JP2005300042A - Defrosting heater, defrosting system and refrigerator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a defrosting heater that can meet safety standards set by The Japan Electrical Manufacturers' Association against refrigerant ignition, on the surface temperature of the defrosting heater, can also meet the same safety standards on the surface temperature of an inner glass tube, can dispense with a cover member, and can suppress bumping noise caused by the evaporation of meltwater on the heater surface. <P>SOLUTION: A metal tube 2 has on an outer surface 21 a first coating of a radioactive material higher in far infrared emissivity than the metal that composes the metal tube and higher in far infrared emissivity about a wavelength causing ice to melt than about any other wavelength, and has on an inner surface 22 a third coating of a radioactive material higher in far infrared absorptivity at 394°C or higher than the metal that composes the metal tube and insusceptible to thermal decomposition at the ignition temperature of isobutane. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a defrosting heater for defrosting a refrigerator of a household refrigerator, a defrosting system using the heater, and a refrigerator having the heater. Here, the refrigerator is a concept including a freezer and a refrigerated freezer.

  As a refrigerant for a refrigerator cooler, isobutane, which is a hydrocarbon-based refrigerant, has come to be used in response to a request for environmental regulations such as prevention of ozone layer destruction and prevention of global warming. Isobutane is a flammable medium and ignites at 494 ° C., unlike alternative chlorofluorocarbon, which is a conventional refrigerant. Therefore, when isobutane is used as a refrigerant, if a defrost heater whose surface temperature is increased to near the ignition point of isobutane is used, there is a risk of ignition or explosion when the refrigerant leaks. Therefore, the Japan Electrical Manufacturers' Association stipulates that the surface temperature of the defrost heater when isobutane is used as a refrigerant must be less than 394 ° C., which is 100 ° C. lower than the ignition point of isobutane.

  By the way, as a defrost heater, the thing of the single glass tube structure formed by inserting a heating wire in a glass tube has been generally used conventionally. However, in a defrost heater having a single glass tube structure, the surface temperature of the glass tube reaches about 450 ° C. in an open empty state. Therefore, it is no longer possible to use a conventional single glass tube structure as a defrosting heater when isobutane is used as a refrigerant.

  Thus, a defrost heater having a double glass tube structure as shown in Patent Document 1 has been developed. This is made by inserting a glass tube through which a heating wire is inserted into a glass tube having a larger diameter. According to this, since the outer glass tube has a large surface area, the surface temperature is suppressed to about 352 ° C., and the safety standard defined by the Japan Electrical Manufacturers' Association can be satisfied.

  However, in the defrosting heater having a double glass tube structure, the frost on the surface of the cooler is melted by the defrosting heater, and cold water and ice pieces fall from the surface of the cooler, resulting in a high temperature on the outer glass tube surface. The glass tube on the outside may be damaged. Therefore, in order to prevent this, a structure is adopted in which the defrost heater is covered from above with an umbrella member made of metal.

However, when a structure covered with an umbrella member is employed, there are the following problems.
(1) Space and cost for arranging the umbrella member are necessary.
(2) Since the heat applied to the cooler from the defrost heater is blocked by the umbrella member, the thermal efficiency of the defrost heater is reduced.

In view of this, a defrosting heater having a double pipe structure having a metal tube on the outside as shown in Patent Document 2 has been developed.
JP 2002-195735 A JP 2004-44899 A

However, the defrosting heater having a double-pipe structure in which the outside is a metal tube has the following problems due to the high heat storage property and low heat dissipation property of the metal.
(1) The heat radiation from the metal tube toward the cooler is weak, and therefore the defrosting effect on the cooler is low.
(2) When a sealing cap made of silicon rubber is directly attached to the metal tube, the sealing cap melts and is fused to the metal tube. Therefore, the sealing cap cannot be directly attached to the metal tube, and it is necessary to provide an insulator, which increases the cost.
(3) When the metal tube expands, a gap may be formed between the metal tube and the sealing cap. If there is a gap, the isobutane refrigerant may flow into the metal tube and cause an explosion.
(4) When the inside of the metal tube becomes high temperature, the heating wire may become high temperature and break.
(5) When the frost on the surface of the cooler is melted by the defrosting heater and cold water or ice pieces fall from the surface of the cooler and collide with the surface of the metal tube, the so-called “sudden boiling” occurs. ”Occurs and a loud sound (sudden noise) is generated.

  Moreover, in a refrigerator, frost adheres not only to a cooler but also to its peripheral parts. Such peripheral parts are often arranged in a state hidden behind the cooler with respect to the defrost heater, and are in a situation where it is difficult to receive heat directly from the defrost heater. Moreover, even if it is a cooler, there exists a part located in the place where the heat from a defrost heater is hard to be transmitted. However, it is necessary to defrost such a cooler part and peripheral parts.

  Further, in the refrigerator, odor components generated from stored foods flow into the cooling space where a cooler or the like is provided to some extent. Many of the odor components dissolve in water and adhere to the cooler as frost. That is, odor components are contained in the frost of the cooler. This odor component is decomposed by the action of far infrared rays when the defrost heater is operated. However, when the defrost heater is not operated, odor components may flow in the cooling space and flow out to the outside.

  An object of this invention is to provide the defrost heater, the defrost system, and the refrigerator which can eliminate the various problems mentioned above.

  The invention described in claim 1 includes a metal tube, a glass tube inserted through the metal tube, a heating wire inserted through the glass tube, and a sealing cap that seals both ends of the metal tube and the glass tube. In the defrosting heater that performs defrosting on the refrigerator cooler, at least the outer surface of the inner and outer surfaces of the metal tube has an emissivity related to far infrared rays than the metal that is a constituent material of the metal tube. A coating film made of a highly radioactive material is formed, and at least the coating film formed on the outer surface contains ceramic powder or deodorizing powder.

  As the metal that is a constituent material of the metal tube, aluminum is mainly used because it is inexpensive and easy to process, but copper, iron, titanium, or the like may be used. In addition, the metal mentioned here is the concept also including the alloy.

As the radioactive material, for example, the following three types can be used.
・ Organic polymer materials.
A composite material of an oxide material, a carbon material, etc. and the above organic polymer material.
A composite material of an oxide material, a carbon material, a carbide material, etc. and the above inorganic polymer material.

  As the organic polymer material, it has a physical property that can be easily applied alone or diluted in a solvent, and the formed coating film has high adhesion to metals and non-metals, high hardness, A material having high toughness can be used, and a silicon resin, a silicon-modified resin, a fluorine resin, a xylene resin, an acrylic resin, an epoxy resin, an amino resin, or the like can be used depending on the use temperature.

As the oxide material, heat-resistant and highly radioactive TiO ₂ , SiO ₂ , ZrO ₂ , Fe ₂ O ₃ , Cu ₂ O, or the like can be used. As the carbon material, heat-resistant and highly radioactive carbon black, graphite, or the like can be used. As the carbide material, heat-resistant and highly radioactive TaC, ZrC, SiC, BC, or the like can be used.

  As the ceramic, magnesia, alumina, silicon carbide, zeolite, or the like can be used. Two or more of these may be used together. The amount to be contained is preferably 5 to 10% by weight. Other porous powders may be used in place of the ceramic powder.

  As the deodorizing powder, zeolite or ceramics having a deodorizing function can be used. Two or more of these may be used together. The amount to be contained is preferably 5 to 10% by weight.

  The invention according to claim 2 is the invention according to claim 1, wherein the coating film is formed on the outer surface and the inner surface of the metal tube, respectively, and the coating film formed on the outer surface is formed of ceramic powder. Body or deodorizing powder.

  The invention according to claim 3 includes a metal tube, a glass tube inserted through the metal tube, a heating wire inserted through the glass tube, and a sealing cap that seals both ends of the metal tube and the glass tube. In the defrost heater that defrosts the refrigerator cooler, the emissivity for far infrared rays is higher on the outer surface of the metal tube than the metal that is a constituent material of the metal tube, and ice is added. A coating made of a radioactive material is formed, which has a higher emissivity for far-infrared rays at wavelengths to be melted than emissivity for far-infrared rays at other wavelengths, and is generated on the inner surface of the metal tube at 394 ° C. or higher. It is characterized in that a coating film made of a radioactive material, which has a higher absorptivity with respect to far-infrared than that of the metal that is a constituent material of the metal tube and does not thermally decompose at the ignition temperature of isobutane, is formed.

  The invention according to claim 4 is the invention according to claim 3, wherein the radioactive material applied to the outer surface of the metal tube has an emissivity at 200 to 300 ° C. of 0.85 or more, and the inner surface of the metal tube The radioactive material applied to the material has an emissivity at 400 to 500 ° C. of 0.85 or more.

  The invention according to claim 5 is the invention according to claim 3, wherein the coating film formed on at least the outer surface of the metal tube contains ceramic powder or deodorizing powder.

  The invention according to claim 6 is the invention according to claim 1 or 3, wherein at least one of the inner surface and the outer surface of the metal tube is an uneven surface.

  The irregularities may be regular or irregular. In addition, as a method for forming the unevenness, for example, a method of roughening by blasting or the like, or a method of groove processing by, for example, knurl can be used.

  The invention according to claim 7 is the invention according to claim 6, wherein the unevenness of the outer surface of the metal tube is constituted by a number of grooves formed in the longitudinal direction of the metal tube.

  The invention according to claim 8 is the invention according to claim 1 or 3, wherein the metal tube has a surface area of 1.5 times or more the surface area of the glass tube.

  The invention according to claim 9 is the invention according to claim 1 or 3, wherein the coating film made of a radioactive material on the outer surface of the metal tube corresponds to the effective heat generation portion of the heating wire in the longitudinal direction of the metal tube. The coating film which consists of a deodorizing material is formed in the area | region of the outer surface other than this area | region.

As a deodorizing material, the following can be used according to the target odor.
・ Titanium oxide, magnesium oxide, calcium oxide, etc. These are particularly effective for the hydrogen sulfide odor.
-Copper oxide, copper chloride, etc. These are particularly effective for hydrogen sulfide odor, trimethylamine odor, and methyl mercaptan odor.
・ Zinc oxide, aluminum oxide, silicon oxide, etc. These are particularly effective for ammonia odor, hydrogen sulfide odor, trimethylamine odor, and methyl mercaptan odor.
In addition, you may use these deodorizing materials individually or in combination of 2 or more types.

  The invention according to claim 10 is the invention according to claim 1 or 3, wherein the sealing cap is directly attached to the metal tube and the glass tube. The sealing cap is generally made of silicon rubber.

  The invention according to claim 11 includes a metal tube, a glass tube inserted through the metal tube, a heating wire inserted through the glass tube, and a sealing cap that seals both ends of the metal tube and the glass tube. In the defrost heater that defrosts the refrigerator cooler, the emissivity for far infrared rays is higher on the outer surface of the metal tube than the metal that is a constituent material of the metal tube, and ice is added. A coating made of a radioactive material is formed, which has a higher emissivity for far-infrared rays at wavelengths to be melted than emissivity for far-infrared rays at other wavelengths, and is generated on the inner surface of the metal tube at 394 ° C. or higher. A coating film made of a radioactive material, which has a higher absorption rate for far infrared rays than metal, which is a constituent material of the metal tube, and does not thermally decompose at the ignition temperature of isobutane, is applied to the outer surface of the metal tube Radioactive material to The emissivity at 50 ° C. is 0.85 or more, and is a composite of an inorganic pigment and an organic polymer material containing a black pigment. The radioactive material applied to the inner surface of the metal tube is 400 to 450. The coating film formed on the outer surface of the metal tube is a composite of an inorganic pigment having an emissivity of 0.85 or more and an organic polymer material containing a black pigment, and having a ceramic powder. Or, it contains deodorizing powder, the inner surface and the outer surface of the metal tube are irregular surfaces, the irregularities are constituted by a number of grooves formed in the longitudinal direction of the metal tube, The metal tube has a surface area of 1.5 times or more with respect to the surface area of the glass tube, and the coating made of a radioactive material on the outer surface of the metal tube corresponds to an effective heat generating portion of the heating wire. The outer surface is formed in a longitudinal region of the region other than the region The region is characterized by, the coating film made of deodorizing material is formed.

  Invention of Claim 12 is equipped with the defrost heater in any one of Claim 1 thru | or 11 in the defrost system with respect to the cooler of a refrigerator, A defrost heater is not obstruct | occluded and opposes a cooler. It is characterized by being.

  A thirteenth aspect of the present invention is the invention according to the twelfth aspect of the present invention, wherein the defrost heater has a tubular shape having a flat surface facing the cooler.

  As the tubular shape, those having a polygonal cross section such as a triangular cross section and a quadrangular cross section can be used.

  The invention according to claim 14 is a refrigerator comprising a cooler and a defrost heater for the cooler, wherein the defrost heater is any one of claims 1 to 11, and It is characterized by having a reflection part that reflects and transmits far-infrared rays radiated from the defrosting heater at the blocked location.

  The invention according to claim 15 is the invention according to claim 14, wherein the reflecting portion is formed by attaching an aluminum foil.

  According to the first aspect of the present invention, since the coating film made of a radioactive material is formed on at least the outer surface of the metal tube, the far infrared rays emitted from the heating wire are actively absorbed and emitted toward the cooler. Is done. That is, when a coating film is formed only on the outer surface, the far-infrared heat emitted by the heating wire increases the surface temperature of the metal tube and is actively absorbed on the outer surface, toward the cooler. Radiated. When a coating film is formed on both the inner surface and the outer surface, the far-infrared rays emitted by the heating wire are actively absorbed on the inner surface and converted into heat, thereby raising the temperature of the metal tube. At the same time, it is actively absorbed on the outer surface and radiated towards the cooler.

  Therefore, according to invention of Claim 1, the radiation | emission of the heat | fever from a defrost heater can be increased, Therefore, a defrost effect can be improved. Moreover, since the heat generated from the heating wire can be actively and gradually dissipated successively, the temperature inside the metal tube can be suppressed low, and therefore the surface temperature of the metal tube can be suppressed to a low temperature and the safety standard can be sufficiently satisfied. .

  According to the first aspect of the present invention, since the metal pipe is provided on the outside, there is no risk of breakage even if cold water or ice pieces collide. Therefore, the umbrella member that covers the defrosting heater from above is provided. Can be made unnecessary. Therefore, the space and cost for arranging the umbrella member can be eliminated, and the defrosting system can be reduced in size and cost. Further, if the umbrella member is eliminated, the heat applied from the defrost heater to the cooler is not blocked by the umbrella member, so that heat transfer from the defrost heater to the cooler can be performed efficiently. The effect can be improved.

  Furthermore, according to the invention of claim 1, when the coating film on the outer surface contains ceramic powder, the ceramic powder which is a porous powder has gas inside, Since the gas becomes a nucleus during boiling, bumping can be effectively prevented. In addition, when the coating film on the outer surface contains deodorizing powder, the odor components flowing in the cooling space where the defrost heater is installed can be decomposed, and malodors are released from the cooling space to the outside. Can be prevented.

  According to invention of Claim 2, the effect by the invention of Claim 1 can be exhibited more reliably.

  In the invention according to claim 3, the emissivity relating to the far infrared ray having a wavelength higher than that of the metal that is a constituent material of the metal tube is higher than that of the metal that is the constituent material of the metal tube, Since the coating film which consists of a radioactive material higher than the emissivity regarding the far-infrared ray of this wavelength is formed, the following effects can be exhibited. That is, since the radioactive material has the former characteristic, the heat of the metal tube can be actively dissipated. Therefore, the radiation of heat from the defrost heater can be increased, the defrost effect can be improved, and the surface temperature of the metal tube can be suppressed low. Moreover, since the radioactive material has the latter characteristic, the ice adhering to the cooler can be melted positively, and the defrosting effect can be improved from this point.

  Furthermore, the inner surface of the metal tube has a higher absorption coefficient for far infrared rays generated at 394 ° C. or higher than that of the metal, which is a constituent material of the metal tube, and is made of a radioactive material that does not thermally decompose at the ignition temperature of isobutane. Since the film is formed, the following effects can be exhibited. That is, since the radioactive material has the former characteristics, far infrared rays generated at 394 ° C. or higher in the glass tube can be actively absorbed by the coating on the inner surface of the metal tube. Therefore, the surface temperature of the glass tube can be suppressed to less than 394 ° C. Moreover, since the radioactive material has the latter property, even if the glass tube breaks and the inside of the metal tube becomes high temperature, the coating film is not decomposed and remains inside the metal tube due to the former property of the radioactive material. Can be suppressed. Therefore, safety when the glass tube is broken can be secured.

  Therefore, according to the invention described in claim 1, the surface temperature of the metal tube can be suppressed to sufficiently satisfy the safety standard, and the surface temperature of the inner glass tube can also be suppressed to sufficiently satisfy the safety standard. Can be met. Therefore, safety can be ensured not only when isobutane leaks but also when flowing into the metal tube.

  Moreover, since the outer side is a metal tube, there is no fear of damage even if cold water or ice pieces collide, and therefore an umbrella member that covers the defrosting heater from above can be eliminated. Therefore, since heat transfer from the defrost heater to the cooler can be performed efficiently, the thermal efficiency of the defrost heater can be improved.

  Furthermore, since a coating film is formed on the outer surface of the metal tube, bumping can be buffered, and bumping noise can be suppressed.

  According to the fourth aspect of the present invention, the coating film on the outer surface of the metal tube can positively dissipate heat suitable for melting ice to the cooler, so that the defrosting effect can be improved. Moreover, since the heat of 400 ° C. or more can be actively radiated to the outside by the coating film on the inner surface of the metal tube, the temperature inside the metal tube can be suppressed to less than 394 ° C.

  According to the fifth aspect of the present invention, when the ceramic powder is contained, the ceramic powder which is a porous powder has a gas inside, and the gas has a core at the time of boiling. Therefore, bumping can be effectively prevented. Moreover, when it contains deodorizing powder, the odor component which flows through the cooling space in which the defrost heater is installed can be decomposed | disassembled, and it can prevent that a bad odor is discharge | released outside from a cooling space.

  According to the invention described in claim 6, since the heat radiation area to the outside of the metal tube can be increased by making the outer surface of the metal tube uneven, the defrosting effect can be improved. Moreover, since the heat absorption area with respect to the heat inside the metal tube can be increased by making the inner surface of the metal tube uneven, the temperature inside the metal tube can be effectively suppressed.

  According to invention of Claim 7, an uneven surface can be formed easily. Moreover, a coating film can be formed uniformly and easily. Moreover, the directionality of the heat to be radiated can be fixed.

  According to the invention of claim 8, since the heat radiation from the metal tube can be performed efficiently, even if the glass tube is broken and the heating wire is exposed, the temperature inside the metal tube can be suppressed to less than 394 ° C., Therefore, the safety when the glass tube is broken can be ensured more reliably.

  According to the ninth aspect of the present invention, even when the defrost heater is not operating, the odor component flowing in the cooling space can be decomposed by the coating film made of the deodorizing material. Therefore, it is possible to prevent malodor from being released from the cooling space to the outside.

  According to the invention described in claim 10, since the insulator interposed between the metal tube or the glass tube and the sealing cap can be made unnecessary, the manufacturing cost can be reduced.

  According to the invention of the eleventh aspect, all the effects of the inventions of the first to ninth aspects can be exhibited.

  According to invention of Claim 12, since the heat from a defrost heater can be directly transmitted to a cooler, the thermal efficiency of a defrost heater can be improved.

  According to the thirteenth aspect of the present invention, heat can be transferred straight to the cooler from the flat surface of the defrost heater facing the cooler. That is, the defrosting heater of the present invention has a portion that can transmit heat straight to the cooler in an area larger than that of a circular tubular defrosting heater. Therefore, the defrosting effect can be improved.

  According to the fourteenth aspect of the present invention, it is possible to reliably perform defrosting even at locations where the defrosting heater is blocked.

  According to invention of Claim 15, a reflection part can be provided easily.

(Embodiment 1)
FIG. 1 is a partial sectional front view of a defrosting heater according to the present embodiment, and FIG. 2 is a sectional view taken along line II-II in FIG. The defrosting heater 1 of the present embodiment has a double tube structure composed of a metal tube 2 and a glass tube 3. That is, the defrost heater 1 seals the metal tube 2, the glass tube 3 inserted through the metal tube 2, the heating wire 4 inserted through the glass tube 3, and both ends of the metal tube 2 and the glass tube 3. And a sealing cap 5 to be made. The heating wire 4 is connected to the lead wire 6 in the sealing cap 5. The sealing cap 5 is made of silicon rubber.

  The heating wire 4 has an effective heat generating portion 41 and ineffective heat generating portions 42 on both sides thereof. The effective heat generating portion 41 is a portion where the heating wire 4 actually generates heat.

  As shown in FIG. 3, a large number of grooves 211 are formed on the outer surface 21 of the metal tube 2 so as to extend in the longitudinal direction. As a result, the outer surface 21 has a concavo-convex shape as shown in FIG. In addition, a large number of grooves 221 are formed on the inner surface 22 of the metal tube 2 in the same manner as shown in FIG.

  And in the defrost heater 1 of this embodiment, the 1st coating film and the 2nd coating film are formed in the outer surface 21 of the metal pipe 2, and the 3rd coating film is formed in the inner surface 22. . In addition, illustration of these coating films is abbreviate | omitted. The first coating film is formed in a region L1 corresponding to the effective heat generating portion 41 of the heating wire 4 on the outer surface 21, and the second coating film is an ineffective heating portion of the heating wire 4 on the outer surface 21. It is formed in a region L2 corresponding to 42.

  The 1st coating film of the outer surface 21 consists of a mixture of a radioactive material and ceramic powder. The radioactive material has a higher emissivity for far-infrared rays than the metal that is the constituent material of the metal tube 2. Specifically, the composition and blending ratio of the first coating film are as shown in Table 1, for example. In addition, it may replace with ceramic powder and may contain deodorizing powder.

  The second coating film on the outer surface 21 is made of a deodorizing material. As the deodorizing material, for example, titanium oxide, magnesium oxide, aluminum oxide and the like having a deodorizing function are preferable.

  The third coating film on the inner surface 22 is made of only a radioactive material, and the radioactive material has a higher emissivity with respect to far infrared rays than the metal that is a constituent material of the metal tube 2. The radioactive material constituting the third coating film may be the same as or different from the radioactive material constituting the first coating film. Although the case of the same thing is shown in Table 2, it will become different if the compounding ratio of a solid component is changed.

  Each coating film of the outer surface 21 and the inner surface 22 is formed along the unevenness shown in FIG.

  The metal tube 2 has a surface area that is 1.5 times or more the surface area of the glass tube 3.

  The sealing cap 5 is directly attached to the metal tube 2 and the glass tube 3.

  FIG. 5 is a partial cross-sectional view of the refrigerator 8 having the defrosting heater 1 configured as described above. In the cooling space 80 of the refrigerator 8, the defrost heater 1, the cooler 71, the fan 72, fan peripheral parts, a heater mounting tool, a heater cord, a coat converging tool, a fuse, a temperature sensor, a fixing tool, and the like are arranged. Yes.

  The defrost heater 1 is disposed directly below the cooler 71 that is the object of defrosting, facing the cooler 71. Thereby, the defrost system is comprised. There is nothing to block between the defrost heater 1 and the cooler 71.

  A first reflector 91 is provided directly below the defrost heater 1. The first reflecting plate 91 is configured by attaching an aluminum foil to the surface of the ridge that receives defrost water.

  Further, the cooling space 80 of the refrigerator 8 is provided with second reflecting plates 92 at a plurality of locations. The second reflecting plate 92 is provided in such an arrangement that the heat from the defrost heater 1 can be reflected and delivered to a location where the heat from the defrost heater 1 does not reach only by going straight. The second reflector 92 is configured by attaching an aluminum foil to the side wall or ceiling of the cooling space 80.

The defrosting heater 1 having the above configuration can exhibit the following effects (1) to (9).
(1) Since the first coating film is formed on the outer surface 21 of the metal tube 2, the far-infrared heat emitted from the heating wire 4 is actively absorbed by the first coating film, and the cooler 71 Can radiate toward. Further, since the third coating film is formed on the inner surface 22, far infrared rays emitted from the heating wire 4 can be actively absorbed by the inner surface 22, and heat can be radiated from the outer surface 21 toward the cooler 71. Therefore, the radiation of heat from the defrost heater 1 can be increased, and therefore the defrost effect can be improved. In addition, since the heat generated from the heating wire 4 can be actively and gradually dissipated successively, the temperature inside the metal tube 2 can be suppressed low, and therefore the surface temperature of the metal tube 2 can be suppressed to a low temperature and the safety standard is sufficiently satisfied. be able to.

(2) Since the first coating film on the outer surface 21 of the metal tube 2 contains the ceramic powder that is a porous powder, the gas contained in the ceramic powder serves as a nucleus during boiling, thereby , Bumping can be effectively prevented. When the deodorizing powder is contained instead of the ceramic powder, the cooling space 80 in which the defrost heater 1 is installed can be deodorized.

(3) Since the outer side is the metal tube 2, there is no fear of breakage even if cold water or ice pieces collide, and therefore an umbrella member that covers the defrosting heater from above can be eliminated. Therefore, since heat transfer from the defrost heater 1 to the cooler 71 can be performed efficiently, the thermal efficiency of the defrost heater 1 can be improved.

(4) Since the outer surface 21 of the metal tube 2 has a concavo-convex shape, the heat radiation area to the outside of the metal tube 2 can be increased, and therefore the defrosting effect can be improved.

(5) Since the inner surface 22 of the metal tube 2 has a concavo-convex shape, the heat absorption area for the heat inside the metal tube 2 can be increased, and therefore the temperature inside the metal tube 2 can be effectively suppressed.

(6) Since the irregularities of the outer surface 21 and the inner surface 22 are constituted by the grooves 211 and 221, the irregular surface can be easily formed. In addition, the first to third coating films can be formed uniformly and easily. Moreover, the directionality of the heat to be radiated can be fixed.

(7) Since the metal tube 2 has a surface area of 1.5 times or more with respect to the surface area of the glass tube 3, even if the glass tube 3 is broken and the heating wire 4 is exposed, the inside of the metal tube 2 The temperature can be suppressed to less than 394 ° C. Therefore, safety when the glass tube 2 is broken can be ensured more reliably.

(8) Since the second coating film made of the deodorizing material is provided in the region L2 of the outer surface 21 of the metal tube 2, the cooling space is formed by the second coating film even when the defrosting heater 1 is not operating. Odor components flowing through 80 can be decomposed. Therefore, the odor component can be prevented from leaking from the cooling space 80 to the outside.

(9) Since the sealing cap 5 is directly attached to the metal tube 2 or the glass tube 3, the insulator interposed between them can be made unnecessary, and thus the manufacturing cost can be reduced.

  Moreover, according to the defrosting system shown in FIG.5 and FIG.6, since there is no thing between the defrosting heater 1 and the cooler 71, the heat from the defrosting heater 1 can be directly transmitted to the cooler 71. Therefore, the thermal efficiency of the defrost heater can be improved.

Furthermore, according to the refrigerator 8, the following effects (A)-(C) can be exhibited.
(A) Since the first reflecting plate 91 is provided, the heat radiated downward from the defrost heater 1 can be reflected and transmitted to the cooler 71, and thus the thermal efficiency of the defrost heater 1 can be improved.

(B) As shown in FIG. 5, since the second reflecting plate 92 is provided, defrosting can be reliably performed even at a location where the defrost heater 1 is blocked.

(C) Since the first reflecting plate 91 and the second reflecting plate 92 are configured by pasting aluminum foil, the first reflecting plate 91 and the second reflecting plate 92 can be easily provided.

In the first embodiment, the following modified structures (I) and (II) may be employed.
(I) As the 1st reflecting plate 91, you may use the cross-sectional shape of a bowl shape, or the plate shape of a flat cross-sectional shape. Also in these cases, heat radiated downward from the defrost heater 1 can be reflected and transmitted to the cooler 71, so that the thermal efficiency of the defrost heater 1 can be improved.

(II) A tubular tube having a flat surface facing the cooler 71 may be used as the metal tube 2. The metal tube 2 shown in FIG. 6 has a tubular shape with a square section and a flat surface 201. In addition, a tube with a triangular cross section or a tube with a semicircular cross section may be used. When such a metal pipe 2 is used, heat can be transferred straight from the plane 201 having a large area to the cooler 71, so that the defrosting effect can be further improved.

(Embodiment 2)
The structure of the defrosting heater 1 of this embodiment is the same as Embodiment 1 shown in FIGS.

  And in the defrost heater 1 of this embodiment, the 1st coating film and the 2nd coating film are formed in the outer surface 21 of the metal pipe 2, and the 3rd coating film is formed in the inner surface 22. . In addition, illustration of these coating films is abbreviate | omitted. The first coating film is formed in a region L1 corresponding to the effective heat generating portion 41 of the heating wire 4 on the outer surface 21, and the second coating film is an ineffective heating portion of the heating wire 4 on the outer surface 21. It is formed in a region L2 corresponding to 42.

  The 1st coating film of the outer surface 21 consists of a mixture of a radioactive material and ceramic powder. The radioactive material has a higher emissivity with respect to far infrared rays than the metal that is a constituent material of the metal tube 2, and has a higher emissivity with respect to far infrared rays having wavelengths that melt ice than that with respect to far infrared rays with other wavelengths. And the emissivity in 200-300 degreeC is a thing of 0.85 or more. Specifically, the composition and blending ratio of the first coating film are as shown in Table 1, for example.

  The second coating film on the outer surface 21 is made of a deodorizing material. As the deodorizing material, for example, titanium oxide is preferable.

  The third coating film of the inner surface 22 is made of a radioactive material, and the radioactive material has a higher absorptivity for far infrared rays generated at 394 ° C. or higher than that of the metal that is a constituent material of the metal tube, and is made of isobutane. It is not pyrolyzed at the ignition temperature, and has an emissivity of 0.85 or more at 400 to 500 ° C. Specifically, the composition and blending ratio of the third coating film are as shown in Table 3, for example.

  Each coating film of the outer surface 21 and the inner surface 22 is formed along the unevenness shown in FIG.

  The metal tube 2 has a surface area that is 1.5 times or more the surface area of the glass tube 3.

  The sealing cap 5 is directly attached to the metal tube 2 and the glass tube 3.

  FIG. 5 is a partial cross-sectional view of the refrigerator 8 having the defrosting heater 1 configured as described above. In the cooling space 80 of the refrigerator 8, the defrost heater 1, the cooler 71, the fan 72, fan peripheral parts, a heater mounting tool, a heater cord, a coat converging tool, a fuse, a temperature sensor, a fixing tool, and the like are arranged. Yes.

  The defrost heater 1 is disposed directly below the cooler 71 that is the object of defrosting, facing the cooler 71. Thereby, the defrost system is comprised. There is nothing to block between the defrost heater 1 and the cooler 71.

  A first reflector 91 is provided directly below the defrost heater 1. The first reflecting plate 91 is configured by attaching an aluminum foil to the surface of the ridge that receives defrost water.

  Further, the cooling space 80 of the refrigerator 8 is provided with second reflecting plates 92 at a plurality of locations. The second reflecting plate 92 is provided in such an arrangement that the heat from the defrost heater 1 can be reflected and delivered to a location where the heat from the defrost heater 1 does not reach only by going straight. The second reflector 92 is configured by attaching an aluminum foil to the side wall or ceiling of the cooling space 80.

The defrosting heater 1 having the above configuration can exhibit the following effects (1) to (9).
(1) Since the third coating film is formed on the inner surface 22 of the metal tube 2 and the radioactive material of the third coating film has the following characteristics, the following (a) to (c) The operational effects of can be demonstrated.

 (a) The absorptance of far infrared rays generated at 394 ° C. or higher is higher than that of the metal that is a constituent material of the metal tube 2. Thereby, far infrared rays generated at 394 ° C. or higher in the glass tube can be positively absorbed by the third coating film on the inner surface 22 of the metal tube 2. Therefore, the surface temperature of the glass tube 3 can be suppressed to less than 394 ° C.

 (b) Does not pyrolyze at the ignition temperature of isobutane. As a result, even if the glass tube 3 is broken and the inside of the metal tube 2 is heated to a high temperature, the third coating film remains without being decomposed, and the temperature inside the metal tube 2 is increased due to the characteristic (a) of the radioactive material. Can be suppressed. Therefore, safety when the glass tube 3 is broken can be secured.

 (c) The emissivity at 400 to 500 ° C. is 0.85 or more. Thereby, since the heat of 400 degreeC or more can be actively dissipated outside, the temperature inside the metal tube 2 can be suppressed to less than 394 degreeC.

  Moreover, since the 1st coating film is formed in the outer surface 21 of the metal pipe 2, and the radioactive material of the 1st coating film has the following characteristics, the following (d)-(f) The effect can be demonstrated.

 (d) The emissivity regarding far infrared rays is higher than the metal which is a constituent material of the metal tube 2. Thereby, the heat of the metal tube 2 can be actively dissipated. Therefore, the radiation of heat from the defrost heater can be increased, the defrost effect can be improved, and the surface temperature of the metal tube 2 can be suppressed low.

 (e) The emissivity of far-infrared rays with wavelengths that melt ice is higher than the emissivity of far-infrared rays with other wavelengths. Thereby, the ice adhering to the cooler can be melted positively, and the defrosting effect can be improved also from this point.

 (f) The emissivity at 200 to 300 ° C. is 0.85 or more. Thereby, since the heat suitable for melting ice can be actively dissipated to the cooler, the defrosting effect can be improved.

  Therefore, the surface temperature of the metal tube 2 can be suppressed to sufficiently satisfy the safety standard, and the surface temperature of the inner glass tube 3 can also be suppressed to sufficiently satisfy the safety standard. Therefore, safety can be ensured not only when isobutane leaks but also when it flows into the metal tube 2.

(2) Since the outer side is the metal tube 2, there is no fear of damage even if cold water or ice pieces collide, and therefore, an umbrella member that covers the defrosting heater from above can be made unnecessary. Therefore, since heat transfer from the defrost heater 1 to the cooler 71 can be performed efficiently, the thermal efficiency of the defrost heater 1 can be improved.

(3) Since the first coating film is formed on the outer surface 21 of the metal tube 2, bumping can be buffered, and bumping noise can be suppressed. And since the 1st coating film contains the ceramic powder which is porous powder, the gas which a ceramic powder has becomes a nucleus at the time of boiling, and can thereby prevent bumping effectively. .

(4) Since the outer surface 21 of the metal tube 2 has a concavo-convex shape, the heat radiation area to the outside of the metal tube 2 can be increased, and therefore the defrosting effect can be improved.

(5) Since the inner surface 22 of the metal tube 2 has a concavo-convex shape, the heat absorption area for the heat inside the metal tube 2 can be increased, and therefore the temperature inside the metal tube 2 can be effectively suppressed.

(6) Since the irregularities of the outer surface 21 and the inner surface 22 are constituted by the grooves 211 and 221, the irregular surface can be easily formed. In addition, the first to third coating films can be formed uniformly and easily. Moreover, the directionality of the heat to be radiated can be fixed.

(7) Since the metal tube 2 has a surface area of 1.5 times or more with respect to the surface area of the glass tube 3, even if the glass tube 3 is broken and the heating wire 4 is exposed, the inside of the metal tube 2 The temperature can be suppressed to less than 394 ° C. Therefore, safety when the glass tube 2 is broken can be ensured more reliably.

(8) Since the second coating film made of the deodorizing material is provided in the region L2 of the outer surface 21 of the metal tube 2, the cooling space is formed by the second coating film even when the defrosting heater 1 is not operating. Odor components flowing through 80 can be decomposed. Therefore, the odor component can be prevented from leaking from the cooling space 80 to the outside.

(9) Since the sealing cap 5 is directly attached to the metal tube 2 or the glass tube 3, the insulator interposed between them can be made unnecessary, and thus the manufacturing cost can be reduced.

  Moreover, according to the defrosting system shown in FIG.5 and FIG.6, since there is no thing between the defrosting heater 1 and the cooler 71, the heat from the defrosting heater 1 can be directly transmitted to the cooler 71. Therefore, the thermal efficiency of the defrost heater can be improved.

Furthermore, according to the refrigerator 8, the following effects (A)-(C) can be exhibited.
(A) Since the first reflecting plate 91 is provided, the heat radiated downward from the defrost heater 1 can be reflected and transmitted to the cooler 71, and thus the thermal efficiency of the defrost heater 1 can be improved.

(B) As shown in FIG. 5, since the second reflecting plate 92 is provided, defrosting can be reliably performed even at a location where the defrost heater 1 is blocked.

(C) Since the first reflecting plate 91 and the second reflecting plate 92 are configured by pasting aluminum foil, the first reflecting plate 91 and the second reflecting plate 92 can be easily provided.

In the second embodiment, the following modified structures (I) to (III) may be employed.
(I) As the 1st reflecting plate 91, you may use the cross-sectional shape of a bowl shape, or the plate shape of a flat cross-sectional shape. Also in these cases, heat radiated downward from the defrost heater 1 can be reflected and transmitted to the cooler 71, so that the thermal efficiency of the defrost heater 1 can be improved.

(II) A tubular tube having a flat surface facing the cooler 71 may be used as the metal tube 2. The metal tube 2 shown in FIG. 6 has a tubular shape with a square section and a flat surface 201. In addition, a tube with a triangular cross section or a tube with a semicircular cross section may be used. When such a metal pipe 2 is used, heat can be transferred straight from the plane 201 having a large area to the cooler 71, so that the defrosting effect can be further improved.

(III) The first coating film on the outer surface 21 of the metal tube 2 may be made of only a radioactive material without containing ceramic powder. Specifically, the radioactive material in that case is as shown in Table 4, for example.

  Since the defrosting heater 1 of the present invention has a high defrosting effect and extremely high safety, the industrial utility value is great.

It is a partial section front view of the defrost heater of the present invention. It is II-II sectional drawing of FIG. It is a front fragmentary view of a metal tube. It is a cross-sectional partial view of a metal tube. It is a section partial view of the refrigerator of the present invention. It is a figure equivalent to FIG. 2 which shows another example of a metal tube.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Defrost heater 2 Metal tube 201,202,203 Plane 21 Outer surface 211,221 Groove 22 Inner surface 3 Glass tube 4 Heating wire 41 Effective heat generation part 5 Sealing cap 71 Cooler 8 Refrigerator 91 1st reflector 92 2nd reflector

Claims (15)

A refrigerator having a metal tube, a glass tube inserted through the metal tube, a heating wire inserted through the glass tube, and a sealing cap that seals both ends of the metal tube and the glass tube. In the defrost heater that performs defrosting on
On at least the outer surface of the inner and outer surfaces of the metal tube, a coating film made of a radioactive material having a higher emissivity with respect to far infrared rays than a metal that is a constituent material of the metal tube is formed,
A defrosting heater characterized in that at least the coating film formed on the outer surface contains ceramic powder or deodorizing powder. The coating film is formed on each of the outer surface and inner surface of the metal tube,
The defrost heater according to claim 1, wherein the coating film formed on the outer surface contains ceramic powder or deodorizing powder. A refrigerator having a metal tube, a glass tube inserted through the metal tube, a heating wire inserted through the glass tube, and a sealing cap that seals both ends of the metal tube and the glass tube. In the defrost heater that performs defrosting on
On the outer surface of the metal tube, the emissivity for far infrared rays is higher than that of the metal that is a constituent material of the metal tube, and the emissivity for far infrared rays having a wavelength for melting ice is higher than the emissivity for far infrared rays of other wavelengths. A coating film made of a high radioactive material is formed,
A coating film made of a radioactive material that has a higher absorption coefficient for far-infrared rays generated at 394 ° C. or higher than the metal that is a constituent material of the metal tube on the inner surface of the metal tube, and that does not thermally decompose at the ignition temperature of isobutane, Is formed, a defrost heater. The radioactive material applied to the outer surface of the metal tube has an emissivity at 200 to 300 ° C. of 0.85 or more,
The defrost heater according to claim 3, wherein the radioactive material applied to the inner surface of the metal tube has an emissivity at 400 to 500 ° C of 0.85 or more.   The defrost heater according to claim 3, wherein the coating film formed on at least the outer surface of the metal tube contains ceramic powder or deodorizing powder.   The defrost heater according to claim 1 or 3, wherein at least one of the inner surface and the outer surface of the metal tube is an uneven surface.   The defrost heater according to claim 6, wherein the irregularities on the outer surface of the metal tube are constituted by a number of grooves formed in the longitudinal direction of the metal tube.   The defrost heater according to claim 1 or 3, wherein the metal tube has a surface area of 1.5 times or more the surface area of the glass tube.   On the outer surface of the metal tube, a coating film made of a radioactive material is formed in a region in the longitudinal direction of the metal tube corresponding to the effective heating portion of the heating wire. The defrost heater according to claim 1 or 3, wherein a coating film made of a material is formed.   The defrost heater according to claim 1 or 3, wherein the sealing cap is directly attached to the metal tube and the glass tube. A refrigerator comprising: a metal tube; a glass tube inserted through the metal tube; a heating wire inserted through the glass tube; and a sealing cap that seals both ends of the metal tube and the glass tube. In the defrost heater that performs defrosting on
On the outer surface of the metal tube, the emissivity for far infrared rays is higher than that of the metal that is a constituent material of the metal tube, and the emissivity for far infrared rays of the wavelength that melts ice is higher than the emissivity for far infrared rays of other wavelengths A coating film made of a high radioactive material is formed,
A coating film made of a radioactive material that has a higher absorptivity for far-infrared rays generated at 394 ° C. or higher on the inner surface of the metal tube than that of the metal that is a constituent material of the metal tube, and that does not thermally decompose at the ignition temperature of isobutane, Is formed,
The radioactive material applied to the outer surface of the metal tube has an emissivity at 210 to 250 ° C. of 0.85 or more, and is a composite of an inorganic pigment and an organic polymer material containing a black pigment.
The radioactive material applied to the inner surface of the metal tube is a composite of an inorganic pigment and an organic polymer material containing a black pigment whose emissivity at 400 to 450 ° C. is 0.85 or more,
The coating film formed on the outer surface of the metal tube contains ceramic powder or deodorizing powder,
The inner surface and outer surface of the metal tube are uneven surfaces,
The unevenness is constituted by a large number of grooves formed in the longitudinal direction of the metal tube,
The metal tube has a surface area of 1.5 times or more with respect to the surface area of the glass tube,
On the outer surface of the metal tube, a coating film made of a radioactive material is formed in a region in the longitudinal direction of the metal tube corresponding to the effective heating portion of the heating wire, and in the region of the outer surface other than the region, deodorizing property is formed. A defrost heater characterized in that a coating film made of a material is formed. In the defrosting system for the refrigerator cooler,
The defrost heater according to claim 1 is provided,
A defrosting system characterized in that the defrosting heater faces the cooler without obstruction.   The defrost system of Claim 12 whose defrost heater is a tubular thing which has a plane which opposes a cooler. In a refrigerator including a cooler and a defrost heater for the cooler,
The defrosting heater is one of claims 1 to 11,
A refrigerator comprising a reflection portion that reflects and transmits far-infrared radiation emitted from a defrost heater at a location blocked by the defrost heater. The refrigerator according to claim 14, wherein the reflecting portion is configured by attaching an aluminum foil.

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