KR20230129799A - Electric heater device utilizing codcuctive heat, radiant heat and convective heat - Google Patents

Abstract

The purpose of the present invention is to provide an electric stove using conductive heat, radiant heat, and convection heat. The structure of the present invention includes a stove body 110; A rear cover 120 coupled to the stove body 110; A reflector 130 coupled to the inside of the stove body 110; A warm air circulation inlet 112 formed on the reflector 130; A ceramic plate 140 coupled to the stove body 110 so as to be disposed in front of the reflector 130; a heater 150 disposed between the reflector 130 and the ceramic plate 140; the rear cover 120 and the 160; It is characterized in that it includes a warm air outlet 114 provided in the stove body 110.
The effect of the present invention is that not only does it use the conductive heat transferred from the heater to the ceramic plate, but it also radiates radiant heat to the front of the ceramic plate coupled to the stove body, and in addition radiates convection heat to the front of the stove body, so that it can be heated in a short period of time at the place where heating is desired. Because it can quickly heat the inside, it is very convenient when using it for heating in the cold winter, and by minimizing the case where the heater itself consumes electricity, it can also save energy by minimizing electricity consumption.

Description

Electric heater device utilizing coductive heat, radiant heat and convective heat}

The present invention relates to an electric heater using conduction heat, radiant heat, and convection heat. More specifically, it relates to an electric heater using conduction heat, radiant heat, and convection heat that can provide heating using radiant heat, convection heat, and conduction heat.

The electric heater is equipped with a heat wire or a heat lamp as a means of generating heat, and heat energy radiated from the heat wire or heat lamp is reflected on a reflector to heat a predetermined space.

Among electric heaters, there is a main body and a heating means inherent in the main body, and the heating means is made of a ceramic tube with a heating wire wound. When power is applied, the heat energy radiated from the heating means inherent in the main body is used for heating. Heating the space.

However, in the case of existing electric heaters, there are cases where the heating means itself consumes electricity, and the amount of electricity consumed by the heating means itself is large, which not only wastes energy, but in the existing conventional convection heating, the location of the heating device or heating part varies depending on the location of the heating device or heating part. Because the heating temperature varies greatly, excessive heating must be used to raise the temperature of the heating blind spot, which reduces heating efficiency.

In the case of existing stoves, it is common to heat the space using only radiant heat, convection heat, or conduction heat, which has the problem of reduced heating efficiency and the need to wait while feeling cold until the space is completely warmed up. there is a problem.

Korean Patent No. 10-0800119 (registered on January 25, 2008) Korean Patent No. 10-2292835 (registered on August 18, 2021) Korean Registered Utility Model No. 20-0243710 (registered on August 8, 2001)

The purpose of the present invention is to provide an electric heater using conduction heat, radiant heat, and convection heat that can efficiently heat using radiant heat, convection heat, and conduction heat, taking into account the existing problem of consuming a large amount of electricity and reducing heating efficiency. will be.

According to the present invention for solving the above problems, the stove body 110; A rear cover 120 coupled to the stove body 110; A reflector 130 coupled to the inside of the stove body 110; A warm air circulation inlet 112 formed on the reflector 130; A ceramic plate 140 coupled to the stove body 110 so as to be disposed in front of the reflector 130; a heater 150 disposed between the reflector 130 and the ceramic plate 140; A fan 160 disposed between the rear cover 120 and the reflector 130; An electric stove using conductive heat, radiant heat, and convection heat is provided, including a warm air outlet 114 provided in the stove body 110.

The radiant heat reaching the ceramic plate 140 due to the heat generation of the heater 150 is transmitted, and the radiant heat is radiated to the front of the ceramic plate 140, and the heat conducted inside by the operation of the fan 160 is transmitted. Air is converted into convection heat as a medium and is radiated more quickly to the front of the ceramic plate 140, and the radiant heat of the heater 150 is reflected toward the ceramic plate 140 by the reflector 130. It is configured to further increase the amount of radiant heat by being supplied to the front of the fan 140, and by operating the fan 160, air flows from the inside of the stove body 110 to the warm air circulation inlet 112 of the reflector 130. Enters the heater 150 and receives the heat conducted to the internal parts and turns into warm air, and the warm air is radiated through the warm air outlet 114 of the stove body 110 to the front of the stove body 110. It is characterized by allowing convection heat to be radiated more quickly.

A thermal insulation sleeve 170 is built into the stove body 110, the heater 150 is disposed inside the thermal sleeve 170, and the outer peripheral surface of the thermal sleeve 170 and the stove body 110 ) is characterized in that a certain space is secured between the inner circumferential surfaces.

The thermal sleeve 170 is made of an insulating material and blocks heat from the heater 150 from being transferred to the stove body 110.

The stove body 110 is provided with an inward protruding piece 110IP protruding toward the center, and the inner surface of the ceramic plate 140 is fixed to the front of the inward protruding piece 110IP in a state in contact with the inward protruding piece 110IP. The protruding piece 110IP is provided with a first coupling support hole 110FH communicating on both sides, and the inward protruding piece 110IP is located further outward than the first coupling hole based on the center of the stove body 110. A second coupling support hole (110SH) is provided at the position, the second coupling support hole (110SH) communicates with both sides of the inward protruding piece (110IP), and the reflector 130 is an outward protruding piece protruding from the outer peripheral surface. (132) is provided, and the outward protruding piece 132 is provided with a first coupling piece (130FP) crossing in the front-back direction, and the first coupling piece (130FP) is provided with a second coupling piece (130SP), , the second coupling piece (130SP) is disposed to face the first coupling piece (130FP), so that the first coupling piece (130FP) is connected to the first coupling support hole (110FH) of the inward protruding piece (110IP). and the second coupling piece (130SP) is inserted into the second coupling support hole (110SH) to maintain the reflector (130) firmly coupled to the stove body (110).

The outward protruding piece 132 is provided with a point contact piece 132CP pointed toward the front, and the pointed portion of the point contact piece is configured to contact the rear surface of the ceramic plate 140.

The rear of the reflector 130 is characterized in that a heat dissipation fin (130DP) is provided.

The rear of the ceramic plate 140 is supported by a spring (SRP) coupled to the reflector plate 130, so that when the ceramic plate 140 expands as the temperature rises, the spring (SPR) is pressed and the ceramic The occurrence of cracks in the ceramic plate 140 is prevented by securing a clearance for the plate 140 to expand, and when the ceramic plate 140 cools and shrinks to its original volume, the spring (SPR) expands. It is characterized by supporting and supporting the ceramic plate 140.

The present invention not only utilizes the conductive heat transferred from the heater to the ceramic plate, but also radiates radiant heat to the front of the ceramic plate coupled to the stove body, and in addition radiates convection heat to the front of the stove body, so that heating can be quickly achieved in a short period of time at the desired location. Since it can be heated easily, it is very convenient when using it for heating in the cold winter. It can also save energy by minimizing electricity consumption by minimizing the case where the heater itself consumes electricity. Accordingly, since the indoor heating temperature does not differ significantly, there is an effect of increasing heating efficiency without the need for excessive heating to raise the temperature of the heating blind spot.

Figure 1 is an exploded perspective view of the main parts of an electric heater using conduction heat, radiant heat, and convection heat according to the present invention;
Figure 2 is a side cross-sectional view showing the main parts of the electric heater using conduction heat, radiant heat, and convection heat according to the present invention in an exploded state;
Figure 3 is a perspective view of an electric heater using conduction heat, radiant heat, and convection heat according to the present invention;
Figure 4 is a side cross-sectional view of Figure 3;
Figure 5 is a front view of an electric heater using conduction heat, radiant heat, and convection heat according to the present invention;
Figure 6 is a rear view showing the internal structure of an electric heater using conduction heat, radiant heat, and convection heat according to the present invention;
Figure 7 is a side cross-sectional view of an electric heater using conductive heat, radiant heat, and convection heat according to another embodiment of the present invention;
Figure 8 is a side cross-sectional view of an electric heater using conductive heat, radiant heat, and convection heat according to another embodiment of the present invention;
Figure 9 is a side cross-sectional view showing an embodiment in which heat dissipation fins are provided on the rear of a reflector, which is the main part of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. The purpose, features, and advantages of the present invention can be more easily understood by referring to the accompanying drawings and the following detailed description. Additionally, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

Additionally, when describing the components of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are only used to distinguish the component from other components, and the nature, sequence, or order of the component is not limited by the term. When a component is described as being "connected," "coupled," or "connected" to another component, that component may be directly connected or connected to that other component, but there is no need for another component between each component. It should be understood that may be “connected,” “combined,” or “connected.”

In addition, the specific structural and functional descriptions in the present invention are merely illustrative for the purpose of explaining embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention may be implemented in various forms and may be applied in the present specification or application. It should not be construed as limited to the embodiments described in.

Figure 1 is an exploded perspective view of the main parts of an electric stove using conduction heat, radiant heat, and convection heat according to the present invention, and Figure 2 is a side cross-sectional view showing an exploded state of the main parts of an electric stove using conduction heat, radiant heat, and convection heat according to the present invention. , Figure 3 is a perspective view of an electric heater using conduction heat, radiant heat, and convection heat according to the present invention, Figure 4 is a side cross-sectional view of Figure 3, and Figure 5 is a front view of an electric heater using conduction heat, radiant heat, and convection heat according to the present invention. , Figure 6 is a rear view showing the internal structure of an electric heater using conduction heat, radiant heat, and convection heat according to the present invention, and Figure 7 is a side cross-sectional view of an electric heater using conduction heat, radiant heat, and convection heat according to another embodiment of the present invention. , Figure 8 is a side cross-sectional view of an electric heater using conduction heat, radiant heat, and convection heat according to another embodiment of the present invention.

Referring to the drawing, the electric heater using conduction heat, radiant heat, and convection heat according to the present invention includes a back cover 120, a reflector 130, and a warm air circulation inlet 112 on a stove body 110 with a warm air outlet 114. and the ceramic plate 140, the heater 150, and the fan 160 are configured to be combined. The unexplained symbol 116 in FIG. 4 is a safety net.

As shown in FIG. 2, the stove body 110 includes a cylindrical body portion 110A and a lower body portion 110B. The unexplained symbol 110TCP shown in FIG. 2 is a control PCB touch panel.

As shown in FIGS. 2 and 4, the body portion 110A is provided with an inward protruding piece 110IP protruding toward the center. Accordingly, the stove body 110 has a structure in which an inward protruding piece 110IP is provided. The body portion 110A is configured in a cylindrical shape with a front open hole and a rear open hole. In the present invention, the body portion 110A is configured in a cylindrical shape with a front open hole and a rear open hole. The hole inside the inner peripheral surface of the inward protruding piece 110IP is a front open hole.

The lower body portion 110B is a portion extending downward from the body portion 110A. As shown in FIGS. 2 and 4, the lower body portion 110B includes a vertical lower body piece connected to the lower outer peripheral surface of the body portion 110A, a proximal end connected to the vertical lower body piece, and a warm air outlet to be described later. A front extending lower body piece extending forward from the vertical lower body piece to face (114), a front end connected to the rear of the vertical lower body piece and extending to the rear of the vertical lower body piece, and the outer peripheral surface of the body portion 110A It includes rear extended lower body pieces arranged side by side.

A rear cover 120 is coupled to the rear of the stove body 110. The rear cover 120 is coupled to the rear of the stove body 110 by fixing means such as bolts and coupling bosses. A coupling boss is provided on the rear extending lower body piece of the body portion 110A and the lower body portion 110B in the stove body 110, and a bolt passing through a bolt hole communicating with both sides of the rear cover 120 is inserted into the stove body 110. The rear cover 120 is coupled to the rear of the stove body 110 by being fastened to the coupling boss. The rear cover 120 blocks the rear open hole of the stove body 110. The back plate blocks the upper rear open hole formed in the body portion 110A of the stove body 110 and the lower rear open hole formed in the lower body portion 110B.

At this time, as shown in Figures 2 and 4, the back plate is provided with air inlet holes communicating on both sides. The air inlet hole is a hole through which external air enters when the fan 160 rotates.

The reflector 130 is provided with an outward protruding piece 132 protruding from the outer peripheral surface. At this time, the base end of the horizontally extending connection reflector portion 130CP is connected to the peripheral portion of the reflector 130, and a ceramic plate support portion 130LP is coupled to some of the front ends of the connection reflector portion 130CP. The front of the reflector 130 and the rear of the ceramic plate support unit 130LP face each other, and a warm air connection discharge passage 130PA is secured between the front of the reflector 130 and the rear of the ceramic plate support unit 130LP. In addition, the hot air connection discharge passage 130PA communicates with the inner surface of the connection reflector portion 130CP in the inner space of the stove body 110 to the outer surface of the stove body 110 and the warm air connection discharge passage ( 130PA) is in communication with the warm air outlet 114 of the stove body 110.

An outward protruding piece 132 protrudes toward the inward protruding piece 110IP of the stove body 110 from the peripheral portion of the connection reflector portion 130CP and the peripheral portion of the lower reflector 130, thereby forming the inward protruding piece 110IP. It is fixed to the inward protruding piece 110IP of the stove body 110. As shown in FIG. 4, a portion of the front of the outward protruding piece 132 of the reflector 130 is fixed to the inner surface of the inward protruding piece 110IP of the stove body 110 by a coupling means such as welding, A reflector 130 may be coupled to the inside of the stove body 110. Accordingly, the reflector 130 is coupled to the inside of the stove body 110.

A warm air circulation inlet 112 is formed in the reflector 130. The warm air circulation inlet 112 communicates with the front and back of the reflector 130. When viewed from the side cross-sectional views shown in FIGS. 2 and 4, the warm air circulation inlet 112 is formed on the upper side of the reflector 130.

As shown in FIG. 3, a ceramic plate 140 is coupled to the stove body 110. A ceramic plate 140 is disposed in front of the reflector 130. The inner surface of the peripheral portion of the ceramic plate 140 is supported and coupled to the inward protruding piece 110IP of the stove body 110, so that the ceramic plate 140 is coupled to block the front open hole of the stove body 110. It becomes a structure. At this time, the ceramic plate 140 and the inward protruding piece 110IP of the stove body 110 may be configured to be joined by a bonding means such as heat-resistant silicon. The ceramic plate 140 is made of radiant heat ceramic glass.

A heater 150 is disposed between the reflector 130 and the ceramic plate 140. The heater 150 is coupled to a plurality of heater support clips 150CL. The heater support clip (150CL) is configured in a bar shape. The heater 150 is coupled to the grip piece provided at the distal end of the heater support clip 150CL. At this time, as shown in FIG. 1, the heater 150 is composed of a halogen heater 150 with a heating wire built into a circular quartz tube. The quartz tube of the heater 150 is configured to be coupled to a plurality of heater support clips 150CL. The clip piece provided at the distal end of the heater support clip 150CL grips the quartz tube of the heater 150, so that the heater support clip 150CL is coupled to the quartz tube of the heater 150. A plurality of heater support clips (150CL) are configured to be coupled to the quartz tube of the heater (150). At this time, the heater 150 may be configured as a PTC heater.

As shown in FIG. 4, the base end of the heater support clip 150CL is fixed to the reflector 130, so that the heater 150 is spaced a certain distance forward from the front of the reflector 130. ), and a heater 150 is disposed between the front of the reflector 130 and the rear of the ceramic plate 140. The heater 150 is spaced a certain distance away from the rear of the ceramic plate 140.

As shown in FIGS. 2 and 4, the fan 160 is coupled to the motor 162 shaft of the fan motor 162. The fan motor 162 is coupled to the bracket. The fan motor 162 is coupled to the bracket. The bracket is fixed to the inner surface of the back plate by a fixture such as a bolt. The inner surface of the rear plate is disposed to face the front open hole of the body portion 110A for coupling the ceramic plate 140, and the fan motor 162 is fixed to the inner surface of the rear plate, so the fan 160 It is placed at a position facing the reflector 130 disposed behind the ceramic plate 140. A fan 160 is disposed between the rear cover 120 and the reflector 130.

As shown in Figures 2 and 4, a warm air outlet 114 is provided in the stove body 110. The warm air outlet 114 communicates with the warm air connection discharge passage 130PA formed inside the stove body 110. A warm air connecting discharge passage (130PA) is secured between the front of the reflector 130 and the ceramic plate support portion 130LP, and the connecting reflector portion 130CP has a warm air connecting discharge passage 130PA communicating from the upper surface to the lower surface. It is provided, and the warm air outlet 114 is formed between the upper surface of the front extending lower body piece of the lower body portion 110B constituting the stove body 110 and a portion of the outer peripheral surface of the lower part of the stove body 110. The warm air outlet 114 communicates with the warm air discharge passage of the reflector built into the stove body 110. At this time, the warm air circulation inlet 112 of the reflector 130 communicates with the warm air outlet 114 of the stove body 110 through the space inside the stove body 110 and the warm air connection discharge passage 130PA, The warm air connection passage has a structure connected to the warm air discharge port 114.

According to the present invention of the above configuration, when the heater 150 is operated and the fan 160 is operated to rotate, external air flows into the stove body 110 through the air inlet hole of the rear cover 120. Entering the interior, some of the air enters the warm air circulation inlet 112 of the reflector 130, and the remaining air hits the rear of the reflector 130 and enters the warm air circulation inlet 112, and the heater 150 The air becomes warm air due to heat, and the conductive heat transferred from the warm air to the ceramic plate 140 is converted into radiant heat, and radiant heat is radiated to the front of the ceramic plate 140, and warm air is discharged through the warm air outlet 114. The convective heat is radiated to the front of the stove body 110.

In other words, the radiant heat reaching the ceramic plate 140 due to the heat generation of the heater 150 is transmitted, and the radiant heat is radiated to the front of the ceramic plate 140, and is conducted inside by the operation of the fan 160. The heat is converted into convection heat using air as a medium and is radiated more quickly to the front of the ceramic plate 140, and the radiant heat of the heater 150 is reflected toward the ceramic plate 140 by the reflector 130, so that the ceramic plate ( It is configured to further increase the amount of radiant heat by being supplied to the front of the fan 140, and by operating the fan 160, air from the inside of the stove body 110 enters the warm air circulation inlet 112 of the reflector 130 The heat of the heater 150 and the heat conducted to the internal parts are received and converted into warm air, and the warm air is radiated through the warm air outlet 114 of the stove body 110 and convection heat is more quickly transferred to the front of the stove body 110. Make sure it radiates properly.

To explain the structure and operating principle of the present invention again, a heater 150 that generates heat above 650°C is installed, and the heater 150 generates heat to generate radiant heat of about 450°C on the ceramic plate 140 (ceramic glass). In addition, the reflector 130 (SUS heating reflector) emits radiant heat with a heating temperature of 450°C or higher when heated by the heater 150.

At this time, the motor 162 is operated to blow wind using the fan 160 to the reflector 130, where radiant heat heated to about 450° C. is radiated, thereby first warming the wind (air). The initially warmed wind (air) is circulated through the warm air circulation inlet 112 to create a heater 150 above 650°C, a radiant heat ceramic plate 140 (radiant heat ceramic glass) heated to about 450°C, and a reflector heated to about 450°C. Pass the primary heated wind (air) through (130).

The passing wind (air) is discharged at a temperature of about 150 to 170°C from the warm air outlet 114, and at the same time as the warm air is discharged, radiant heat is emitted at a temperature of about 300°C from the ceramic plate 140.

Due to this principle, it is possible to use the exothermic heater 150 and the warm air heater 150 at the same time by applying radiant heat with one heater 150, and heat loss is also reduced by dispersing heat in two ways with one heater 150. It is a structure that uses two types of heat distribution, reducing energy consumption by more than half and enabling use of more than 100% heat distribution.

For example, it is a structure that uses radiant heat from a 1,000W heat source to produce a heat distribution greater than 2,000W of a conventional PCT heater.

Meanwhile, in the present invention, the thermal insulation sleeve 170 (thermal mica) has a structure that prevents heat from leaking or being released as much as possible.

Therefore, the present invention not only uses the conductive heat transferred from the heater 150 to the ceramic plate 140, but also radiates radiant heat to the front of the ceramic plate 140 coupled to the stove body 110, and in addition, the stove body 110 By radiating convection heat to the front of the heater, you can quickly heat the place you want to heat within a short period of time, which is very convenient when using it for heating in the cold winter. Electricity consumption is also reduced by minimizing the case where the heater itself consumes electricity. Energy savings can be achieved by minimizing the heating temperature, and since the indoor heating temperature does not vary greatly depending on the location of the heating device or heating area, there is no need to overheat to raise the temperature of the heating blind spot, thereby improving heating efficiency. It has the effect of increasing .

The present invention does not heat the heating space using only radiant heat, convection heat, or conduction heat, but rather uses conduction heat as well as radiant heat and convection heat at the same time, so the heating space is cold until it is completely warmed. It is very good in that it has the effect of solving the problem of having to wait while feeling. In other words, the present invention is very good to use for heating, especially in the cold winter, because it raises the temperature of the heating area as quickly as possible in places that require heating, such as a bathroom.

At this time, when using the present invention in a place where water is used, such as a restroom or bathroom, the ceramic plate 140 does not break even if water splashes on the ceramic plate 140, making it safer and more reliable in spaces such as a restroom. It can be used like this.

Meanwhile, the fan 160 cools the reflector 130, the heater 150, the ceramic plate 140, and the stove body 110 itself, while converting the heat of the heater 150 into convection heat to generate warm air in the stove body 110. Since it is supplied to the discharge port 114, heating efficiency is increased and burns are prevented from overheating of the stove body 110.

Meanwhile, as shown in FIGS. 2 and 4, a thermal insulation sleeve 170 is built into the stove body 110. The thermal sleeve 170 is also called a thermal mycara. The thermal sleeve 170 has a tubular shape with a space inside and openings at the front and rear ends. Since the upper body portion 110A of the stove body 110 is cylindrical, the thermal sleeve 170 is also configured to have a cylindrical shape. The distal end of the insulating sleeve 170 is fixed to the inner surface of the inward protruding piece 110IP of the stove body 110 by a coupling means such as welding, so that the insulating sleeve 170 is provided inside the stove body 110. Can be built-in.

In addition, the heater 150 is disposed inside the thermal insulation sleeve 170, and a certain space is secured between the outer peripheral surface of the thermal sleeve 170 and the inner peripheral surface of the stove body 110. The thermal sleeve 170 is made of an insulating material such as mica.

Therefore, the thermal sleeve 170 is made of an insulating material to block the heat of the heater 150 from being conducted toward the stove body 110 by the thermal insulation sleeve 170, and in particular, the outer peripheral surface of the thermal sleeve 170 and the stove body 110 ) A space is secured between the outer peripheral surfaces of the heater to prevent the heat of the heater 150 from being transferred directly to the stove body 110, thereby preventing the stove body 110 from becoming hot due to the heater 150 and causing burns. In addition, by ensuring that the heat of the heater 150 is completely supplied to the ceramic plate 140, loss of heating heat can be prevented and heating efficiency can be further increased.

Meanwhile, as shown in FIG. 7, the inward protruding piece 110IP of the stove body 110 is provided with a first coupling support hole 110FH communicating on both sides, and the inward protruding piece 110IP has a stove body. A second coupling support hole (110SH) is provided at a position more outer than the first coupling hole based on the center of (110), and the second coupling support hole (110SH) communicates with both sides of the inward protruding piece (110IP). The outward protruding piece 132 of the reflector 130 is provided with a first coupling piece 130FP that crosses in the front-back direction, and a second coupling piece 130SP is connected to the first coupling piece 130FP. , the second coupling piece (130SP) is arranged to face the first coupling piece (130FP).

The first coupling piece (130FP) is inserted into the first coupling support hole (110FH) of the inward protruding piece (110IP) of the stove body 110, and the second coupling piece (130SP) is inserted into the second coupling support hole (110SH). By being inserted into the stove body 110, the reflector 130 can be maintained in a firmly coupled state while it is embedded in the stove body 110. When coupling the reflector 130 to the stove body 110, it is quick and convenient, and the structure for coupling the reflector 130 to the stove body 110 is strengthened.

Meanwhile, as shown in FIG. 8, the outward protruding piece 132 of the reflector 130 is provided with a point contact piece 132CP pointed toward the front, and the sharp portion of the point contact piece 132CP is disposed at the ceramic plate. It is in point contact with the back of (140).

Therefore, the case where the heat of the heater 150 transferred to the ceramic plate 140 is minimized from the ceramic plate 140 to the reflector 130 is minimized, and the heat is conducted from the ceramic plate 140 toward the stove body 110. Since this shearing is minimized, there is an effect of preventing the stove body 110 from becoming hot due to conductive heat transmitted from the ceramic plate 140 and the reflector plate 130, and as a result, the stove body 110 becomes hot. It is more effective in preventing burns.

Additionally, as shown in FIG. 9, a heat dissipation fin (130DP) is provided on the rear side of the reflector 130. A plurality of heat dissipation fins 130DP are disposed at regular intervals on the back of the reflector 130.

Therefore, the cooling efficiency of the reflector 130 itself is further increased by the heat dissipation fin 130DP by the air blown when the fan 160 rotates, and the function of reflecting heat of the heater 150 from the reflector 130 is properly performed. By increasing the cooling efficiency of the reflector 130 itself, heat is conducted from the reflector 130 to surrounding objects such as the stove body 110, thereby more reliably reducing the risk of burns due to overheating of the stove body 110. It has a preventive effect.

Meanwhile, in the present invention, as shown in FIGS. 2 and 4, a reflector 130 is built into the stove body 110, and the rear of the ceramic plate 140 has a spring coupled to the reflector 130. It is configured to be supported by SRP).

As shown in FIG. 4, a pin (PN) is coupled to the inward protruding piece 110IP of the stove body 110, a spring (SPR) is coupled to the outer peripheral surface of the pin (PN), and the pin (PN) The spring (SPR) is interposed between the head (PH) and the ceramic plate support portion (130LP) of the reflector plate 130, so that the spring (SPR) is coupled to the reflector plate 130, and the ceramic plate The rear of 140 is configured to be supported by a spring (SPR) coupled to the reflector 130.

Therefore, when the ceramic plate 140 expands as the temperature rises, the spring (SPR) is pressed to secure the clearance for the ceramic plate 140 to expand, thereby suppressing the expansion of the ceramic plate 140. Since it prevents a load from being applied to 140, it has the effect of preventing cracks from occurring in the ceramic plate 140, and when the ceramic plate 140 cools and shrinks to its original volume, a spring (SPR) ) increases, the spring (SPR) firmly supports and supports the ceramic plate 140.

Above, specific embodiments of the present invention have been described in detail. However, the spirit and scope of the present invention are not limited to these specific embodiments, and it is known by common knowledge in the technical field to which the present invention pertains that various modifications and variations can be made without changing the gist of the present invention. Anyone who has it will understand.

Therefore, the embodiments described above are provided to fully inform those skilled in the art of the present invention of the scope of the invention, and should be understood as illustrative in all respects and not restrictive. The invention is defined only by the scope of the claims.

110. Stove body 110IP. inward projection
110FH. 1st combined support hole 110SH. 2nd combination support hole
112. Warm air circulation inlet 114. Warm air outlet
120. Rear cover 130. Reflector
130 CP. Connected reflector part 130LP. Ceramic plate support section
130PA. Hot air connection discharge passage 130FP. 1st combined part
130SP. Second combined piece 132. Outward protruding piece
132 CP. Point contact part 140. Ceramic plate
150. Heater 160. Fan
162. Motor 170. Insulating sleeve

Claims (8)

Stove body (110);
A rear cover 120 coupled to the stove body 110;
A reflector 130 coupled to the inside of the stove body 110;
A warm air circulation inlet 112 formed on the reflector 130;
A ceramic plate 140 coupled to the stove body 110 so as to be disposed in front of the reflector 130;
a heater 150 disposed between the reflector 130 and the ceramic plate 140;
A fan 160 disposed between the rear cover 120 and the reflector 130;
An electric stove using conductive heat, radiant heat, and convection heat, comprising a warm air outlet (114) provided in the stove body (110).
According to paragraph 1,
The radiant heat reaching the ceramic plate 140 due to the heat generation of the heater 150 is transmitted, and the radiant heat is radiated to the front of the ceramic plate 140, and the heat conducted inside by the operation of the fan 160 is transmitted. Air is converted into convection heat as a medium and is radiated more quickly to the front of the ceramic plate 140, and the radiant heat of the heater 150 is reflected toward the ceramic plate 140 by the reflector 130. It is configured to further increase the amount of radiant heat by being supplied to the front of the fan 140, and by operating the fan 160, air flows from the inside of the stove body 110 to the warm air circulation inlet 112 of the reflector 130. Enters the heater 150 and receives the heat conducted to the internal parts and turns into warm air, and the warm air is radiated through the warm air outlet 114 of the stove body 110 to the front of the stove body 110. An electric heater using conduction heat, radiant heat, and convection heat, characterized by allowing convection heat to radiate more quickly.
According to paragraph 1,
A thermal insulation sleeve 170 is built into the stove body 110, the heater 150 is disposed inside the thermal sleeve 170, and the outer peripheral surface of the thermal sleeve 170 and the stove body 110 ) An electric heater using conduction heat, radiant heat, and convection heat, characterized in that a certain space is secured between the inner peripheral surfaces of the.
According to paragraph 3,
The thermal sleeve 170 is made of an insulating material, and blocks heat from the heater 150 from being transferred to the stove body 110 and being lost. An electric heater using conductive heat, radiant heat, and convection heat.
According to paragraph 1,
The stove body 110 is provided with an inward protruding piece 110IP protruding toward the center, and the inner surface of the ceramic plate 140 is fixed to the front of the inward protruding piece 110IP in a state in contact with the inward protruding piece 110IP. The protruding piece 110IP is provided with a first coupling support hole 110FH communicating on both sides, and the inward protruding piece 110IP is located further outward than the first coupling hole based on the center of the stove body 110. A second coupling support hole (110SH) is provided at the position, the second coupling support hole (110SH) communicates with both sides of the inward protruding piece (110IP), and the reflector 130 is an outward protruding piece protruding from the outer peripheral surface. (132) is provided, and the outward protruding piece 132 is provided with a first coupling piece (130FP) crossing in the front-back direction, and the first coupling piece (130FP) is provided with a second coupling piece (130SP), , the second coupling piece (130SP) is disposed to face the first coupling piece (130FP), so that the first coupling piece (130FP) is connected to the first coupling support hole (110FH) of the inward protruding piece (110IP). Conduction heat, characterized in that the reflector 130 is firmly coupled to the stove body 110 by inserting the second coupling piece 130SP into the second coupling support hole 110SH. and electric heaters using radiant heat and convection heat.
According to clause 5,
The outward protruding piece 132 is provided with a point contact piece 132CP pointed toward the front, and the pointed part of the point contact piece is configured to contact the rear surface of the ceramic plate 140. Conductive heat, radiant heat, and convection heat. Electric stove using.
According to paragraph 1,
An electric heater using conductive heat, radiant heat, and convection heat, characterized in that a heat dissipation fin (130DP) is provided on the rear of the reflector (130).
According to paragraph 1,
The rear of the ceramic plate 140 is supported by a spring (SRP) coupled to the reflector plate 130, so that when the ceramic plate 140 expands as the temperature rises, the spring (SPR) is pressed and the ceramic The occurrence of cracks in the ceramic plate 140 is prevented by securing a clearance for the plate 140 to expand, and when the ceramic plate 140 cools and shrinks to its original volume, the spring (SPR) expands. An electric heater using conductive heat, radiant heat, and convection heat, characterized in that the ceramic plate 140 is supported and supported.

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