CN117565708A - High-efficient liquid cooling overcharge machine - Google Patents

Abstract

The invention provides a high-efficiency liquid cooling super-charging machine. The high-efficient liquid cooling super charging machine includes: the charging machine comprises a charging machine shell, a conveying pipe and a first pipeline; the left part and the right part of the front side of the charging motor shell are fixedly connected with a plurality of conveying pipes respectively; all the conveying pipes are commonly provided with a first pipeline. According to the invention, as the interception net is arranged at the corner of the installation groove frame, and the water passes through the corner of the installation groove frame, the water can become turbulent, so that the water generates a turning effect, and the turned water drives the ice residues around the interception net to turn, so that the ice residues are prevented from being deposited at the bottom of the water, and the water temperature of the upper layer and the lower layer is inconsistent, so that the heat dissipation of the water to the electric appliance element is influenced.

Description

High-efficient liquid cooling overcharge machine

Technical Field

The invention relates to the technical field of chargers, in particular to a high-efficiency liquid-cooling super-charging charger.

Background

The super-charge liquid cooling module, which is also called a power converter, is a power conversion device used on a charging pile. Such power conversion devices include a plurality of power devices for implementing ac/dc power to be converted to various voltage levels used on the battery.

In the superfilling liquid-cooled module power supply, a large amount of heat is generated when the power devices are in an operating state, so that an effective heat dissipation design must be adopted to dissipate the heat generated by the power devices, so as to avoid affecting the overall operation performance due to heat accumulation. The traditional heat radiation structure is that the electric elements are attached to a heat radiation area on the side wall of a cooling water tank, and then water in the cooling water tank is in a circulating flow state, so that heat radiation of the electric elements is achieved, and in the heat radiation process, a cooler cools the water;

however, because the charger is used for charging the pile, the volume of the cooler is relatively small, so that the cooling power of water is limited, and the temperature of the water gradually rises in the long-time heat dissipation process of the electric elements, so that the cooling of the water by the cooler does not meet the requirement, and the heat exchange efficiency of the water to the electric elements is reduced after the water enters the cooling water tank, the stability of the electric elements in operation is further affected, and even the service life of the electric elements is reduced.

Disclosure of Invention

The invention aims to provide a high-efficiency liquid cooling super-charging machine so as to solve the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions:

a high-efficiency liquid cooling super-charging machine comprises a charging machine shell, a conveying pipe and a first pipeline; the left part and the right part of the front side of the charging motor shell are fixedly connected with a plurality of conveying pipes respectively; all the conveying pipes are commonly provided with a first pipeline;

the device also comprises a pipeline component, an installation groove frame, an elastic telescopic rod, a template, an air bag, a first telescopic pipe and a second telescopic pipe; the charging motor shell is connected with a pipeline component for conveying water and gas; the inner side of the charger shell is fixedly connected with a mounting groove frame for mounting an electric element, and the mounting groove frame is communicated with the conveying pipe; a plurality of cavities are arranged on the outer side of the mounting groove frame; the inner side of the mounting groove frame is provided with a plurality of cavities; the opposite sides of each cavity are fixedly connected with a plurality of elastic telescopic rods respectively, and one end of each elastic telescopic rod is connected with the pipeline part; the other ends of all the elastic telescopic rods adjacent to each other up and down are fixedly connected with a template together; each template is provided with a first through groove; a groove is respectively formed in the inner side of each template; an air bag is respectively arranged on the inner side of each template, and the air bags are communicated with the first through grooves; the upper part of the opposite sides of each template is respectively provided with a first telescopic pipe, the first telescopic pipes penetrate through the mounting groove frames, and the first telescopic pipes are communicated with the pipeline components; the middle part of each template opposite side is respectively provided with a second telescopic pipe for conveying water, the second telescopic pipe passes through the mounting groove frame, and the second telescopic pipe is communicated with the pipeline component.

Further, a chamber is arranged around each cavity, and the chamber is in a vacuum environment.

Further, the grooves are arranged in an isosceles trapezoid shape, and after the air bag is inflated, the shape of the air bag is consistent with the shape of the grooves.

Further, the inner upper side and the inner lower side of the groove are both cambered surfaces.

Further, the device also comprises a connecting column and a connecting strip; each template is provided with a second through groove; the middle parts of the opposite sides of each cavity are fixedly connected with a connecting column respectively; each connecting column is fixedly connected with a connecting strip, and the connecting strips are matched with the second through grooves.

Further stated, sealing strips are arranged on two sides of the connecting strip.

Further, the pipeline component comprises a connecting pipe, a second pipeline and a fixed pipe; the upper part in the charging motor shell is fixedly connected with two connecting pipes; one end of each connecting pipe is provided with a second pipeline; the lower side of each connecting pipe is provided with a plurality of fixed pipes respectively; the fixed pipe is communicated with the other end of the elastic telescopic rod, and the other ends of the first telescopic pipe and the second telescopic pipe are communicated with the fixed pipe.

Further, the device also comprises an interception net; a plurality of interception nets are respectively arranged on the outer sides of the installation groove frames; the inner sides of the installation groove frames are respectively provided with a plurality of interception nets.

Further stated, the interception net is arranged as a double layer, and meshes between the interception nets of the double layer are distributed in a staggered manner, so that the interception net can better intercept the ice residues.

Further illustrated, the blocking net is disposed at a corner of the mounting bezel.

Advantageous effects

A. According to the invention, in the process that the water enters the mounting groove frame, the water flows through the ice blocks, and the water inlet height of the ice blocks is larger than the water outlet height of the ice blocks, so that the flow velocity of the water flow is increased when the water passes through the ice blocks, and the water can take away the heat generated by the electrical elements more quickly.

B. The invention also prevents the ice blocks from being washed away by water due to the adhesion of the protruding part and the connecting strip, and simultaneously prevents the protruding part from being moved when the water is melted earlier than the ice blocks when circularly flowing in the mounting groove frame due to the thickness of the protruding part being thicker than the ice blocks, thereby affecting the water to pass through between the ice blocks.

C. According to the invention, the water in the installation groove frame is cooled through the ice cubes, so that the cooled water can absorb heat generated by the electrical elements better, the heat dissipation effect of the electrical elements is improved, and the service life of the electrical elements is prolonged;

meanwhile, the problem that in the prior art, the volume of a cooler is relatively smaller because a charger is used for a charging pile, so that the cooling power of water is limited, and the temperature of water gradually rises in the process of radiating an electrical element for a long time, so that the cooling of the cooler to the water does not meet the requirement, the heat exchange efficiency of the water to the electrical element is reduced after the water enters the mounting groove frame, the stability of the electrical element during operation is further affected, and the service life of the electrical element is even reduced is solved.

D. According to the invention, the blocking net is arranged at the corner of the installation groove frame, and water passes through the corner of the installation groove frame, so that the water can be turbulent, a turning effect is generated, the turned water drives the ice residues around the blocking net to turn, the ice residues are prevented from being deposited at the bottom of the water, and the water temperature of the upper layer and the lower layer is inconsistent, so that the heat dissipation of the water to the electric appliance element is influenced.

Drawings

FIG. 1 is a schematic diagram of a first view angle structure of a high efficiency liquid cooled overcharge charger of the present invention;

FIG. 2 is a schematic diagram of a second view angle structure of the high-efficiency liquid-cooled overcharge charger of the present invention;

FIG. 3 is a schematic diagram of a third view angle structure of the high-efficiency liquid-cooled overcharge charger of the present invention;

FIG. 4 is a schematic view of the piping components of the high efficiency liquid cooled overcharge battery of the present invention;

FIG. 5 is a first partial cross-sectional view of the high efficiency liquid cooled overcharge charger of this invention;

FIG. 6 is an enlarged view of the A-site of the high efficiency liquid cooled overcharge battery of the present invention;

FIG. 7 is a first exploded view of the high efficiency liquid cooled overcharge battery of this invention;

FIG. 8 is a second exploded view of the high efficiency liquid cooled overcharge battery of this invention;

fig. 9 is a third exploded view of the high efficiency liquid cooled overcharge battery of this invention.

Reference numerals: 01-ice cubes, 02-protruding parts, 1-charging machine shell, 2-conveying pipes, 3-first pipelines, 4-mounting groove frames, 41-cavities, 42-cavities, 5-interception nets, 6-elastic telescopic rods, 7-templates, 71-first through grooves, 72-grooves, 73-second through grooves, 8-air bags, 9-first telescopic pipes, 10-second telescopic pipes, 11-connecting columns, 12-connecting bars, 201-connecting pipes, 202-second pipelines and 203-fixed pipes.

Detailed Description

The technical scheme of the invention is further described below with reference to the accompanying drawings.

Example 1

The efficient liquid cooling super-charging machine comprises a charging machine shell 1, a conveying pipe 2 and a first pipeline 3 as shown in figures 1-9; at least six conveying pipes 2 which are distributed in an up-down equidistant way are fixedly connected to the left part of the front side and the right part of the front side of the charging motor shell 1 respectively; all the conveying pipes 2 are fixedly connected together and communicated with a first pipeline 3;

the device also comprises a pipeline component, an installation groove frame 4, an elastic telescopic rod 6, a template 7, an air bag 8, a first telescopic pipe 9 and a second telescopic pipe 10; the charging motor shell 1 is connected with a pipeline component; the inner side of the charging machine shell 1 is fixedly connected with a mounting groove frame 4, the mounting groove frame 4 is communicated with the conveying pipe 2, the outer side of the mounting groove frame 4 is in a convex shape, and the inner side of the mounting groove frame 4 is in a square frame shape; five cavities 41 are arranged on the outer side of the mounting groove frame 4; the inner side of the mounting groove frame 4 is provided with four other cavities 41 which are distributed in a rectangular shape; two elastic telescopic rods 6 which are distributed at equal intervals up and down are fixedly connected to opposite sides of each cavity 41, and one end of each elastic telescopic rod 6 is connected with a pipeline component; the other ends of all the elastic telescopic rods 6 adjacent to each other up and down are fixedly connected with a template 7; each template 7 is provided with a first through groove 71 for cold air to pass through; a groove 72 is respectively formed on the inner side of each template 7; an air bag 8 is respectively arranged on the inner side of each template 7, and the air bag 8 is communicated with the first through groove 71; the upper parts of the opposite sides of each template 7 are fixedly connected and communicated with a first telescopic pipe 9, the first telescopic pipe 9 passes through the mounting groove frame 4, the first telescopic pipe 9 is communicated with a pipeline part, and an electromagnetic valve is arranged in the first telescopic pipe 9, so that water is prevented from entering the first through groove 71 and the air bag 8 through the first telescopic pipe 9; the middle parts of the opposite sides of each template 7 are fixedly connected and communicated with a second telescopic pipe 10, the second telescopic pipe 10 passes through the mounting groove frame 4, and the second telescopic pipe 10 is communicated with the pipeline part.

A chamber 42 is arranged around each cavity 41, and a vacuum environment is arranged in the chamber 42 for preserving the heat of the made ice cubes 01.

The recess 72 is provided in the shape of an isosceles trapezoid, and the shape of the airbag 8 is identical to the shape of the recess 72 after expansion, so that the water flow rate of water flow increases when water passes through the ice 01 after the ice 01 is made and the water inlet height of the ice 01 is greater than the water outlet height thereof.

Both the inner upper side and the inner lower side of the recess 72 are provided with cambered surfaces, so that the mold 7 is better separated from the ice cubes 01.

The connecting column 11 and the connecting strip 12 are also included; each template 7 is provided with a second through groove 73; the middle parts of the opposite sides of each cavity 41 are fixedly connected with a connecting column 11 respectively; each connecting column 11 is fixedly connected with a connecting strip 12, and the connecting strips 12 are matched with the second through grooves 73.

The sealing strips are arranged on two sides of the connecting strip 12, so that the sealing performance of the connecting strip 12 to the second through groove 73 is stronger.

The pipe member includes a connection pipe 201, a second pipe 202, and a fixing pipe 203; the upper part in the charging motor shell 1 is fixedly connected with two connecting pipes 201; one end of all connecting pipes 201 are fixedly connected together and communicated with a second pipeline 202; eighteen fixing pipes 203 are respectively arranged on the lower side of each connecting pipe 201; the fixed tube 203 is communicated with the other end of the elastic telescopic rod 6, and the other ends of the first telescopic tube 9 and the second telescopic tube 10 are communicated with the fixed tube 203.

When the efficient liquid cooling super-charging machine is used, firstly, the first pipeline 3 is in butt joint with the peripheral cooler, the electromagnetic valve arranged in the first telescopic pipe 9 is in a closed state, the one-way valve is arranged in the second telescopic pipe 10, the left part of the second pipeline 202 is in butt joint with the peripheral pump, the right part of the second pipeline 202 is in butt joint with the peripheral water pump, and the initial positions of the two adjacent templates 7 are in a non-contact state;

when the charging pile is not in operation, the external pump machine can be controlled to convey cold air into the fixed pipe 203 through the second pipeline 202 and the connecting pipe 201, then the cold air enters the elastic telescopic rod 6, the telescopic part of the elastic telescopic rod 6 is forced to extend out, the telescopic part of the elastic telescopic rod 6 drives the two templates 7 to move in opposite directions, the air bag 8 moves synchronously along with the corresponding templates 7, the first telescopic pipe 9 and the second telescopic pipe 10 are stretched, the two adjacent templates 7 are contacted with each other, the second through groove 73 is blocked by the connecting strip 12, as shown in fig. 6, then the electromagnetic valve in the first telescopic pipe 9 is controlled to be opened, so that the cold air entering the connecting pipe 201 enters the air bag 8 through the first telescopic pipe 9 and the first through groove 71, the air bag 8 is inflated, as shown in fig. 8, the two inflated air bags 8 are contacted with each other, the rear side of the inflated air bag 8 is contacted with the grooves 72, the rest parts of the air bags 8 are not contacted with the grooves 72, so that a cavity is formed between the air bags 8 and the grooves 72, then the external pump is controlled to be closed, and then the water is controlled to flow into the cavity through the second pipeline 202 and the second through the second pipeline 203, and the water is also filled into the cavity 10 through the second pipeline 203, and the one-way valve is fixed, and the cavity is not filled into the cavity 10, and the water is filled into the cavity through the second pipeline 203, and the water is filled into the cavity, and the one-way pipe is filled into the cavity and is filled into the air cavity through the air pipe 203;

meanwhile, since the external pump is always in a state of delivering cold air to the second pipeline 202, the cold air cools the water in the cavity, so that the water is condensed into ice cubes 01, the ice cubes 01 are hollow, the subsequent water can pass through conveniently, and under the action of the second through groove 73, a convex part 02 is formed on two sides of the ice cubes 01, as shown in the right part of fig. 9, and thus, the ice cubes 01 are manufactured;

when the battery needs to be charged, the peripheral pump is controlled to pump cold air out of the fixed pipe 203, so that the telescopic part of the elastic telescopic rod 6 is changed from an extending state to a normal state, in the process of changing the elastic telescopic rod 6, the two templates 7 are driven to move back to reset, meanwhile, the electromagnetic valve in the first telescopic pipe 9 is controlled to be opened, so that gas in the air bag 8 is discharged, the air bag 8 is changed from an expanding state to a normal state, the templates 7 and the air bag 8 are separated from ice cubes 01, the bulge 02 are adhered with the connecting strip 12, in the process of quickly charging the charging pile, the peripheral cooler is controlled to convey water into the installation groove frame 4 through the conveying pipe 2, the water enters the installation groove frame 4 from the left conveying pipe 2, then flows into the right conveying pipe 2 from the other end of the installation groove frame 4, and the water in the right conveying pipe 2 enters the peripheral cooler, so that the water in the installation groove frame 4 is circulated, so that the water in the installation groove frame 4 is in a flowing state, and the water dissipates heat of the electric appliance elements installed on the wall of the installation groove frame 4;

in the process that the water enters the installation groove frame 4, the water flows through the ice blocks 01, and as the water inlet height of the ice blocks 01 is larger than the water outlet height of the ice blocks 01, the flow speed of the water flow is increased when the water passes through the ice blocks 01, so that the water can take away heat generated by the electrical elements more quickly, meanwhile, the water is prevented from being washed away by the water due to the fact that the protruding parts 02 are adhered to the connecting strips 12, and meanwhile, the thickness of the protruding parts 02 is thicker than that of the ice blocks 01, when the water circularly flows in the installation groove frame 4, the protruding parts 02 are prevented from melting earlier than the ice blocks 01, and the ice blocks 01 move to influence the water to pass through the ice blocks 01;

meanwhile, the ice blocks 01 are used for cooling water in the installation groove frame 4, so that the cooled water can absorb heat generated by the electrical elements better, the heat dissipation effect of the electrical elements is improved, the service life of the electrical elements is prolonged, meanwhile, the problems that in the prior art, the volume of a cooler is relatively small, the cooling power of the water is limited, the temperature of the water can be gradually increased in the long-time heat dissipation process of the electrical elements, the cooling efficiency of the cooler on the water does not meet the requirement, the heat exchange efficiency of the water on the electrical elements is reduced after the water enters the installation groove frame 4, the stability of the electrical elements in operation is further affected, the service life of the electrical elements is even reduced and the like are solved;

here, when the battery is charged quickly, the output power of the charger will decrease, so the heat generated by the charger will also decrease greatly, at this time, the peripheral cooler is controlled to discharge the water in the installation groove frame 4 through the right conveying pipe 2, and then the above steps for making ice cubes 01 are repeated, thereby realizing the re-making of ice cubes 01, and facilitating the subsequent continuous cooling of the water in the installation groove frame 4.

Example 2

On the basis of the embodiment 1, as shown in fig. 5, the device also comprises an interception net 5; four interception nets 5 which are distributed in a rectangular shape are respectively arranged on the outer sides of the installation groove frames 4; the inner sides of the installation groove frames 4 are respectively provided with four other interception nets 5 which are distributed in a rectangular shape.

The interception net 5 is arranged to be double-layered, meshes between the interception nets 5 of the double-layered are distributed in a staggered mode, so that the interception net 5 can better intercept the ice residues, and the ice residues are prevented from entering the right conveying pipe 2 to cause blockage of the conveying pipe 2.

The interception net 5 is disposed at the corner of the installation frame 4.

When the ice cubes 01 cool down the water in the installation groove frame 4, after a long time, the ice cubes 01 are melted into ice residues and small ice cubes 01, so that the water drives the ice residues to move, in the moving process, the ice residues are intercepted by the interception net 5, the ice residues are prevented from entering the right conveying pipe 2, the conveying pipe 2 is blocked, meanwhile, the interception net 5 is arranged at the corner of the installation groove frame 4, the water is turbulent when passing through the corner of the installation groove frame 4, the water generates a turning effect, the turned water drives the ice residues around the interception net 5 to turn, the ice residues are prevented from precipitating at the bottom of the water, and the water temperature of the upper layer and the lower layer is inconsistent, so that the heat dissipation of the water to the electrical elements is affected.

While the invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.

Claims (10)

1. A high-efficiency liquid cooling super-charging machine comprises a charging machine shell (1); the left part and the right part of the front side of the charging motor shell (1) are fixedly connected with a plurality of conveying pipes (2) respectively; all the conveying pipes (2) are commonly provided with a first pipeline (3); the method is characterized in that: the charging motor shell (1) is connected with a pipeline component for conveying water and gas; the inner side of the charging machine shell (1) is fixedly connected with a mounting groove frame (4) for mounting an electric element, and the mounting groove frame (4) is communicated with the conveying pipe (2); a plurality of cavities (41) are arranged on the outer side of the mounting groove frame (4); the inner side of the mounting groove frame (4) is provided with a plurality of other cavities (41); the opposite sides of each cavity (41) are fixedly connected with a plurality of elastic telescopic rods (6) respectively, and one ends of the elastic telescopic rods (6) are connected with the pipeline components; the other ends of all the elastic telescopic rods (6) adjacent to each other up and down are fixedly connected with a template (7) together; each template (7) is provided with a first through groove (71); a groove (72) is respectively formed in the inner side of each template (7); an air bag (8) is arranged on the inner side of each template (7), and the air bag (8) is communicated with the first through groove (71); the upper part of the opposite sides of each template (7) is respectively provided with a first telescopic pipe (9), the first telescopic pipes (9) penetrate through the mounting groove frame (4), and the first telescopic pipes (9) are communicated with the pipeline components; the middle part of the opposite sides of each template (7) is respectively provided with a second telescopic pipe (10) for conveying water, the second telescopic pipes (10) penetrate through the mounting groove frame (4), and the second telescopic pipes (10) are communicated with the pipeline components.

2. The high efficiency liquid cooled overcharge charger of claim 1, wherein: a cavity (42) is arranged around each cavity (41), and a vacuum environment is arranged in the cavity (42).

3. The high efficiency liquid cooled overcharge charger of claim 1, wherein: the groove (72) is arranged in an isosceles trapezoid shape, and the shape of the air bag (8) is consistent with the shape of the groove (72) after the air bag is inflated.

4. The high efficiency liquid cooled overcharge charger of claim 1, wherein: the inner upper side and the inner lower side of the groove (72) are both cambered surfaces.

5. A high efficiency liquid cooled overcharge battery as claimed in any one of claims 2 to 4 and wherein: the device also comprises a connecting column (11); each template (7) is provided with a second through groove (73); the middle parts of the opposite sides of each cavity (41) are fixedly connected with a connecting column (11); each connecting column (11) is fixedly connected with a connecting strip (12), and the connecting strips (12) are matched with the second through grooves (73).

6. The efficient liquid-cooled overcharge charger of claim 5, wherein: sealing strips are arranged on two sides of the connecting strip (12).

7. The efficient liquid-cooled overcharge charger of claim 5, wherein: the pipeline component comprises a connecting pipe (201); the upper part in the charging motor shell (1) is fixedly connected with two connecting pipes (201); one end of all the connecting pipes (201) is commonly provided with a second pipeline (202); the lower side of each connecting pipe (201) is respectively provided with a plurality of fixed pipes (203); the fixed tube (203) is communicated with the other end of the elastic telescopic rod (6), and the other ends of the first telescopic tube (9) and the second telescopic tube (10) are communicated with the fixed tube (203).

8. The high efficiency liquid cooled overcharge charger of claim 7, wherein: the device also comprises an interception net (5); a plurality of interception nets (5) are respectively arranged on the outer sides of the installation groove frames (4); the inner sides of the installation groove frames (4) are respectively provided with a plurality of interception nets (5).

9. The efficient liquid-cooled overcharge battery of claim 8, wherein: the interception net (5) is arranged to be double-layered, and meshes between the interception nets (5) of the double-layered are distributed in a staggered mode, so that the interception net (5) can better intercept the ice residues.

10. The efficient liquid-cooled overcharge battery of claim 8, wherein: the interception net (5) is arranged at the corner of the installation groove frame (4).