KR20050123415A - Eletric heat hose structure - Google Patents

Abstract

The present invention relates to a heat transfer hose structure of an electric boiler filled with a solid particle heat storage material, and in particular, a heat storage material made of mica stone (molecule mica, biotite) or jade solid particles is embedded in a hose in which a heating wire is embedded. By distributing the mixture of mica stone (mica mica, biotite) or jade stone that emits far infrared rays in the hose itself, the heat storage material rises at an early temperature during the heating operation of the heating wire, and as the heat storage material accumulates heat for a long time after the temperature rises, In addition to maintaining warmth for a long time, far infrared rays radiated from heat storage materials and mixtures spread inside the building's rooms, which is beneficial to the human body.As solid particles are filled in the hose, it is possible to completely block leakage from the connection part of the hose, Electric boilers filled with solid particle regenerators to avoid the risk of short circuits The thermal hose structure.

Description

Electrothermal Hose Structure of Electric Boiler Filled with Solid Particle Regenerative Material {ELETRIC HEAT HOSE STRUCTURE}

The present invention relates to a heat transfer hose structure of an electric boiler filled with a solid particle heat storage material, and in particular, when the heat generation operation of the heating wire is performed, the heat storage material rises in temperature prematurely, and after the temperature rises, the heat storage material accumulates heat for a long time to warm up for a long time. And the far-infrared rays radiated from the heat storage material and the mixture are spread to the interior of the building to benefit the human body, and as solid particles are filled in the hose, it is possible to completely block leakage from the connection part of the hose, The present invention relates to a heat transfer hose structure of an electric boiler filled with a solid particle regenerative material that can escape.

In general, the ondol boiler used in domestic homes is one of the methods of heating the inside of a room where a person lives, and is to warm the inside of the room by raising the water in the boiler hose embedded in the floor to a predetermined temperature.

Such ondol has a feature that can be used in addition to keeping the room warm from ancient times.

Examples of the ondol method include briquette boilers, oil boilers, and gas boilers, and most of them heat the water in a heater installed separately from the outside and circulate the heated water to the boiler hose using a circulation pump.

However, since these oil and gas boilers require a separate installation space and use relatively expensive fuel, the fuel (oil and gas) consumption is high to compensate for the heat loss generated during the circulation of the heated water. There is a problem such as causing a waste of energy, high heat generation without requiring a separate installation space, it is possible to reduce the energy and fuel costs, it is provided with an electric boiler that can expect a poultice effect.

2 to 4 show a conventional electric boiler,

The hose device 1 of the electric boiler includes a hose 2 of a synthetic resin material having a predetermined length, a hose stopper 6 for sealing both ends of the hose 2, and a heating wire 4 housed inside the hose 2. And a salt sensor (7) filled in the hose (2) and a temperature sensor (8) for measuring the temperature of the salt solution in the filler.

The hose 2 is also applicable to an axle pipe.

3 and 4, the hose 2 is embedded to have a zigzag shape on the floor 30, the material of the hose 2 is made of PPC material in consideration of flexibility and durability, heat resistance, corrosion The hose 2 is used, and the hose 2 is provided in plural, and is hermetically connected to the connecting means 16 such as ripple or union in the middle of the hose 2.

In addition, both ends of the hose 2 are fitted with a hose plug 6 injection-molded as the same PPC material as the hose 2, the power line 3 and the temperature sensor in the center of the hose plug 6 (8) is installed while passing through keeping the airtight, the function of the hose cap 6 is to prevent the filling material 7 filled in the hose 2 to flow out.

In the inner center of the hose 2, a heating wire 4 that receives power from the power supply line 3 and generates heat is wired in the longitudinal direction, and is disposed between both ends of the heating line 4 and the end of the power supply line 3. It is electrically connected to each other via the joints 5 and 5a.

Meanwhile, the filling material 7 filled in the hose 2 is made by dissolving 80% to 90% of salt in 10% to 20% of water so that no precipitate is formed in the inside of the hose 2. Since the amount contains calcium chloride (CaCl 2), which has excellent heat storage property, the amount can have an excellent effect on the temperature rise and the elevated temperature of the salt solution, and the poultice effect is increased.

In the conventional electric boiler as described above, as shown in FIG. 4, the hose 2 is embedded in the floor 30, and the power line 3 formed at both ends of the hose 2 is separately installed outside. It is connected to the controller 22, the temperature controller 22 is connected to an external power supply (not shown) by an electric plug 24.

In the conventional electric boiler configured as described above, when the user operates the temperature controller 22 and the power is supplied to the heating wire 4 in the hose 2, the heating wire 4 generates heat to fill the temperature of the salt liquid filled in the hose 2. Will be raised. Then, the heat according to the temperature rise of the salt solution is transmitted to the floor 30 to heat the floor 30 and the inside of the room (heating). At this time, since the temperature of the salt solution is excellent in heat storage and contains a calcium chloride component that emits far-infrared rays, it can maintain the elevated temperature with a relatively small electrical energy, delay the temperature drop, and also obtain a poultice effect.

 However, since the conventional electric boiler uses salt solution as the heat storage material, not only water leakage occurs from the connection portion of the hose 2 when used for a certain period of time, but also a hose connection member having a complicated structure must be installed to prevent water leakage. Is increased, even though the heat storage property of the salt solution is excellent, the limit of the liquid is exposed to the heat retention is deteriorated, as well as a lot of time at the initial temperature rise, there was a problem that the power consumption increases.

Therefore, the present invention for solving the above problems is a built-in heat storage material made of solid particles of mica stone (mica mica, biotite) or jade stone inside the hose in which the heating wire is embedded, and the mica stone radiating far infrared rays to the hose itself. (Will mica, biotite) or a mixture of jade stone material, the heat accumulating material early rises during the heating operation of the heating wire, the heat accumulating material accumulates heat for a long time after the temperature rises, as well as the heat storage material And far-infrared rays radiated from the mixture are beneficial to the human body as it spreads inside the building's room, and solid particles are filled in the hose so that leakage from the connection part of the hose can be completely blocked and solid particles can escape the risk of short circuit of the heating wire. An object of the present invention is to provide a heat transfer hose structure of an electric boiler filled with heat storage material.

The present invention for achieving the above object,

In the heat transfer hose structure in which the heating wire is embedded in the longitudinal direction in the inner center of the hose which is buried on the floor with a predetermined length, and both ends of the hose are blocked by a hose plug in which a power line and a temperature sensor are installed.

The heat storage material is built in the hose to increase the temperature due to the heating of the heating wire, the heat storage material is characterized in that the solid powder particles having a size of 0.1mm ~ 0.5mm.

In addition, the heat storage material is characterized in that the powder particles of mica (barrage of mica, biotite) or jade.

The hose is characterized in that the mica stone (mica mica, biotite) or jade stone powder mixture material is added to the material of the synthetic resin material during extrusion molding to distribute the mica stone (mica mica, biotite) or jade particles that emit far infrared rays in the hose itself. do.

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

In the description of the present invention, the same components as in the prior art will be denoted by the same reference numerals to avoid redundant description.

According to the drawings, the biggest feature of the present invention is to fill the heat storage material (100) consisting of solid particles in the heat transfer hose (2).

The heat storage material 100 is made by pulverizing mica stones (coal mica, black mica) or jade which emits far infrared rays in the size of 0.1 ~ 0.5mm, the heat storage material 100 is charged into the hose (2).

The mica stone used as the heat storage material 100 contains a large amount of germanium, and has a feature of emitting far infrared rays when the temperature rises.

As described above, when the mica stone (mica mica, biotite) or jade powder powder is filled in the hose 2, the heat storage material 100 rapidly heats up by heating when the heating wire 4 inside the hose 2 is heated. Even after the supply of electricity to the heating wire 4 is cut off, the heating state is maintained for a long time according to the heat storage characteristics of the mica stones (coal mica, biotite) and jade.

In addition, when the heat storage material 100 is heated, a large amount of far-infrared rays are emitted from mica stones (coccinyl mica, biotite) and jade stone powder itself, and thus are transmitted into the room, thereby improving the heat and blood circulation as well as the steaming effect to those indoors. You will be able to expect such effects.

On the other hand, in the present invention, by distributing mica stones (coal mica, biotite) and jade stones in the hose 2 itself so that far infrared rays are emitted from the hose 2 itself.

That is, when the hose 2 is extruded, the hose 2 is mixed in a state in which a predetermined amount of mica stone (coal mica, biotite) and a mixed material 101 made of jade stones are mixed with a synthetic resin material which is a raw material of the hose 2. By extrusion molding, as shown in the cross-sectional view of FIG. 1, the solid powder particles (mica, mica, biotite or jade powder particles) are distributed in the hose 2 itself.

As described above, when the mica stones (coccus mica, biotite) or jade powder particles are distributed in the hose 2 itself, far infrared rays are also emitted from the hose 2 itself, so that the far infrared emission amount supplied to the room can be expected to be increased. Will be.

Table 1 below is a table showing the results of testing the temperature characteristics of the present invention and the prior art,

After the power supply to the heating wire (4) starts to generate heat is compared the temperature characteristics of the heat storage material mica stone (mica mica, biotite) and octane powder of the present invention and salt water of the conventional heat storage material.

According to the table, when the heat storage material 100 of the present invention to the size of the grains of sand after 5 minutes-35 degrees, 25 minutes-52.6 degrees early rise in temperature, when the heat storage material 100 to the flour powder level heating wire (4) It can be seen that the temperature increased sharply at the initial stage of heat generation.

     Number      time   Heat storage ash (sand grain size)   Heat storage ash (powder powder size)    Conventional heat storage material (small amount)        One      start     24.5 degrees   Early rise    24.6 degrees        2     5 minutes     35 degrees    31.8 degrees        3     Elapsed 13 minutes     48.5 degrees    41.2 degrees        4     19 minutes passed     50.8 degrees    45.3 degrees        5     25 minutes passed     52.6 degrees    47.1 degrees        6     32 minutes passed     56.7 degrees    50.4 degrees        7     38 minutes passed     56.4 degrees    50.6 degrees        8     After 42 minutes     57.7 degrees     53.7 degrees    52.2 degrees    Sum     42 minutes   33.2 degree rise     29.1 degrees    27.6 degree rise   Rise per 10 minutes     7.9 degrees     6.93 degrees   6.57 degrees

However, in the case of the conventional salt water, it can be seen that the temperature characteristic is slightly lower than the solid particle heat storage material 100 of the present invention at a level of -31.8 degrees after 5 minutes and 47.1 degrees after 25 minutes after the heating wire 4 starts to generate heat.

When the heat storage material 100 made of solid particles is charged to the hose 2 as described above, the temperature rises at a much faster rate than the conventional salt water, so that the power consumption of the electric boiler can be significantly reduced. Even if a gap occurs in the joint part of the hose 2, there is no need to worry about leakage.

In addition, once the heat storage material 100 accumulates heat, the heat accumulation characteristics of the solid and the air layer distributed between the heat storage material 100 in the hose 2 cause heat storage for a long time. Can be reduced.

As described above, the present invention incorporates a heat storage material made of mica stone (coal mica, biotite) or jade stone solid particles in a hose in which a heating wire is embedded, and emits far-infrared rays to the hose itself. Biotite) or jade mixtures are distributed, so that the heat storage material rises at an early temperature during the heating operation of the heating wire, and as the heat storage material accumulates heat for a long time after the temperature rises, the warmth is maintained for a long time, as well as in the heat storage material and the mixture material. Radiated far-infrared radiation spreads inside the building's room to benefit the human body, and solid particles accumulate to prevent leakage from the heating wire while completely blocking leakage from the connection part of the hose as solid particles are filled in the hose. The effect of providing the heat transfer hose structure of the filled electric boiler can be expected.

1 is a cross-sectional view showing the heat transfer hose structure of the electric boiler filled with the solid particle heat storage material of the present invention.

Figure 2 is a cross-sectional view showing a heat transfer hose structure for a conventional electric boiler.

Figure 3 is an installation state of the electric boiler using a conventional heat transfer hose.

4 is a state diagram used in the electric boiler using a conventional heat transfer hose.

Explanation of symbols for main parts of the drawings

1: hose, 2: hose,

3: power line, 4: heating wire,

6: hose plug, 8: temperature sensor,

100: heat storage material, 101: mixed material,

Claims (3)

A heating wire 4 is embedded in the longitudinal direction in the inner center of the hose 2 embedded in the floor with a predetermined length, and both ends of the hose 2 are attached to a hose plug 6 in which a power line and a temperature sensor are embedded. In the heat transfer hose structure blocked by The heat storage material 100, the temperature is increased by the heating of the heating wire in the interior of the hose 2, the heat storage material 100 is characterized in that the solid powder particles having a size of 0.1mm ~ 0.5mm Heat transfer hose structure of electric boiler filled with solid particle heat storage material. The method of claim 1, wherein the heat storage material 100 is a heat transfer hose structure of the electric boiler filled with solid particles heat storage material, characterized in that the powder particles of mica stone (mica mica, biotite mica) or jade. According to claim 1, wherein the hose 2 is a mica stone (mica mica, biotite) that emits far-infrared rays to the hose itself by adding a mica stone (mica mica, biotite) or jade stone powder mixture to the material of the synthetic resin material during extrusion An electrothermal hose structure of an electric boiler filled with a solid particle heat storage material, characterized in that octane particles are distributed.