CN114484580A - Copper capillary induced air type radiator - Google Patents

Abstract

The invention discloses a copper capillary induced-draft radiator, which comprises a base body, a capillary radiating pipe group, a water collector, a water distributor and an air circulation assembly, wherein the capillary radiating pipe group is arranged on the base body; the water collector and the water separator are arranged on the base body, wherein the water separator is positioned at the upper end of the water collector; the capillary tube radiating pipe group is arranged between the water collector and the water distributor; the air circulation assembly is arranged on the base body and drives cold air to be radiated and discharged through the capillary tube radiating pipe group. The invention has reasonable design and ingenious structure, is used for heating, adopts a plurality of capillary radiating tubes as radiating elements, and has good radiating effect, large radiating area and good heating effect; the energy waste and the uneven phenomenon problems of cold and hot appearance caused by central heating can be overcome, the domestic radiator has the advantage of energy conservation, the emission of carbon dioxide is indirectly reduced, and the future prospect is considerable.

Description

A copper capillary induced air radiator

technical field

The invention relates to a heat dissipation device, in particular to a copper capillary induced air radiator.

Background technique

With the improvement of people's daily life, heating in winter is an indispensable need, especially in northern regions. The reduction of carbon dioxide emissions is imminent, and the energy saving of heating in winter is an inevitable development trend.

SUMMARY OF THE INVENTION

Therefore, in order to solve the problem of reducing the waste of resources and rationally using energy, the present invention provides a heat dissipation device with reasonable design and ingenious structure for heating. The present invention adopts several capillary heat dissipation pipes as heat dissipation elements, which has good heat dissipation effect and heat dissipation. It has a large area and good heating effect; it can not only overcome the energy waste caused by central heating and the phenomenon of uneven heating and cooling, but also has the advantage of being more energy-saving than traditional household radiators, indirectly reducing carbon dioxide emissions, and the future is promising.

The present invention is realized by constructing a copper capillary induced air radiator, which includes a base body, a capillary radiating pipe group, a water collector, a water separator and an air circulation assembly;

The water collector and the water separator are installed on the base body, wherein the water separator is located at the upper end of the water collector;

The capillary radiating pipe group is installed between the water collector and the water separator;

The capillary radiating pipe group is composed of several capillary radiating pipes arranged side by side, and the upper and lower ends of the capillary radiating pipes are respectively connected with the water separator and the water collector;

One side of the water separator is connected with the heat source water pipe assembly, and the water collector is connected with the external return water pipe assembly;

The air circulation assembly is installed on the base body, and drives the cold air to dissipate heat and discharge through the capillary radiating tube group.

Preferably, the air circulation assembly includes an air inlet opened in the base and located below the water collector, an air duct located in the base and communicated with the air inlet, and a cross-flow fan installed in the base to circulate the air. There are several air outlets located behind the capillary heat pipe group.

Preferably, the capillary heat dissipation pipe group includes a row of capillary heat dissipation pipes that are closely arranged, and are closed by copper plates on the left and right sides.

Preferably, a filter screen is installed at the air inlet, and the purpose of this setting is to prevent foreign matter from entering the air duct and damage the cross-flow fan or the capillary cooling pipe.

Preferably, several of the air outlets are located behind the capillary radiating pipe group and their heights increase sequentially. The purpose of this setting is to allow the cold air to enter the capillary radiating pipe group more evenly, so that the cooling effect of the cold air is better, and the heat exchanged air Divide more evenly into the room.

Preferably, the water separator is connected to the water storage end of the hot water storage tank through a pipeline with a circulating water pump, and the water collector is connected to the return water end of the hot water storage tank through a pipeline with a valve; The hot water storage tank provides a hot water source for the water separator, and circulates the heat-exchanged water into the hot water storage tank.

Preferably, the hot water storage tank is connected with a gas furnace for heating to provide a heat source for the hot water storage tank. If the water temperature provided by the gas furnace exceeds the upper limit temperature of the set water temperature range, the gas furnace stops running; When the lower temperature limit of the temperature range is set, by opening the solenoid valve and starting the circulating water pump, the water temperature in the hot water storage tank is reheated until the upper temperature limit value.

The present invention has the following advantages:

The invention has reasonable design and ingenious structure, and is a heat dissipation device for heating. The invention adopts several capillary heat dissipation pipes as heat dissipation elements, which has good heat dissipation effect, large heat dissipation area and good heating effect; it can not only overcome the energy caused by central heating It also has the advantage of being more energy-saving than traditional household radiators, indirectly reducing carbon dioxide emissions, and has a promising future.

The invention adopts a copper capillary network for home heating, and the heat source is provided by natural gas. Since the heating water system is closed, the water can be treated with pure water, thereby reducing the effect of blockage on the pipeline. The several capillary radiating pipes of the present invention are connected in series, which overcomes the difference in branch flow caused by different impedances in parallel, which affects the heating effect.

At the same time, the base body of the present invention is provided with 3-4 air inlets, a cross-flow fan is placed inside, and the front end of the base body is provided with an air outlet. The generated hot water enters the water distribution main pipe, is distributed to each branch pipe, enters the capillary network, and finally enters the water collection main pipe. In this process, on the one hand, the capillary conducts radiation heat dissipation, and on the other hand, driven by the cross-flow fan, the indoor circulating air and the capillary conduct convective heat exchange. In the whole process, there are both radiative heat exchange and convection heat exchange, which increases the Exchange heat.

Description of drawings

1 is a schematic perspective view of the invention;

Fig. 2 is the installation schematic diagram of the present invention;

Fig. 3 is the sectional schematic diagram of A-A in Fig. 2;

Fig. 4 is the top view schematic diagram of the capillary radiating pipe group of the present invention;

Fig. 5 is the sectional schematic diagram of B-B in Fig. 2;

Figure 6 is a system block diagram of the heating cycle of the present invention.

Detailed ways

The present invention will be described in detail below with reference to Fig. 1 to Fig. 6, and the technical solutions in the embodiments of the present invention will be described clearly and completely. Obviously, the described embodiments are only a part of the embodiments of the present invention, rather than all the implementations. example. Based on the embodiments of the present invention, all other embodiments obtained by those of ordinary skill in the art without creative efforts shall fall within the protection scope of the present invention.

The present invention provides a copper capillary induced draft radiator 606 through improvement, including a base body 100, a capillary radiating tube group 400, a water collector 200, a water separator 300 and an air circulation assembly;

The water collector 200 and the water separator 300 are installed on the base body 100, wherein the water separator 300 is located at the upper end of the water collector 200;

The capillary heat dissipation pipe group 400 is installed between the water collector 200 and the water separator 300;

The capillary heat dissipation pipe group 400 is composed of several capillary heat dissipation pipes 401 arranged side by side, and the upper and lower ends of the capillary heat dissipation pipes 401 are respectively connected to the water separator 300 and the water collector 200;

One side of the water separator 300 is connected to the heat source water pipe assembly, and the water collector 200 is connected to an external return water pipe assembly;

The air circulation assembly is installed on the base body, and drives the cold air to dissipate heat and discharge through the capillary heat dissipation pipe group 400 .

In this embodiment, the air circulation assembly includes an air inlet 101 opened on the base body 100 and located below the water collector 200 , an air duct 500 located in the base body 100 and communicated with the air inlet 101 , and installed in the base body 100 to allow For the cross-flow fan 105 for air circulation, the air duct 500 is provided with several air outlets 501 located behind the capillary heat dissipation pipe group 400 .

As shown in FIG. 4 , in this embodiment, the capillary heat dissipation pipe group includes 3-4 rows of capillary heat dissipation pipes that are closely arranged, and are closed by copper plates on the left and right sides.

In this embodiment, a filter screen 102 is installed on the air inlet 101 .

In this embodiment, several of the air outlets 501 are located behind the capillary heat dissipation pipe group 400 and their heights increase sequentially.

In this embodiment, the water distributor 300 is connected to the water storage end of the hot water storage tank 602 through a pipeline with a circulating water pump 605 , and the water collector 200 is connected to the hot water storage tank through a pipeline with a valve 607 The return end of 602 is connected.

In this embodiment, the hot water storage tank 602 is connected to a gas furnace 601 for heating. If the water temperature provided by the gas furnace exceeds the upper limit temperature of the set water temperature range, the gas furnace 601 stops running; When the temperature is at the lower limit of the temperature range, the water temperature in the hot water storage tank 602 is reheated to the upper temperature limit by opening the solenoid valve 603 and starting the heating circulating water pump 604 .

The working process of the present invention is as follows:

The hot water in the hot water storage tank 602 is heated by the gas furnace 601, and the heated hot water enters the water separator 300 of the copper capillary induced draft radiator 606 through the circulating water pump 605, and the hot water passes through the water separator 300. It is divided into several capillary heat dissipation pipes 401 of the capillary heat dissipation pipe group 400, and the heat is dissipated through the capillary heat dissipation pipe 401. When the capillary heat dissipation pipe 401 is dissipating heat, the cold air enters the air duct from the air inlet 101 through the filter screen 102, and the cross-flow fan Under the action of 105, the air in the air duct is accelerated to be discharged from the air outlet, so that the air discharged from the air outlet increases in temperature under the heat exchange of the capillary radiating pipe 401, and enters the room to increase the indoor temperature. The heat dissipation efficiency is high and the effect is high. Obviously, the cross-flow fan 105 can drive the indoor cold air to circulate.

The above description of the disclosed embodiments enables any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be implemented in other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein, but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (7)

1. The utility model provides a copper capillary induced air formula radiator which characterized in that: the device comprises a base body (100), a capillary tube heat dissipation pipe set (400), a water collector (200), a water separator (300) and an air circulation assembly;

the water collector (200) and the water separator (300) are arranged on the base body (100), wherein the water separator (300) is positioned at the upper end of the water collector (200);

the capillary tube radiating pipe set (400) is arranged between the water collector (200) and the water distributor (300);

the capillary heat dissipation pipe set (400) is formed by arranging a plurality of capillary heat dissipation pipes (401) side by side, and the upper end and the lower end of each capillary heat dissipation pipe (401) are respectively connected with the water distributor (300) and the water collector (200);

one side of the water separator (300) is connected with a heat source water pipe assembly, and the water collector (200) is connected with an external water return pipe assembly;

the air circulation component is arranged on the base body and drives cold air to be radiated and discharged through the capillary tube radiating tube set (400).

2. The copper capillary induced-draft heat sink of claim 1, wherein: the air circulation assembly comprises an air inlet (101) arranged on the base body (100) and positioned below the water collector (200), an air duct (500) arranged in the base body (100) and communicated with the air inlet (101), and a cross-flow fan (105) arranged in the base body (100) and used for circulating air, wherein the air duct (500) is provided with a plurality of air outlets (501) positioned behind the capillary heat dissipation tube set (400).

3. The copper capillary induced-draft heat sink of claim 1, wherein: the capillary heat dissipation pipe set comprises 3-4 rows of capillary heat dissipation pipes which are closely arranged and are sealed by copper plates at the left side and the right side.

4. The copper capillary induced-draft heat sink of claim 1, wherein: and the air inlet (101) is provided with a filter screen (102).

5. The copper capillary induced-draft heat sink of claim 2, wherein: the air outlets (501) are located behind the capillary tube heat dissipation tube set (400) and the heights of the air outlets are increased in sequence.

6. The copper capillary induced-draft heat sink of claim 1, wherein: the water separator (300) is connected with the water storage end of the heat storage water tank (602) through a pipeline with a water circulating pump (605), and the water collector (200) is connected with the water return end of the heat storage water tank (602) through a pipeline with a valve (607).

7. The copper capillary induced-draft heat sink of claim 6, wherein: the heat storage water tank (602) is connected with a gas furnace (601) for supplying heat.

Images