KR200446762Y1 - A Plant cultivation far infrared ray lamp - Google Patents

Abstract

The present invention relates to the lighting installed in the house during plant cultivation, and has a deodorizing effect and prevents the growth of various pathogens such as Pseudomonas aeruginosa or E. coli in the house, and installs a far-infrared lamp to promote plant growth. In this case, the connection socket is prevented from being overheated due to overheating of the far-infrared lamp that generates heat at a high temperature, thereby preventing the contact from melting and breaking, thereby improving the life of the far-infrared lamp.

Accordingly, the apparatus of the present invention includes an enclosure type reflecting plate 10 having an open bottom, and is provided with a far-infrared lamp 20 interpolatingly mounted on the reflecting plate 10 and having a length, and an upper surface of the reflecting plate 10. Fixing both sides, and having a support part 30 having a fastening plate 31 spaced upwards at a predetermined interval, and a heat insulating socket 40 seated and fixed to the fastening plate 31 of the support part 30, It is characterized by consisting of a ground socket 50 is coupled to the insulating socket 40 and grounded with the wire (L) of both ends of the far-infrared lamp (20).

Lamp, plant cultivation, far infrared ray, halogen lamp, porcelain (ceramic), quartz tube

Description

A plant cultivation far infrared ray lamp

The present invention relates to the lighting installed in the house when plant cultivation, more specifically, the antibacterial action to prevent the propagation of various pathogens such as Pseudomonas aeruginosa to E. coli in the house, while having an antibacterial effect and promoting plant growth. The present invention relates to a far-infrared lamp having an improved structure by prolonging the life of the far-infrared lamp by installing a far-infrared lamp and preventing the connection socket from overheating and melting due to overheating of the far-infrared lamp that is heated to a high temperature.

Far infrared ray is an infrared ray having a wavelength of 5 to 12 μm, which is longer than visible light and is invisible, has a strong penetration force, and has strong resonance and resonance effects on organic compound molecules.

This far-infrared ray removes germs that cause various diseases, expands capillaries to help blood circulation and cell tissue formation, and activates cellular tissues when they touch water and protein molecules that make up cells. Do it.

In particular, far-infrared rays, such as deodorization, antibacterial, mold growth prevention, dehumidification, air purification, and the like are widely used in various fields, such as medical devices, textiles, bedding, jjimjilbang.

On the other hand, a lamp for plant cultivation generally used includes a lamp 100 having a predetermined size as shown in FIG. 1, and a light is irradiated to one side 120 by applying a reflector 110 to one surface of the lamp 100. The ground socket 130 is integrally provided on the top thereof, and is used to be coupled to the socket 200.

In the conventional lamp 100, when the lamp is used for a long time, heat is transmitted along the body of the lamp 100 made of glass, and heat is transferred to the grounding socket 130 at the upper end, whereby the grounding socket 130 is overheated. As a result, the contact portion 140 at the end melted and shorted, or a short occurred in a state in which the contact portion 140 is coupled to the socket 200, and thus, the contact portion 140 is broken together with the socket 200.

In particular, when a short occurs along with the socket 200 and is broken, it may cause a short circuit, and even a fire may be the main cause of various safety accidents.

Therefore, the present invention was devised in view of the above-described conventional problems, and a first object of the present invention is that a short circuit occurs due to melting of a contact portion of a socket due to a lamp that is heated to a high temperature. In order to prevent the connection socket from being broken, the lamp and the connection socket are configured to be spaced apart at regular intervals, and to provide a lamp having an improved structure which prevents heat transfer to the connection socket by blocking heat generated from the lamp.

The second object of the present invention is to provide a far-infrared lamp suitable for plant cultivation using the lamp of the improved structure and to grow the plant by cultivating the plant using the same, and to inhabit in a humid environment in the house due to the radiation of far-infrared To provide a far-infrared lamp for plant cultivation that has an antibacterial action of various pathogens such as Pseudomonas aeruginosa to E. coli.

Other objects, advantages, and features of the present invention and the present invention will become more apparent from the detailed description for carrying out the present invention with reference to the accompanying drawings showing the preferred embodiments.

According to the above object, the device of the present invention has a length, and includes a reflecting plate having an open bottom, and is provided with a far-infrared lamp having an length interpolated to the reflecting plate, and fixing both sides of the upper surface of the reflecting plate. And a support part having a fastening plate spaced upward at a predetermined interval, the heat insulating socket seated on the fastening plate of the support part, and a ground socket coupled to the wires at both ends of the far-infrared lamp and grounded. Is achieved by

In addition, the insulating socket is made of magnetic (ceramic), and formed into a screw portion on the outer circumferential surface is inserted into the grounding socket and coupled, it can be carried out by being fastened by a fastening plate and a fixing member of the support.

By the use of the structure-improved far-infrared lamp for plant cultivation of the present invention obtained through the above object and the means for solving the problem to achieve the object, the heat transfer is blocked due to the insulation socket of the far-infrared lamp and the ground socket, the contact portion of the ground socket by the high temperature Preventing melting, thereby preventing short circuits and breakage in the socket, thereby extending the life of the far-infrared lamp and the socket.

In addition, by cultivating the plant using a far-infrared lamp to promote the growth of the plant, there is an effect of antibacterial and deodorizing action of various pathogens such as Pseudomonas aeruginosa to E. coli that live in a humid environment in the house due to the radiation of the far infrared.

Hereinafter will be described in more detail through the accompanying drawings showing an embodiment of the present invention.

The present invention has a length of the left and right, as shown in Figure 2 and Figure 3, having a housing-like reflecting plate 10 that is open on the bottom, and is inserted into the reflecting plate 10, the far-infrared lamp 20 having a length from side to side ).

The reflector 10 is made of aluminum or metal to enhance durability, so that the reflector 10 may be easily installed on an exposed site such as a farmhouse, and the far-infrared lamp may be formed through a through hole 11 formed at left and right sides as shown in FIG. 4. 20 is inserted through the left and right, and the wire (L) is connected to the left and right side ends of the far infrared ray lamp 20 is installed.

In addition, the support plate 30 is fixed to support both sides of the upper surface of the reflecting plate 10, and is spaced upward at a predetermined interval, and includes a support part 30 including the fastening plate 31, which is inserted into the reflecting plate 10 as illustrated in FIG. 5. The wire L of the far-infrared lamp 20 is wrapped by the guide plate 32, and both ends thereof are inserted through the through hole H of the fastening plate 31 to protrude upward.

At this time, the fixing of the reflecting plate 10 and the support 30 is that the reflecting plate 10 and the support 30 is fixed by riveting using a plurality of rivets (R), which is various binding to facilitate those skilled in the art It may be modified by the method.

The reflection plate 10 is a distance between the far-infrared lamp 20 and the ground socket 50 so that heat of the far-infrared lamp is not transmitted, and serves as a heat sink that emits heat to the outside.

On the other hand, the grounding socket which is coupled to the heat insulating socket 40 and the heat insulating socket 40 which is seated and fixed to the fastening plate 31 of the support part 30 and the ground (L) both ends of the far-infrared lamp 20 50, wherein both ends of the electric wire L penetrated through the through hole H of the fastening plate 31 are upwardly penetrated into the heat insulating socket 40, and the bottom surface of the heat insulating socket 40 is provided. After being seated on the fastening plate 31, it is fixed through the fixing member (B).

Here, the heat insulating socket 40 of the present invention, may be made of a magnetic (ceramic), can be implemented, the threaded portion 41 is formed on the outer circumferential surface is inserted into the grounding socket 50 is coupled, the support portion 30 of The fastening plate 31 and the fixing member (B) may be fastened and fixed.

On the other hand, the far-infrared lamp 20 of the present invention, as shown in Figure 7 is applied to the surface of the primary binder 22 and the primary binder 22 of a certain thickness applied to the surface of the quartz tube 21, It may be implemented with a far infrared ray lamp 20 composed of a secondary binder 23 and a far infrared radiator 24 applied to the secondary binder 23.

In the far-infrared lamp for plant cultivation of the present invention, which is constructed as described above, as shown in FIG. 2, the heat transfer is blocked by the reflector 10 and the ground socket 50 by the support part 30 and the heat insulation socket 40. This prevents the contact of the ground socket 50 from overheating and melting or short-circuit with the socket (S).

In this case, the support 30 lowers the temperature of heat transmitted by releasing heat transmitted from the far-infrared lamp 20 laterally, and the heat insulating socket fixed to the fastening plate 31 of the support 30. 40) the heat is secondarily blocked, thereby completely blocking heat transfer to the ground socket 50 coupled thereto.

Here, the heat insulation socket 40 is made of magnetic (ceramic) such as insulator to block heat transfer, and is screwed through the ground socket 50 and the threaded portion 41, and then ground socket to fix it more firmly. The end of the 50 and the end portion of the threaded portion 41 of the heat insulation socket 40 may be pressed or welded to fix the fastening so as not to loosen.

Meanwhile, wires connected to both ends of the far-infrared lamp 20 and wrapped through the guide plate 32 of the support part 30, and then grounded to the ground socket 50 through the upper fastening plate 41. L) is preferably used by covering with a heat insulating material so that the coating does not melt due to high temperature.

Hereinafter will be described in more detail through an embodiment of the present invention.

<Example>

The present invention is provided with a reflecting plate 10 of a predetermined size having an opening shape as shown in Figure 4, the through-hole 11 is formed on both sides of the reflecting plate 10, the far-infrared lamp 20 of a predetermined length Insert through).

Here, the far-infrared lamp 20 is fixed to a wire (L) of a predetermined length at both ends, the wire (L) is used as a heat insulating coating.

After attaching the far-infrared lamp 20 to the reflector 10 as described above, as shown in FIG. 5, both ends of the support 30 having a predetermined length diagonally at both ends are provided with rivets R at the left and right sides of the reflector 10. It is fixed through riveting, withdraw both ends of the far infrared lamp 20 along the inner surface of the support portion 30 to the through-hole (H) formed in the fastening plate 31 of the upper end of the support portion 30, the far infrared support ( 30) wrap the wire (L) exposed between the guide plate (32).

On the other hand, the electric wire L drawn out to the upper side of the fastening plate 31 is inserted through the bottom surface of the heat insulating socket 40 seated on the upper surface thereof and drawn out to the upper side, and the heat insulating socket 40 is fastened to the fastening plate 31. After being seated in close contact, it is fastened and fixed through the fixing member (B). Wherein the fixing member (B) is preferably carried out by bolts / nuts.

After fixing the heat insulating socket 40 to the upper surface of the fastening plate 31 as described above, the both ends of the wire L drawn out through the heat insulating socket 40 are grounded to the inside of the ground socket 50, respectively, and the heat insulating socket ( The bottom surface of the ground socket 50 is extrapolated and fixed to the threaded portion 41 of 40).

At this time, after screwing the heat insulating socket 40 and the ground socket 50, the end of the ground socket 50 can be crimped or welded to prevent loosening in the fully coupled state.

In the present invention implemented as described above, the far-infrared lamp 20 is applied to the surface of the quartz tube (halogen lamp, 21) as shown in Fig. 7, the primary binder 22 and the high temperature adsorption, and the primary binder 22 ) And a far-infrared lamp made by applying a far-infrared radiator 24 and a secondary binder 23 of an intermediate medium material which is well adsorbed at the same time, which is one of the types of far-infrared lamps. It will be omitted. At this time, reference numeral "C" is a coil provided across the inside of the quartz tube 21.

The far-infrared lamp 20 was used to carry out the antibacterial test of Escherichia coli to Pseudomonas aeruginosa, and the results are shown in Table 1.

object Test environment Initial concentration Concentration after 24 hours % Reduction   Escherichia coli  General house 2.4 X 10 ⁵ 9.2 X 10 ⁵  -  Far Infrared Lamp House 1.5 X 10 ⁵  83.7   Pseudomonas aeruginosa  General house 3.1 X 10 ⁵ 1.2 X 10 ⁶  -  Far Infrared Lamp House 2.1 X 10 ⁵  82.5

As shown in Table 1, it can be seen that the concentration of E. coli and Pseudomonas aeruginosa is reduced by more than 80% in the plant cultivation house to which the far-infrared lamp is applied.

In addition, the deodorization test was performed on a certain sample using the far infrared lamp 20, the results are shown in Table 2.

  object   Elapsed time (minutes)  Normal sample concentration (ppm)  Concentration of Far Infrared Sample (ppm)   Deodorization rate (%)   Deodorization test Early 500 500 - 30 490 155 68 60 480 150 69 90 460 135 71 120 450 125 72

As shown in Table 2, the sample exposed to the far infrared for a certain time reaches a deodorization rate of 68% for the first 30 minutes, and it can be seen that the deodorization rate continuously increases thereafter.

On the other hand, in the present invention, the far-infrared lamp 20 is applied by laminating the primary and secondary binders 22 and 23 and the far-infrared radiator 24 so that the brightness of the light is 1 m instead of the usual 400 Lux (lux) per 1 m. It is preferably adjusted to 10Lux (lux), so that the plant does not perform photosynthesis even when the far-infrared lamp 20 is turned on at night.

The structure-improved far-infrared lamp for plant cultivation of the present invention, the far-infrared lamp 20 is heated to an appropriate temperature at which a large amount of far-infrared radiation can be radiated, wherein the heated heat is through the support 30 and the heat insulation socket 40 The heat transfer is completely blocked to prevent the ground portion of the ground socket 50 from being damaged or damaged by heat.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it will be readily apparent to those skilled in the art that various other changes and modifications can be made without departing from the spirit and scope of the present invention. It is obvious that all modifications belong to the attached utility model registration claims.

1 is a perspective view showing an example of a conventional plant cultivation lamp.

Figure 2 is a perspective view showing an example of an improved far-infrared lamp for plant cultivation of the present invention.

Figure 3 is an isolated perspective view of the far-infrared lamp with improved structure for plant cultivation.

Figure 4 is a perspective view showing a coupling example of the reflector and the far-infrared lamp of the plant-structured far-infrared lamp for plant cultivation of the present invention.

Figure 5 is a perspective view showing a coupling example of the reflector and the support of the structure-infrared lamp for plant cultivation of the present invention.

Figure 6 is a perspective view showing a coupling example of the support portion and the heat insulation socket of the plant-structured far-infrared lamp for cultivation of the present invention.

7 is a cross-sectional view showing an example of the far-infrared lamp among the improved far-infrared lamp for plant cultivation of the present invention.

[Explanation of symbols on the main parts of the drawings]

10: Reflector 11: Through Hole

20: far infrared lamp 21: quartz tube

22: primary binder 23: secondary binder

24: far infrared emitter 30: support

31: Fastening plate 32: Guide plate

40: heat insulation socket 41: threaded portion

50: grounding socket B: holding member

C: coil H: through hole

L: Wire R: Rivet

S: socket

Claims (6)

In the lamp used for a house for plant cultivation, An enclosure-type reflector 10 having a length from side to side and having an open bottom; A far-infrared lamp 20 interpolatingly mounted to the reflector 10 and having a length from side to side; A support part 30 supporting both sides of the upper surface of the reflecting plate 10 and having a fastening plate 31 spaced upwardly at a predetermined interval; An insulated socket 40 seated and fixed to the fastening plate 31 of the support part 30; It is composed of a grounding socket 50 is coupled to the insulating socket 40 and grounded with the wire (L) of both ends of the far infrared ray lamp 20, The heat insulation socket 40 is made of magnetic (ceramic), The heat insulating socket 40 is formed by screwing the outer peripheral surface 41 is inserted into the grounding socket 50 is coupled, and fastened and fixed by the fastening plate 31 and the fixing member (B) of the support 30. Improved far-infrared lamp for plant cultivation. The method of claim 1, The support part 30 further includes a guard plate 32 having a predetermined length on both sides so that the wire L at both ends of the far infrared ray lamp 20 is connected to the fastening plate 31, so as not to be exposed to the outside. An improved far-infrared lamp for plant cultivation, characterized in that (L) is wrapped. delete delete delete delete

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