KR200290307Y1 - Matrix structure for arranging flexible ceramic thermistor in thermal insulation mat - Google Patents

Abstract

The present invention relates to a matrix structure of a flexible ceramic thermistor thermal insulation mat, and more specifically, by using a mat, logic arrangement of a thin film-like circuit on the upper surface, and directly on top of two plus and minus circuits. Install multiple ceramic thermistor heaters, and arrange the relationship lines vertically or horizontally between each heater so that they are parallel to each other, and hot on the opposite side between the mat and the cover. By applying a melt coating film and then covering the cover is characterized in that it provides a thermal insulation mat that is easily bent and waterproof effect.

Description

Matrix structure of flexible ceramic thermistor thermal insulation mat {MATRIX STRUCTURE FOR ARRANGING FLEXIBLE CERAMIC THERMISTOR IN THERMAL INSULATION MAT}

Thermal insulation mat composed of a typical constant temperature ceramic thermistor heater is formed of a ceramic thermistor having a rigid quadrangular body as shown in FIG. 1, the conduction method of the heater is positive and negative on both sides, and a conductive series material is coated. . In the thermal insulation mat, the conductive thermistor plate 11 is attached to the upper, lower, and negative sides of the ceramic thermistor heater 1, and then the outer surface is covered with the hard package 12. In addition, when a current flows in the upper and lower metal plates 11, the current flows to the heat generator 1, and after heat resistance work, a temperature is generated, and heat is released again by the metal plate 11 again. Since the metal plate 11 is made of a hard board, the heat insulating mat is only planar radiant heat insulating, and the use range is narrow.

Therefore, the present invention is particularly innovative in designing the arrangement method, and in addition to using the matrix arrangement of the reasonably, the thermal compresses of the heating material having a curved curved surface or a curved surface of the human body are easily bent. It is a main object of the present invention to provide a thermal insulation mat.

The present invention uses a flexible mat as a support for a circuit, and securely closes by bonding the mat and the cover mat to each other by an insulated hot melt bonding method, and also obtains a waterproof effect by the hot melt coating. To protect the second object of the present invention.

1 is a perspective view of a thermal insulation mat of the prior art;

2 is a basic explanatory diagram showing a heater installation state of the present invention;

3 is an explanatory diagram of a heat generator matrix arrangement relationship of the present invention;

Figure 4 is an explanatory view of the glue coating of the mat of the present invention;

5 is an explanatory diagram of an application example of the present invention;

6 is a view for explaining another embodiment of the present invention; And

7 is a view showing another embodiment of the present invention.

* Explanation of symbols for the main parts of the drawings

1: heat generator 2: circuit

3: mat 4: cover mat

5: heating material 6: press cover

7: pressing plate 10: thermal insulation mat

11: metal plate 12: hard package

13, 14, 15, and 16: conductive coating layers 21 and 22: conductive flakes

30,40: glue layer 31: punch hole

60: engaging plate 61, 71: insertion hole

62, 72: Book 63: Space

70: engaging plate 73: base plate

X ₁ , X ₂ : Horizontal array line Y ₁ , Y ₂ : Vertical array line

T: Thickness W: Attack Section

L: diagonal

In the configuration of the present invention, as shown in Fig. 2, the constant temperature ceramic thermistor heater 1 is used as a heat source, and the relation surfaces of the conductive metal flakes 21 and 22 are glued to the correlation surfaces at both front and rear ends thereof. . Then, after coating the conductive coating films 13 and 14, the conductive metal flakes 21 and 22 are attached to the upper surface of the mat 3 in association with each other. The mat 3 is a thin layer of heat resistant fiber fabric or synthetic resin and has an insulating heat conducting effect. The thermally conductive metal flakes 21 and 22 are arranged on the top surface of the mat 3 in a logic parallel manner, which take the form of several rows. The conductive metal flakes 21 and 22 themselves not only have a conductive function, but also have a thermal conduction effect, so that the conductive coating layers 13 and 14 provided in accordance with the negative side of the relation heat generator 1 are effectively combined, whereby the metal flakes 21, The power of 22 is passed through the heater 1 in a parallel manner. Heat generated in the heat generator 1 is distributed in the metal foils 21 and 22 due to the contact relationship between the conductive metal foils 21 and 22 in addition to the heat radiation of the heat generator 1, and also the foils 21 and 22. Since the silver is evenly distributed on the mat 3, the heat energy generated in the heat generator 1 is evenly distributed evenly across the mat 3.

3 shows a matrix relationship in which the heaters 1 of the present invention are arranged on the conductive metal flakes 21 and 22 in a plurality, and evenly distributed on the upper surface of the mat 3 shown. In addition, the vertical alignment lines (Y ₁ , Y ₂ ) adjacent to each other and the horizontal alignment lines (X ₁ , X ₂ ) adjacent to each other are parallel, and in this way, when the mat is bent, the parallel arrangement between vertical and horizontal Due to this, the large dividing line W between each heater 1 is in the same section. Therefore, when the mat is bent, the resistance of the asymmetry is reduced, and the relation angle formed on each diagonal (L) is symmetrically equal, so when the mat (3) is used, it flexibly deforms according to the curved surface of the heating object and adheres to the entire surface do.

As shown in FIG. 5, the presence of the facing section W forms a gap in each of the heaters 1, and when acting on the curved surface of the heating body 5, the mat 3 and the cover mat 4 are separated. The opposing facing section W has a flexible property, so that the whole insulating mat 10 changes according to the curved surface of the heating material 5 and is flexibly attached to the surface. In addition, since the thickness (T) of the heater (1) is much smaller than the width (W) of the facing section, the heat insulating mat can be easily bent.

As shown in FIG. 4, after arranging the conductive foils 21 and 22 on the mat 3 of the present invention, as shown in FIGS. 2 and 3, a plurality of heaters 1 are installed and again. The entire upper surface of the mat 3 is applied with the glue layer 30, and the mating surface of the cover mat 4 corresponding to the upper part is also coated with the glue layer 40 at the same time. This glue layer is a heat-resistant hot melt coating that has an insulating and waterproofing effect on itself so that after covering the mat 3 with the cover mat 4, it becomes a flat flexible insulating mat 10. As you will see later in the figure, the flat insulation mat can be bent and deformed arbitrarily, for example, when you need to heat the curved surface of the human body for physical therapy such as thermal compresses, or to keep the bottom of a cylindrical object or tableware or water jug and It can be used for warming eggplant.

As shown in Fig. 4, the mat 3 itself of the present invention is made of a flexible material such as a flexible synthetic fabric cloth made of a nonwoven fabric or a synthetic resin material woven from heat-resistant fibers, and treated with a hot melt coating (30, 40). By increasing the bonding force to the interface, and furthermore, the waterproofing effect of the coating layer has an antioxidant protection effect on the inner conductive flakes (21, 22) and each heater (1).

As shown in FIG. 6, the mat 3 and the heater 1 of the present invention are formed by tightly coupling the press cover 6, which is an external component, with the engagement plate 60, wherein the conductive coating layer 13 is formed. 14 effectively presses the conductive flakes 21 and 22. In addition, in the coupling form between the press cover 6 and the engaging plate 60, a space 63 into which the heat generator 1 can be placed is formed in the press cover 6. The outer shape of 1) is put in, and the press cover 6 acquires the effect of the objective and position fixing of the insulation with respect to the exterior. Insertion holes 61 are drilled in the corners of the press cover 6, respectively, so that the tenons 62 at opposite positions of the interlocking plate 60 can be fitted, and the tenons 62 of the interlocking plate 60 are After passing through the perforations 31 in the position of the conductive flakes (21, 22) associated with each other installed on the mat (3) is fitted into the insertion hole (61) to engage. The combination of the tenon 62 and the insertion hole 61 may adopt various connection methods such as tenon connection, rivet connection, or ring connection.

As shown in FIG. 7, the mating between the mat 3 and the heat generator 1 of the present invention is additionally used to allow electricity to flow by using the “convex” type pressing plate 7 and the engaging plate 70. In other words, the conductive coating layers 15 and 16 of the heating element are located slightly larger than the positive and negative two sides of the heating element at the correlated positive and negative poles of the conductive foils 21 and 22, respectively. It can be attached to both plus and minus sides to allow power to flow. As shown in FIG. 7, the conductive coating layer 16 formed on the negative side of the heat generator 1 is closely adhered to the conductive foil 22, and the conductive coating layer 15 of the upper electrode is pressed. After pressing with (7), the circuit is touched. However, the situation in which the pressing plate 7 is electrically conducted with respect to the conductive foil 21 is combined with the ledger 72 installed in the engaging plate 70, and then the side bottom plate 73 of the pressing plate 7 is flake 22. By being in close contact with each other, electricity flows, and the positive and negative electrodes of the conductive foils 21 and 22 are led to the conductive coating layer 15 of the heat generator 1 via the pressing plate 7. And the negative side conductive coating layer 16 is pressed down to contact the other conductive flake 22. In this configuration, a constant temperature ceramic thermistor PTC having conductive coatings on both sides of the positive and negative sides is generally installed, and the center of the width face of the engaging plate 70 is placed in a position corresponding to the thin plate 21 to be arcuately designed. After the combination with the pressing plate (7) to obtain a tension to support the pressure. In addition, both the flakes 21 and the negative-side conductive coating layer 16 can effectively maintain the force firmly in close contact.

As described above, according to the present invention, it is possible to provide a thermal insulation mat that easily bends in heat-heat insulation of a heating material having a curved curved surface or a curved surface of a human body, and furthermore, It can be used as a base, and the mat and cover mat can be tightly bonded to each other by an insulating hot melt bonding method, as well as to obtain a waterproof effect by the hot melt coating, thereby protecting each electronic component therein.

Claims (5)

In the matrix structure form of the flexible ceramic thermistor thermal insulation mat, more specifically, in a thermal compressive thermal insulation mat structure that is attached to the entire surface with respect to the heating material having a curved surface, The positive and negative conducting flakes are logically arranged on the upper surface of the flexible mat, and the multiple constant temperature ceramic thermistor heating elements are arranged on the upper part of the positive and negative conducting flakes. A matrix structure of a flexible ceramic thermistor thermal insulation mat, characterized in that it is bonded to a position, coated with a conductive coating layer so that electric power is passed through to the heater, and a flexible cover mat is covered on the upper portion, and bonded to each other with a glue layer therebetween. The method of claim 1, A matrix structure of a flexible ceramic thermistor thermal insulation mat, comprising a mat and a cover mat using a non-woven fabric made of heat-resistant fibers and having a water-resistant and heat-conductive effect between the surfaces facing each other. The method of claim 1, A matrix structure of a flexible ceramic thermistor thermal insulation mat, characterized in that the arrangement of the heaters is parallel to each other between the vertical relation lines adjacent to each other and the horizontal relation lines adjacent to each other, and the diagonal lines associated with each heater are equal in shape. The method of claim 1, A matrix structure of a flexible ceramic thermistor thermal insulation mat, which covers the heater using a cover, is engaged with the engagement plate with the mat interposed therebetween, and attaches two conductive coating layers to the conductive foil. The method of claim 1, A conductive coating layer is formed on two sides of the heater body, plus and minus, spaced apart from the mat by using the pressing plate and the engaging plate, and then through one polar circuit on one side of the pressing plate. A matrix structure of a flexible ceramic thermistor thermal insulation mat, which is brought into close contact with a thin piece of electrode.