KR101059951B1 - Lamp for plant cultivation - Google Patents

Abstract

PURPOSE: A lamp for plant cultivation is provided to increase the lifetime of the lamp by efficiently discharging heat from an LED lamp. CONSTITUTION: An LED module(50) includes a red LED with the wavelength of 660 nm and a blue LED with the wavelength of 450 nm. A heat sink(40) absorbs heat from the LED module. The heat sink is installed on the upper side of the LED module. An anion generation circuit unit(30) is formed in the inside of the upper side of the heat sink. An LED control circuit unit(20) is installed on the upper side of the anion generation circuit unit. The LED module, the heat sink, the anion generation circuit unit, and the LED control circuit unit are stacked in a housing. The housing includes a male socket(12) which receives electric energy and a plurality of slits(11) which discharges heat. A transmitting cap(70) is installed on the lower side of the housing. A protection plate(60) is formed on the lower side of the LED module.

Description

Plant growing lamps {LAMP FOR PLANT CULTIVATION}

The present invention relates to a lamp for plant cultivation, and more specifically, a red LED lamp and a blue LED lamp necessary for plant growth are properly mixed to sufficiently irradiate the amount of light while efficiently emitting heat generated when the LED is turned on, and when ozone is generated, ozone is generated. And a lamp for plant cultivation with increased anion emission.

Plants can live because of oxygen in the air and carbon compounds on the ground, both of which result from photosynthesis, which is also affected by light intensity and carbon dioxide concentration.

In other words, photosynthesis is affected by light intensity and carbon dioxide concentration. As light intensity increases, photosynthesis becomes active as the concentration of carbon dioxide increases and does not increase any more when a certain level is reached. This photosynthesis produces electrons, hydrogen ions and oxygen.

Plants breathe photosynthesis and breath at the same time, and breathe only if there is no light. Photosynthesis produces oxygen using carbon dioxide, and respiration uses oxygen to emit carbon dioxide. In the presence of light, oxygen is released in large quantities because photosynthesis produces more oxygen than carbon dioxide caused by respiration.

Therefore, in the homes and offices where indoor living is mainly, many plants are grown to reduce indoor carbon dioxide concentration and increase oxygen concentration. Among these plants, cultivated edible plants not only purify the air but also cultivated plants Some people eat it.

Therefore, in order to extend the photosynthesis time of plants by artificially controlling the amount of light irradiation and irradiation time for plant cultivation indoors, a plant cultivation apparatus using a lamp has been developed and widely used.

As one example thereof, there may be mentioned Patent No. 902071 (Method for cultivating a plant using a LED lamp and a device thereof), wherein the plant cultivation device 1 using the LED lamp is 660 nanometers as shown in FIG. The red LED (2) in the wavelength band and the blue LED (3) in the 450 nanometer wavelength band are mixed in a ratio of 5: 1, whereby the light amount ratio of the red LED to the blue LED is 5: 1.

The plant cultivation apparatus is helpful in shortening the time of plant cultivation by irradiating a light source required for plant cultivation, but the protection device from the pests that are the most problematic during plant cultivation is excluded. In other words, there is a lack of a device capable of removing viruses, bacteria and fungi that cause pests during plant cultivation, and the risk transmitted to the human body from these pests increases rapidly indoors rather than outdoors.

In addition, there is a problem in that the life of the lamp is shortened by failing to efficiently discharge the heat generated from the LED lamp.

The present invention has been invented to solve the above conventional problems, by combining a red LED having a wavelength of 660 nanometers and a blue LED having a wavelength of 450 nanometers necessary for plant growth in an appropriate ratio to promote plant growth In addition, the object of the present invention is to provide a lamp for plant cultivation that can efficiently discharge heat generated from an LED lamp to increase the life of the lamp.

Plant cultivation lamp of the present invention for achieving the above object is the LED module 50, the red LED (L1) having a wavelength of 660 nanometers and the blue LED (L2) having a wavelength of 450 nanometers is arranged; A heat sink 40 installed on an upper surface of the LED module 50 to absorb and radiate heat generated from the LED module 50; An anion generating circuit unit 30 provided inside the upper portion of the heat sink 40; An LED control circuit unit 20 provided on an upper surface of the negative ion generating circuit unit 30; The LED module 50, the heat dissipation plate 40, the negative ion generating circuit unit 30 and the LED control circuit unit 20 is stacked and embedded, a plurality of hydrogen socket 12 and the generated heat is applied to the electric energy applied A housing 10 having a slit 11 and a light emitting cap 70 for transmitting light to a lower side of the housing 10; It is achieved by consisting of.

The present invention can prevent the pests that may occur during plant cultivation by removing or preventing the growth, virus, bacteria and fungi generated during plant cultivation by anion generator, and the intermittent cycle of lighting and turning off the LED lamp Through this, it is possible to provide a plant cultivation lamp that can increase the life of the lamp by minimizing the generation of heat when the LED lamp is turned on, and efficiently discharging even if heat is generated.

In addition, it is possible to provide a plant cultivation lamp that can promote plant growth by combining an appropriate ratio of red and blue LEDs.

1 is a perspective view of a device for conventional plant cultivation,
2 is a perspective view of a plant cultivation lamp according to the present invention;
3 is a cross-sectional view taken along line AA ′ of FIG. 2;
4 is an exploded perspective view of the bottom side of the lamp for plant cultivation according to the present invention;
5 is a plane exploded perspective view of a plant cultivation lamp according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail the lamp for plant cultivation according to the present invention.

Figure 2 of the accompanying drawings is a perspective view of the plant cultivation lamp 100 according to the present invention, Figure 3 is a cross-sectional view of the AA 'of Figure 2, the plant cultivation lamp 100 of the present invention when the LED is turned on Efficiently dissipate the generated heat and radiate negative ions that do not generate ozone to remove viruses, bacteria and fungi that are concerned when growing plants. The composition of the LED module 50, the heat sink 40, The negative ion generating circuit unit 30, the LED control circuit unit 20, the protective plate 60, the housing 10 and the floodlight cap 70 is made of.

The configuration according to the present invention can be seen in more detail through an exploded perspective view, Figure 4 of the accompanying drawings is a bottom side exploded perspective view of the plant cultivation lamp according to the invention, Figure 5 is a plan view of the plant cultivation lamp according to the invention Side exploded perspective view is shown, through which the present invention will be described in detail.

LED module 50 is provided with a plurality of LEDs, a red LED (L1) having a wavelength of 660 nanometers and a blue LED (L2) having a wavelength of 450 nanometers is arranged. The LED module 50 may be made of a metal PCB (METAL Printed Circuit Board) to effectively transfer the heat generated from the LED when the LED is turned on, the LED module 50 in contact with the heat sink 40 to be described below. Heat generated in the heat-contacting heat radiation to the heat sink 40 may reduce the temperature of the LED.

The red LED L1 has a wavelength of 660 nanometers (nm) which has the greatest influence on plant photosynthesis, and can be used in various plants and homes for growing vegetables such as lettuce with artificial light.

Blue LED (L2) is reported to affect the root growth of the plant, through which can help to increase the absorption of the water supplied to the root growth of the plant.

By providing a red LED (L1) having a wavelength of 660 nanometers and a blue LED (L2) having a wavelength of 450 nanometers can promote the photosynthesis of the plant to promote growth in both the root and leaves of the plant.

In addition, the number of red LEDs L1 having a wavelength of 660 nanometers (nm) having the greatest effect in plant photosynthesis by arranging the ratio of the red LEDs L1 and blue LEDs L2 to be 3: 1, respectively. 3 times more than the number of blue LEDs (L2) having a wavelength of 450 nanometers can be induced to achieve a balanced growth.

A heat sink 40 is installed on the upper surface of the LED module 50 to absorb and radiate heat generated by the LED module 50.

The heat sink 40 may be made of a metal material having a low specific heat so as to absorb heat well and radiate the absorbed heat. The heat sink 40 is in contact with the LED module 50, and an upper part of the heat sink is divided into a grid-shaped partition. 41 is provided, by which the heat radiation fins 41 increase the contact area with air and promote heat dissipation.

An anion generating circuit part 30 is provided inside the heat dissipation plate 40, that is, inside the heat dissipation fin 41.

The negative ion generating circuit unit 30 converts the voltage into a voltage at which negative ions are generated by using electric energy applied thereto. The negative ion generating circuit unit 30 may discharge the negative ions by an electron emission method.

Representative methods of discharging negative ions include corona discharge and electron radiation. Among them, the corona discharge is connected to the discharge electrode at the (-) terminal and the opposite electrode at the (+) terminal and is applied by applying a high voltage DC voltage. It is a method of anionizing oxygen by destroying the insulation of air by discharging and colliding electrons with oxygen molecules in the air.

One of the methods of discharging negative ions is a method of discharging electrons into the air by applying a high voltage of (-) pulse to the discharge electrode, also called parus discharge. The electron emission method is characterized by electrons being radiated, colliding with oxygen molecules of the air and negatively ionizing oxygen. This electron emission method does not generate ozone because energy (voltage) that generates negative ions is smaller than that of corona discharge. There is an advantage.

Therefore, in the present invention, it can be configured to discharge the negative ions in an electron-spinning method that can generate negative ions at low voltage without generating ozone than the corona discharge method.

The upper surface of the negative ion generating circuit unit 30 is provided with an LED control circuit unit 20, wherein the heat dissipation plate 40 and the LED control circuit unit 20 is installed so as to be spaced apart by a predetermined thickness of the negative ion generating circuit unit 30. do.

The LED control circuit unit 20 controls the LED module 50 to control the alternating on and off.

Photosynthesis of plants consists of two stages: light reaction (photochemical reaction) using light energy and dark reaction (thermochemical reaction) of synthesis of carbohydrates by reducing carbon dioxide using the product of light reaction. By controlling the red LED (L1) and the blue LED (L2) of the module 50 to be turned on and off alternately, the plant is configured to achieve a light reaction and a dark reaction according to photosynthesis.

In the intermittent cycle of switching on and off, the red LED (L1) and blue LED (L2) are turned on for 400 ms and off for 200 ms, and the red and blue LEDs (L1, L2) are turned off for a certain time. It is made by having.

This intermittent cycle consumes less power than the LED is always lit, and the heat generated by the LED is significantly reduced due to the off during idle time.

On the other hand, the lower portion of the LED module 50 is provided with a protective plate 60, the protective plate 60 to prevent the human body contact with the LED module 50.

On the central side of the protective plate 60, the discharge tip 31 for discharging negative ions by the voltage applied from the negative ion generating circuit unit 30 and the safe cover 32 for protecting the outer side of the discharge tip 31 Is provided.

The discharge tip 31 may be manufactured by sintering and spraying / coating a nano-metal mixture. The metal mixture may be formed by mixing carbon, silver, nickel, manganese, potassium silicate and the like.

That is, the protection plate 60, the LED module 50, the heat dissipation plate 40, the negative ion generating circuit unit 30, and the LED control circuit unit 20 are sequentially stacked inside the housing 10.

The housing 10 has a plurality of slits (eg, a plurality of slits which are collected from the heat sink 40 and the heat generated when the LED is applied to the hydrogen socket 12 and the LED light) which are discharged to the outside of the housing 10. 11, slit) is provided.

The slits 11 may be recessed into the inner side of the housing 10 as shown in 2 to 5 of the accompanying drawings, and a plurality of slits are provided along the outer periphery of the housing 10 at the upper side of the housing 10. A plurality of second slits 11b may be provided along the outer circumference of the housing 10 at one slit 11a and the center of the housing 10.

As described above, the present invention can prevent the pests that may occur during plant cultivation by removing or preventing proliferation of viruses, bacteria and fungi that are generated during plant cultivation by anion generators and preventing proliferation, LED lamps Reduces power consumption through intermittent cycles of lighting and lighting, minimizes heat generation when the LED lamp is lit, and increases the life of the lamp by collecting the generated heat from the heat sink and efficiently discharging it through the slit even if heat is generated. You can.

In addition, it is possible to provide a plant cultivation lamp that can promote plant growth by combining an appropriate ratio of red and blue LEDs.

100: plant cultivation lamp 10: housing
11: slit 11a: first slit
11b: second slit 12: hydrogen rocket
20: LED control circuit portion 30: negative ion generating circuit portion
31: negative ion discharge tip 32: safe cover
40: heat sink 41: heat sink fin
50: LED module 60: protective plate
70: floodlight cap
L1: Red LED L2: Blue LED

Claims (7)

An LED module 50 in which a red LED L1 having a wavelength of 660 nanometers and a blue LED L2 having a wavelength of 450 nanometers are arranged;
A heat sink 40 installed on an upper surface of the LED module 50 to absorb and radiate heat generated from the LED module 50;
Anion generating circuit unit 30 provided inside the upper portion of the heat sink 40;
An LED control circuit unit 20 provided on an upper surface of the negative ion generating circuit unit 30;
The LED module 50, the heat dissipation plate 40, the negative ion generating circuit unit 30 and the LED control circuit unit 20 is stacked and embedded, a plurality of hydrogen socket 12 and the generated heat is applied to the electric energy applied Housing 10 is provided with a slit 11 and
It is provided on the lower side of the housing 10 is made of a light transmitting cap 70 for transmitting light,
The lower portion of the LED module 50 further includes a protective plate 60, a discharge tip 31 for discharging negative ions by the voltage applied from the negative ion generating circuit portion 30 in the center of the protective plate 60 and the Lamp for plant cultivation, characterized in that the safe cover 32 to protect the outer side of the discharge tip (31) is provided.
The method according to claim 1,
The LED control circuit unit 20 turns on the red LED L1 and the blue LED L2 for 400 ms and turns off the lights for 200 ms so that the red-blue LEDs L1 and L2 are turned off for a predetermined time. Plant cultivation lamp, characterized in that provided.
delete The method according to claim 1,
The method for discharging the negative ions in the negative ion generating circuit unit 30 is a lamp for plant cultivation, characterized in that the electron radiation method.
The method according to claim 1,
The LED module 50 is made of a metal PCB lamp for plant cultivation, characterized in that the heat radiation in contact with the heat sink (40).
The method according to claim 5,
Lamp for plant cultivation, characterized in that the ratio of the red LED (L1) and the blue LED (L2) arranged in the LED module 50 is 3: 1 each.
The method according to claim 1,
The slit 11 provided in the housing 10
Lamp for plant cultivation comprising a plurality of first slits (11a) provided on the upper side of the housing (10) and a plurality of second slits (11b) provided on the center side of the housing (10).

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