KR20150118860A - Oven - Google Patents

Abstract

The present invention relates to an oven including a divider arranged with a vacuum insulation panel. The oven comprises: a casing; a cooking chamber positioned within the casing; and the divider formed to maintain the inside in a vacuum state in order to divide the cooking chamber into a plurality of cooking chambers making each of the cooking chambers have different temperatures. The present invention may provide the oven including the divider which can block heat transfer between the cooking chambers to cook different foods.

Description

Oven {OVEN}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an oven, and more particularly to an oven including a divider provided as a vacuum insulation material.

The oven is a mechanism for sealing, heating and cooking the cooking material, and can generally be classified into an electric type, a gas type, and an electronic type depending on the heat source. Electric ovens use electric heaters as heat sources, and gas ovens and microwave ovens use frictional heat of water molecules as a heat source due to gas heat and high frequency, respectively.

In recent years, a dual cook oven has been used which can be divided into a first cooking chamber located at the upper portion and a second cooking chamber located at the lower portion. Dual Cook ovens can be cooked differently in each cooking room. Accordingly, a divider is disposed between the first and second cooking chambers to divide the cooking chamber.

However, heat transfer between the first and second cooking chambers can occur because the first and second cooking chambers are difficult to seal completely in the presently used dividers. Accordingly, in the first and second cooking chambers, only the cooking in a similar temperature range is possible, so that it is limited to allow the respective cooking to proceed at the same time.

Currently, dividers are available in various forms using insulation. However, there is a problem that the temperature difference between the cooking chamber is limited due to the limit of the heat insulating performance of the divider and the heat conducted on the cavity wall. In addition, there is a problem that heat exchange occurs between the cooking chamber and the flow of air due to the circulating fans installed in the cooking chamber. After all, the dual cook oven has a problem that limits the cooking range of the consumer.

One aspect of the present invention provides an oven capable of being cooked differently using a divider using vacuum insulation.

Also, an oven that maximizes a temperature difference between the cooking chamber due to a divider installed to pass through one surface of the cooking chamber is provided.

The oven according to the present invention includes a casing, a cooking chamber located inside the casing, and a divider formed to maintain the inside of the cooking chamber in a vacuum state in order to divide the cooking chamber into a plurality of cooking chambers that can be cooked at different temperatures.

The divider may include a core material and a jacket material disposed outside the core material.

The jacket material may include stainless steel.

The outer covering material may be provided with a thickness of 0.4 mm or more and 1.0 mm or less.

The covering material may include a first covering material and a second covering material which are combined to form a receiving space in which the core material is received.

The first outer covering material and the second outer covering material may be welded to each other.

In order to minimize the contact area of the first outer cover material and the second outer cover material, one end of at least one of the first outer cover material and the second outer cover material may be provided in a shape that gradually decreases in thickness.

And a door that opens and closes the cooking chamber, and the divider may include a gasket in contact with the door.

The divider may include a gasket in contact with at least one side of the cooking chamber.

The divider may be installed to pass through one side of the cooking cavity.

A through groove provided at one side of the cooking chamber so that the divider is installed to penetrate the cooking chamber and a blocking member for opening and closing the through groove according to the attachment / detachment of the divider.

The oven according to the present invention includes a casing, a first cooking chamber and a second cooking chamber located inside the casing, and a divider installed to prevent heat from being transmitted between the first cooking chamber and the second cooking chamber , The divider includes a vacuum insulation material forming a vacuum insulation layer.

The divider may include a core in a vacuum state and a casing member surrounding the core.

And a first circulation fan and a second circulation fan coupled to one surface of each of the cooking chambers to circulate the air in the respective cooking chambers, wherein the divider is disposed between the first circulation fan and the second circulation fan As shown in FIG.

The first cooking chamber and the second cooking chamber may be formed of an inner wall and a door, and the divider may include a gasket contacting at least one of the inner wall and the door.

It is possible to provide an oven including a divider capable of blocking heat transfer between the cooking chamber so that different cooking can be performed.

Further, the divider can minimize the heat transfer between the gasket contacting the door and the inner wall, and the heat transfer between the inner wall and the cooking chamber.

1 is a view illustrating an oven according to an embodiment of the present invention.
2 is a side cross-sectional view of an oven according to an embodiment of the present invention.
FIG. 3 is an enlarged view of a portion 'A' of FIG. 2, illustrating a divider mounting state of an oven according to an embodiment of the present invention.
4 is a view illustrating a divider of an oven according to an embodiment of the present invention.
5 is a side sectional view of a divider of an oven according to an embodiment of the present invention.
6 is a side sectional view of a divider of an oven according to another embodiment of the present invention.
FIG. 7 is a view showing a divider mounting state of an oven according to another embodiment of the present invention.
8 is a view illustrating a state in which a divider is mounted on an oven according to another embodiment of the present invention.

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

FIG. 1 is a view showing an oven 1 according to an embodiment of the present invention, and FIG. 2 is a side sectional view of an oven 1 according to an embodiment of the present invention.

1 and 2, the oven 1 includes a casing 10 and a cooking chamber 20 located inside the casing 10. As shown in Fig. The casing 10 may be provided to form the appearance of the oven 1.

The cooking chamber (20) is a cooking space formed by the inner wall and the door (12) located inside the casing (10). The cooking chamber 20 may be formed in a box shape by an inner wall and a door 12. [ The inner wall may include a top plate 21, a bottom plate 22, both side plates 23 and a back plate 24. The front surface of the cooking chamber 20 may be provided with a front plate 25 forming a front opening and a door 12 opening and closing the front opening.

The front opening may be provided for receiving and discharging the food, and the door 12 may be rotatably coupled to one side of the front plate 25. [ The door 12 can be hinged to be vertically rotatable with respect to the cooking chamber 20. The door 12 may be provided with a handle 11 so that the user can grasp the door 12 to rotate the door 12. At least a part of the door 12 may be made of a transparent material such as glass so that the cooking process of the food inside the cooking chamber 20 can be confirmed from the outside.

On the upper part of the cooking chamber 20, an electric field chamber 17 in which various electric components (not shown) such as a circuit board are disposed is provided. A display 13 and an operation unit 14 may be provided on the front surface of the electric field chamber 17. The display 13 displays various operation information of the oven 1 and the operation unit 14 may be provided with a button or the like capable of operating the operation of the oven 1.

A cooling fan unit 27 for cooling the inside of the electric field chamber 17 and the door 12 is provided on the upper portion of the cooking chamber 20. The cooling fan unit 27 sucks outside air into the electric room 17 and discharges it to the front of the oven 1. The air introduced by the cooling fan 27 may be discharged to the outside through a front flow path 28 provided to communicate with the outside.

The door (12) may be provided to form at least one cooling flow passage (13). Therefore, the air located in the cooling passage 13 flows together with the air discharged to the outside along the front flow path 28 and can be discharged to the outside. The air can move along the cooling passage 13 and cool the door 12. [

At least one rack 29 for placing the food may be disposed inside the cooking chamber 20. A rail 29a may be provided on the inner side surface of both side plates 23 so that the rack 29 can be detached from the cooking chamber 20. The user can move the rack 29 through the rails 29a and take out or raise the food.

A divider 100 may be installed inside the cooking chamber 20. The divider 100 can be installed so as to divide the cooking chamber 20 into a plurality of cooking chambers which can be cooked at different temperatures. The divider 100 is mounted horizontally in the cooking chamber 20 so that the cooking chamber 20 can be separated into the first cooking chamber 30 and the second cooking chamber 40. An upper portion of the divider 100 is referred to as a first cooking chamber 30 and a lower portion of the divider 100 is referred to as a second cooking chamber 40 for convenience of explanation.

The sizes of the first and second cooking chambers 30 and 40 do not have to be equal to each other and the sizes of the first and second cooking chambers 30 and 40 may be different from each other. The divider 100 may be removably mounted to the cooking chamber 20. [ Accordingly, the user can use the divider 100 as one cooking chamber 20 as needed.

Circulating fans (32, 42) may be provided on the rear plate (24) to circulate the air inside the cooking chamber (20). A fan cover 50 may be coupled to the outside of the rear plate 24 to provide circulation fans 32 and 42. The back plate 24 may include a through hole 56 so that the fluid flowing by the circulating fans 32 and 42 can move into the interior of the cooking chamber 20. [ The circulating fans 32 and 42 may include a first circulating fan 32 and a second circulating fan 42 provided in the first and second cooking chambers 30 and 40, respectively.

The first circulation fan 32 can convect the air in the first cooking chamber 30 and the second circulation fan 42 can convect the air in the second cooking chamber 40. That is, the first circulation fan 32 and the second circulation fan 42 can be driven by respectively having the first motor 34 and the second motor 44, respectively. The first circulation fan 32 and the second circulation fan 42 may include a first heater 36 and a second heater 46, respectively.

An upper heater 54 is provided on the upper portion of the cooking chamber 20 and a lower heater (not shown) may be provided on the lower portion of the bottom plate 22. [ The upper heater 54 and the lower heater (not shown) can heat the food inside the cooking chamber 20 together with the first heater 36 and the second heater 46.

The first cooking chamber 30 and the second cooking chamber 40 may be insulated from the outside to cook the food. Therefore, the heat insulating member 52 may be disposed on the upper surface plate 21, the bottom plate 22, and the both side plates 23 forming the cooking chamber 20. A heat insulating member 52 is also provided on the outer side of the fan cover 50 to prevent the heat inside the cooking chamber 20 from being transmitted to the outside of the casing 10.

The first cooking chamber 30 and the second cooking chamber 40 may be used to heat different kinds of food or to use any one of the cooking chambers 20. Accordingly, the divider 100 may be made of a heat insulating material to prevent heat from being transferred between the first and second cooking chambers 30 and 40. [

3 is an enlarged view of a portion 'A' in FIG. FIG. 3 shows the mounting state of the divider 100 of the oven 1 in detail according to an embodiment of the present invention schematically shown in FIG. 4 is a view showing a divider 100 of an oven 1 according to an embodiment of the present invention, and FIG. 5 is a side sectional view of a divider of an oven according to an embodiment of the present invention .

The divider 100 may include a vacuum insulation panel (VIP) that forms a vacuum insulation layer. Vacuum insulation is a type of insulation that uses a low thermal conductivity property of vacuum by decompressing the inner space and forming it in vacuum. That is, the divider 100 is formed so as to keep the inside of the vacuum state, so that heat exchange between the first and second cooking chambers 30 and 40 can be minimized.

The divider 100 may include a core material 110 and a covering material 130 and 140 disposed outside the core material 110. The core member 110 is provided in a vacuum state and the shell members 130 and 140 may be provided to surround the core member 110 so that the core member 110 can maintain a vacuum state. In addition, the outer cover materials 130 and 140 can block the minute gas and moisture permeating into the core material 110, thereby maintaining the life of the vacuum thermal insulator.

The outer covering materials 130 and 140 may include a first outer covering material 130 and a second outer covering material 140 which are combined to form a receiving space in which the core material 110 is received. Referring to FIG. 5, the first covering material 130 located at a lower portion of the core material 110 and the second covering material 140 positioned at an upper portion of the core material 110 are referred to as a second covering material.

The first outer covering material 130 and the second outer covering material 140 may include stainless steel. The first shell material 130 may be drawn to form a space for accommodating the core material 110. The second outer covering material 140 may be provided in the form of a flat plate so as to cover the upper portion of the core member 110 to form a closed receiving space.

The core material 110 may include glass fibers having excellent heat insulating properties. It is possible to obtain a high thermal insulation effect by forming a laminated structure of panels woven with glass fibers as thin as possible. Specifically, as the pore size between glass fibers is smaller, the effect of radiation, which is an adiabatic characteristic, can be minimized, so that a high thermal insulation effect can be expected.

The diameter of the glass fiber is preferably not less than 3 mu m and not more than 6 mu m, and the length of the glass fiber is preferably not less than 20 mm and not more than 70 mm. Further, the gap between the glass fibers may preferably be 30um or more and 80um or less. However, the diameter and length of the glass fiber, and the gap between the glass fibers are not limited to the above examples.

In addition, silica can be used as the core material. Silica can be used for a long time because it has little change in performance even when used for a longer time than glass fiber.

Further, the divider 100 provided as a vacuum insulating material may include an adsorbent (Getter) 120. The adsorbent 120 is provided inside the core member 110 and can adsorb moisture or the like flowing into the core member 110 to maintain the vacuum state of the core member 110. The adsorbent 120 may be in powder form and may be configured to have a predetermined block or rectangular parallelepiped shape.

The adsorbent 120 may comprise a moisture adsorbent. The adsorbent 120 can adsorb and remove the residual moisture inside the divider 100 and the moisture that penetrates into the divider 100. (120) The adsorbent may comprise a chemical adsorbent comprising at least one of CaO, BaO, MgO and CaCl ₂ and a physical adsorbent comprising at least one of molecular sieve, activated carbon, zeolite, activated alumina and MgCO ₃ .

The higher the specific surface area, the better the adsorption performance of the adsorbent 120. The chemical adsorbent preferably has a specific surface area of 10 m 2 / g or more, and the physical adsorbent preferably has a specific surface area of 50 m 2 / g or more.

To describe the manufacturing process of the divider 100, the core 110 and the adsorbent 120 are accommodated in the accommodating space of the first outer covering material 130 drawn. The second cover member 140 is coupled with the first cover member 130 to seal the accommodation space. At this time, the first outer covering material 130 and the second outer covering material 140 may be welded to each other. A pumping pipe (not shown) is connected to one side of the receiving space to discharge the air, and the receiving space is formed in a vacuum state. The pumping pipe (not shown) is removed and the coupling portion is joined to seal the accommodation space.

In addition, the coating layer 150 can be formed on the surface of the divider 100 in which the inside is formed in a vacuum state. Coating layer 150 may include a non-stick coating, a ceramic coating. The coating layer 150 may be formed by spraying on the outer covering materials 130 and 140.

The divider 100 may include a gasket 160 to block heat conducted along the inner wall of the cooking chamber 20 and the door 12. [ The gasket 160 can enhance the adhesion between the inner wall and the door 12 and the divider 100 and can shield the first and second cooking chambers 30 and 40.

The gasket 160 may be installed at the edge of the divider 100 to contact the inner wall and the door 12. [ As shown in FIGS. 4 and 5, the divider 100 may include a gasket 160 that is directed toward the door 12. The heating jacket 160 may contact the door 12 to increase the adhesion between the door 12 and the divider 100 to prevent the heat from being transmitted. The gasket 160 may be installed at the edge of the divider 100 to contact the back plate 24 and the both side plates 23.

As described above, the first outer covering material 130 and the second outer covering material 140 may be formed by welding at the corners. Heat transfer between the first cooking chamber (30) and the second cooking chamber (40) can take place with such corner portions. It is preferable to minimize the thicknesses of the first outer covering material 130 and the second outer covering material 140 in order to lower the thermal conductivity of the corner portions. The first outer covering material 130 and the second outer covering material 140 may be provided with a thickness (a) of 0.4 mm or more and 1.0 mm or less.

6 is a side sectional view of a divider 100a of the oven 1 according to another embodiment of the present invention.

In addition, the smaller the contact area between the first outer covering material 130a and the second outer covering material 140a, the less heat is transmitted. Therefore, in order to minimize the contact area between the first outer covering material 130a and the second outer covering material 140a, at least one of the first outer covering material 130a and the second covering material 140a has a gradually increasing thickness It can be provided in a reduced shape.

As shown in FIG. 6, one end of the first outer covering material 130a contacting the second outer covering material 140a is formed so that the thickness gradually decreases. Therefore, the area in which the first outer covering member 130a and the second outer covering member 140a contact each other is reduced, and accordingly, the heat transfer amount through the corner portions of the outer covering members 130a and 140a can be reduced.

7 is a view showing a state in which the divider 100b is mounted on the oven 1 according to another embodiment of the present invention.

The first circulation fan 32b and the second circulation fan 42b including the first heater 36b and the second heater 46b are connected to the first cooking chamber 30b and the second cooking chamber 40b, respectively, Respectively. It is important to block the heat transfer of the rear plate 24b where the first heater 36b as the heat source and the second heater 46b are located in blocking the heat transfer between the first cooking chamber 30b and the second cooking chamber 40b .

Therefore, the divider 100b can be installed so as to pass through one side of the cooking chamber 20b. That is, one side of the divider 100b may be installed to pass between the first circulation fan 30b and the second circulation fan 40b. The rear plate 24b may include a through-hole 171 so that the divider 100b is installed to pass therethrough. The through groove 171 may be provided through the rear plate 24b and the fan cover 50b.

The divider 100b may include a protrusion 170 provided at an edge portion facing the rear plate 24b. For effective insulation, the divider 100b may be formed such that the core 110b is positioned inside the protrusion 170. [ The projecting portion 170 may be inserted into the rear plate 24b and the fan cover 50b through the through groove 171. [ Therefore, heat conduction through the rear plate 24b and flow mixing by the first circulation fan 32b and the second circulation fan 42b can be prevented.

In addition, a blocking member 180 for opening and closing the through-hole 141 may be provided in accordance with the attachment / detachment of the divider 100b. When the user does not use the cooking chamber 20 separately, the divider 100b can be separated. At this time, the blocking member 180 may block the through-hole 171 to prevent heat transfer to the outside.

The blocking member 180 may be provided in the form of a damper whose one side is rotatably fixed. A support member 182 may be provided to allow the blocking member 180 to be rotatably fixed. The support member 182 may be fixed to one surface of the fan cover 50b which is in contact with the through groove 171. [ Therefore, when the divider 100b is not engaged, the blocking member 180 blocks the penetrating groove 171 to maintain the tightness of the cooking chamber 20b. When the divider 100b is engaged, the blocking member 180 is rotated by the protrusion 170 to open the through-hole 171. [

8 is a view showing a state in which the divider 100c is mounted on the oven 1 according to another embodiment of the present invention.

The divider 100c includes the protrusion 172 and the back plate 24c includes the through groove 173 through which the protrusion 172 can pass. In addition, a blocking member 190 for opening and closing the through-hole 173 may be provided in accordance with detachment of the divider 100c.

The blocking member 190 may be movably installed inside the housing member 194. [ The housing member 194 can be fixed to one surface of the fan cover 50c whose one side is in contact with the through-hole 173. An elastic member 192 is provided inside the housing member 194 so that the blocking member 190 can elastically move. Therefore, when the divider 100c is not engaged, the blocking member 190 blocks the penetration groove 173 to maintain the tightness of the cooking chamber 20c. When the divider 100c is engaged, the projecting portion 190 is inserted into the through groove 173, and the blocking member 190 moves under pressure to compress the elastic member 192. [

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

1: oven 10: casing
12: door 20: cooking chamber
30: 1st cooking chamber 40: 2nd cooking chamber
100: Divider 110: Core
120: adsorbent 130: first shell material
140: second covering material 150: coating layer
160: Gasket

Claims (15)

Casing;
A cooking chamber located inside the casing;
A divider configured to maintain the interior of the cooking chamber in a vacuum state so as to divide the cooking chamber into a plurality of cooking chambers that can be cooked at different temperatures;
And an oven. The method according to claim 1,
Wherein the divider comprises a core material and a jacket material disposed outside the core material. 3. The method of claim 2,
Characterized in that said shell material comprises stainless steel. 3. The method of claim 2,
Wherein the outer covering material is provided in a thickness of 0.4 mm or more and 1.0 mm or less. 3. The method of claim 2,
Wherein the outer cover material comprises a first outer cover material and a second outer cover material which are combined to form a receiving space in which the core material is accommodated. 6. The method of claim 5,
Wherein the first outer covering material and the second outer covering material are welded to each other. 6. The method of claim 5,
Wherein at least one of the first outer covering member and the second outer covering member is formed in such a shape that the thickness thereof gradually decreases in order to minimize a contact area between the first outer covering member and the second outer covering member. The method according to claim 1,
And a door for opening and closing the cooking chamber,
Wherein the divider comprises a gasket in contact with the door. The method according to claim 1,
Wherein the divider comprises a gasket in contact with at least one side of the cooking chamber. The method according to claim 1,
And the divider is installed to pass through one side of the cooking chamber. 11. The method of claim 10,
A through-hole provided on one side of the cooking chamber so that the divider is installed to penetrate,
And a blocking member that opens and closes the through-hole in accordance with detachment of the divider. Casing;
A first cooking chamber and a second cooking chamber located inside the casing;
And a divider installed to prevent heat from being transmitted between the first cooking chamber and the second cooking chamber,
Wherein the divider comprises a vacuum insulation material forming a vacuum insulation layer. 13. The method of claim 12,
Wherein the divider includes a core in a vacuum state and a casing member surrounding the core. 13. The method of claim 12,
And a first circulation fan and a second circulation fan coupled to one surface of each of the cooking chambers to circulate the air inside each of the cooking chambers,
And the divider is installed to pass between the first circulation fan and the second circulation fan. 13. The method of claim 12,
Wherein the first cooking chamber and the second cooking chamber are formed of an inner wall and a door,
Wherein the divider includes a gasket contacting at least one of the inner wall and the door.

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