CN107313851B

CN107313851B - Radiator hydroecium with rectification mechanism

Info

Publication number: CN107313851B
Application number: CN201710383623.5A
Authority: CN
Inventors: 许元峰
Original assignee: Jiangsu Herui Precision Manufacturing Co ltd
Current assignee: Jiangsu Herui Precision Manufacturing Co ltd
Priority date: 2017-05-26
Filing date: 2017-05-26
Publication date: 2023-08-11
Anticipated expiration: 2037-05-26
Also published as: CN107313851A

Abstract

The application discloses a radiator water chamber with a rectifying mechanism. This radiator hydroecium belongs to vehicle radiator technical field, has solved radiator hydroecium among the prior art and has set up respectively, the pipe connection is complicated, the uneven problem of fluid velocity of flow, including the casing, the inside baffle that separates the casing into first cavity and second cavity that is equipped with of casing, outside is equipped with rectifier mechanism, baffle one side is equipped with telescopic machanism, and the opposite side is equipped with the positioning mechanism that the restriction baffle removed, and rectifier mechanism is equipped with the buffer column row that is connected with radiator core including the buffer chamber that is used for balancing the refrigerant velocity of flow including being used for the buffer chamber. According to the application, different chambers are respectively connected with different radiators, so that the effect that a plurality of radiator water chambers are integrated is realized, the problems of large occupied space and complex pipeline connection of the radiator water chambers are avoided, and the pressure of fluid flowing into the buffer column is uniform by utilizing the rectifying mechanism.

Description

Radiator hydroecium with rectification mechanism

Technical Field

The application belongs to the technical field of vehicle radiators, and particularly relates to a radiator water chamber with a rectifying mechanism.

Background

The automobile radiator is an important part for ensuring the cooling performance of the whole automobile, the cooling liquid brings heat to the radiator and radiates the heat, and the radiator assembly generally consists of a cooling liquid inlet, a cooling liquid outlet, an upper water chamber, a lower water chamber, a radiator core body and the like. When fluid enters the water chamber through the inlet, the fluid easily forms vortex at the water chamber inlet, so that uneven flow velocity distribution of the fluid entering the core body is caused, meanwhile, due to the fact that the fluid flows in the water chamber, the water pressure of the fluid at each section point is different, the time of entering the flat tube in the core body is different, the heat dissipation effect of the fluid is uneven, for a speed changer cooling vehicle model, an engine radiator and a speed changer radiator are arranged separately, the two radiator are different in size, the installation area occupation is large, and the pipeline connection is complex.

Disclosure of Invention

The application aims to provide a radiator water chamber with a rectifying mechanism, which has the advantages of simple pipeline connection, uniform fluid flow rate and long radiating stroke.

In order to achieve the technical purpose, the radiator water chamber with the rectifying mechanism adopts the following technical scheme:

the utility model provides a radiator hydroecium with rectifier mechanism, includes the casing, the inside baffle that separates the casing into first cavity and second cavity that is equipped with of casing, outside is equipped with rectifier mechanism, baffle one side is equipped with telescopic machanism, and the opposite side is equipped with the positioning mechanism that the restriction baffle removed, rectifier mechanism is including the buffer chamber that is used for balancing refrigerant velocity of flow, the buffer chamber is equipped with the buffer column row of being connected with the radiator core, positioning mechanism is including the slide rail of arranging in casing both sides lateral wall in, the slide rail includes upper rail and the lower rail of upper and lower parallel, be equipped with first ball and second ball side by side between upper rail and the lower rail, the second ball passes through connecting rod and baffle fixed connection, be equipped with a plurality of restriction second ball rolling arc grooves on the lower rail, the arc groove tank bottom is equipped with the flat board, flat board both sides are connected with the arc groove cell wall through the spring, be equipped with the air column between flat board bottom and the arc groove tank bottom.

Preferably, the first chamber is provided with a first water inlet, and the second chamber is provided with a second water inlet.

Preferably, the pipe diameter of the buffer cavity gradually increases from the position close to the first water inlet to the position of the partition plate. Through the change of pipe diameter, the refrigerant flows into the radiator core at a constant speed, thereby ensuring the heat radiation performance of the radiator.

Preferably, the pipe diameter of the buffer cavity gradually increases from the position close to the second water inlet to the position of the partition plate. Through the change of pipe diameter, the refrigerant flows into the radiator core at a constant speed, thereby ensuring the heat radiation performance of the radiator.

Preferably, the buffer column row comprises a plurality of buffer columns with uniform and consistent intervals, one end of each buffer column is communicated with the buffer cavity, and the other end of each buffer column is communicated with the core body of the radiator. The heat exchange flow of the refrigerant is prolonged by utilizing the plurality of buffer columns, and the heat exchange effect of the refrigerant is enhanced.

Preferably, the radius of the arc-shaped groove is larger than the radius of the first ball. By arranging the arc-shaped groove and the radius of the first ball, the first ball is ensured to be stably positioned in the arc-shaped groove when being positioned.

Preferably, the sum of the diameters of the first ball and the second ball is larger than the vertical distance between the upper rail and the bottom of the arc-shaped groove. In order to ensure that the second ball cannot move continuously during positioning, the sum of the diameters of the first ball and the second ball is larger than the vertical distance between the upper rail and the bottom of the arc-shaped groove.

Preferably, the telescopic mechanism comprises a telescopic cylinder, a telescopic cylinder or a telescopic sliding rod.

Preferably, the gas column is connected with the compressed gas storage tank through a connecting pipe.

Compared with the prior art, the application has the beneficial effects that:

1. according to the application, the shell is arranged into the first cavity and the second cavity, so that the first cavity and the second cavity are respectively connected with different radiators, the effect that a plurality of radiator water chambers are integrated is realized, and the problems of large occupied space of the radiator water chambers and complex pipeline connection are avoided;

2. according to the application, the rectification mechanism is utilized to homogenize the pressure of the fluid flowing into the buffer column, so that the fluid is ensured to flow into the radiator core at a uniform speed, the radiating stroke of the fluid is prolonged, and the radiating performance of the radiator is ensured;

3. according to the application, the first ball, the second ball and the arc-shaped groove are matched in the positioning mechanism, so that the second ball cannot move continuously during positioning, and the positioning effect of the partition plate is ensured.

Drawings

FIG. 1 is a schematic diagram of the structure of the present application;

FIG. 2 is a schematic view of the positioning mechanism of the present application;

FIG. 3 is a schematic diagram of the rectifying mechanism of the present application;

fig. 4 is a schematic structural view of embodiment 3 of the present application.

In the figure: 1. a first chamber; 2. a second chamber; 3. a partition plate; 4. a telescoping mechanism; 5. a buffer chamber; 6. a top rail; 7. a lower rail; 8. a first bead; 9. a second bead; 10. a connecting rod; 11. an arc-shaped groove; 12. a flat plate; 13. a spring; 14. a gas column; 15. a first water inlet; 16. a second water inlet; 17. a buffer column; 18. a third chamber; 19. a first separator; 20. a second separator; 21. a third water inlet; 22. and a positioning rod.

Detailed Description

The present application is further illustrated in the accompanying drawings and detailed description which are to be understood as being merely illustrative of the application and not limiting of its scope, and various modifications of the application, which are equivalent to those skilled in the art upon reading the application, fall within the scope of the application as defined in the appended claims.

As shown in fig. 1 to 4, a radiator water chamber with rectification mechanism comprises a housing, the inside baffle 3 that separates the casing into first cavity 1 and second cavity 2 that is equipped with of casing, outside is equipped with rectification mechanism, baffle 3 one side is equipped with telescopic machanism 4, and the opposite side is equipped with the positioning mechanism that restricts baffle 3 and removes, rectification mechanism is including the buffer chamber 5 that is used for balancing the refrigerant velocity of flow, buffer chamber 5 is equipped with the buffering column that is connected with the radiator core, positioning mechanism is including the slide rail of built-in casing both sides lateral wall, the slide rail includes upper rail 6 and the lower rail 7 that are parallel from top to bottom, be equipped with first ball 8 and second ball 9 side by side between upper rail 6 and the lower rail 7, second ball 9 passes through connecting rod 10 and baffle 3 fixed connection, be equipped with a plurality of restriction second ball 9 rolling arc groove 11 on the lower rail 7, arc groove 11 tank bottom is equipped with flat board 12, flat board 12 both sides are connected with arc groove 11 cell wall through spring 13, be equipped with air column 14 between flat board 12 bottom and the arc groove 11 tank bottom.

The first chamber 1 is provided with a first water inlet 15 and the second chamber 2 is provided with a second water inlet 16.

The pipe diameter of the buffer cavity 5 gradually increases from the position close to the first water inlet 15 to the position of the partition plate 3.

The pipe diameter of the buffer cavity 5 gradually increases from the position close to the second water inlet 16 to the position of the partition plate 3.

The buffer column row comprises a plurality of buffer columns 17 with uniform and consistent intervals, one end of each buffer column 17 is communicated with the buffer cavity 5, and the other end of each buffer column is communicated with a core body of the radiator.

The radius of the arc-shaped groove 11 is larger than the radius of the first ball 8.

The sum of the diameters of the first ball 8 and the second ball 9 is larger than the vertical distance between the upper rail 6 and the bottom of the arc-shaped groove 11.

The telescopic mechanism 4 comprises a telescopic oil cylinder, a telescopic air cylinder or a telescopic sliding rod.

The gas column 14 is connected to a compressed gas storage tank by a connecting pipe.

Example 1:

referring to fig. 1-3 of the specification, the radiator water chamber with the rectification mechanism comprises a shell, wherein a baffle plate 3 for dividing the shell into a first cavity 1 and a second cavity 2 is arranged in the shell, the rectification mechanism is arranged outside the shell, the first cavity 1 is provided with a first water inlet 15, the second cavity 2 is provided with a second water inlet 16, one side of the baffle plate 3 is provided with a telescopic cylinder 4, the other side of the baffle plate 3 is provided with a positioning mechanism for limiting the movement of the baffle plate 3, the rectification mechanism comprises a buffer cavity 5 for balancing the flow rate of a refrigerant, the pipe diameter of the buffer cavity 5 is gradually increased from a position close to the first water inlet 15 to the baffle plate 3, the pipe diameter of the buffer cavity 5 is gradually increased from a position close to the second water inlet 16 to the baffle plate 3, the buffer cavity 5 is provided with a buffer column row connected with a radiator core, the buffer column row comprises a plurality of buffer columns 17 with uniform and consistent intervals, one end of each buffer column 17 is communicated with the buffer cavity 5, the other end of each buffer column is communicated with a core body of the radiator, the positioning mechanism comprises a sliding rail which is internally arranged on two side walls of the shell, the sliding rail comprises an upper rail 6 and a lower rail 7 which are parallel up and down, a first ball 8 and a second ball 9 are arranged between the upper rail 6 and the lower rail 7 side by side, the second ball 9 is fixedly connected with the partition plate 3 through a connecting rod 10, a plurality of arc grooves 11 which limit the second ball 9 to roll are formed in the lower rail 7, a flat plate 12 is arranged at the bottom of each arc groove 11, two sides of each flat plate 12 are connected with the groove walls of the arc grooves 11 through springs 13, an air column 14 is arranged between the bottom of each flat plate 12 and the groove 11, and the air column 14 is connected with a compressed gas storage tank through a connecting pipe. Wherein the radius of the arc-shaped groove 11 is larger than the radius of the first ball 8, and the sum of the diameters of the first ball 8 and the second ball 9 is larger than the vertical distance between the upper rail 6 and the bottom of the arc-shaped groove 11.

In order to save the installation space of the radiator and avoid complex pipeline connection, two radiator water chambers are integrated, the telescopic cylinder 4 is started, the telescopic cylinder 4 pushes the partition plate 3 to move, the second round beads 9 fixedly connected with the partition plate 3 push the first round beads 8 to roll along the sliding rail until the first round beads 8 roll into the arc-shaped grooves 11 of the lower rail 7, and the sum of the diameters of the first round beads 8 and the second round beads 9 is larger than the vertical distance between the upper rail 6 and the bottom of the arc-shaped grooves 11 at the same time, so that the second round beads 9 cannot continue to move, and the position of the partition plate 3 is fixed at the moment; when the position of the partition plate 3 needs to be changed again, gas is filled into the gas column 14, and the height of the gas column 14 gradually rises along with the increase of the gas filling quantity, so that the flat plate 12 is driven to move towards the notch of the arc-shaped groove 11 until the flat plate 12 is leveled with the notch of the arc-shaped groove 11, and the first round beads 8 and the second round beads 9 continuously slide along the sliding rail, so that the flexible positioning of the partition plate 3 is realized; the first water inlet 15 and the second water inlet 16 respectively flow into the first chamber 1 and the second chamber 2, and then flow into the buffer chamber 5, so that along with the change of the pipe diameter of the buffer chamber 5, the flow speed of the flow entering the buffer column 17 is uniform, the problem of stress concentration is solved, the refrigerant can flow at a uniform speed in the radiator core, the heat dissipation stroke of the refrigerant is prolonged, and the heat dissipation effect of the refrigerant is enhanced.

Example 2:

the application relates to a radiator water chamber with a rectifying mechanism, which is combined with an attached drawing 1-3 of an instruction book, and comprises a shell, wherein a baffle 3 for dividing the shell into a first cavity 1 and a second cavity 2 is arranged inside the shell, the rectifying mechanism is arranged outside the shell, the first cavity 1 is provided with a first water inlet 15, the second cavity 2 is provided with a second water inlet 16, one side of the baffle 3 is provided with a telescopic cylinder 4, the other side of the baffle 3 is provided with a positioning mechanism for limiting the movement of the baffle 3, the rectifying mechanism comprises a buffer cavity 5 for balancing the flow rate of a refrigerant, the pipe diameter of the buffer cavity 5 gradually increases from a position close to the first water inlet 15 to the baffle 3, the pipe diameter of the buffer cavity 5 gradually increases from a position close to the second water inlet 16 to the baffle 3, the buffer cavity 5 is provided with a buffer column row connected with a radiator core, the buffer column row comprises a plurality of buffer columns 17 with uniform intervals, one end of the buffer column 17 is communicated with the buffer cavity 5, the other end of the buffer column is communicated with the core of the radiator, the positioning mechanism comprises a sliding rail arranged on two side walls of the shell, the sliding rail comprises an upper rail and a lower rail 6 and a lower rail 7, the lower rail 7 is connected with a lower rail 11 and a side of the buffer column 11, the two side of the buffer column is provided with a groove 11 and a groove 11 is provided with a groove 11, a groove 11 is provided with a groove 11 and a groove 11 is provided with a groove 11. Wherein the radius of the arc-shaped groove 11 is larger than the radius of the first ball 8, and the sum of the diameters of the first ball 8 and the second ball 9 is larger than the vertical distance between the upper rail 6 and the bottom of the arc-shaped groove 11.

In order to save the installation space of the radiator and avoid complex pipeline connection, two radiator water chambers are integrated, the telescopic cylinder 4 is started, the telescopic cylinder 4 pushes the partition plate 3 to move, the second round bead 9 fixedly connected with the partition plate 3 pushes the first round bead 8 to roll along the sliding rail until the first round bead 8 rolls into the arc-shaped groove 11 of the lower rail 7, and the radius of the arc-shaped groove 11 is larger than that of the first round bead 8, meanwhile, the sum of the diameters of the first round bead 8 and the second round bead 9 is larger than the vertical distance between the upper rail 6 and the bottom of the arc-shaped groove 11, so that the second round bead 9 cannot continue to move, and the position of the partition plate 3 is fixed at the moment; when the position of the partition plate 3 needs to be changed again, gas is filled into the gas column 14, and the height of the gas column 14 gradually rises along with the increase of the gas filling quantity, so that the flat plate 12 is driven to move towards the notch of the arc-shaped groove 11 until the flat plate 12 is leveled with the notch of the arc-shaped groove 11, and the first round beads 8 and the second round beads 9 continuously slide along the sliding rail, so that the flexible positioning of the partition plate 3 is realized; the first water inlet 15 and the second water inlet 16 respectively flow into the first chamber 1 and the second chamber 2, and then flow into the buffer chamber 5, so that along with the change of the pipe diameter of the buffer chamber 5, the flow speed of the flow entering the buffer column 17 is uniform, the problem of stress concentration is solved, the refrigerant can flow at a uniform speed in the radiator core, the heat dissipation stroke of the refrigerant is prolonged, and the heat dissipation effect of the refrigerant is enhanced.

Example 3:

referring to fig. 1-4 of the drawings, the radiator water chamber with the rectifying mechanism of the present application comprises a housing, wherein a first partition 19 and a second partition 20 for dividing the housing into a first chamber 1, a second chamber 2 and a third chamber 18 are arranged in the housing, the rectifying mechanism is arranged outside the housing, the first chamber 1 is provided with a first water inlet 15, the second chamber 2 is provided with a second water inlet 16, the third chamber 18 is provided with a third water inlet 21, a positioning rod 22 is arranged between the first partition 19 and the second partition 20, a telescopic cylinder 4 is arranged at the other side of the first partition 19, a positioning mechanism for limiting the movement of the second partition 20 is arranged at the other side of the second partition 20, the rectifying mechanism comprises a buffer cavity 5 for balancing the flow rate of refrigerant, the pipe diameter of the buffer cavity 5 gradually increases from the position close to the first water inlet 15 to the position of the first partition 19, the pipe diameter of the buffer cavity 5 gradually increases from a position close to the second water inlet 16 to a position of the second partition plate 20, the pipe diameter of the buffer cavity 5 is transitionally kept unchanged from the first partition plate 19 to the second partition plate 20, the buffer cavity 5 is provided with a buffer column connected with a radiator core, the buffer column comprises a plurality of buffer columns 17 with uniform intervals, one end of the buffer column 17 is communicated with the buffer cavity 5, the other end of the buffer column is communicated with the core of the radiator, the positioning mechanism comprises a sliding rail which is internally arranged on the side walls of the two sides of the shell, the sliding rail comprises an upper rail 6 and a lower rail 7 which are parallel up and down, a first round bead 8 and a second round bead 9 are arranged between the upper rail 6 and the lower rail 7 side by side, the second round bead 9 is fixedly connected with the partition plate 3 through a connecting rod 10, a plurality of arc grooves 11 are arranged on the lower rail 7, the bottoms of the arc grooves 11 are provided with flat plates 12, the two sides of the flat plate 12 are connected with the groove walls of the arc-shaped groove 11 through springs 13, an air column 14 is arranged between the bottom of the flat plate 12 and the groove bottom of the arc-shaped groove 11, and the air column 14 is connected with a compressed gas storage tank through a connecting pipe. Wherein the radius of the arc-shaped groove 11 is larger than the radius of the first ball 8, and the sum of the diameters of the first ball 8 and the second ball 9 is larger than the vertical distance between the upper rail 6 and the bottom of the arc-shaped groove 11.

In order to save the installation space of the radiator and avoid complex pipeline connection, three radiator water chambers are integrated, the telescopic oil cylinder 4 is started, the telescopic oil cylinder 4 pushes the first partition plate 19 to move, the second partition plate 20 moves in the same direction because a positioning rod 22 is arranged between the first partition plate 19 and the second partition plate 20, the second round beads 9 fixedly connected with the second partition plate 20 push the first round beads 8 to roll along the sliding rail until the first round beads 8 roll into the arc grooves 11 of the lower rail 7, and the radius of the arc grooves 11 is larger than that of the first round beads 8, and meanwhile, the sum of the diameters of the first round beads 8 and the second round beads 9 is larger than the vertical distance between the upper rail 6 and the bottom of the arc grooves 11, so that the second round beads 9 cannot continue to move, and the positions of the first partition plate 19 and the second partition plate 20 are fixed; when the positions of the first partition plate 19 and the second partition plate 20 need to be changed again, gas is filled into the gas column 14, and the height of the gas column 14 gradually rises along with the increase of the gas filling quantity, so that the flat plate 12 is driven to move towards the notch of the arc-shaped groove 11 until the flat plate 12 is leveled with the notch of the arc-shaped groove 11, the first round beads 8 and the second round beads 9 continue to slide along the sliding rail, and flexible positioning of the first partition plate 19 and the second partition plate 20 is realized; the first water inlet 15, the second water inlet 16 and the third water inlet 21 respectively feed running water into the first chamber 1, the second chamber 2 and the third chamber 18, the running water flows into the buffer chamber 5 again, the running water speed entering the buffer column 17 is uniform along with the change of the pipe diameter of the buffer chamber 5, the problem of stress concentration is solved, the refrigerant can flow at a uniform speed in the radiator core body, the radiating stroke of the refrigerant is prolonged, and the radiating effect of the refrigerant is enhanced.

According to the application, different chambers are respectively connected with different radiators, so that the effect that a plurality of radiator water chambers are integrated is realized, and the problems of large occupied space of the radiator water chambers and complex pipeline connection are avoided; the rectification mechanism is utilized to homogenize the pressure of the fluid flowing into the buffer column, so that the refrigerant is ensured to flow into the radiator core at a uniform speed, and the heat dissipation performance of the radiator is ensured; through the cooperation between first ball, second ball and the arc groove in the positioning mechanism, make the second ball unable the continuation removal when the location, guaranteed the location effect of baffle.

Claims

1. Radiator hydroecium with rectification mechanism, including the casing, its characterized in that: the inside baffle that separates the casing into first cavity and second cavity that is equipped with of casing, outside is equipped with rectification mechanism, baffle one side is equipped with telescopic machanism, and the other side is equipped with the positioning mechanism that restriction baffle removed, rectification mechanism is including being used for balancing the buffering chamber of refrigerant velocity of flow, the buffering chamber is equipped with the buffering column that is connected with the radiator core, positioning mechanism includes the smooth rail of built-in casing both sides lateral wall, the slide rail includes upper rail and the lower rail of upper and lower parallel, be equipped with first round bead and second round bead side by side between upper rail and the lower rail, the second round beads are fixedly connected with the partition plate through the connecting rod, a plurality of arc grooves used for limiting the rolling of the second round beads are formed in the lower rail, a flat plate is arranged at the bottom of the arc groove, two sides of the flat plate are connected with the wall of the arc groove through springs, an air column is arranged between the bottom of the flat plate and the bottom of the arc groove, a first water inlet is formed in a first cavity, a second water inlet is formed in a second cavity, the pipe diameter of the buffer cavity gradually increases from a position close to the first water inlet to a position close to the partition plate, and the pipe diameter of the buffer cavity gradually increases from a position close to the second water inlet to the position of the partition plate.

2. The radiator water chamber with a rectifying mechanism according to claim 1, characterized in that: the buffer column row comprises a plurality of buffer columns with uniform intervals, one end of each buffer column is communicated with the buffer cavity, and the other end of each buffer column is communicated with the core body of the radiator.

3. The radiator water chamber with a rectifying mechanism according to claim 1, characterized in that: the radius of the arc-shaped groove is larger than that of the first ball.

4. The radiator water chamber with a rectifying mechanism according to claim 1, characterized in that: the sum of the diameters of the first ball and the second ball is larger than the vertical distance between the upper rail and the bottom of the arc-shaped groove.

5. The radiator water chamber with a rectifying mechanism according to claim 1, characterized in that: the telescopic mechanism comprises a telescopic oil cylinder, a telescopic air cylinder or a telescopic sliding rod.

6. The radiator water chamber with a rectifying mechanism according to claim 1, characterized in that: the air column is connected with the compressed gas storage tank through a connecting pipe.