KR20100092707A - Heating pad - Google Patents

Abstract

PURPOSE: A heating pad is provided to transmit heat generated from a heating layer to a triplex through a cushion layer without heat loss to the outside. CONSTITUTION: A heating pad(100) comprises a cushion layer(110), a transmitting layer(120), a heating layer(130), an insulation layer(140), and a main body layer(150). The cushion layer is formed in contact with the triplex. The heating layer is laminated on the cushion layer. The heating layer heats up by receiving power from an external power source. The main body layer is laminated on the heating layer. A honeycomb is formed in the main body. The cushion layer directly contacts the triplex positioned below the heating pad.

Description

Heating pad

The present invention relates to a heating pad. More particularly, the invention relates to a heating pad used to attach a triplex in a LNG cargo hold.

In general, insulation panels are installed in LNG cargo holds. The insulation panel has a two-stage structure including a bottom panel formed in contact with a hull and a top panel having a smaller size than the bottom panel and integrally formed on the bottom panel.

Such insulation panels are arranged in plural along the surface of the hull. At this time, a triplex is formed between the adjacently arranged pair of insulation panels to form a secondary barrier.

In order to attach the triplex, first, an adhesive such as epoxy glue is applied to the bottom surface of the triplex to be temporarily bonded to the upper side of the bottom panel. The heating pad is placed on the upper side of the triplex, and the adhesive is heated and cured for a predetermined time.

At this time, the heating pad includes a main body layer that can substantially withstand an external impact or load. Such a body layer generally consists of a plate shape made of wood, synthetic resin or plastic.

At this time, when the main body layer is wooden, the main body layer is dried during heating, and in some cases may cause a large fire accident, heat deformation and distortion may occur. In addition, when the main body layer is made of synthetic resin and plastic, it is necessary to have various molds for each size during extrusion production, and it is not possible to completely remove the warp in the longitudinal direction of the panel.

In addition, in the conventional heating pad, heat generated under the main body layer is easily leaked to the outside through the main body layer, so that the heat cannot be effectively transferred to the triplex side located below the heating pad.

Meanwhile, an air bag is disposed on the heating pad to press the heating pad so that the triplex is effectively bonded to the upper surface of the bottom panel. At this time, it is necessary to thicken the main body layer in order to increase the pressing force by the airbag. As described above, when the main body layer is thickened, if the main body layer is made of the above-described material, there is a problem in that the weight of the heating pad itself becomes heavy, making the operation difficult.

The present invention has been made to solve the above problems and the object of the invention is to provide a heating pad configured to maximize heat transfer to the triplex side.

It is another object of the present invention to provide a heating pad that is light enough to withstand loads applied from the outside.

It is another object of the present invention to provide a heating pad which is light in weight while thickening the body layer.

According to the present invention to achieve the above object, a heating pad used when attaching a triplex to the LNG cargo hold, a cushion layer formed to contact the triplex; A heat generating layer stacked on the cushion layer and generating heat by receiving power from an external power source; And a body layer stacked on the heat generating layer and having a honeycomb structure formed thereon.

At this time, the main body layer preferably comprises a honeycomb core (honeycomb core) of the honeycomb shape in which the unit cells in the hexagonal hollow machine is formed continuously.

At this time, it may further include a transfer layer located between the cushion layer and the heating layer to transfer the heat emitted from the heating layer to the cushion layer.

At this time, it may further include a heat insulating layer located between the main body layer and the heat generating layer to prevent the outflow of heat generated from the heat generating layer.

At this time, the heating layer is made of a carbon fiber fabric heating element, the heating layer may be formed with an electrode member that is energized with an external power source to apply electricity to the carbon fiber fabric heating element.

Meanwhile, an adhesive layer may be formed between the neighboring layers.

On the other hand, the transfer layer may be a temperature sensor for detecting the heat generated from the heat generating layer.

At this time, the heating pad includes a connector electrically connected to the temperature sensor and the electrode member, the connector supplies power for heating the heating pad and reads a value detected by the temperature sensor to supply power. It can be connected with a temperature control device for controlling the.

According to the present invention, since the heat insulation layer and the transfer layer are formed on the upper and lower sides of the heat generating layer, heat generated from the heat generating layer does not leak to the outside, and can be effectively transmitted to the triplex side through the cushion layer.

In addition, since the honeycomb structure made of aluminum is formed on the main body layer, the heating pad including the main body layer can withstand the external load well, and even if the thickness of the main body layer is thick, the weight of the entire heating pad is suitable for the worker to work. Can be maintained.

In addition, the thickness of the main body layer is made thick and the entire heating pad is made thick, and then an air bag is placed on the heating pad to pressurize the heating pad, thereby increasing the pressing force. Can be delivered to improve the quality of work.

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

1 is an exploded perspective view of a heating pad according to an embodiment of the present invention, Figure 2 is a schematic cross-sectional view of the heating pad according to an embodiment of the present invention. The heating pad 100 according to an embodiment of the present invention shown in FIG. 1 is a triplex (not shown) positioned below the heating pad 100 and an adhesive applied to a lower side of the triplex (not shown). ) Is used for long time heating.

For example, the heating pad 100 according to an embodiment of the present invention satisfies a triplex attachment technique (for example, a work manual or a specification), and has a predetermined length (for example, 3.5m ± 50) corresponding to the manual or specification. Cm) and width, and can be connected in parallel with a well-known external control apparatus (for example, a temperature control apparatus, etc.) in plurality.

1 and 2, the heating pad 100 according to an embodiment of the present invention includes a cushion layer 110, a transfer layer 120, a heating layer 130, a heat insulation layer 140, and a body layer 150. ).

The cushion layer 110 is in direct contact with a triplex (not shown) positioned below the heating pad 100. The cushion layer 110 withstands the corresponding pressure applied when the triplex is attached, for example, so that the adhesive applied to the bottom surface of the triplex to attach the triplex can be spread evenly on the surface. For example, it is formed so that it may have thickness of 1t-3t (where 1t = 1mm).

The cushion layer 110 preferably has flexibility and elasticity, and has a heat-resistant cushion material such as any one of a heat resistant rubber material having low high temperature strain, a heat resistant synthetic sponge, and R-PUF (reinforced polyurethane foam). .

1 and 2, a transfer layer 120 is stacked on the cushion layer 110. The transfer layer 120 is a configuration for transferring heat generated from the heat generating layer 130 to be described later to the cushion layer 110.

At this time, the transfer layer 120 has a structure for facilitating heat transfer, for example, may be manufactured in a manner that surrounds the outer surface of the inner core material made of glass fiber with aluminum foil or the like.

Such a transfer layer 120 also serves to protect not only heat transfer but also the heat generating layer 130 described later from the trauma that may occur in the cushion layer 110.

1 and 2, a heat generating layer 130 is stacked on the transfer layer 120. The heat generating layer 130 is configured to generate heat for heating a triplex (not shown) positioned below the cushion layer 110.

According to one embodiment of the invention, the heating layer 130 is made of a carbon fiber fabric heating element 132. The carbon fiber fabric heating element 132 is manufactured by impregnating pure cotton in a carbon material. In this case, impregnation means filling or infiltrating another material into pores originally present in the carbon material.

The heating layer 130 is formed with an electrode member 134 that is energized with an external power source to apply electricity to the carbon fiber fabric heating element 132. The electrode member 134 may be, for example, a copper plate, and may be formed along the upper edge of the fabric heating element 132.

The heating layer 130 is an optimized resistance value (unit ohms, ohms), such as 70 to 600 Ω per one time (1hb = 1m x 1m), so that heating can be performed during the working time of the optimum triplex attachment operation. It is preferable to have.

If it is less than 70Ω, the adhesive may not be cured due to excessive overheating or there is a risk of fire.If it is over 600Ω, the adhesive may not be sufficiently cured even if it is heated for a long time. Is understood as a critical figure.

The heating layer 130 is corrosion by utilizing the characteristics of the fiber material that compensates for the disadvantages of conventional stainless steel or nonferrous metal precision processing surface heating layer or linear heating element (eg electric heating panel) to surface heating element (eg film heater) It is free from cracking, semi-permanent use and relatively good resistance.

1 and 2, a heat insulation layer 140 is stacked on the heat generating layer 130. The heat insulation layer 140 prevents heat generated from the heat generating layer 130 from flowing out. In this case, the heat insulation layer 140 may be made of, for example, polyester. As described above, polyester has superior heat insulating properties and strength compared to plywood materials, and is relatively light.

1 and 2, the body layer 150 is stacked on the heat insulation layer 140. The body layer 150 is configured to withstand the impact that the heating pad 100 is transmitted from the outside.

According to an embodiment of the present invention, a honeycomb structure is formed in the main body layer 150. In more detail, the body layer 150 includes a honeycomb core 152 which is a honeycomb-shaped structure in which unit cells of hexagonal hollow columns are continuously formed. At this time, the upper plate 154, the lower plate 156 and the side plate 158 may be formed on the upper and lower end surfaces and side surfaces of the honeycomb core 152.

At this time, the honeycomb core 152 is preferably made of aluminum, which is lightweight and excellent in moisture resistance. In addition, the upper plate, the lower plate and the side plate 154, 156, 158 located on the upper and lower end surfaces and side surfaces of the honeycomb core 152 is also preferably made of aluminum.

Meanwhile, referring to FIG. 1, adhesive layers 161, 162, 163, and the like are laminated on the cushion layer 110, the transfer layer 120, the heat generating layer 130, the heat insulation layer 140, and the body layer 150, respectively. 164 is formed. The adhesive layers 161, 162, 163, and 164 serve to attach and fix neighboring layers.

The adhesive layers 161, 162, 163, and 164 may be formed by a coating method or have a heat-resistant adhesive material such as a double-sided heat-resistant adhesive tape in which planar flatness is maintained without being deformed at a high temperature.

The adhesive layers 161, 162, 163, and 164 have edges on the contact surfaces of the adjacent layers so as to fix the edge portions of the adjacent layers for the purpose of fabrication, reduction of material use, and increased flexibility. It may be a ring-shaped double-sided heat-resistant adhesive tape surrounding the gap, the voids 171, 172, 173, 174 corresponding to the thickness of the adhesive layer (161, 162, 163, 164) in the ring-shaped inner portion (see Fig. 2). ) May be formed.

Considering only stronger adhesive performance, the adhesive layers 171, 172, 173, and 174 are formed by fixing means such as a full-sided double-sided heat-resistant adhesive tape or any full-coated adhesive that can adhere all of the contact surfaces of neighboring layers. Can be.

On the other hand, the heating pad 100 according to an embodiment of the present invention is provided with a temperature sensor 142 for detecting the heat generated from the heat generating layer 130. In more detail, the temperature sensor 142 is installed below the heat insulation layer 140. To this end, an accommodating groove 144 for accommodating the temperature sensor 142 is formed under the heat insulating layer 140.

Referring to FIG. 1, the heating pad 100 may include a connector 180 that is electrically connected to the temperature sensor 142. The connector 180 has a sensor terminal (not shown) that electrically connects with an end of the sensor line 146 extending from the temperature sensor 142.

In this case, the connector 150 may be electrically connected to the electrode member 134 of the heating layer 130. To this end, the connector 180 has a power supply terminal (not shown) electrically connected to an end of the power supply line 136 extending from the electrode member 134.

The connector 150 supplies power for heating the heating pad 100 and reads a value sensed by the temperature sensor 142 (see FIG. 1) to control the power supply (not shown). As a means for connecting with, in one embodiment of the present invention is formed to protrude to the front side of the heating pad 100. However, if necessary, the connector 150 may be formed in various forms such as being recessed and seated in the heating pad 100.

At this time, the temperature control device is connected to the temperature input and output unit and the temperature input and output unit for receiving a temperature measurement value measured from the heating layer 130 and outputs a temperature set value corresponding to the set temperature, for example. It may include a power supply for supplying a power corresponding to the temperature set value instructed by the temperature input and output unit to the heating pad. However, the information regarding such a temperature control device is only an example, and various modifications exist and such modifications are known to those skilled in the art.

Although the heating pad according to an embodiment of the present invention has been described above, the spirit of the present invention is not limited to the embodiments presented herein, and those skilled in the art to understand the spirit of the present invention are within the scope of the same idea. Other embodiments may be easily proposed by adding, changing, deleting, or adding components, but this is also within the scope of the present invention.

1 is an exploded perspective view of a heating pad according to an embodiment of the present invention,

2 is a view schematically showing a cross section of the heating pad according to an embodiment of the present invention.

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

110: cushion layer 120: transfer layer

130: heat generating layer 140: heat insulating layer

150: main body layer 152: honeycomb core

Claims (8)

Heating pad used when attaching Triplex to LNG cargo holds, A cushion layer formed to contact the triplex; A heat generating layer stacked on the cushion layer and generating heat by receiving power from an external power source; And And a heating pad stacked on the heat generating layer, the body layer including a honeycomb structure. The method of claim 1, The main body layer is a heating pad, characterized in that the honeycomb core (honeycomb core) of the honeycomb shape is formed in a continuous unit cell in the hexagonal hollow machine. The method of claim 2, And a transfer layer positioned between the cushion layer and the heat generating layer to transfer the heat radiated from the heat generating layer to the cushion layer. The method according to any one of claims 1 to 3, And a heat insulating layer disposed between the main body layer and the heat generating layer to prevent external leakage of heat generated from the heat generating layer. The method of claim 4, wherein The heating layer is made of a carbon fiber fabric heating element, the heating layer is characterized in that the heating pad is formed with an electrode member that is energized with an external power source to apply electricity to the carbon fiber fabric heating element. The method of claim 4, wherein A heating pad, characterized in that an adhesive layer is formed between the neighboring layers. The method of claim 5, And a temperature sensor for detecting heat generated from the heat generating layer in the transfer layer. The method of claim 7, wherein The heating pad includes a connector electrically connected to the temperature sensor and the electrode member. And the connector is connected to a temperature control device for supplying power for heating the heating pad and reading a value sensed by the temperature sensor to control the supply power.

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