KR100908183B1 - Heat-emitting lamp for hothouse - Google Patents

Abstract

A heat radiating lamp for greenhouses is provided to be easily and conveniently exchanged for another one by being rotatably fixed to the lower part of a reflector. A lower part of a cover(10) is opened. A reflector(30) is fixed in the state of being accommodated in the cover. A heat radiating lamp fixing unit(50) is installed within the reflector. A heat radiating lamp(70) is fixed to the heat radiating lamp fixing unit. A reflecting board(90) is located on the lower part of the reflector and radiates the heat generated from the heat radiating lamp to the reflector. The both sides of the reflecting board are rotatably connected to the lower part of the reflector.

Description

Heat dissipation lamp for greenhouse {HEAT-EMITTING LAMP FOR HOTHOUSE}

The present invention is a cover with an open bottom; A reflection shade fixed in a state accommodated in the cover; A heat dissipation lamp fixing part fixedly installed in the reflection shade; A heat dissipation lamp fixed to the heat dissipation lamp fixing unit; It is fixed to the bottom of the reflection shade is a heat sink for a greenhouse comprising a; reflecting plate for reflecting the heating wire generated from the heat radiation lamp to the reflection shade.

In general, a greenhouse is a building which is equipped with a facility for raising internal temperature for the purpose of growing hot plants in the cold season and flowering and fruiting in seasons other than normal, that is, having a heating facility inside. Greenhouses such as plants and fruits are grown because these greenhouses are easy to manage.

On the other hand, in recent years there has been proposed a heat dissipation mechanism having a heat dissipation lamp installed inside the greenhouse to dissipate heat required for the growth of the crops to the crop.

The heat dissipation mechanism is generally composed of a reflection shade installed inside the greenhouse and a heat dissipation lamp provided in the reflection shade to generate heat to the crop.

However, when dew is generated in the greenhouse due to a temperature difference between the outside of the greenhouse and the inside of the greenhouse, there is a problem that dew may be introduced into the reflecting shade, so that the heat dissipation lamp may leak due to the dew introduced into the reflecting shade. .

In addition, when the reflection lamp and the greenhouse, in particular, the vinyl of the vinyl house is in contact with the temperature rise due to the heat dissipation lamp, there is not only a risk that the vinyl of the vinyl house is damaged, but there is also a concern that a fire may occur in the plastic house. have.

In addition, since heat generated from the heat dissipation lamp is radiated downward and is directly transmitted to the crops, dryness occurs in the crops, which causes a problem that the growth of the crops is reduced.

The present invention was created in order to solve the above-described problems, and the heat dissipation lamp that transmits the hot wire to the crops is not likely to be shorted by dew, and of course, the temperature rises, so that the reflection shade and the greenhouse can be prevented from contacting each other. There is no fear that the greenhouse will be damaged or the fire will be caused in the greenhouse due to the reflection shade of which the temperature has risen, and furthermore, since the heating wire generated from the heat dissipation lamp is indirectly transmitted to the crop, there is no fear of dryness in the crop. Of course, there is no fear of lowering the growth of the crop, and the growth function of the crop is more activated because the far-infrared radiation material made of silica, alumina, tourmaline and nanosilver is coated on the upper surface of the heat dissipation lamp and the reflector. Not only can the high antibacterial properties of crops It is aimed to provide heat radiation lamp for greenhouse which there is.

The present invention for achieving the above object and the cover is formed open; A reflection shade fixed in a state accommodated in the cover; A heat dissipation lamp fixing part fixedly installed in the reflection shade; A heat dissipation lamp fixed to the heat dissipation lamp fixing unit; It is fixed to the bottom of the reflection shade provides a heat radiation lamp for a greenhouse comprising a; reflecting plate for reflecting the heating wire generated from the heat radiation lamp to the reflection shade.

Here, the reflecting plate may be fixedly coupled so that both ends are rotated to the lower end of the reflecting shade.

In addition, the reflecting plate is composed of a reflecting plate portion, a connecting plate portion extending laterally on each side of the reflecting plate portion, and a bending plate portion bent in the vertical direction at both ends of the connecting plate portion and fixed to the lower end of the reflecting shade, Both sides of the connecting plate portion is preferably provided with a receiving groove for receiving the reflection shade when the reflecting plate rotates.

Furthermore, it is preferable that a plurality of embossing is formed on the reflection shade and the reflection plate.

In addition, it is preferable that the heat radiation lamp is coated with far-infrared rays and anion emitting materials.

In addition, it is preferable that the far infrared and anion emitting material is coated on the lower surface of the reflecting plate.

According to the present invention, since a cover accommodating the reflection shade inside prevents dew, etc. generated by the temperature difference from the outside of the greenhouse and the inside of the greenhouse, from entering the reflection shade, the heat dissipation lamp transferring heat rays to the crop grown in the greenhouse is caused by dew. Since the cover prevents contact between the greenhouse and the reflecting lamp whose temperature is raised by the heat dissipation lamp, there is no fear that the greenhouse will be damaged or a fire will be caused by the greenhouse. Further, since the heat wire generated from the heat radiation lamp is indirectly transmitted to the crops grown in the greenhouse due to the reflection plate reflecting the heat wire generated from the heat radiation lamp to the reflection shade, there is no fear that dryness may occur in the crop as in the prior art. Of course, this causes the growth of the farm There is an effect that is likely to be lost.

In addition, since both ends of the reflector are fixedly coupled to the lower end of the reflector, the heat dissipation lamp having an end of life or being damaged can be easily replaced.

In particular, when the reflecting plate is rotated, the reflecting shade is accommodated in the receiving grooves provided at both sides of the connecting plate portion of the reflecting plate, so that the range of rotation of the reflecting plate can be widened. There is an effect that can be easily replaced.

In addition, due to the plurality of embossing formed on the reflector and the reflector plate, the reflector may reflect more heat rays from the reflector to the reflector. have.

Furthermore, since the far-infrared radiation material consisting of silica, alumina, tourmaline and nanosilver is coated on the heat dissipation lamp, the growth function of the crop can be more activated, as well as a high antibacterial effect can also have the crop.

In addition, since the far-infrared radiation material consisting of silica, alumina, tourmaline, and nano silver is coated on the upper surface of the reflector, the growth function of the crop can be more activated, and the antimicrobial effect can also be higher. There is.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Of course, the scope of the present invention is not limited to the following examples, and various modifications can be made by those skilled in the art without departing from the technical gist of the present invention.

1 is a perspective view schematically showing a heat dissipation lamp for a greenhouse of an embodiment of the present invention, FIG. 2 is an exploded perspective view of FIG. 1, and FIG. 3 is a cross-sectional view of FIG. 1.

The greenhouse heat radiation lamp of an embodiment of the present invention is large, as shown in Figure 1 and 2, the cover 10, the reflection shade 30, the heat dissipation lamp fixing portion 50, the heat dissipation lamp 70 and the reflector plate 90 It is made, including.

First, the cover 10 is to accommodate the reflection shade 30 therein, the lower portion is formed as shown in FIG.

Next, the reflection shade 30 is accommodated in the cover 10, the heating wire generated in the heat dissipation lamp 70 and reflected through the reflecting plate 90 (see dotted arrow in FIG. 6). It is indirectly delivered to crops such as plants and fruits grown inside the greenhouse.

The reflection shade 30 is, for example, as shown in Figure 2 and 3, the fixing bolt 311 which is screwed vertically to the upper center of the cover 10 and the reflection shade 30, and the fixing bolt ( It may be fixed in a state accommodated in the cover 10 by a fixing member 310 made of a nut 313 screwed to the bottom of 311.

Next, the heat dissipation lamp fixing part 50 is fixed to both ends of the heat dissipation lamp 70 to be detachably fixed to both sides of the lower end, for example, as shown in Figure 2 and 3, Fixing bolt 511 that is vertically screwed to both sides of the bottom plate 501 of the government unit 50 and the upper both sides of the reflector 30, and nuts 513 screwed to the upper portion of the fixing bolt 511 The fixing member 510 may be fixedly installed in the reflection shade 30.

Next, the heat dissipation lamp 70 generates a Far Infrared ray (also referred to as Far Infrared Ray, which is far infrared ray, and refers to an electromagnetic wave having a wavelength longer than visible light). As shown in 3, both ends of the heat dissipation lamp fixing part 50 are detachably fitted.

4 is a bottom view schematically illustrating the reflector 90 coupled to the bottom of the reflector 30.

Next, the reflector plate 90 reflects the heat rays generated from the heat dissipation lamp 70 to the reflector 30 to indirectly transmit the heat rays to the crops grown in the greenhouse, the reflector 30 Is fixed at the bottom.

Here, the reflective plate 90 is preferably fixedly coupled so that both ends are rotated to the lower end of the reflection shade 30 as shown in FIGS.

More specifically, both ends of the reflective plate 90 as shown in FIGS. 2 to 4, for example, rivets 911 fixed to penetrate horizontally through both ends of the lower end of the reflection shade 30 and both ends of the reflective plate 90 horizontally. By the fixing member 910, such as may be fixed to be rotated to the lower end of the reflection shade (30).

Since both ends of the reflector 90 are fixedly coupled to the lower end of the reflector 30, there is an advantage that the heat dissipation lamp 70, which has reached the end of its life or is damaged by external force, can be replaced more easily.

On the other hand, the reflector 90 has a reflector 930 as shown in Figures 2 and 4; Connecting plate portions 950 extending laterally on both sides of the reflecting plate portion 930; Bending plate portion 970 which is bent in the vertical direction at both ends of the connecting plate portion 950, and fixed to the lower end of the reflection shade 30 by the fixing member 910, such as rivets (911); .

5 is a perspective view schematically illustrating a state in which the reflector 90 of FIG. 4 is rotated.

Here, as shown in FIGS. 4 and 5, both side portions of the connection plate part 950 may further include accommodation grooves 951 in which the reflection shade 30 is accommodated when the reflection plate 90 is rotated.

As such, when the receiving grooves 951 are provided at both sides of the connecting plate 950, as shown in FIG. 5, both sides of the connecting plate 950 of the reflecting plate 90 when the reflecting plate 90 is rotated. Since the lower end of the reflector 30 is accommodated in the accommodating groove 951 provided therein, the range of rotation of the reflector 90 can be widened, so that the heat dissipation lamp 70 which has reached the end of its life or is damaged more easily. This has the advantage of being replaceable.

FIG. 6 is a cross-sectional view schematically illustrating a state in which a plurality of embossings 330 and 931 are formed in the reflection shade 30 and the reflection plate 90.

Next, as shown in FIG. 6, a plurality of embossings 330 and 931 may be formed in the reflection shade 30 and the reflection plate 90.

More specifically, a plurality of embossing 330 protrudes inwardly on the inner circumferential surface of the reflection shade 30, and a plurality of embossing on the upper surface of the reflecting plate portion 930 and the connecting plate portion 950 of the reflecting plate 90. 931 may protrude upwards, respectively.

Due to the plurality of embossings 330 and 931 formed on the reflector 30 and the reflector 90, the heat rays reflected by the reflector 90 to the reflector 30 may be more diffused, and as a result, There is also an advantage that can be spread more heat wire indirectly transmitted to the.

7 is a cross-sectional view schematically illustrating a state in which the far-infrared radiation material 100 is coated on the heat dissipation lamp 70 and the reflector 90.

Next, as shown in Figure 7, the outer circumference of the heat dissipation lamp 70 is preferably coated with a known far-infrared radiation material (100).

The far-infrared radiating material 100 may be indirectly transmitted to the crops grown in the greenhouse together with the heat rays generated from the heat dissipation lamp 70.

The far-infrared radiation substance 100 is for activating the growth function of the crops grown in the greenhouse, so that the crop has a high antimicrobial, for example, silica (SIO ₂ ), alumina (AL ₂ O ₃ ), It may be made of tourmaline and NANO SILVER, but is not necessarily limited thereto. Preferably, a large amount of anions are also generated to remove contaminants from the air in the greenhouse, thereby ensuring that the greenhouse is always fresh and clear. In this case, it is preferable to use nano silver, which destroys the cell walls and cell membranes of tourmaline or bacteria, also called tourmaline, which allows crops to grow freshly.

Since the far-infrared radiation material 100 made of silica, alumina, tourmaline, nanosilver, etc. is coated on the heat dissipation lamp 70, the growth function of crops grown in a greenhouse can be more activated, as well as high antimicrobial properties. There is an advantage to this.

Further, as shown in FIG. 7, for example, the far infrared ray emitting material 100 may be coated on the lower surfaces of the reflecting plate 930 and the connecting plate 950 of the reflecting plate 90.

The far-infrared radiation material 100 coated on the lower surface of the reflector 90 is heat-transferred to the crops grown in the greenhouse together with the heat rays generated from the heat dissipation lamp 70.

Since the far-infrared radiation material 100 made of silica, alumina, tourmaline, nanosilver, etc. is coated on the lower surface of the reflector 90, the growth function of the crops grown inside the greenhouse may be more activated. High antimicrobial properties also have the advantage that crops may have.

8 to 10 are perspective views schematically illustrating a state in which the bracket 130, the socket 150, and the cap 170 are provided on the cover 10.

Next, the cover 10 may be fixed to the upper side of the greenhouse, for example, where the greenhouse may mean, for example, a glass greenhouse, a plastic house, but is not necessarily limited thereto.

The cover 10 is, for example, a bracket 130 method, a socket 150 method or a cap 170, which is known to be completely fixed or detachably fixed to, for example, an upper side of a greenhouse as shown in FIGS. 8 to 10. It may be installed in a manner such as, but is not necessarily limited to this may be fixed to the upper inside of the greenhouse in a variety of ways.

In the present invention configured as described above, since the cover 10 accommodated inside the reflection shade 30 prevents dew, etc. generated by the temperature difference from the outside of the greenhouse and the inside of the greenhouse, from entering the reflection shade 30. There is no fear that the heat dissipation lamp 70 that transmits the heating wire to the crops grown in the ground may be leaked by dew, etc., and the cover 10 may have the reflection shade 30 whose temperature is increased by the heat dissipation lamp 70. Since the reflection shade 30 of which temperature rises because the vinyl of the greenhouse, in particular, the vinyl house is prevented from contacting, there is no fear that the vinyl of the greenhouse, in particular, the vinyl house is damaged or a fire is generated in the greenhouse, that is, the greenhouse. Furthermore, due to the reflector plate 90 reflecting the heat rays generated from the heat dissipation lamp 70 to the reflection shade 30, the heat rays generated from the heat dissipation lamp 70 are transferred to the greenhouse. Since the indirect transfer to the crops that are grown there are advantages doemeun be no possibility that the dryness occurs in conventional crops, as well as because of this that would be no fear that the growth of the crops decreased.

1 is a perspective view schematically showing a heat dissipation lamp for an embodiment of the present invention,

Figure 2 is an exploded perspective view of Figure 1,

3 is a cross-sectional view of the combination of FIG.

Figure 4 is a bottom view schematically showing a reflector coupled to the bottom of the reflector,

5 is a perspective view schematically illustrating a state in which the reflector of FIG. 4 is rotated;

6 is a cross-sectional view schematically showing a state in which a plurality of embossings are formed on the reflection shade and the reflection plate,

7 is a cross-sectional view schematically illustrating a state in which a far-infrared radiation material is coated on a heat dissipation lamp and a reflector.

8 to 10 are perspective views schematically showing a state in which a bracket, a socket, and a cap are provided on an upper portion of a cover.

*** Explanation of symbols for main parts of drawing ***

10; Cover, 30; Reflection,

310, 510, 910; Fixing members 311 and 511; Fixing Bolt,

313, 513; Nuts, 330, 931; Embossing,

50; Heat dissipation lamp fixing part, 501; Bottom Plate,

70; Heat dissipation lamp, 90; Reflector,

911; Rivets, 930; Reflector,

950; Connecting plate portion, 951; Receiving Home,

970; Bent plate portion, 100; Far Infrared Radiation,

130; Bracket, 150; socket,

170; cap.

Claims (6)

A cover having an open bottom portion; A reflection shade fixed in a state accommodated in the cover; A heat dissipation lamp fixing part fixedly installed in the reflection shade; A heat dissipation lamp fixed to the heat dissipation lamp fixing unit; A reflection plate fixed to the bottom of the reflection shade to reflect the heating wire generated from the heat dissipation lamp to the reflection shade; The reflecting plate is a heat radiation lamp for a greenhouse, characterized in that the both ends are fixedly coupled to the lower end of the reflecting shade. The method of claim 1, The reflecting plate is composed of a reflecting plate portion, a connecting plate portion extending laterally on each side of the reflecting plate portion, and a bending plate portion bent in the vertical direction to both ends of the connecting plate portion and fixed to the lower end of the reflecting shade, Both sides of the connecting plate portion is a heat radiation lamp for a greenhouse, characterized in that the receiving groove for receiving the reflection shade is provided when the reflecting plate is rotated. The method according to claim 1 or 2, The reflector and the reflecting plate is a greenhouse heat radiation lamp, characterized in that a plurality of embossing is formed. The method of claim 1, The heat dissipation lamp is a heat radiation lamp for a greenhouse, characterized in that the far infrared and anion radiation material is coated. The method of claim 1, Far-infrared radiation and anion radiation material is coated on the lower surface of the reflecting plate, characterized in that the greenhouse heat radiation. delete

Images