CN204574897U

CN204574897U - Water-filled radiator

Info

Publication number: CN204574897U
Application number: CN201520199984.0U
Authority: CN
Inventors: 李俊宇
Original assignee: Shenzhen Wanjinghua Technology Co ltd
Current assignee: Shenzhen Wanjinghua Technology Co ltd
Priority date: 2015-04-03
Filing date: 2015-04-03
Publication date: 2015-08-19
Anticipated expiration: 2025-04-03

Abstract

The utility model belongs to radiator field, particularly relates to a kind of water-filled radiator, is intended to solve existing water-filled radiator and causes because structural member is more installation to bother the technical problem poor with sealing.One-body molded in cylindrical body have spaced walls and cylindrical body be divided internally into the first holding tank and the second holding tank, second holding tank one end is covered with absorber plate, second holding tank is divided into the first inner chamber and the second inner chamber by deflector, motor in water pump is arranged in the first holding tank that magnetic impeller is arranged in the first inner chamber, complete the assembling of heat radiation module, the less installation of this heat emission module structure part is easy, improves relative to the sealing of outside, allows heat-conducting fluid be difficult to reveal.When motor-driven magnetic wheel rotation, heat-conducting fluid enters in the second holding tank by the inlet opening of cylindrical body, flowed out by apopore after the heat that heater members produces is passed to heat-conducting fluid by absorber plate and deliver to cold type, be low temperature by heat-conducting fluid by high temperature shift by cold type, realize heat radiation.

Description

Water-filled radiator

Technical field

The utility model belongs to radiator field, particularly relates to a kind of water-filled radiator.

Background technology

The cold type that water-filled radiator of the prior art generally includes heat radiation module and is connected with heat radiation module pipeline, heat radiation module comprises housing, is arranged on dividing plate on the opposite end of housing and absorber plate, the water pump be arranged on dividing plate respectively, housing offers inlet opening and apopore, in housing, be filled with heat-conducting fluid.Heat-conducting fluid enters enclosure interior by inlet opening under the driving of water pump, and the heat that heater members produces is passed to through absorber plate and is discharged by apopore after heat-conducting fluid and to deliver to cold type, is low temperature, realizes heat radiation by cold type by heat-conducting fluid by high temperature shift.Existing water-filled radiator structural member is more, and install trouble, poor relative to the sealing of outside, heat-conducting fluid is easily revealed.

Utility model content

The purpose of this utility model is to provide a kind of water-filled radiator, is intended to solve existing water-filled radiator and causes because structural member is more installation to bother the technical problem poor with sealing.

The utility model realizes like this, a kind of water-filled radiator, the cold type comprising heat radiation module and be connected with described heat radiation module pipeline, described heat radiation module comprises mount pad, and described mount pad comprises cylindrical body and one-body moldedly in described cylindrical body, along the axis of this cylindrical body, the inner space of this cylindrical body is divided into the spaced walls of the first holding tank and the second holding tank; Described heat radiation module also comprise cover at described second holding tank away from the absorber plate on one end of described first holding tank and the deflector that is arranged in described second holding tank, the madial wall of described spaced walls, described deflector and described cylindrical body encloses formation first inner chamber, the madial wall of described deflector, described absorber plate and described cylindrical body encloses formation second inner chamber, described deflector offers the through hole for being communicated with described first inner chamber and described second inner chamber; Described heat radiation module also comprises the water pump be arranged in described spaced walls, and described water pump comprises the motor be contained in described first holding tank, be fixed in described first inner chamber and the drive-connecting shaft arranged with described motors and being contained in described first inner chamber and the magnetic impeller be articulated on described drive-connecting shaft; Described cylindrical body offers the inlet opening with described second intracavity inter-connection, described cylindrical body offers the apopore with described first intracavity inter-connection; Be filled with heat-conducting fluid in described second holding tank, enter described first inner chamber by described through hole after described heat-conducting fluid enters described second inner chamber by described inlet opening when described motor drives described magnetic impeller to rotate and flowed out by described apopore.

Further, described magnetic impeller comprises rounded substrate, circumferentially be distributed in described substrate towards the some blades on the side of described deflector, in first annular wall extended to form along the axis of described cylindrical body near its axle center place of described substrate and in the outer rim of described substrate along the second annular wall that the axis of described cylindrical body extends to form, described first annular wall is set in the inner side stretching into described motor on described drive-connecting shaft and along the axis of described cylindrical body, described second annular wall ring is located at the outside of described motor, often be formed with the first flow flowed towards the direction away from the axle center of described substrate for described heat-conducting fluid between adjacent two described blades, described spaced walls and described magnetic impeller are separately and form the second runner flowed around the inner and outer of described motor for described heat-conducting fluid.

Further, the position between often adjacent two described blades of described substrate offers the via hole for being communicated with described first flow and described second runner.

Further, described through hole is opened on the position corresponding to described drive-connecting shaft of described deflector.

Further, being provided with on the side of described absorber plate for guiding described heat-conducting fluid to flow to the guiding wall of described through hole by described second inner chamber of described deflector.

Further, be provided with support arm in described through hole, wherein one end of described drive-connecting shaft is fixed in described spaced walls that other one end of this drive-connecting shaft is fixed on described support arm.

Further, described second inner chamber is provided with the involute sidewall suitable with the outline of described magnetic impeller, and this involute sidewall connects with described apopore.

Further, described heat radiation module also comprises and to be arranged between described deflector and described absorber plate and cushion for absorbing the bulbs of pressure that described heat-conducting fluid produces in time being heated.

Further, described heat radiation module also comprises two joints be rotatably installed in respectively on described inlet opening and described apopore.

Further, described inlet opening is concordant with described apopore to be arranged in described cylindrical body, described deflector offers the breach for being communicated with described inlet opening and described second inner chamber.

The utility model relative to the technique effect of prior art is: one-body molded in cylindrical body have spaced walls and cylindrical body be divided internally into the first holding tank and the second holding tank, second holding tank is covered with absorber plate away from one end of the first holding tank, second holding tank is divided into the first inner chamber and the second inner chamber by deflector, motor in water pump is arranged in the first holding tank that magnetic impeller is arranged in the first inner chamber, complete the assembling of heat radiation module, this heat emission module structure part is less, install easily, improve relative to the sealing of outside, allow heat-conducting fluid be difficult to reveal.When motor-driven magnetic wheel rotation, heat-conducting fluid enters in the second holding tank by the inlet opening of cylindrical body, flowed out by apopore after the heat that heater members produces is passed to heat-conducting fluid by absorber plate and deliver to cold type, be low temperature by heat-conducting fluid by high temperature shift by cold type, realize heat radiation.

Accompanying drawing explanation

Fig. 1 is the three-dimensional installation diagram of the water-filled radiator that the utility model embodiment provides.

Fig. 2 is the three-dimensional exploded view of the water-filled radiator of Fig. 1.

Fig. 3 is the three-dimensional exploded view of another angle of the water-filled radiator of Fig. 1.

Fig. 4 is the sectional view along A-A line of the water-filled radiator of Fig. 1.

Fig. 5 is the sectional view along B-B line of the water-filled radiator of Fig. 1.

Detailed description of the invention

In order to make the purpose of this utility model, technical scheme and advantage clearly understand, below in conjunction with drawings and Examples, the utility model is further elaborated.Should be appreciated that specific embodiment described herein only in order to explain the utility model, and be not used in restriction the utility model.

Refer to Fig. 1 to Fig. 3, a kind of water-filled radiator that the utility model embodiment provides, the cold type (not shown) comprising heat radiation module and be connected with described heat radiation module pipeline (not shown), described heat radiation module comprises mount pad 10, and described mount pad 10 comprises cylindrical body 11 and one-body moldedly in described cylindrical body 11, along the axis of this cylindrical body 11, the inner space of this cylindrical body 11 is divided into the spaced walls 12 of the first holding tank 13 and the second holding tank 14, please refer to Fig. 4, described heat radiation module also comprise cover at described second holding tank 14 away from the absorber plate 20 on one end of described first holding tank 13 and the deflector 30 that is arranged in described second holding tank 14, described spaced walls 12, described deflector 30 encloses formation first inner chamber 141 with the madial wall of described cylindrical body 11, described deflector 30, described absorber plate 20 encloses formation second inner chamber 142 with the madial wall of described cylindrical body 11, please refer to Fig. 2, described deflector 30 offers the through hole 31 for being communicated with described first inner chamber 141 and described second inner chamber 142, described heat radiation module also comprises the water pump 40 be arranged in described spaced walls 12, and described water pump 40 comprises the motor 41 be contained in described first holding tank 13, be fixed in described first inner chamber 141 and with the coaxial drive-connecting shaft 42 that arranges of described motor 41 and to be contained in described first inner chamber 141 and the magnetic impeller 43 be articulated on described drive-connecting shaft 42, described cylindrical body 11 offers the inlet opening 111 be connected with described second inner chamber 142, described cylindrical body 11 offers the apopore 112 be connected with described first inner chamber 141, be filled with heat-conducting fluid in described second holding tank 14, enter described first inner chamber 141 by described through hole 31 after described heat-conducting fluid enters described second inner chamber 142 by described inlet opening 111 when described motor 41 drives described magnetic impeller 43 to rotate and flowed out by described apopore 112.

One-body molded in cylindrical body 11 have spaced walls 12 and cylindrical body 11 be divided internally into the first holding tank 13 and the second holding tank 14, second holding tank 14 is covered with absorber plate 20 away from one end of the first holding tank 13, second holding tank 14 is divided into the first inner chamber 141 and the second inner chamber 142 by deflector 30, motor 41 in water pump 40 is arranged in the first holding tank 13 that magnetic impeller 43 is arranged in the first inner chamber 141, complete the assembling of heat radiation module, this heat emission module structure part is less, install easily, improve relative to the sealing of outside, allow heat-conducting fluid be difficult to reveal.When motor 41 drives magnetic impeller 43 to rotate, heat-conducting fluid enters in the second holding tank 14 by the inlet opening 111 of cylindrical body 11, flowed out by apopore 112 after the heat that heater members produces is passed to heat-conducting fluid by absorber plate 20 and deliver to cold type, be low temperature by heat-conducting fluid by high temperature shift by cold type, realize heat radiation.

Particularly, please refer to Fig. 3, motor 41 comprises iron core 411 and the winding 412 of winding on iron core 411, motor 41 roughly in the form of a ring, first holding tank 13 in the form of a ring, motor 41 can be contained in the first holding tank 13 and to be fixed on an installing plate 413, and this installing plate 413 is covered on outside the first holding tank 13.Please refer to Fig. 2, Fig. 4, absorber plate 20 comprises in tabular and the body 21 of fitting with heater members and be arranged on some on body 21 and the radiating fin 22 of column distribution, the runner flow through for heat-conducting fluid is formed between adjacent heat radiation fin 22, body 21 is covered on one end away from the first holding tank 13 of the second holding tank 14 by securing member (not shown), and is provided with sealing ring 15 between body 21 and cylindrical body 11.Second holding tank 14 is divided into the first inner chamber 141 and the second inner chamber 142 by deflector 30, allows heat-conducting fluid enter the second inner chamber 142 and after the abundant heat absorbed on absorber plate 20, flows to the first inner chamber 141 through through hole 31, improving radiating effect.Cold type is prior art, has water inlet and delivery port, high-temperature heat-conductive fluid enter cold type by water inlet and dispel the heat in cold type by high temperature become make low temperature, low temperature heat-conducting fluid is discharged by delivery port.

Further, please refer to Fig. 2 to Fig. 4, described magnetic impeller 43 comprises rounded substrate 431, circumferentially be distributed in described substrate 431 towards the some blades 433 on the side of described deflector 30, in first annular wall 434 extended to form along the axis of described cylindrical body 11 near its axle center place of described substrate 431 and in the outer rim of described substrate 431 along the second annular wall 435 that the axis of described cylindrical body 11 extends to form, described first annular wall 434 is set in the inner side stretching into described motor 41 on described drive-connecting shaft 42 and along the axis of described cylindrical body 11, described second annular wall 435 ring is located at the outside of described motor 41, often be formed with the first flow 81 flowed towards the direction away from the axle center of described substrate 431 for described heat-conducting fluid between adjacent two described blades 433, described spaced walls 12 and described magnetic impeller 43 are separately and forms the second runner 82 that the described heat-conducting fluid of confession flows around the inner and outer of described motor 41.Particularly, the cross section of blade 433 is roughly in crescent, and heat-conducting fluid makes centrifugal motion after entering the first inner chamber 141 by the through hole 31 of deflector 30 under the drive of magnetic impeller 43, and is discharged by the apopore 112 tangent with the inwall of the first inner chamber 141.This structure allows heat-conducting fluid can be looped around the inner and outer flowing of motor 41, accelerates heat transmission, good heat dissipation effect.

Further, the position between often adjacent two described blades 433 of described substrate 431 offers the via hole 432 for being communicated with described first flow 81 and described second runner 82.Allow the wherein a part of heat-conducting fluid in first flow 81 enter the second runner 82 through via hole 432 flow around the inner and outer of motor 41, accelerate heat transmission further, radiating effect is better again.

Further, please refer to Fig. 2, Fig. 3, described through hole 31 is opened on the position corresponding to described drive-connecting shaft 42 of described deflector 30.This structure is convenient to middle part heat-conducting fluid being guided to magnetic impeller 43, then is with action centrifugal motion by blade 433.

Further, being provided with on the side of described absorber plate 20 for guiding described heat-conducting fluid to flow to the guiding wall 32 of described through hole 31 by described second inner chamber 142 of described deflector 30.Particularly, the cross section of guiding wall 32 is roughly in normal distribution curve, and through hole 31 is positioned on the recessed position at this knee of curve place, and this structure is conducive to the pressure loss reducing heat-conducting fluid, improves radiating effect.

Further, please refer to Fig. 4, be provided with support arm 311 in described through hole 31, wherein one end of described drive-connecting shaft 42 is fixed in described spaced walls 12 that other one end of this drive-connecting shaft 42 is fixed on described support arm 311.This structure allows drive-connecting shaft 42 stablize and is arranged in the first inner chamber 141.

Further, please refer to Fig. 5, described second inner chamber 142 is provided with the involute sidewall 143 suitable with the outline of described magnetic impeller 43, and this involute sidewall 143 connects with described apopore 112.Magnetic impeller 43 is rotated the heat-conducting fluid in the second inner chamber 142 better at discharge apopore 112 under motor 41 drives.

Further, please refer to Fig. 2 to Fig. 4, described heat radiation module also comprises and to be arranged between described deflector 30 and described absorber plate 20 and cushion 50 for absorbing the bulbs of pressure that described heat-conducting fluid produces in time being heated.Particularly, cushion 50 adopts silica gel or foam to make, and have favorable elasticity, cushion 50 is folded between deflector 30 and absorber plate 20, for absorbing the bulbs of pressure that heat-conducting fluid produces in time being heated.Cushion 50 comprises the matrix 51 in tabular and is arranged on the limited wall 52 paralleled on the relative both sides of matrix 51 and with the radiating fin 22 of absorber plate 20, these two limited wall 52 one_to_one corresponding are fastened on two relatively outermost radiating fins 22, matrix 51 offsets with the side away from body 21 of all radiating fins 22, matrix 51, adjacent two radiating fins 22 form some runners, in the heat-conducting fluid allowing heat fully be delivered in the second inner chamber 142 with body 21.Deflector 30 be provided with on the side of cushion 50 some offset with cushion 50 abut post 33, allow the matrix 51 of cushion 50 keep offseting away from the side of body 21 with radiating fin 22.

Further, described heat radiation module also comprises two joints 60 be rotatably installed in respectively on described inlet opening 111 and described apopore 112.Particularly, the outside of joint 60 offers annular groove 61 vertically, by plugging in the annular groove 61 of securing member 62 a to joint 60 in cylindrical body 11, to limit joint 60 along inlet opening 111 or apopore 112 position in the axial direction.Be arranged with sealing ring 63 outside joint 60, reveal to avoid heat-conducting fluid.

Further, please refer to Fig. 5, described inlet opening 111 is concordant with described apopore 112 to be arranged in described cylindrical body 11, described deflector 30 offers the breach 34 for being communicated with described inlet opening 111 and described second inner chamber 142.This structure is convenient to configuring pipes, compact conformation.

Further, please refer to Fig. 1, Fig. 2, described water-filled radiator also comprises the illuminating module 70 be arranged on close described first holding tank 13 of described cylindrical body 11.This illuminating module 70 luminescence when water pump 40 works, is convenient to observe this water-filled radiator.

The foregoing is only preferred embodiment of the present utility model; not in order to limit the utility model; all do within spirit of the present utility model and principle any amendment, equivalent to replace and improvement etc., all should be included within protection domain of the present utility model.

Claims

1. a water-filled radiator, it is characterized in that: the cold type comprising heat radiation module and be connected with described heat radiation module pipeline, described heat radiation module comprises mount pad, and described mount pad comprises cylindrical body and one-body moldedly in described cylindrical body, along the axis of this cylindrical body, the inner space of this cylindrical body is divided into the spaced walls of the first holding tank and the second holding tank; Described heat radiation module also comprise cover at described second holding tank away from the absorber plate on one end of described first holding tank and the deflector that is arranged in described second holding tank, the madial wall of described spaced walls, described deflector and described cylindrical body encloses formation first inner chamber, the madial wall of described deflector, described absorber plate and described cylindrical body encloses formation second inner chamber, described deflector offers the through hole for being communicated with described first inner chamber and described second inner chamber; Described heat radiation module also comprises the water pump be arranged in described spaced walls, and described water pump comprises the motor be contained in described first holding tank, be fixed in described first inner chamber and the drive-connecting shaft arranged with described motors and being contained in described first inner chamber and the magnetic impeller be articulated on described drive-connecting shaft; Described cylindrical body offers the inlet opening with described second intracavity inter-connection, described cylindrical body offers the apopore with described first intracavity inter-connection; Be filled with heat-conducting fluid in described second holding tank, enter described first inner chamber by described through hole after described heat-conducting fluid enters described second inner chamber by described inlet opening when described motor drives described magnetic impeller to rotate and flowed out by described apopore.

2. water-filled radiator as claimed in claim 1, it is characterized in that: described magnetic impeller comprises rounded substrate, circumferentially be distributed in described substrate towards the some blades on the side of described deflector, in first annular wall extended to form along the axis of described cylindrical body near its axle center place of described substrate and in the outer rim of described substrate along the second annular wall that the axis of described cylindrical body extends to form, described first annular wall is set in the inner side stretching into described motor on described drive-connecting shaft and along the axis of described cylindrical body, described second annular wall ring is located at the outside of described motor, often be formed with the first flow flowed towards the direction away from the axle center of described substrate for described heat-conducting fluid between adjacent two described blades, described spaced walls and described magnetic impeller are separately and form the second runner flowed around the inner and outer of described motor for described heat-conducting fluid.

3. water-filled radiator as claimed in claim 2, is characterized in that: the position between often adjacent two described blades of described substrate offers the via hole for being communicated with described first flow and described second runner.

4. water-filled radiator as claimed in claim 1, is characterized in that: described through hole is opened on the position corresponding to described drive-connecting shaft of described deflector.

5. water-filled radiator as claimed in claim 4, is characterized in that: being provided with on the side of described absorber plate for guiding described heat-conducting fluid to flow to the guiding wall of described through hole by described second inner chamber of described deflector.

6. water-filled radiator as claimed in claim 4, is characterized in that: be provided with support arm in described through hole, and wherein one end of described drive-connecting shaft is fixed in described spaced walls that other one end of this drive-connecting shaft is fixed on described support arm.

7. the water-filled radiator as described in any one of claim 1 to 6, is characterized in that: described second inner chamber is provided with the involute sidewall suitable with the outline of described magnetic impeller, and this involute sidewall connects with described apopore.

8. the water-filled radiator as described in any one of claim 1 to 6, is characterized in that: described heat radiation module also comprises and to be arranged between described deflector and described absorber plate and cushion for absorbing the bulbs of pressure that described heat-conducting fluid produces in time being heated.

9. the water-filled radiator as described in any one of claim 1 to 6, is characterized in that: described heat radiation module also comprises two joints be rotatably installed in respectively on described inlet opening and described apopore.

10. water-filled radiator as claimed in claim 9, is characterized in that: described inlet opening is concordant with described apopore to be arranged in described cylindrical body, described deflector offers the breach for being communicated with described inlet opening and described second inner chamber.