect to the integrated controller shell.
Preferably, the left side cooling assembly comprises a cooling port, a mounting frame, a cooling fan, an air inlet and a dust separation net, wherein fixing sheets are welded on the upper side and the lower side of the mounting frame, and the fixing sheets are covered on the side wall of the integrated controller shell and fixed through bolts.
Preferably, two groups of air inlets are formed in the wall plate of the mounting frame, and two groups of heat dissipation openings are formed in the wall plate of the integrated controller shell and are opposite to the air inlets.
Preferably, the air inlet is in threaded connection with a cooling fan, one side of the air inlet, which is far away from the cooling fan, is covered with a dust-separating net, and the dust-separating net is arranged in a circular shape.
Preferably, the right side heat dissipation assembly and the left side heat dissipation assembly are combined together to form an air convection assembly inside the integrated controller shell.
Preferably, the positioning plates are welded on two sides of the bottom of the integrated controller shell, two groups of positioning grooves are formed in the surface of the mounting plate, the positioning grooves are matched with the positioning plates in size, the positioning plates are inserted into the positioning grooves, and meanwhile the integrated controller shell and the mounting plate are positioned and mounted through the positioning grooves and the positioning plates.
Compared with the prior art, the utility model has the beneficial effects that:
the two rows of cooling fans work simultaneously, outside air enters the inside of the integrated controller shell after being accelerated, air convection is formed in the inside of the integrated controller shell, after the integrated controller shell is cooled, the outside air is discharged through the cooling holes, and efficient cooling work of the inside of the integrated controller shell is achieved.
The dust separation net and the L-shaped heat dissipation holes can isolate dust in gas to be introduced into the integrated controller shell, so that a large amount of dust outside is prevented from entering the inside of the integrated controller shell, and damage is caused to electronic elements inside the integrated controller shell.
Drawings
FIG. 1 is a schematic elevational view of the structure of the present utility model;
FIG. 2 is a side view of the structure of the present utility model, FIG. 1;
FIG. 3 is a top view of the structure of FIG. 1 of the present utility model;
FIG. 4 is an enlarged schematic view of the structure of the present utility model at A in FIG. 1;
fig. 5 is an enlarged schematic view of the structure of fig. 1 in the structure of the present utility model.
Reference numerals in the drawings: 1. a mounting plate; 2. an integrated controller housing; 3. a right side heat dissipating assembly; 4. a cover plate; 5. a heat radiation hole; 6. a left side heat dissipation assembly; 61. a heat radiation port; 62. a mounting frame; 63. a heat radiation fan; 64. an air inlet; 65. a dust-separating net; 7. a positioning plate; 8. and a positioning groove.
Detailed Description
The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.
Referring to fig. 1-5, the utility model provides an integrated controller heat dissipation shell for an automatic driving intelligent device, which comprises an integrated controller shell 2, wherein the integrated controller shell 2 is installed on the surface of a mounting plate 1 of the automatic driving intelligent device, the integrated controller shell 2 and the mounting plate 1 are fixed through bolts, the top of the integrated controller shell 2 is covered with a cover plate 4, the cover plate 4 is uniformly fixed on the integrated controller shell 2 through four groups of hexagon socket head cap bolts, meanwhile, the right side of the integrated controller shell 2 is in threaded connection with a right side heat dissipation assembly 3, the left side of the integrated controller shell 2 is in threaded connection with a left side heat dissipation assembly 6, a plurality of groups of heat dissipation holes 5 are uniformly formed in the surface of the cover plate 4, and the transverse section of the heat dissipation holes 5 is in an L-shaped arrangement.
Working principle: when using, when needing to dispel the heat to the inside of integrated controller shell 2, start the external switch of right side radiator unit 3, the inside radiator fan 63 of left side radiator unit 6 simultaneously this moment, two rows of radiator fans 63 simultaneous workings this moment, enter into the inside of integrated controller shell 2 after accelerating external gas to form the air convection in the inside of integrated controller shell 2, after the heat dissipation to integrated controller shell 2 finishes, discharge the external through louvre 5, realize carrying out the high-efficient heat dissipation work to the inside of integrated controller shell 2.
As a preferred embodiment, the left heat dissipating component 6 and the right heat dissipating component 3 have the same composition, and the left heat dissipating component 6 and the right heat dissipating component 3 have a symmetrical structure with respect to the integrated controller housing 2.
As shown in fig. 1: the left side heat dissipation component 6 and the right side heat dissipation component 3 are symmetrical structures with respect to the integrated controller shell 2, two groups of heat dissipation fans 63 are arranged in the left side heat dissipation component 6 and the right side heat dissipation component 3, four groups of heat dissipation fans 63 are arranged in total, and efficient heat dissipation work of the inside of the integrated controller shell 2 is achieved.
As a preferred embodiment, the left heat dissipation assembly 6 includes a heat dissipation port 61, a mounting frame 62, a heat dissipation fan 63, an air inlet 64 and a dust-proof net 65, and fixing pieces are welded on the upper and lower sides of the mounting frame 62, and the fixing pieces cover the side wall of the integrated controller housing 2 and are fixed by bolts.
As shown in fig. 1-2: the dust separation net 65 can separate dust in the gas to be introduced into the integrated controller housing 2, so that a large amount of dust outside is prevented from entering the integrated controller housing 2, and damage is prevented to electronic components inside the integrated controller housing 2.
As a preferred embodiment, two groups of air inlets 64 are formed on the wall plate of the mounting frame 62, and two groups of heat dissipation openings 61 are formed on the wall plate of the integrated controller housing 2, wherein the heat dissipation openings 61 are opposite to the air inlets 64.
As shown in fig. 1-2: the heat dissipation port 61 is disposed opposite to the air intake 64, and air accelerated by the heat dissipation fan 63 can enter the heat dissipation port 61 through the air intake 64 and enter the integrated controller housing 2 through the heat dissipation port 61, thereby completing ventilation and heat dissipation of the integrated controller housing 2.
As a preferred embodiment, the air inlet 64 is screwed with the heat dissipation fan 63, and a side of the air inlet 64 away from the heat dissipation fan 63 is covered with the dust-separating net 65, and the dust-separating net 65 is circular.
As a preferred embodiment, the right side heat sink assembly 3 and the left side heat sink assembly 6 are combined to form an air convection assembly within the integrated controller housing 2.
As a preferred implementation mode, the positioning plates 7 are welded on two sides of the bottom of the integrated controller shell 2, two groups of positioning grooves 8 are formed in the surface of the mounting plate 1, the positioning grooves 8 are matched with the positioning plates 7 in size, the positioning plates 7 are inserted into the positioning grooves 8, and meanwhile, positioning and mounting are carried out between the integrated controller shell 2 and the mounting plate 1 through the positioning grooves 8 and the positioning plates 7.
As shown in fig. 1 and 4: the integrated controller shell 2 and the mounting plate 1 are positioned and mounted through the positioning grooves 8 and the positioning plate 7, so that through holes on two sides of the bottom of the integrated controller shell 2 and screw holes on the mounting plate 1 can be quickly in a communication state, and fixing bolts can be conveniently threaded into the screw holes through the through holes.
As shown in fig. 1 and 5: the cross section of the heat dissipation hole 5 is in an L shape, when the heat dissipation fan 63 does not work, dust of an external machine can not quickly enter the integrated controller shell 2 through the heat dissipation hole 5, and the dust can be adhered to the inner wall of the heat dissipation hole 5.
The heat radiator can be matched with and installed on an integrated controller to help the integrated controller to radiate heat, and is more suitable for SPC-SFMC-X2024G, and the integrated controller is purchased directly on the market.
Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.