KR100393280B1 - Water tank having far infrared ray radiating device - Google Patents

Abstract

The present invention relates to a bucket equipped with far infrared radiation sphere. It has an inner space consisting of a bottom surface and a wall portion and a spout portion is covered with a lid, but the bottom surface is provided with a water hole provided with an installation hole sealed by a sealing cap; It is installed in the water tank through the installation hole to radiate far infrared rays, characterized in that the far-infrared radiation sphere having one end fixed to the bottom surface is provided.

The present invention made as described above, by installing a far-infrared radiation sphere radiating far-infrared rays inside the water tank to prevent the breeding of various bacteria in the stored water as well as the taste of the water. In particular, when the tap water is stored in the water tank, the far-infrared rays remove various odors and heavy metals in the tap water, as well as minerals in the tap water, so that the tap water can be safely consumed.

Description

Water tank having far infrared ray radiating device

The present invention relates to a bucket containing water, and more particularly, to a bucket provided with far-infrared radiation spheres configured to apply far-infrared rays to stored water by installing a radiator emitting far-infrared rays in the bucket.

The pollution caused by the increase of population also affects the drinking water, which is the age of buying and drinking water at stores. The water traded is usually drawn from a relatively less contaminated subterranean rock bed and sold in buckets of different capacities. There is also a fixing bucket called a conventional bottled water bottle to be used in the cold and hot water from the small size that can be carried.

As is known, if the water container containing the bottled water is left open for a long time, even if the lid is closed, the water stored inside is easily contaminated and deteriorated by various bacteria. Particularly, in case of a large bottle of water, the possibility of the contamination is higher because it takes a relatively long time until the water is consumed after opening the stopper, and the person may drink the bottled water through a separate purifier.

However, since the purifier is mostly expensive and the purifier itself may be a source of contamination, it does not actually solve the problem of contamination or deterioration.

The present invention was created to solve the above problems, by installing a far-infrared radiation sphere radiating far-infrared rays inside the water tank to prevent the growth of various bacteria in the stored water, as well as to improve the taste of water, in particular in the water tank In the case of storing the tap water, it is possible to remove various odors and heavy metals in the tap water by the far-infrared rays, and to supplement minerals in the tap water.

1 is an exploded perspective view showing a bucket equipped with a far infrared ray radiation sphere according to an embodiment of the present invention.

Figure 2 is a perspective view of the water tank in the bucket with far infrared radiation sphere according to an embodiment of the present invention shown.

Figure 3 is a perspective view showing a porous case provided in the bucket provided with far-infrared radiation sphere according to an embodiment of the present invention.

Figure 4 is a view showing for explaining the configuration of a bucket equipped with far-infrared radiation sphere according to an embodiment of the present invention.

5 is a view showing a spiral synthetic resin member that can be applied to a bucket equipped with far-infrared radiation sphere according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

10: bucket 12: bottom

16: packing 18: porous case

20: support flange 22: handle

24: Hole 26: Closed cap

28: Airtight cap seating surface 30: Female thread

32: support flange mounting surface 34: male thread

36: mounting hole 38: far infrared radiation

40: Far-infrared radiation exit 42: Gripping part

46: spiral synthetic resin member 48: interspace portion

50: body 52: bottom

In order to achieve the above object, the present invention includes a bucket having an inner space consisting of a bottom surface and a wall portion and a spout portion covered with a lid, the bottom surface of which is provided with an installation hole sealed by a sealing cap; It is installed in the water tank through the installation hole to radiate far infrared rays, characterized in that the far-infrared radiation sphere having one end fixed to the bottom surface is provided.

In addition, the far infrared radiation sphere; A plurality of through-holes are formed and one end thereof includes a porous case supported at the edge portion of the installation hole, and a far-infrared radiator inserted into the porous case to emit far infrared rays.

In addition, the porous case has a cylindrical shape, and a handle is fixed to one end of the inner circumferential surface so that the porous case can be inserted or removed through the installation hole, and a support flange is formed on the outer circumferential surface of the periphery of the installation hole. It is characterized by.

In addition, the sealing cap is a stopper having a male screw thread formed on the outer peripheral surface thereof, and a female screw thread coupled with the male screw thread of the sealing cap is formed on the bottom surface corresponding to the outer side of the edge of the installation hole. In accordance with the screw thread, the support flange spanning the edge of the installation hole is in close contact with the edge portion, characterized in that for sealing the installation hole.

In addition, the far-infrared radiation emitter is any one of ceramic balls, elvan, germanium stone, or a spiral synthetic resin member formed by repeatedly folding along the longitudinal direction after forming a synthetic resin strip having a certain length, width and thickness in a spiral manner do.

Hereinafter, one embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

1 is an exploded perspective view showing a bucket equipped with a far infrared ray radiation sphere according to an embodiment of the present invention.

Referring to the drawings, the bucket equipped with the far-infrared radiation sphere according to the present embodiment, the bucket 10 is formed with a mounting hole 36 in the center of the bottom surface 12, and the bucket through the mounting hole 36 (10) a porous case (18) inserted into the inside and supported by the edge of the installation hole (36), a far-infrared radiator (38 in FIG. 4) filled in the porous case (18), and the installation hole (36). It is configured to include a sealing cap 26 to prevent the sealing.

In this embodiment, the bucket 10 used a bottle of water containing the drinking spring water, but the shape of the bucket is of course different depending on the embodiment.

The installation hole 36 is a circular hole having a constant diameter, and the support flange seating surface 32 is formed at the edge thereof. The support flange seating surface 32 is formed flat and parallel to the bottom surface 12. A sealing cap seating surface 28 is formed at an outer side of the support flange seating surface 32. Similarly to the support flange seating surface 32, the closed cap seating surface 28 provides a flat surface and is parallel to the bottom surface 12.

The support flange seating surface 32 and the sealing cap seating surface 28 are layered like steps. In addition, a female thread 30 is vertically formed between the sealing cap seating surface 28 and the support flange seating surface 32.

The support flange seating surface 32 is a surface for supporting the support flange 20, which will be described later, the sealing cap seating surface 28 is a gripping portion 42 of the sealing cap 26 with the packing 16 therebetween. Pressurized surface.

The closed cap seating surface 28 is a portion that is concavely molded toward the inner space side of the bucket 10 with respect to the bottom surface 12 to provide a plane, the support flange seating surface 32 is a closed cap seating surface 28 It is a portion that is concavely molded toward the inner space side of the bucket 10 to provide a flat surface.

The depth to the bottom surface 12 of the sealing cap seating surface 28 is deeper than the thickness of the grip portion (42). In addition, the depth of the sealing cap seating surface 28 of the support flange seating surface 32 is deeper than the height of the male thread 34. Therefore, the sealing cap 26 does not protrude from the bottom surface 12.

The porous case 18 inserted and installed into the water tank 10 through the installation hole 36 is a hollow cylindrical case filled with a far-infrared radiator which will be described later. The porous case 18 has a plurality of holes 24 formed therethrough, having a constant diameter and height, and a support flange 20 formed on the outer circumference of the upper end of the drawing.

In addition, a handle 22 is provided inside the porous case 18. The handle 22 is a member fixed to the inner circumferential surface of the porous case 18 and is provided so that the porous case 18 can be easily lifted by hand.

In addition, the plurality of through holes 24 formed in the porous case 18 allow water to freely flow into and out of the porous case 18. Of course, the diameter of the hole 24 should be smaller than the size of the far-infrared radiator (38 of FIG. 4) to be described later. The far-infrared radiator usually uses minerals, so if the minerals are finely divided, the diameter of the holes 24 will be smaller, and conversely, the larger the mass, the larger the diameter will be.

However, the diameter of the hole 24 may be about 0.5mm to about 1.0mm.

The sealing cap 26 for sealing the installation hole 36 is a stopper having a male screw thread 34 formed on its outer circumferential surface and having a diameter larger than the outer diameter of the male screw thread 34 so that it can be easily turned by hand. 42 is integrally formed. The outer periphery of the gripping portion 42 is preferably formed so as to prevent slipping of hands.

The sealing cap 26 is coupled to the female screw thread 30 to seal the installation hole 36.

A packing 16 is provided between the bottom surface of the gripping portion 42 and the sealing cap seating surface 28. The packing 16 has a water-sealed cap 26 coupled to the bucket 10 to the outside. Do not leak and completely seal the inner space of the bucket 10 to the outside.

FIG. 2 is a perspective view illustrating a water bottle in a bucket equipped with far-infrared radiation sphere according to an embodiment of the present invention.

As shown, the installation hole 36 is formed in the center of the bottom surface 12 of the water tank 10, and the support flange seating surface 32 and the sealing cap seating surface (in the outward direction of the mounting hole 36) ( 28 are sequentially formed.

In addition, as described above, the support flange seating surface 32 and the sealing cap seating surface 28 have a step like a step from the bottom surface 12. Therefore, when the male screw thread 34 of the sealing cap 26 is coupled to the female screw thread 30, the gripping portion 42 pressurizes the packing (16 in FIG. 1) as shown in FIG. At this time, the sealing cap 26 does not protrude from the bottom surface 12 so that the bucket 10 may be stably placed.

On the other hand, the diameter of the sealing cap seating surface 28 is larger than the outer diameter of the gripping portion 42 of the closing cap 26 so that the interspace portion 48 is provided as shown in FIG. The interspace portion 48 is a space for turning the gripping portion (42 in FIG. 1) by inserting a finger when tightening or releasing the sealing cap 26 with respect to the bucket 10.

3 is a perspective view illustrating a porous case of a bucket having a far infrared ray radiation sphere according to an embodiment of the present invention.

As shown, the porous case 18 is a hollow cylinder in which a plurality of holes 24 are formed, the lower end of which is blocked by the bottom 52 and the upper end of which is open. In addition, the support flange 20 formed on the outer peripheral surface of the upper end of the porous case 18 is bent at a right angle with respect to the body portion (50).

The outer diameter of the body portion 50 is equal to the inner diameter of the installation hole (36 in Fig. 2). Therefore, when the porous case 18 is inserted into the installation hole 36, the outer circumferential surface of the body portion 50 is supported in contact with the inner circumferential surface of the installation hole 36.

The handle 22 fixed to the inner circumferential surface of the porous case 18 is a member having a shape of a substantially c-shape in which both ends are fixed to the inner circumferential surface of the body portion 50. Since the handle 22 is fixed inside the porous case 18 as described above, it is easy to lift the porous case 18. The shape of the handle may be variously modified according to the embodiment.

Figure 4 is a view showing for explaining the configuration of a bucket equipped with far-infrared radiation sphere according to an embodiment of the present invention.

Referring to the drawings, it can be seen that the far-infrared radiation sphere 40 is installed vertically inside the bucket 10. The far-infrared radiation sphere 40 as far infrared rays are radiated from the inside, the lower end is supported on the support flange seating surface 32 and the vertically positioned porous case 18, and filled in the interior of the porous case 18 Is composed of a far infrared ray radiator 38.

The support flange 20 at the lower end of the porous case 18 is pressed in the direction of arrow a by the sealing cap 26 to be in close contact with the support flange seating surface 32. While the sealing cap 26 is screwed to the bucket 10, the support flange 20 is pressed in the direction of the arrow a to press the support flange seating surface 32 side.

In addition, the packing 16 sandwiched between the sealing cap seating surface 28 and the gripping portion 42 is also compressed in accordance with the combination of the sealing cap 26 to prevent the water in the bucket 10 from leaking to the outside.

On the other hand, the far-infrared radiator 38 filled in the porous case 18 may be a ceramic ball, ganban stone or germanium stone, which is well known as a mineral that emits far infrared rays.

Further, according to the embodiment, for example, a spiral synthetic resin member 60 known through Japanese Patent Application Laid-open No. Hei 7-75712 (published on May 1, 1995) may be applied without applying the ceramic ball, elvan or germanium stone.

The spiral synthetic resin member 60 is formed by spirally molding a synthetic resin strip having a predetermined length, width, and thickness as if it were a ramp road surface of a parking lot, and repeatedly folding it repeatedly up and down along the longitudinal direction. It is known to emit wide and far infrared rays.

5 is a view schematically showing the spiral synthetic resin member 60.

As shown, it can be seen that the spiral synthetic resin member 60 has a large surface area is formed by a plurality of wrinkles. Therefore, the total amount of far infrared rays generated from one spiral synthetic resin member 60 is much higher.

In the bucket equipped with the far-infrared radiation sphere made as described above, when the water tank 10 is placed upside down, the airtight cap 26 is opened and the handle 22 is picked up, and the far-infrared radiation sphere 40 is released from the water tank 10. ) Can be taken out. Therefore, if necessary, the far-infrared radiation sphere 40 can be removed or inserted from the water tank 10 through the installation hole 36.

In any case, the far-infrared radiation sphere 40 installed in the water tank 10 as described above radiates far-infrared rays into the water in the container so that various bacteria do not form in the water, and the water is in a fresh state. Therefore, even if the water stored in the bucket is old, the taste of the water is always good, you can drink water without worrying about bacteria.

As mentioned above, although this invention was demonstrated in detail through the specific Example, this invention is not limited to the said Example, A various deformation | transformation is possible for a person with ordinary knowledge within the scope of the technical idea of this invention. In particular, the coupling method of the far-infrared radiation sphere 40 and the sealing method of the bucket 10 with respect to the bucket 10 can of course be modified according to the embodiment.

The bucket equipped with the far-infrared radiation sphere of the present invention made as described above, by installing a far-infrared radiation sphere radiating far-infrared rays inside the bucket to prevent the growth of various bacteria in the stored water, as well as the taste of the water. In particular, when the tap water is stored in the water tank, the far-infrared rays remove various odors and heavy metals in the tap water, as well as minerals in the tap water, so that the tap water can be safely consumed.

Claims (6)

An inner space consisting of a bottom surface and a wall portion and a spout portion covered with a lid, wherein the bottom surface 12 has a bucket 10 provided with an installation hole 36 sealed by a closure cap 26; The bucket is installed in the water tank (10) through the installation hole (36) to radiate far infrared rays, characterized in that the one end is provided with a far infrared radiation sphere (40) fixed to the bottom surface (12). The method of claim 1, The far infrared radiation sphere 40 is; A porous case 18 in which a plurality of through holes 24 are formed and one end thereof is supported by an edge portion of the installation hole 36; A bucket with far-infrared radiation sphere, characterized in that it comprises a far-infrared radiator (38) which is introduced into the porous case (18) to radiate far-infrared rays. The method of claim 2, The porous case 18 has a cylindrical shape, and a handle 22 is fixed to an inner circumferential surface of one end thereof so that the porous case 18 can be inserted or removed through the installation hole 36, and the mounting hole is formed on an outer circumferential surface thereof. 36 is a bucket provided with a far-infrared radiation sphere, characterized in that the support flange 20 is supported across the edge portion. The method of claim 3, wherein The closed cap 26 is a stopper having a male thread 34 is formed on the outer peripheral surface thereof, On the bottom surface corresponding to the outer side of the edge of the installation hole 36, a female thread 30 is formed to engage the male thread 34 of the sealing cap 26, and the sealing cap 26 is a female thread ( 30 is a bucket with far-infrared radiation sphere characterized in that the support flange 20 over the rim of the installation hole 36 in close contact with the rim to seal the installation hole (36). The method of claim 2, The far-infrared radiator 38 is a bucket provided with a far-infrared radiation sphere, characterized in that any one of a ceramic ball, ganban stone, germanium stone. The method of claim 2, The far-infrared radiator 38 is a bucket having a far-infrared radiation sphere, characterized in that the spiral synthetic resin member 60 formed by repeatedly folding the synthetic resin strip having a predetermined length, width and thickness in a spiral direction, .