KR20120028739A - A portable hot water supply device - Google Patents

Abstract

PURPOSE: A portable hot water supply device is provided to improve thermal efficiency by heat-exchanging water in all directions. CONSTITUTION: A portable hot water supply device(1) comprises a storage container(100), a heat exchange body(200), and multiple heat exchange pipes(300). The storage container stores water. The heat exchange body penetrates through the storage container. An inlet port(210) and an outlet port(220) are formed in both ends of the heat exchange body. The heat exchange pipes penetrate through the heat exchange body and perform heat exchange. A torch lamp(10) for jetting flames is coupled to the inlet port.

Description

Portable Hot Water Heater {A PORTABLE HOT WATER SUPPLY DEVICE}

The present invention relates to a hot water supply device, and more particularly, to a portable hot water supply device that can easily and efficiently heat the water stored in the storage box using a torch lamp.

As a hot water supply means for cooking water or boiling water for other purposes, a container which can hold water such as Kocher and the like and a burner which is a heating means are used.

A burner is generally used as a portable gas stove. A commonly used portable gas stove is provided with a container for accommodating butane cans on the side and connected to a gas supply pipe, and a flame generating unit and a cooking vessel pedestal at the top. The control lever for controlling the ignition and gas ejection amount for the ignition of the gas is provided.

However, such a gas stove has a disadvantage that it is very uncomfortable to carry in a bulky, heavy point.

In addition, since the flame emitted from the flame generating unit is closed only in the upward direction by the bottom of the container placed on the pedestal, and is exposed to the outside in all directions in the horizontal direction, the heat loss lost in the direction outside the container is high. There is a disadvantage that the thermal efficiency is not good compared to the amount of gas.

In particular, due to the nature used outdoors, the blowing is not accompanied by problems such as the flame is turned off or the heat transfer to the cooking vessel is not properly blocked.

Another gas burner is a small gas burner commonly used for mountain climbing. This burner is also equipped with a butane can can be heated to support a container containing water, but the advantage of portability compared to a portable gas stove in terms of volume and light weight.

However, such a burner also has the problems of the above-described gas stove in terms of thermal efficiency.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is to provide a portable hot water supply device manufactured to replace the above-described gas stove or gas burner with a small torch lamp.

In order to solve the above problems, a preferred embodiment of the present invention is a storage box formed so that the water is stored therein, and formed in the form of a pipe (pipe) penetrating through the storage box, the inlet and the exhaust is coupled to the storage box is formed at both ends It comprises a heat exchanger body and a plurality of heat exchanger pipes formed through the heat exchanger body and heat exchanged through the inside and the outside.

According to the present invention, in order to heat the water contained in the storage box, a small torch lamp may be carried in place of the above-described gas stove or climbing gas burner, so that portability is much improved.

In addition, since the flame ejected from the torch lamp may be located inside the inlet portion and thus is not affected by the ambient wind, heat loss may be minimized.

In addition, since the heat exchanger body penetrates the inside of the storage box, heat can be exchanged from the inside of the stored water in all directions, thereby improving thermal efficiency.

In addition, according to the heat exchange pipe, the hot air (heat) moving inside the heat exchange body is heat exchanged with the heat exchange pipe during the movement, thereby maximizing thermal efficiency.

1 is a perspective view of a portable hot water supply apparatus according to an embodiment of the present invention,
2 is a side cross-sectional view of the bin shown in FIG. 1, FIG.
3 is a sectional view showing the main parts of the inlet shown in FIG. 2;
FIG. 4 is a cross-sectional view illustrating main parts of the torch lamp coupled to the inlet shown in FIG. 3;
5 is a side cross-sectional view showing a state in which the auxiliary container is accommodated in the storage box shown in FIG.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figures 1 to 5, the portable hot water supply apparatus 1 according to an embodiment of the present invention, comprises a storage box 100, the heat exchanger body 200 and the heat exchange pipe 300.

As shown in FIGS. 1 and 2, the storage box 100 is provided with a space in which water can be stored, and may be formed in various shapes. As shown in the drawing, an example having a generally rectangular parallelepiped shape and an open top portion is shown. According to this example, it is possible to easily pour water into the storage box 100 through the open top of the storage box 100.

Meanwhile, when the storage box 100 has the aforementioned shape, the auxiliary container 110 may be further accommodated in the storage box 100 as shown in FIG. 5. According to the accommodated auxiliary container 110 may be provided a space that is isolated from the space that is outside of the auxiliary container 110 and the inside of the storage box (100). Therefore, the water containing drinking water in the auxiliary container 110 inside the storage container 100 outside the auxiliary container 110 can be used to separate the water while heating the water while separating the water.

Although not shown in another example of the storage box 100, an example in which an inlet for inflow of water into the inside of the storage box 100 is formed while the inside is hermetically sealed. The inlet is coupled with a cap for opening and closing the inlet. The inlet may also function as an outlet for outflow of water as well as inflow of water. According to this example, the storage box 100 may be transported while the water is stored therein so that the water does not leak to the outside.

The storage box 100 may be made of various materials. Specifically, it may be made of a material having high heat resistance that does not cause deformation of the shape even when directly touching the flame (F) when ejecting the flame (F) from the torch lamp 10 to be described later.

In addition, even if the material may be a little heat deformation at high temperature, the ejection position of the flame (F) such as to be located inside the heat exchanger body 200 to be described later, such as close to the storage box (100) portion and The thermal deformation by flame (F) of the storage (100) in a variety of ways, such as spaced apart between the flame (F), or by adding a separate heat-resistant member to the portion of the storage box 100 that is located close to the flame (F). Because it can be prevented, the storage box 100 may be made of a synthetic resin material. In addition, as described above, the storage box 100 may be made of a fabric.

1 and 2, the heat exchange body 200 is a medium for causing the heat supplied from the flame (F) ejected from the torch lamp 10 to be described later heat exchanged with water outside the heat exchange body (200) It is produced from a material having good thermal conductivity.

The heat exchange body 200 is provided with an air moving space therein to allow the heated air inside the heat exchange body 200 including the combustion gas generated when the flame F is ejected to move in one direction.

Therefore, the heat exchange body 200 is formed in a tubular shape with both ends opened while an air moving space is formed therein. Preferably, considering the heat exchange area of the heat exchanger body 200, efficient movement and exhaust of the heated internal air, manufacturing convenience of the heat exchanger body 200, etc., it may be generally formed in a cylindrical tube shape. However, it is not limited to the example of such a shape.

The heat exchange body 200 is disposed to penetrate the inside of the storage box 100 and both ends thereof are coupled to the storage box 100. At this time, the through hole 101 is formed in each of the two ends of the heat exchange body 200 in the storage box 100 is coupled to the end of the heat exchange body 200 through.

And various methods or means to prevent the outflow of water through the through hole 101 is used. Although not shown as a specific example, a watertight packing material is interposed between the combined outer circumferential surface of the heat exchanger body 200 and the inner circumferential surface of the through hole 101, or a waterproof adhesive such as silicone filling a gap therebetween is applied. It may be.

Alternatively, as illustrated in FIG. 3, a fastener 211 having a through hole corresponding to the through hole 101 is coupled to the storage box 100 while being disposed inside and outside of the through hole 101, and is connected to the fastener 211. As the ends of the heat exchanger body 200 are coupled, the inner circumferential surface of the fixture 211 and the outer circumferential surface of the end of the heat exchanger body 200 may be watertight by the aforementioned method or means. In the bar shown, the fixture 211 is coupled to the inner and outer sides of the storage box 100, respectively, of course, may be provided with a fixture 211 is coupled to only one side of the outer or inner.

In addition, in the case where the fastener 211 is formed, the inlet part 210 and the exhaust part 220 which will be described below do not simply mean the end of the heat exchanger body 200, but the heat exchanger body including the fastener 211 ( It can be understood to mean the end of 200, this meaning is equally applicable to the following, so the description thereof will be omitted below.

Opened one end of the heat exchange body 200 coupled to the storage box 100 is a flame (F) generated from the torch lamp 10 to be described later to be the inlet 210 through which heat is introduced, the other end opened The exhaust gas 220 is discharged to the outside.

The inlet 210 is coupled to the means for supplying heat to the heat exchanger body 200, a torch lamp (Torch lamp) can be coupled as described above as a specific example of the heat source.

The torch lamp is a flame (F) ejection device that is commonly used for home use, industrial use, etc. As an example, a torch lamp 10 commonly referred to as a gas torch shown in FIG. 1 may be used. Alternatively, various torch lamps may be used, such as a torch lamp (not shown) using oil or a torch lamp (not shown) connected to a connection hose from a gas reservoir.

The torch lamp 10 of the example shown in FIG. 1 is usually used by mounting a butane can 15. The torch lamp 10 is a device in which ignition and flame ejection are performed by an ignition means in the process of evaporating liquefied butane gas filled in the butane can 15, followed by mixing and evaporating air into vaporized butane gas. In addition, the torch lamp 10 includes a torch nozzle (not shown) having a generally cylindrical flame ejection opening 11 having a longitudinal direction in front of the front end.

The torch lamp 10 is coupled to the inlet 210 so that the flame F ejected at the front end of the flame outlet 11 is disposed at a suitable position to efficiently transfer heat to the heat exchange body 200.

At this time, if the storage box 100 is a material that is not large heat resistance, in order to prevent the thermal deformation of the storage box 100 by the heat of the flame (F) as described above, the location of the flame (F) in close proximity to the storage area, that is, It needs to be spaced apart from the side wall 102 of the reservoir 100. Therefore, the torch lamp 10 is preferably coupled to the inlet 210 such that the flame outlet 11 is inserted and positioned through the inlet 210. In this case, the inlet 210 has a larger diameter than the flame outlet 11 so that the flame outlet 11 can be inserted. And, if the flame (F) is located inside the inlet 210, even if the wind from the surrounding does not affect the flame (F) has the advantage of minimizing the heat loss.

On the other hand, various methods or means by which the torch lamp 10 is coupled to the inlet 210 may be presented. Although not shown as a specific example of the coupling method, an example such that the flame outlet 11 of the torch lamp 10 is fitted into the semi-circular fitting portion formed on the inner circumferential surface inside the inlet 210 may be combined.

Alternatively, as shown in FIG. 4, a binding ring 212 may be formed in the aforementioned fixture 211 to be used as a fixing means of the torch lamp 10. Specifically, the binding ring 212 is protruded outward from the fastener 211 disposed outside the through hole 101, the thread is formed on the outer peripheral surface. And, provided with a separate fitting port 51 that can be fitted with the flame outlet 11 is fitted, this fitting 51 is the same as the diameter of the binding ring 212 and the binding when connecting with the binding ring 212 Threads of the ring 212 and extending threads are formed on the outer circumferential surface. In addition, the outer circumferential surface of the fitting port 51 is provided with a threaded and screwed connector 52, the connector 52 is sufficient to be firmly fixed in the state in which the fitting 51 is connected to the binding ring 212 Has a width. In the process of coupling the torch lamp 10 to the inlet 210 by such a coupling means, first, the flame outlet 11 of the torch lamp 10 is inserted into the fitting hole 51, and the fitting hole in that state ( 51 is connected to the binding ring 212, and then rotates the connector 52 to move to cover the interconnection portion of the fitting port 51 and the binding ring 212.

Although the above-described binding ring 212 is not shown, it may be formed extending from the end of the heat exchange body 200, not the fixture 211.

Exhaust unit 220 is a place where the internal air of the heated heat exchanger body 200 including the combustion gas generated by the flame (F) as described above moves in the opposite direction of the inlet portion 210 and is discharged to the outside to be.

At this time, the position of the exhaust unit 220 may be formed to be located at the same height as the position of the inlet (210). That is, although not shown, the heat exchanger body 200 is generally formed in a cylindrical straight tube and is disposed horizontally in the storage box 100 so that the exhaust part 220 and the inlet part 210 may be placed at the same height.

Alternatively, as shown in FIG. 2, the location of the exhaust part 220 may be higher than that of the inlet part 210. This makes the movement of the hot air to the exhaust part 220 more smoothly by using the increase in volume expansion of the heated air along the longitudinal direction of the heat exchanger body 200 in all or some sections. This is to increase the heat conductivity in the longitudinal direction of the heat exchanger body 200 and further improve the exhaust rate.

Specifically, although not shown, an example in which the heat exchanger body 200 is linear and inclined in the storage box 100 may be formed to be higher than the inlet part 210. That is to use the lifting force of the heated air in the entire section of the heat exchange body (200).

Alternatively, as shown in FIG. 2, the heat exchange body 200 has a first horizontal portion 201 formed horizontally at the inlet portion 210 and a second horizontal portion 203 formed horizontally at the exhaust portion 220. ) And a connecting portion 202 connecting the first horizontal portion 201 and the second horizontal portion 203 may be presented. In this example, the lifting force of the heated air is used only in some sections of the heat exchanging body 200, that is, only in the sections of the connection unit 202. This is to make the inside of the heat exchanger body 200 more discharged while improving the mobility of the internal air. That is, to allow the high temperature internal air to be discharged after sufficient heat exchange with respect to the heat exchange body 200.

On the other hand, the heat exchange pipe 300 is to maximize the thermal efficiency of the present invention, it is configured to penetrate through the heat exchange body 200.

Specifically, the heat exchange pipe 300 is generally perpendicular to or shown in the flow direction with respect to the hot air moving inside the heat exchange body 200 while being coupled through at the center of the heat exchange body 200 as shown in FIG. 2. It is arranged inclined as shown. This arrangement causes friction with the moving hot air and receives heat in the process. The heat thus received is transferred to the heat exchange body 200 again to exchange heat with the water contained in the storage box 100.

The heat exchange pipe 300 may be formed of a hollow pipe having both ends fixed to the heat exchange body 200. In this case, the water contained in the storage box may be filled into the internal space of the heat exchange pipe 300, and the heat received by the heat exchange pipe 300 is exchanged with the water filled therein while being transferred to the inside.

 The heat exchange pipe 300 also slows down the speed of the moving air so that high temperature internal air is discharged after sufficient heat exchange in the heat exchange body 200.

In order to sufficiently receive the heat contained in the moving air, the heat exchange pipe 300 may be formed of a plurality of penetrating spaced apart along the longitudinal direction of the heat exchange body 200 as shown. In this case, each of the heat exchange pipes 300 receives heat sequentially during the movement of the internal air, thereby widening the surface area friction with the moving air as a whole, resulting in sufficient heat exchange from the air.

At this time, the heat exchange pipe 300 may be disposed in a substantially spiral along the longitudinal direction of the heat exchange body (200). In this arrangement, when only the straight stream toward the exhaust portion 220 of the moving air is placed, the heat exchange pipe 300 disposed behind is subjected to the air with minimal interference by the heat exchange pipe 300 disposed earlier. And as a result the overall heat exchange efficiency can be further improved. In addition, since the vortex may be formed during the movement of the air, this also helps to improve the heat exchange efficiency.

Meanwhile, in the example in which the heat exchanger body 200 is formed of the first horizontal portion 201, the second horizontal portion 203, and the connecting portion 202, the heat exchange pipe 300 is the second horizontal portion 203. It can only be formed inside. This is to cause the heat exchange action on the heat exchange pipe 300 after the air reaches the required moving speed while passing through the connecting portion 202 which is a rising section.

Since the present invention can be variously modified by those skilled in the art without departing from the scope of the claims claimed in the claims, the technical protection scope of the present invention is limited to the specific preferred embodiments described above. It is not limited.

One; Portable hot water supply device 10; Torch lamp
11; Flame outlet F; flame
15; Butane can 51; Fitting
52; Connector 100; Saved
101; Through-hole 110; Auxiliary container
200; Heat exchanger body 201; 1st horizontal part
202; Connection 203; Second horizontal part
210; Inlet 211; Fixture
212; Binding ring 220; Exhaust
300; Heat exchanger pipe

Claims (10)

A storage box configured to store water therein;
A heat exchange body formed in a pipe shape and penetrating through the storage box, and having an inlet and an exhaust part coupled to the storage box at both ends; And
Is formed through the heat exchange body, a plurality of heat exchange pipe heat exchange is made through the inside and outside;
The inlet is a portable hot water supply device, characterized in that the torch lamp for ejecting the flame is coupled.
The method of claim 1, wherein the inlet is,
And having a diameter larger than that of the flame jet port so that the flame jet port of the torch lamp is inserted, and the flame jetted from the flame jet port reaches to the inside of the sidewall of the storage box.
According to claim 1, wherein the heat exchange pipe,
Penetrates the center of the heat exchange body;
Portable hot water supply apparatus, characterized in that the overall arrangement is made in a spiral.
The method of claim 1,
The inlet portion is a portable hot water supply device, characterized in that the binding ring is formed by the torch lamp is fitted.
The method of claim 1,
Portable exhaust water heater, characterized in that the exhaust portion is formed higher than the inlet portion.
The method of claim 5, wherein the heat exchange body,
A first horizontal part horizontally formed at the inlet, a second horizontal part formed horizontally at the exhaust part, and a portable part connected to the first horizontal part and the second horizontal part Hot water device.
The method according to claim 6,
The heat exchange pipe is a portable hot water supply device, characterized in that formed only inside the second horizontal portion.
The method according to any one of claims 1 to 7,
The storage box is a portable hot water supply device, characterized in that made of synthetic resin or fabric.
The method according to any one of claims 1 to 7,
One side of the storage box is formed with an inlet formed so that water is introduced or discharged into the inside,
A cap is formed that is coupled to the inlet,
Except for the inlet, the storage box is a portable hot water supply device, characterized in that formed in a sealed form.
The method according to any one of claims 1 to 7,
The storage box is formed in the shape of a container with an upper opening,
A portable container for hot water supply, characterized in that it further comprises; an auxiliary container accommodated in the storage box.

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