CN218763253U - Illumination heat energy utilization system - Google Patents

Abstract

The utility model relates to an illumination heat utilization system, include: the LED lamp comprises a shell, LED lamp beads and a lamp panel, wherein the LED is coupled on the lamp panel, the lamp panel is arranged in the shell, and the shell corresponding to the light emitting surface of the LED lamp beads is made of a light-transmitting material; the active heat dissipation fluid cavity is attached to the non-light emitting surfaces of the LED lamps; the heat dissipation fluid pool inputs fluid to the active heat dissipation fluid cavity through a heat dissipation fluid pump; one end of the heat exchange equipment is connected with the tail ends of the active heat dissipation fluid cavities communicated with the active heat dissipation fluid cavities, and the other end of the heat exchange equipment is connected with the heat dissipation fluid pool to form heat dissipation fluid circulation; and the heat conduction terminal is connected with the heat exchange equipment through a heat conduction pipe and returns to the heat exchange equipment through a circulating pump to form a heat conduction cycle.

Description

Illumination heat energy utilization system

Technical Field

The utility model relates to a heat utilization technical field especially relates to an illumination heat utilization system.

Background

The LED illuminating lamp can produce a large amount of heat energy when using, and current LED illuminating lamp all is the natural heat dissipation, dispels the heat promptly passively, and not only the heat dissipation is slow, leads to LED illuminating lamp temperature height, influences LED life, has restricted LED's power, and energy utilization efficiency is low moreover.

SUMMERY OF THE UTILITY MODEL

In view of the above circumstances, it is necessary to provide an illumination heat energy utilization system that improves energy utilization efficiency.

In order to solve the technical problem, the utility model discloses a technical scheme be: an illumination thermal energy utilization system comprising:

the LED lamp comprises a shell, LED lamp beads and a lamp panel, wherein the LED is coupled on the lamp panel, the lamp panel is arranged in the shell, and the shell corresponding to the light emitting surface of the LED lamp beads is made of a light-transmitting material;

the active heat dissipation fluid cavity is attached to the non-light emitting surfaces of the LED lamps;

the heat dissipation fluid pool inputs fluid to the active heat dissipation fluid cavity through a heat dissipation fluid pump;

one end of the heat exchange equipment is connected with the tail ends of the active heat dissipation fluid cavities communicated with the active heat dissipation fluid cavities, and the other end of the heat exchange equipment is connected with the heat dissipation fluid pool to form heat dissipation fluid circulation;

and the heat conduction terminal is connected with the heat exchange equipment through a heat conduction pipe and returns to the heat exchange equipment through a circulating pump to form a heat conduction cycle.

Furthermore, the active heat dissipation fluid cavity attached to the LED lamp is made of metal, alloy or heat-conducting plastic.

Further, the heat-conduction terminal is connected with a temperature control mechanism, the temperature control mechanism comprises an adjustable valve, a cold water pipe, a mixed flow device, a heat compensation device and a temperature sensor, the adjustable valve controls the flow rate of the cold water pipe, the cold water pipe is connected with the heat conduction pipe through the mixer, the heat compensation device is connected with the heat conduction pipe or the mixed flow device, the outlet of the mixer is connected with the heat-conduction terminal, and the temperature sensor measures the temperature of the heat-conduction terminal.

Further, the heat conduction terminal is also connected with a buzzer.

Furthermore, a booster pump is arranged between the heat conduction terminal and the temperature control mechanism.

Furthermore, the heat conduction terminal is a heating pipeline, the heating pipeline is connected with the circulating pump, and a water outlet of the circulating pump is connected with the heat conduction pipe to form circulation.

Furthermore, the temperature rising pipeline is configured in the wall body of the plant greenhouse and/or the root soil of the plant.

Furthermore, a heat-insulating layer is arranged above the temperature-rising pipeline in the root soil of the plant.

Further, the heating pipeline is arranged in the wall body of the farm and/or underground soil.

Furthermore, the outer layer of the wall body of the farm is provided with a heat preservation layer.

The beneficial effects of the utility model reside in that: the LED lamp actively takes away the generated heat through the active heat dissipation fluid cavity. The heat dissipation fluid pool enables fluid to actively flow to the active heat dissipation fluid cavity through the heat dissipation fluid pump, the heat dissipation speed is accelerated, and the fluid flows back to the heat dissipation fluid pool through the heat exchange equipment to form a heat dissipation cycle. Meanwhile, the heat conduction terminal also forms heat conduction circulation through the circulating pump, the two circulations are not interfered and run independently, so that liquid in the heat dissipation circulation can adopt liquid with excellent heat dissipation performance, and the heat dissipation effect and the exchange efficiency of the heat exchange equipment are improved.

Drawings

Fig. 1 is a schematic structural diagram of an illumination heat energy utilization system according to an embodiment of the present invention;

fig. 2 is a schematic view of an illumination heat energy utilization system according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a temperature control mechanism of an illumination heat energy utilization system according to an embodiment of the present invention.

Description of reference numerals:

100. an LED lamp; 200. an active heat dissipation fluid cavity; 300. a heat sink fluid pool;

400. a heat sink fluid pump; 500. a heat exchange device; 600. a temperature control mechanism; 610. an adjustable valve;

620. a cold water pipe; 630. a flow mixer; 640. a temperature sensor; 650. a buzzer;

660. a thermal compensation device; 670. a hot water pipe; 700. a booster pump; 800. a thermally conductive terminal;

900. and a circulating pump.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the following description, with reference to the accompanying drawings and embodiments, will explain the present invention in further detail. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

Referring to fig. 1 to 3, an illumination heat energy utilization system includes:

the LED lamp 100 comprises a shell, LED lamp beads and a lamp panel, wherein the LEDs are coupled on the lamp panel, the lamp panel is arranged in the shell, and the shell corresponding to the light emitting surfaces of the LED lamp beads is made of a light-transmitting material;

the active heat dissipation fluid cavity 200 is attached to the non-light emitting surfaces of the LED lamps 100;

a heat sink fluid pool 300, wherein the heat sink fluid pool 300 inputs fluid to the active heat sink fluid cavity 200 through a heat sink fluid pump 400;

a heat exchange device 500 having one end connected to the ends of the active heat dissipation fluid chambers 200 communicated with the active heat dissipation fluid chambers 200 and the other end connected to the heat dissipation fluid pool 300 to form a heat dissipation fluid circulation;

the heat transfer terminal 800 is connected to the heat exchange device 500 through a heat pipe and returns to the heat exchange device 500 through the circulation pump 900 to form a heat transfer cycle.

The LED lamp 100 actively carries away the generated heat through the active heat dissipating fluid chamber 200. The heat sink fluid pool 300 actively flows to the active heat sink fluid cavity 200 through the heat sink fluid pump 400 to accelerate the heat dissipation speed, and then flows back to the heat sink fluid pool 300 through the heat exchange device 500 to form a heat dissipation cycle. Meanwhile, the heat conduction terminal 800 also forms a heat conduction cycle through the circulation pump 900, the two cycles do not interfere with each other and run independently, so that the liquid in the heat dissipation cycle can adopt the liquid with excellent heat dissipation performance, and the heat dissipation effect and the exchange efficiency of the heat exchange device 500 are improved.

Preferably, the fluid in the heat dissipation cycle is heat transfer oil or heat transfer liquid, and the fluid in the heat transfer cycle is water.

Referring to fig. 1, preferably, the active heat dissipation fluid chamber 200 attached to the LED lamp 100 is made of a material with good thermal conductivity. In particular, the active heat dissipation fluid chamber 200 attached to the LED lamp 100 is made of metal, alloy or thermal conductive plastic. The bonding between the LED lamp 100 and the active heat dissipation fluid chamber 200 can be achieved by gluing, welding, fastening, screwing, and the like. Preferably, the LED lamp 100 and the housing of the active heat dissipation fluid chamber 200 are surface-bonded, that is, both are planar surfaces or both are arc surfaces.

Referring to fig. 2 and 3, the heat conduction terminal 800 is connected to a temperature control mechanism 600, the temperature control mechanism 600 includes an adjustable valve 610, a cold water pipe 620, a mixer 630, a thermal compensation device 660, and a temperature sensor 640, the adjustable valve 610 controls the flow rate of the cold water pipe 620, the cold water pipe 620 is connected to the heat conduction pipe through the mixer, the thermal compensation device 660 is connected to the heat conduction pipe or the mixer 630, the outlet of the mixer is connected to the heat conduction terminal 800, and the temperature sensor 640 measures the temperature of the heat conduction terminal 800. The temperature control mechanism 600 is provided to ensure the temperature of the heat-conducting terminal 800. When the temperature sensor 640 detects that the temperature is lower than the required temperature, the temperature is raised through the thermal compensation device 660; when the temperature sensor 640 detects a temperature higher than a desired temperature, the temperature is lowered by the refrigerator, the cold water pipe 620 and the flow mixer 630. Simply, the thermal compensation device 660 is an electric heater or a water heater, and hot water in the heat conduction pipe can be directly introduced into the water heater for heating according to needs, and hot water in the water heater can also be introduced into the mixer 630 through the hot water pipe 670 for mixing.

Referring to fig. 3, the heat conduction terminal 800 is further connected to a buzzer 650. The buzzer 650 is arranged, and can give an alarm in time when the temperature is too high or too low.

Referring to fig. 3, a booster pump 700 is further disposed between the thermal conduction terminal 800 and the temperature control mechanism 600. The booster pump 700 is provided to ensure fluid pressure at the thermally conductive terminal 800.

Preferably, the heat conduction terminal 800 is a warming pipeline, the warming pipeline is connected to the circulation pump 900, and a water outlet of the circulation pump 900 is connected to the heat conduction pipe to form circulation. The provision of the circulation pump 900 circulates the water flow within the heat-conducting terminal 800, thereby avoiding waste of water resources and reducing heat loss.

Preferably, the warming pipeline is configured in the wall body of the plant greenhouse and/or the root soil of the plant. The heating pipeline is arranged in the wall body of the plant greenhouse, so that the overall temperature in the plant greenhouse is increased, and the suitable environment for plant growth is obtained. The heating pipe is arranged in the root soil of the plant, so that the development of the plant root system can be promoted. Preferably, an insulating layer is arranged above the heating pipeline in the root soil of the plant. The soil can be simply covered with non-woven fabrics, films, turf and the like to form a heat-insulating layer.

Or the heating pipeline is arranged in the wall body of the farm and/or underground soil. The heating pipeline can also be used for animal breeding heating to keep the animals from passing the winter. In particular, the outer layer of the wall body of the farm is provided with a heat preservation layer. Preferably, the heat insulation layer is polyurethane foam or extruded sheet.

To sum up, in the lighting heat energy utilization system provided by the utility model, the LED lamp actively drives away the generated heat through the active heat dissipation fluid cavity; and because encapsulating, the heat that produces can better transmit the fluid in the initiative heat dissipation fluid cavity, reduces the heat loss. The heat dissipation fluid pool enables the fluid to actively flow to the active heat dissipation fluid cavity through the heat dissipation fluid pump, and then flows back to the heat dissipation fluid pool through the heat exchange equipment to form circulation. The utility model discloses a system is utilized to illumination heat energy can be applicable to plant greenhouse and plant well, for the growth of animals and plants provides the advantage, simultaneously energy-concerving and environment-protective.

The above description is only a preferred embodiment of the present invention, and the present invention is not limited to the above description in any form, and although the present invention has been disclosed with reference to the preferred embodiment, it is not limited to the present invention, and any skilled person in the art can make modifications or changes equivalent to the equivalent embodiment of the above embodiments without departing from the scope of the present invention.

Claims (10)

1. An illumination thermal energy utilization system, comprising:

the LED lamp comprises a shell, LED lamp beads and a lamp panel, wherein the LED is coupled on the lamp panel, the lamp panel is arranged in the shell, and the shell corresponding to the light emitting surface of the LED lamp beads is made of a light-transmitting material;

the active heat dissipation fluid cavity is attached to the non-light emitting surfaces of the LED lamps;

a heat sink fluid reservoir that inputs fluid to the active heat sink fluid chamber through a heat sink fluid pump;

one end of the heat exchange equipment is connected with the tail ends of the active heat dissipation fluid cavities communicated with the active heat dissipation fluid cavities, and the other end of the heat exchange equipment is connected with the heat dissipation fluid pool to form heat dissipation fluid circulation;

and the heat conduction terminal is connected with the heat exchange equipment through a heat conduction pipe and returns to the heat exchange equipment through a circulating pump to form a heat conduction cycle.

2. The illumination heat energy utilization system of claim 1, wherein the active heat dissipation fluid cavity attached to the LED lamp is made of metal, alloy or thermally conductive plastic.

3. The illumination heat energy utilization system according to claim 1, wherein the heat conduction terminal is connected with a temperature control mechanism, the temperature control mechanism comprises an adjustable valve, a cold water pipe, a mixer, a heat compensation device and a temperature sensor, the adjustable valve controls the flow rate of the cold water pipe, the cold water pipe is connected with the heat conduction pipe through the mixer, the heat compensation device is connected with the heat conduction pipe or the mixer, the outlet of the mixer is connected with the heat conduction terminal, and the temperature sensor measures the temperature of the heat conduction terminal.

4. An illumination and heat energy utilization system according to claim 3, wherein a buzzer is further connected to the heat conduction terminal.

5. An illumination heat energy utilization system according to claim 3, wherein a booster pump is further provided between the heat conduction terminal and the temperature control mechanism.

6. An illumination heat energy utilization system according to claim 1, wherein the heat conduction terminal is a temperature rising pipe, the temperature rising pipe is connected with the circulating pump, and a water outlet of the circulating pump is connected with the heat conduction pipe to form a circulation.

7. An illumination and heat energy utilization system according to claim 6, wherein the warming pipeline is disposed in the wall of the plant greenhouse and/or in the soil of the roots of the plants.

8. An illumination and heat energy utilization system according to claim 7, wherein an insulating layer is provided above the warming pipe in the root soil of the plant.

9. An illumination and heat energy utilization system according to claim 6, wherein the warming pipe is disposed in a wall of a farm and/or in underground soil.

10. An illumination and heat energy utilization system according to claim 9, wherein the outer layer of the wall of the farm is provided with an insulating layer.

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