CN205003610U - Display card liquid cooling ware of control by temperature change induction type - Google Patents

Abstract

The utility model provides a temperature control induction type graphics card water cooling radiator, comprising: a water pump, a heat dissipation bottom plate, a water pipe, a water cooling circulation joint, a fin module, a temperature control switch, a heat pipe and a fan; On the bottom plate, the heat dissipation bottom plate is in contact with the GPU of the graphics card, and the water pump is connected to the water cooling cycle joint through the water pipe; the temperature control switch is in contact with the heat dissipation bottom plate and connected to the water pump; The fin module is arranged around the water pipe; the heat dissipation bottom plate is connected to the fin module through the heat pipe, and the fan is arranged above the fin module. In the utility model, the water pump is placed inside the water-cooled radiator of the graphics card, and the heat pipe and the water pipe are connected with the same group of fin modules. When the temperature control switch is triggered, the heat pipe and the water pipe transfer heat to the air at the same time, greatly improving the Heat dissipation efficiency; and can automatically control the start and stop of the water pump, prolonging its service life.

Description

A temperature-controlled induction-type graphics card water-cooled radiator

technical field

The utility model relates to a graphics card water-cooling radiator, in particular to a temperature-controlled induction type graphics card water-cooling radiator.

Background technique

Most of the traditional graphics card water-cooled radiators use air-cooled technology, which has low heat dissipation efficiency, high noise, and easy to cause dust to accumulate in the radiator, or some high-end graphics cards use water-cooled radiators, but this kind of water-cooled radiator requires additional external The water-cooling system and water drain take up a lot of space and are connected by water pipes externally, which makes installation and movement inconvenient.

Contents of the invention

The technical problem to be solved by the utility model is to provide a graphics card water-cooled radiator that can improve heat dissipation efficiency, reduce noise, reduce occupied space, and prolong service life.

In this regard, the utility model provides a temperature-controlled induction-type graphics card water-cooled radiator, including: a water pump, a heat dissipation bottom plate, a water pipe, a water-cooled circulation joint, a fin module, a temperature control switch, a heat pipe and a fan; On the heat dissipation bottom plate, the heat dissipation bottom plate is in contact with the GPU of the graphics card, and the water pump is connected to the water cooling cycle joint through the water pipe; the temperature control switch is in contact with the heat dissipation bottom plate, and is connected to the water pump The fin module is arranged around the water pipe; the heat dissipation bottom plate is connected to the fin module through the heat pipe, and the fan is arranged above the fin module.

A further improvement of the utility model is that the water pump is arranged between the heat dissipation bottom plate and the fin module.

A further improvement of the utility model is that the water pipe is nestedly connected with the fin module.

A further improvement of the utility model is that the number of the water pipes is two, and the water pump is connected to the water-cooling circulation joint through two water pipes respectively.

A further improvement of the utility model is that the heat dissipation bottom plate is a copper plate.

A further improvement of the utility model lies in that the number of the fans is at least two.

A further improvement of the utility model is that the at least two fans are arranged side by side and evenly above the fin module.

A further improvement of the utility model is that the number of the heat pipes is at least two.

A further improvement of the utility model is that the at least two heat pipes are arranged side by side and parallel under the fan.

A further improvement of the utility model is that the water pump is arranged on the heat dissipation bottom plate through a card seat.

Compared with the prior art, the utility model has the beneficial effects of: including a water cooling system composed of a water pump, a water pipe, a temperature control switch and a fin module, and including at least one fan, a fin module and a heat pipe The air-cooling system can place the water pump in the water-cooling system inside the water-cooling radiator of the graphics card, and the heat pipe and water pipe are connected to the same set of fin modules. When the temperature is too high, it can be automatically activated by the temperature control switch The water pump enables the heat pipe and the water pipe to transfer heat to the air at the same time, reasonably integrates the air cooling system and the water cooling system, greatly improves the efficiency of the graphics card water cooling radiator, and can also reduce the speed of the fan to It achieves the effect of reducing noise, takes up less space, and is easy to install and move; when the temperature drops below the valve temperature of the temperature control switch, the temperature control switch is automatically disconnected, and the water pump is also automatically disconnected, and the water cooling system Stop working, thereby prolonging its service life and reducing power consumption.

Description of drawings

Fig. 1 is the overall structural representation of a kind of embodiment of the utility model;

Fig. 2 is a schematic diagram of the longitudinal structure of an embodiment of the utility model;

Fig. 3 is a schematic diagram of the lateral structure of an embodiment of the utility model;

Fig. 4 is a schematic diagram of the lateral structure of a water cooling system according to an embodiment of the present invention;

Fig. 5 is a schematic longitudinal structure diagram of a water cooling system according to an embodiment of the present invention.

detailed description

Below in conjunction with accompanying drawing, preferred embodiment of the present utility model is described in further detail.

As shown in Figures 1 to 5, this example provides a temperature-controlled induction-type graphics card water-cooled radiator, including: water pump 1, heat dissipation bottom plate 2, water pipe 3, water-cooling circulation joint 4, fin module 5, temperature control switch 9. Heat pipe 6 and fan 7; the water pump 1 is arranged on the heat dissipation bottom plate 2, the heat dissipation bottom plate 2 is in contact with the GPU of the graphics card, and the water pump 1 is connected to the water cooling circulation joint 4 through the water pipe 3 The temperature control switch 9 is in contact with the heat dissipation bottom plate 2 and connected with the water pump 1; the fin module 5 is arranged around the water pipe 3; the heat dissipation bottom plate 2 passes through the heat pipe 6 Connected to the fin module 5 , the fan 7 is arranged above the fin module 5 .

The fin module 5 described in this example is a heat dissipation fin module, the heat pipe is an air-cooled heat pipe, and the heat dissipation bottom plate 2 is in contact with the GPU of the graphics card; as shown in Figure 2, the water pump 1 is preferably arranged at the between the heat dissipation bottom plate 2 and the fin module 5; as shown in Figure 3, the water pipe 3 is preferably nested and connected with the fin module 5; as shown in Figure 4, the number of the water pipe 3 is two The water pump 1 is connected to the water-cooling circulation joint 4 through two water pipes 3 to facilitate the circulation of the cooling liquid. The cooling liquid is preferably a high-resistance cooling liquid; the heat dissipation bottom plate 2 is preferably a copper plate.

As shown in Figure 2 and Figure 3, the number of fans 7 described in this example is at least two, and the at least two fans 7 are evenly arranged side by side above the fin module 5; the number of heat pipes 6 is At least two, the at least two heat pipes 6 are arranged side by side and parallel under the fan 7; as shown in FIG. 2 and FIG.

This example includes a water cooling system composed of a water pump 1, a water pipe 3, a temperature control switch 9 and a fin module 5, and an air cooling system composed of at least one fan 7, a fin module 5 and a heat pipe 6, which can The water pump 1 in the water cooling system is placed inside the water cooling radiator of the graphics card, the heat pipe 6 and the water pipe 3 are connected to the same set of fin modules 5, when the temperature is too high, the temperature control switch 9 can automatically start the The water pump 1 described above makes the heat pipe 6 and the water pipe 3 transfer heat to the air at the same time, reasonably integrates the air-cooling system and the water-cooling system, greatly improves the efficiency of the graphics card water-cooling radiator, and can also reduce the fan 7 speed to achieve the effect of reducing noise, and takes up less space, and is easy to install and move; when the temperature drops below the valve temperature of the temperature control switch 9, the temperature control switch 9 is automatically disconnected, and the water pump 1 is also Automatic disconnection, the water cooling system stops working, which can prolong its service life and reduce power consumption.

The temperature control switch 9 described in this example is in contact with the heat dissipation base plate 2 (copper plate), and the heat dissipation base plate 2 is in contact with the GPU of the graphics card. The power line of the temperature control switch 9 is connected in series with the power line of the water pump 1. When the temperature control switch 9 is turned on After that, the water pump 1 starts; when the temperature control switch 9 is turned off, the water pump 1 is turned off. When the GPU load is large and the temperature is high, the heat of the GPU is transmitted to the temperature control switch 9 through the heat dissipation base plate 2, and when the temperature control switch 9 senses a certain temperature, such as when the temperature reaches the range of 40°~75° , the temperature control switch 9 is turned on, which automatically triggers the start of the water pump 1. At this time, the air cooling system and the water cooling system work at the same time; the conduction valve of the temperature control switch 9 can preferably be 60°. When the GPU load is small, the temperature of the GPU is low, and the heat transferred from the GPU to the temperature control switch 9 is relatively small, the temperature control switch 9 is automatically disconnected, the water pump 1 is also automatically disconnected, and the water cooling system stops working.

The principle of the air cooling system described in this example is: the heat of the graphics card chip is transferred to the heat pipe 6 through the copper plate in contact with the chip, and then transferred to the fin module 5 through the heat pipe 6 in contact with the copper plate, and then driven by the fan 7 The air flows to transfer heat to the air; the principle of the water cooling system in this example is: when the temperature control switch 9 is turned on, the water pump 1 is automatically triggered to start, so that the heat of the graphics card chip is transferred to the On the coolant of the water pump 1, the coolant, under the action of the water pump 1, transfers heat to the fin module 5 through the water pipe 3, and then drives the air flow through the fan 7 to transfer the heat to the air; when the temperature drops to a low When the valve temperature of the temperature control switch 9 is reached, the temperature control switch 9 is automatically disconnected, the water pump 1 is also automatically disconnected, and the water cooling system stops working, thereby prolonging its service life and reducing power consumption.

The specific implementations described above are preferred implementations of the present utility model, and are not intended to limit the specific implementation scope of the present utility model. The scope of the present utility model includes but is not limited to this specific implementation. , The equivalent changes made by the structure are all within the protection scope of the present utility model.

Claims (10)

1. A temperature-controlled induction-type graphics card water-cooled radiator, characterized in that it comprises: a water pump, a heat dissipation base plate, a water pipe, a water-cooled circulation joint, a fin module, a temperature control switch, a heat pipe and a fan; the water pump is arranged on the The heat dissipation bottom plate is in contact with the GPU of the graphics card, and the water pump is connected to the water cooling cycle joint through the water pipe; the temperature control switch is in contact with the heat dissipation bottom plate, and is connected to the water pump. connection; the fin module is arranged around the water pipe; the heat dissipation bottom plate is connected to the fin module through the heat pipe, and the fan is arranged above the fin module. 2 . The temperature control induction type graphics card water cooling radiator according to claim 1 , wherein the water pump is arranged between the heat dissipation base plate and the fin module. 3 . 3 . The temperature-controlled induction-type graphics card water-cooling radiator according to claim 1 , wherein the water pipe is nestedly connected to the fin module. 4 . 4. The temperature-controlled induction-type graphics card water-cooling radiator according to claim 1, wherein there are two water pipes, and the water pump is connected to the water-cooling circulation joint through two water pipes respectively. 5. The temperature-controlled induction-type graphics card water-cooling radiator according to any one of claims 1 to 4, wherein the heat dissipation bottom plate is a copper plate. 6. The temperature-controlled induction-type graphics card water-cooling radiator according to any one of claims 1 to 4, characterized in that the number of the fans is at least two. 7 . The temperature-controlled induction-type graphics card water-cooling radiator according to claim 6 , wherein the at least two fans are arranged side by side and uniformly above the fin module. 7 . 8. The temperature-controlled induction-type graphics card water-cooling radiator according to any one of claims 1 to 4, wherein the number of the heat pipes is at least two. 9. The temperature-controlled induction-type graphics card water-cooling radiator according to claim 8, wherein the at least two heat pipes are arranged side by side and parallel under the fan. 10. The temperature-controlled induction-type graphics card water-cooling radiator according to any one of claims 1 to 4, wherein the water pump is arranged on the heat-dissipating bottom plate through a deck.