KR200290829Y1 - Heater using a conductive exothermal plate - Google Patents

Abstract

The present invention relates to a radiator using a conductive plate heating element is a low-temperature heating.

The radiator of the present invention has an outer casing 2 having a front surface and a portion of an upper surface thereof, a plate heater 3 mounted vertically inside the casing 2, and a constant distance between the back surface of the plate heater 3. A heat reflecting plate 4 disposed in parallel with the plate heating element, a fan 5 installed below the plate heating element 3 inside the casing 2, and a heat reflecting plate 4 inside the casing 2. The casing (2) has a metal safety net (7) and the suction grill (9) is installed up and down on the open front, and the plate-shaped heating element (3) of the upper surface A discharge grill 8 is mounted in the space between the heat reflection plates 4.

In the heat radiator using the conductive plate heating element of the present invention, the temperature of the plate heating element is maintained at a temperature of less than 100 ° C. during operation of the radiator, so that the relative humidity of the room can be maintained higher than that of the conventional high temperature heating radiator, thereby providing a relatively high sense of heat. In addition to reducing the possibility of respiratory diseases caused by dry indoor air, the plate-like heating element is composed of a low-temperature heating element, and the surface is coated with an insulating coating layer to cause a fire. The risk is minimized, and even if a part of the body comes into contact with the heating element due to carelessness, there is an effect that the possibility of burn or electric shock is excluded.

Description

Heater using a conductive exothermal plate

The present invention equips the front and top of the radiator casing with a uniformly mixed dispersion of graphite in the cement cured body and concrete to form a plate-shaped conductive heating element, and installs a fan at the bottom of the conductive plate-shaped heating element to supply power. By a radiant heat and convection heat emitted from the front and rear surface of the plate heating element by the heat dissipator using a plate heating element to enable the heating to the space of the radiator attention.

Conventional portable stand type electric heaters, gas heaters, and wall-hung gas heaters are always exposed to the risk of fire and burns as their heating parts are maintained at a high temperature of several hundred degrees or more. As the indoor air is reduced, there is a problem that the feeling of heat decreases and adversely affects the respiratory system of the human body.

The present invention is to solve the problems of the conventional high temperature heating heater, by providing a low temperature heating radiator using a low temperature heating element that maintains a constant temperature, more specifically, the temperature of less than 100 ℃ when generating heat to heat generation The purpose of the present invention is to solve the problems of fire occurrence and thermal sensation reduction.

Another object of the present invention is to provide a conductive plate heating element for maximizing thermal efficiency by allowing the heat generated from the plate heating element to be discharged to the surroundings effectively while minimizing heat loss by heat radiation and tropical flow. To provide a used heater.

Figure 1 is a partially cutaway perspective view showing the entire structure of one embodiment of the present invention.

2 is a longitudinal cross-sectional view of the heat sink of FIG.

Figure 3 is a partially cutaway perspective view showing the plate-like heating element separated from the radiator of Figure 1;

4 is a cross-sectional view taken along the line A-A of FIG.

Figure 5 is a longitudinal cross-sectional view showing the overall structure of another embodiment of the heat sink of the present invention.

((Description of the code for the main part of the drawing))

1,1 '. Radiator 2,2 '. Casing

3,3 ', 3 ". Plate Heater 4. Heat Reflector

5,5 '. Fan 6,6 '. Control

7,7 '. Safety Net 8.8 '. Exhaust grill

9.9 '. Suction grill 11,11 '. electrode

11a. Electrode exposure section 12, 12 '. Lower support

13,13 '. Power supply terminals 15, 15 '. Operation Button

16. Temperature sensor 17. Overheat protector

The present invention has a primary technical feature of a radiator having a conductive heating element formed in a plate shape by uniformly dispersing graphite in a cement hardened body and concrete as a low temperature heating element.

In the conductive plate-like heating element of the present invention, an electrode made of copper or the like is embedded in both sides of a rectangular plate, so that when heating is applied through these electrodes, resistance heating by current flowing between the electrodes is achieved, thereby causing maximum heating of the plate-like body. It is manufactured to have the property that the temperature is maintained below 100 ℃.

On the other hand, the plate-like heating element of the present invention having the structure and characteristics as described above is mounted in an upright state inside the radiator casing with a portion of the front and top surface, and the plate-shaped heat reflecting plate at regular intervals to the rear of the plate-like heating element It is arranged in parallel with the plate-like heating element, and a blower fan (for example, a sirocco fan) is installed in the lower portion of the plate-like heating element so that the heat generated from the back of the plate-like heating element is discharged to the upper part of the casing.

Looking at the configuration of an embodiment of a radiator using a conductive plate-like heating element of the present invention as shown in Figures 1 to 4 as follows.

First, Figure 1 is a partially cutaway perspective view showing the whole structure of an embodiment of the radiator according to the present invention, Figure 2 is a longitudinal cross-sectional view of the radiator shown in Figure 1, Figure 3 is to separate the plate heating element from the radiator of Figure 1 4 is a perspective view partially cut away, and FIG. 4 is a cross-sectional view taken along the line AA of FIG.

As shown, the heat sink 1 of the present embodiment is mounted in a vertical state by being guided by an outer casing 2 having a front portion and an upper portion thereof, and guide grooves (not shown) formed on both side walls of the casing 2. On the plate-like heating element 3, the heat reflecting plate (4) arranged in parallel with the plate-like heating element at regular intervals on the back surface of the plate-like heating element (3), and the lower plate-like heating element (3) inside the casing (2) It consists of a fan (5) to be installed, and a control unit (6) embedded in the rear of the heat reflection plate (4) inside the casing (2).

At this time, the casing (2) is provided with a metal safety net (7) on the open front, the discharge grill 8 is mounted in the space between the plate-shaped heating element (3) and the heat reflection plate (4) of the upper surface. In addition, a suction grill 9 is installed below the safety net 7 on the front side of the casing 2, and a dust collecting filter 10 is installed in the space between the suction grill 9 and the fan 5 to radiate heat from the room. (1) is configured to collect dust and the like contained in the air flowing into the interior.

The plate-shaped heating element 3 has a structure in which electrodes 11 made of a pair of copper rods are embedded on both sides thereof, as shown in FIGS. 3 and 4, and the lower end of the electrode 11 is exposed. The electrode exposed portion 11a is held in contact with the power supply terminal 13 formed on the lower support 12 that supports the lower end of the plate heating element 3 when held in the casing 2. The power supply terminal 13 is composed of an elastic coil spring or a leaf spring, for example, and elastically in close contact with the electrode exposed portion 11a, and is connected to the controller 6 through the wire 14. have.

The plate-like heating element 3 is produced by compression molding or extrusion molding a slurry obtained by adding an appropriate amount of water to a mixing composition of cement and graphite, for example, into a plate shape, the electrode 11 embedded therein May be formed integrally at the same time as the compression or extrusion molding or by drilling a hole on both sides of the plate-shaped heating element (3) through a separate processing process after the cement concrete molding and the electrode may be inserted therein. At this time, it is preferable that the position of the electrode 11 embedded in the plate heating element 3 is located at both edges of the plate heating element 3 so as to evenly heat the entire area of the plate heating element 3. .

On the other hand, specific matters relating to the electrical characteristics, such as the composition and the molding method of the plate-shaped heating element (3) is shown in the prior application (application number: Patent Application Nos. 97-24179 and 97-65544) by the present applicant.

The plate heating element 3 is covered with an insulating coating layer ec made of a resin such as epoxy over the entire outer circumferential surface thereof, and even if a part of the human body contacts the plate heating element 3 due to carelessness during operation of the radiator. It is desirable to prevent safety accidents.

Next, the heat reflection plate 4 is a thin plate body provided with heat resistance to serve to reflect the heat emitted from the back surface of the plate heating element 3 installed in front of the heat reflection plate 4 and formed on the inner surfaces of both side walls of the casing 2. It is inserted into and supported by a guide groove (not shown).

On the other hand, the control unit 6 performs control including driving and stopping of the radiator by a signal from the operation button 15 formed on one outer surface of the casing 2, and the control unit 6 controls the plate-shaped heating element 3. The temperature detector 16, which is connected to each other to detect the current temperature of the plate heating element, and the overheat protector 17, which cuts off the power when the temperature of the plate heating element is overheated above a predetermined set temperature, are connected.

At this time, the overheat protector 17 is set such that the operation of the radiator 1 is stopped when the temperature of the plate heater 3 exceeds 100 ° C.

Arrow A in the figure shows the movement of the radiant heat emitted through the front surface of the plate heating element 3, arrow B from the space portion between the plate heating element 3 and the heat reflection plate 4 by the drive of the fan (5). The movement of the convection heat discharged to the upper part of the radiator 1 is shown.

Looking at the heating process by the radiator using the plate-shaped heating element of the present invention embodiment made of such a structure as follows.

First, when the operation of the radiator 1 is performed by operating the operation button 15, power is supplied to the plate-shaped heating element 3 to generate heat, and the driving of the fan 5 is started so that the air in the room is It is sucked through the suction grill (9) is discharged to the discharge grill 8 through the space between the plate-like heating element (3) and the heat reflection plate (4).

At this time, since the front surface of the plate heating element 3 is in direct contact with the air in the room, radiant heat is emitted from the front surface of the plate heating element 3, and by the heat and the heat reflecting plate 4 emitted from the back of the plate heating element. The reflected heat is discharged through the discharge grill 8 provided on the upper surface of the casing of the radiator by a path as indicated by arrow B by the driving of the fan 5.

The plate-like heating element (3) is designed and manufactured to be maintained at a temperature of less than 100 ℃ in the nature of the material, so that in normal operating state it will always maintain a heating state of less than 100 ℃.

When the temperature of the plate heating element 3 exceeds the predetermined heating temperature range (for example, more than 100 ° C.) during the operation of the radiator according to the present invention, such an overheating state is caused by the temperature sensor 16. When the overheating condition is detected, the overheat protector 17 is operated to stop the supply of power so that the operation of the radiator is stopped.

The present invention is a structure different from the above-described embodiment, in which the two plate heaters are mounted inside the casing in parallel with each other in a state where a predetermined interval is maintained, and the radiator is configured by installing a fan under the plate heaters. The heat radiation is made at the front and rear of the heat sink, and at the same time, the continuous convection of the heat emitted from the rear surface of the two plate-shaped heating elements is driven by the fan, and FIG. 5 shows the structure of such a double-sided heating chamber radiator. Giving.

That is, Figure 5 is a longitudinal cross-sectional view showing the overall structure of the heat sink of the embodiment of the present invention, as shown in the heat sink 1 'of the present embodiment, the front and rear and the upper surface of the outer casing 2' A pair of plate-shaped heating elements 3 'and 3 "guided to guide grooves (not shown) formed on both side walls of the casing 2' and mounted in a vertical state in parallel with each other while maintaining a constant distance from each other, A fan 5 'installed under the plate-shaped heating elements 3' and 3 "inside the casing 2 ', and a control unit 6' embedded under the fan 5 'inside the casing 2; Is made of.

At this time, the casing (2 ') is provided with a metal safety net (7') is installed on the front, the rear, the opening, and the discharge grill (8 ') is mounted in the space between the pair of plate-shaped heating elements (3', 3 "). In addition, a suction grill 9 'is provided below each safety net 7' on the front and rear of the casing 2 ', and dust is collected in the space between the suction grill 9' and the fan 5 '. The filter 10 'is installed to collect and remove dust and the like contained in the air flowing into the radiator 1' from the inside of the room. The structure of the embedded electrode 11 ′, the power supply terminal 13 ′ in contact with the electrode, and the lower support 12 ′ supporting the lower portion of the plate heating element is illustrated in FIGS. 1 to 4 as described above. Since it is the same as in the radiator 1 of an example, description of these is abbreviate | omitted.

In the radiator 1 'of the present embodiment structure, when the radiator is started by the operation of the operation button 15', a pair of plate heaters 3 'and 3 "generate heat and discharge from the outer surface of the plate heater. The heat generated is directed directly into the room as indicated by arrow A '.

The heat generated from the rear surfaces of the plate heaters 3 'and 3 " is discharged 8' on the casing 2 'through the operation of the fan 5' mounted on the bottom of the plate heaters. That is, the fan 5 'has a suction part facing the suction grill 9' installed at the lower part of the front and rear surfaces of the casing 2 ', and its discharge port is formed on both plates. As it is installed toward the space between the heating elements 3 'and 3 ", the air in the room during the operation of the fan 5' is sucked on both sides of the intake grill 9 'under the radiator 1' as indicated by the arrow B '. Through the fan 5 'and warmed in the process of passing through the space between the plate heaters 3' and 3 "(in other words, after heat exchange), and then back to the room through the discharge grill 8 '. The indoor air flow is continuously made when the fan 5 'is operated.

As described above, in the radiator using the plate-shaped heating element of the present invention, the temperature of the heating element is maintained at a temperature of less than 100 ℃ during operation of the radiator, so that the relative humidity of the room can be maintained relatively high compared to the conventional high temperature heating radiator. In addition, there is an advantage of providing a high sense of warmth and also has the advantage of reducing the likelihood of respiratory disease caused by the drying of indoor air.

On the other hand, the conventional heat transfer equation radiator is mainly a conductive plate-like heating elements of Nichrome wire, such as the subject innovation resistivity of 10 ^-3 to ΩCm degree of metal wire was given a resistance in a state formed with a long length in a small cross-section compared with the heat generation of the works 10 ⁰ It is a special heating element with a specific resistance of ΩCm. It is a method of generating heat by having the same resistance at a short length in a large section. Thus, to the same heat to be equal to the current flowing through the resistor section and the conductive plate-like heat generating element in the case of the metal heating wire cross section is present or about 1mm ² degree devised is about 4000 ~ 5000mm ² about the intensity of the current flowing per unit area is the Since the reciprocal of the drainage, the plate-shaped heating element of the present invention significantly reduces the amount of electromagnetic waves generated as compared to the conventional metal heating wire. As a specific example, when using a general metal wire, electromagnetic waves of about 500 to 1500mG are emitted, whereas the conductive heating element of the present invention emits only a very small amount of electromagnetic waves of about 4mG.

In addition, the plate-like heating element of the present invention is composed of a low-temperature heating element and the insulation coating layer is coated on the surface thereof, thereby minimizing the risk of fire, and inadvertently burns or electric shock when a part of the body contacts the heating element. There is a significant reduction in the risk of accidents.

In addition, the present invention also has the effect of maintaining a high thermal efficiency by allowing the heating of the room by the heat radiation made in the front surface of the plate heating element and the convection heat made in the circulation of the indoor air by the fan.

Claims (6)

An outer casing 2 having a front surface and a portion of an upper surface thereof, a plate heating element 3 mounted vertically inside the casing 2, and parallel to the plate heating element at regular intervals on the back surface of the plate heating element 3. A heat reflection plate 4 formed in a state, a fan 5 installed below the plate-shaped heating element 3 inside the casing 2, and a control unit built in the rear of the heat reflection plate 4 inside the casing 2. A radiator using a conductive plate heater, characterized in that (6). The casing (2) is provided with a metal safety net (7) and a suction grill (9) up and down on the front surface of the casing 2, the space between the plate-shaped heating element (3) and the heat reflection plate (4) of the upper surface A radiator using a conductive plate heating element, characterized in that the discharge grill (8) is mounted. The plate-shaped heating element (3) according to claim 1, wherein a pair of electrodes (11) are embedded at both sides thereof, and the lower end portion of the electrode (11) is exposed so that the electrode exposed portion (11a) is mounted in the casing (2). ) Is a heat radiator using a conductive plate-shaped heating element, characterized in that configured to be in contact with the power supply terminal 13 formed on the lower support (12) supporting the lower end of the plate-shaped heating element (3). 4. The radiator according to claim 3, wherein the plate heater (3) is provided with an insulating coating layer (ec) made of an epoxy resin on its entire surface. The plate heater (3) has a temperature detector (16) for detecting the current temperature of the plate heaters and a thermal protector to cut off the power when the temperature of the plate heaters is overheated above a predetermined set temperature. 17) A radiator using a conductive plate heating element, characterized in that provided. An outer casing 2 'having front and rear surfaces and a top surface, a pair of plate-shaped heating elements 3' and 3 "mounted in parallel to each other at regular intervals inside the casing, and the casing (2 ') is installed under the plate heaters 3' and 3 "inside, and sucks indoor air from the front and rear surfaces of the lower part of the casing 2 ', and the sucked air is supplied to the pair of plate heaters 3' ( And a fan 5 'for discharging through the upper portion of the casing through the space between the 3') and a control part 6 'embedded under the fan 5' inside the casing 2; Radiator using conductive plate heating element.