KR20200136585A - Oven - Google Patents

Abstract

An oven according to the idea of the present invention includes: a main body having a front panel; a cooking chamber provided inside the main body and opened to the front; a door for opening and closing the cooking chamber; a blower fan disposed at the top of the cooking chamber to send air sucked from the outside of the main body; and a discharge passage formed to discharge the air sucked by the blower fan to the outside of the main body. The front panel includes a discharge port forming one end of the discharge passage. The cross-sectional area of the discharge port is provided to be smaller than a vertical cross-sectional area with respect to the front of the discharge passage.

Description

Oven{OVEN}

The present invention relates to an oven including an air guide provided to guide the flow of air discharged from the discharge passage.

In general, an oven is a device that cooks food by having a cooking chamber, a heating device that applies heat to the cooking chamber, and a circulation device that circulates heat generated by the heating device in the cooking chamber.

In the case of cooking using an oven, the internal temperature of the cooking compartment may be increased to 150 to 450 degrees Celsius depending on the cooking conditions, and may also be increased to the outside temperature of the cooking compartment.

When the external temperature of the cooking compartment rises, the electronic devices inside the oven may fail due to the influence of thermal shock, so the oven may include a blower such as an exhaust channel for cooling the outside of the cooking compartment.

Heat generated inside the oven may be discharged to the outside of the oven through a blower, and at this time, the discharge efficiency of the blower may be a problem.

The present invention discloses an oven including an improved blowing device capable of efficiently discharging heat generated inside the oven.

In particular, the present invention discloses an oven including an improved discharge passage capable of efficiently discharging heat generated inside the oven and heat generated inside the door.

A main body having a front panel according to the idea of the present invention, a cooking chamber provided inside the main body and opened to the front, a door opening and closing the cooking chamber, and a blowing fan disposed above the cooking chamber to blow air sucked from the outside of the main body And a discharge passage configured to discharge the air sucked by the blowing fan to the outside of the main body, and the front panel includes an outlet forming one end of the discharge passage, and the cross-sectional area of the discharge port is the discharge passage It is provided smaller than the vertical power of the front.

In addition, the discharge flow path is a reduction section in which the vertical cross-sectional area with respect to the front decreases in the direction in which air flows, a maintenance section connected to the reduction section and maintaining a constant vertical cross-sectional area with respect to the front, and between the discharge port and the holding section. And a discharge section in which a vertical cross-sectional area with respect to the front side is smaller than that of the holding section.

In addition, a flow path base disposed above the cooking chamber and forming a part of the discharge flow path, and a flow path cover forming another part of the discharge flow path and covering the flow path base, wherein the flow path cover is in the holding section. The extension angle in the front-rear direction and the extension angle in the front-rear direction in the discharge section are provided differently.

In addition, the extension angle in the front-rear direction in the discharge section is provided smaller than the extension angle in the front-rear direction in the holding section.

In addition, the flow path base is provided with the same extension angle in the front-rear direction in the holding section and the extension angle in the front-rear direction in the discharge section.

In addition, the height in the vertical direction in the discharge section is provided smaller than the height in the vertical direction in the holding section.

Further, a flow path base disposed above the cooking chamber and forming a part of the discharge flow path, and a flow path cover forming another part of the discharge flow path and covering the flow path base, the front end of the flow path cover is bent. .

In addition, the door includes a door inlet and a door outlet disposed above the door and through which air flowing in the door is discharged, and the door outlet is disposed adjacent to the outlet.

In addition, it further includes an intermediate region formed between the outlet and the door outlet, and the air pressure in the intermediate region is provided to be formed to be lower than the air pressure inside the outlet and the air pressure inside the door outlet when the blowing fan is driven. .

In addition, the width in the left-right direction in the discharge section is provided smaller than the width in the left-right direction in the holding section.

In addition, the width in the left and right direction in the discharge section is provided to gradually decrease toward the front.

In addition, the flow path cover includes a sidewall forming a side of the discharge flow path, and the sidewall includes a curved portion positioned on the discharge section.

In addition, the reduction section is provided so that the speed of the air flowing in the reduction section increases toward the discharge port. The holding section is provided so that the speed of air flowing in the holding section is constant, and the discharge section is provided so that the speed of air flowing in the discharge section is greater than the speed of air flowing in the holding section. .

A main body having a front panel according to the idea of the present invention, a cooking chamber provided inside the main body and open to the front, a door for opening and closing the cooking chamber, and a door disposed above the cooking chamber to blow air sucked from the outside of the main body A blower fan, a discharge passage configured to discharge the air sucked by the blower fan to the outside of the main body, a passage base disposed above the cooking chamber and forming a part of the discharge passage, and another of the discharge passage A flow path cover forming a part and covering the flow path base may be further included, and the front panel includes a discharge port forming one end of the discharge flow path, and a front end portion of the flow path cover connected to the discharge port is bent.

In addition, the discharge flow path is a reduction section in which the vertical cross-sectional area with respect to the front decreases in the direction in which air flows, and the maintenance section in which the vertical cross-sectional area with respect to the front is kept constant, and the front end of the flow channel cover It includes a discharge section corresponding in the direction and provided with a vertical cross-sectional area smaller than the cross-sectional area of the holding section.

In addition, the flow path cover is provided larger than an extension angle in the front-rear direction in the holding section and an extension angle in the front-rear direction in the discharge section.

In addition, the height in the vertical direction in the discharge section is provided smaller than the height in the vertical direction in the holding section.

In addition, the width in the left-right direction in the discharge section is provided smaller than the width in the left-right direction in the holding section.

In addition, the width in the left and right direction in the discharge section is provided to gradually decrease toward the front.

In addition, the flow path cover includes a sidewall forming a side of the discharge flow path, and the sidewall includes a curved portion positioned on the discharge section.

In the present invention, the cross-sectional area perpendicular to the front-rear direction of the discharge port in the discharge passage is formed to be smaller than the cross-sectional area perpendicular to the front-rear direction of the discharge passage adjacent to the discharge port, thereby increasing the flow velocity of air discharged from the discharge passage.

As the flow rate of the exhaust air at the outlet increases, the flow of air discharged from the door outlet provided adjacent to the outlet may be smoothed, thereby efficiently improving the flow of air inside the door.

1 is a perspective view of an oven according to the present invention.
2 is a view showing a state in which the door of the oven according to the present invention is opened.
3 is a side cross-sectional view of the oven according to the present invention.
4 is a view showing a flow of air discharged through a discharge passage in the oven according to the present invention.
5 is a plan view of the oven in a state in which the upper surface of the main body is removed in the oven according to an embodiment of the present invention.
6 is a side cross-sectional view of a part of a blowing device in the oven according to an embodiment of the present invention.
7 is a plan view of the oven in a state in which an upper surface of a main body and an upper surface of a flow path cover are removed in the oven according to an embodiment of the present invention.
8 is a plan view of the oven in a state in which the upper surface of the main body and the upper surface of the flow path cover are removed in the oven according to another embodiment of the present invention.
9 is a side cross-sectional view of a part of a blower in the oven according to another embodiment of the present invention.

The embodiments described in the present specification and the configurations shown in the drawings are only preferred examples of the disclosed invention, and there may be various modified examples that may replace the embodiments and drawings of the present specification at the time of filing of the present application.

In addition, the same reference numerals or reference numerals shown in each drawing of the present specification indicate parts or components that substantially perform the same function.

In addition, terms used in the present specification are used to describe embodiments and are not intended to limit and/or limit the disclosed invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

In the present specification, terms such as "comprise" or "have" are intended to designate the presence of features, numbers, steps, actions, components, parts, or combinations thereof described in the specification, but one or more other features. It does not preclude the presence or addition of elements, numbers, steps, actions, components, parts, or combinations thereof.

In addition, terms including ordinal numbers such as "first" and "second" used herein may be used to describe various elements, but the elements are not limited by the terms, and the terms are It is used only for the purpose of distinguishing one component from other components.

For example, without departing from the scope of the present invention, a first element may be referred to as a second element, and similarly, a second element may be referred to as a first element. The term "and/or" includes a combination of a plurality of related stated items or any of a plurality of related stated items.

Meanwhile, terms such as “front”, “rear”, “upper” and “lower” used in the following description are defined based on the drawings, and the shape and position of each component are not limited by this term. .

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

1 is a perspective view of an oven according to the present invention. 2 is a view showing a state in which the door of the oven according to the present invention is opened. 3 is a side cross-sectional view of the oven according to the present invention.

1 to 3, the oven 1 is an inner case 20 in which the cooking chamber 30 is formed, and an outer case that is coupled to the outer side of the inner case 20 to form the exterior of the oven 1 It may include a body 10 including a case (not shown).

The inner case 20 and the outer case (not shown) may each have a substantially box shape with an open front surface.

Also, the present invention is not limited thereto, and the oven 1 may be installed in a system kitchen in a built-in method.

In this case, the main body 10 does not include an outer case, and a cabinet of a system kitchen that can be accommodated may be disposed adjacent to the inner case 20.

The oven 1 may include a door 50 provided on the front side of the main body 10 to open and close the cooking compartment 30.

The inner case 20 includes a front panel 21 forming the front surface of the body 10, a top panel 22 forming the upper surface of the body 10, and a side panel 23 forming a side surface of the body 10. , And a rear panel 24 forming a rear surface of the main body 10.

An opening is provided in the front panel 21, and a front surface of the cooking chamber 30 provided inside the main body 10 may be opened by the opening. An electric machine room cover 41 covering the front of the electric machine room 40 may be provided on the front upper part of the front panel 21. The display module 60 may be mounted on the full-length cover 41.

Inlets 23a and 24a may be provided in the side panel 23 and the rear panel 24 so that air is sucked into the battlefield 40, respectively. Air sucked into the battlefield 40 through the inlets 23a and 24a flows inside the battlefield 40 and cools the electric equipment.

However, the present invention is not limited thereto, and the inlets 23a and 24a may be formed in various positions within the limit of guiding external air to be sucked into the battlefield 40.

The cooking chamber 30, which has a box shape inside the main body 10 and is provided so that the front surface is open, is formed by the top plate 31, the bottom plate 32, both side plates 33, and the rear plate 34. Can be. The cooking chamber 30 is a cooking space and is opened through an opening of the front panel 21 so that food can be put in and out.

A plurality of supports 35 may be provided on the inner surfaces of both side plates 33. At least one detachable rack 36 on which food can be placed may be mounted on the plurality of supports 35.

Rails (not shown) may be installed on the plurality of supports 35 so that the rack 36 is slidable. The user can move the rack 36 through a rail (not shown) to take out or place food.

A divider 37 capable of dividing the cooking chamber 30 into a plurality of pieces may be mounted to be detachable inside the cooking chamber 30. The cooking chambers 30a and 30b divided into a plurality by the divider 37 do not have to be the same in size, and may have different sizes.

Through this, the user can variously utilize the space of the cooking chambers 30a and 30b divided into a plurality according to the intention. The divider 37 may be made of an insulating material to insulate each cooking chamber 30.

A heater 38 for heating food may be provided in the cooking chamber 30, and the heater 37 may be an electric heater including an electric resistor. However, the present invention is not limited thereto, and the heater 37 may be a gas heater that generates heat by burning gas. Accordingly, the oven may include an electric oven and a gas oven.

The rear plate 34 of the cooking chamber 30 may be provided with a circulation fan 39a that circulates the air in the cooking chamber 30 so that food is heated evenly, and a circulation motor 39b that drives the circulation fan 39a. have.

A fan cover 39c covering the circulation fan 39a may be provided on the front surface of the circulation fan 39a, and an outlet hole through which air may flow may be formed in the fan cover 39c.

The opened front of the cooking chamber 30 is opened and closed by the door 50, and the door 50 may be coupled by a hinge 53 at the lower portion of the main body 10 so as to be rotatable with respect to the main body 10.

The door 50 is rotatably coupled to the main body 10 to open and close the entire cooking chamber 30, and the first door 51 is rotatably coupled to the first door 51. A second door 52 that opens and closes the provided opening (not shown) may be included.

A door handle 56 that can be gripped by a user is provided on the upper front of the second door 52, which is the upper front of the door 50, and the door 50 is fixed to the main body 10 on the door handle 56. And a locking device 57 may be provided that is fixed or released, or the second door 52 is fixed to and released from the first door 51.

As described above, the cooking chamber 30 can be divided by the divider 37, and the cooking chamber 30 can be divided into a first cooking chamber 30a and a second cooking chamber 30b from below, centering on the divider 37. have.

The user can selectively open the second door 52 to open only the second cooking room 30b through the locking device 55, and open the first door 51 to open the first cooking room 30a and the second cooking room ( 30b) can all be opened.

However, the present disclosure is not limited thereto, and the door 50 may be formed as a single door or may additionally include a third door.

The display module 60 provided to display various operation information of the oven 1 and to allow a user to input an operation command may be mounted on the electric chamber cover 41 provided on the front upper part of the front panel 21. . An operation unit 62 capable of operating the oven 1 may be provided on the electric chamber cover 41.

The display module 60 may include a liquid crystal display (LCD), and the liquid crystal display may display electrical information as visual information by using a change in liquid crystal transmittance according to an applied voltage.

The liquid crystal display device may include a liquid crystal module that displays an image and a light source unit that emits light to the liquid crystal module, and an LED (light emitting diode) may be used as the light source unit.

The display module 60 may include a cover panel 61 provided on the front surface of the liquid crystal display. The cover panel 61 may simply be a protective panel for protecting the liquid crystal display device, but may be a touch panel capable of receiving a user's touch command.

An insulating material (not shown) is provided between the battlefield 40 and the cooking chamber 30 to insulate the battlefield 40 and the cooking chamber 30 to prevent heat from the cooking chamber 30 from being transmitted to the battlefield 40 Can be.

Insulation material (not shown) may be provided to cover the entire outside of the cooking chamber 30 so that heat from the cooking chamber 30 is not transmitted to the outside of the oven 1 as well as between the electric chamber 40 and the cooking chamber 30. have.

Since the interior of the electrical equipment room 40 may increase in temperature due to the heat of various electrical equipment, the oven 1 is a blower that can cool the electrical equipment room 40 by circulating air around the electrical equipment room 40. 100 can be provided.

The blowing device 100 may include a blowing fan 110 for flowing air, and a discharge passage 120 provided to discharge air sucked by the blowing fan 110 to the front of the oven 1. .

The blowing fan 110 may suck air in the axial direction and then discharge it in the radial direction. That is, the blowing fan 110 according to the present invention may be a centrifugal fan. However, the present invention is not limited thereto, and unlike the present embodiment, the blowing fan 110 may include an axial fan.

External air can be sucked into the battlefield 40 through the inlets 23a and 24a formed on the side panel 23 and the rear panel 24, respectively, and the air sucked into the battlefield 40 may be sucked into the battlefield ( After cooling the electrical equipment while flowing through the interior of 40), it may be discharged to the front of the oven 1 through the discharge port 150 along the discharge passage 120.

The outlet 150 may be formed on the front panel 21. In detail, it may be formed in a space between the upper end of the front panel 21 and the full-length cover 41.

Some of the air inside the cooking chamber 30 may be sucked into the discharge passage 120 through the cooking chamber passage 160 and discharged to the front of the oven 1.

On the other hand, a bypass hole 161 for introducing a part of air flowing from the discharge passage 120 to the discharge port 150 into the cooking chamber passage 160 may be formed, and the bypass hole 161 is an opening/closing device 162 ) Can be opened and closed.

As the bypass hole 161 is opened and closed by the opening/closing device 162, the amount of air flowing from the discharge passage 120 to the discharge port 150 is adjusted, so that the amount of the air flowing into the cooking chamber flow passage 160 is adjusted. The amount of air exhausted from 30) to the cooking chamber flow path 160 may be adjusted.

The blowing device 110 may include a flow path base 130 disposed above the cooking chamber 30 and a flow path cover 140 provided to cover the flow path base 130.

The discharge passage 120 may be formed by the passage base 130 and the passage cover 140. The discharge passage 120 may be formed by the passage base 130, the passage cover 140, and the upper portion of the front panel 21.

The flow path base 130 and the flow path cover 140 may be spaced apart, and a blowing fan 110 or the like may be disposed in the space between the flow path base 130 and the flow cover 140.

The first door 50 includes a front glass 53 installed at the front, a rear glass 55 installed at the rear of the front glass 53 to seal the cooking compartment 20, and the front glass 53 and the rear glass ( 55) may include an intermediate glass 54 provided between.

The intermediate glass 54 may be formed in plural.

The door 50 formed in the first door 51 and the second door 52 may include a plurality of glasses 53, 54, and 55.

A space is formed between the plurality of glasses 53, 54, 55 through the plurality of glasses 53, 54, 55, and thus, heat from the cooking compartment 30 can be prevented from being directly transmitted to the front of the door 50. have.

In addition, even when the door 50 is closing the cooking chamber 30 through the plurality of glasses 53, 54, 55, the inside of the cooking chamber 30 can be seen from the outside.

The door 50 is provided to close the cooking chamber 30 so that heat generated from the cooking chamber 30 may be transferred to the door 50. Accordingly, the space inside the door 50 may be heated.

Hereinafter, the process of cooling the door 50 will be described in detail.

4 is a view showing a flow of air discharged through a discharge passage in the oven according to the present invention, and FIG. 5 is an oven in a state in which the upper surface of the main body is removed in the oven according to an embodiment of the present invention. It is a top view.

The door 50 includes a door inlet 58 provided to allow external air to flow into the door 50 to cool the inside of the heated door 50 and a door outlet 59 through which the introduced air flows out. Can be (see Fig. 3)

The door inlet 58 may be formed under the door 50. In detail, the door inlet 58 may be formed under the first door 51. The door inlet 58 is not limited thereto, and may be additionally formed on the side of the first door 51 or the second door 52, respectively.

It may be formed on the upper side of the door 50 of the door outlet (59). In detail, the door outlet 59 may be formed above the second door 52.

In addition, the door 50 may include a door flow path 50a provided in the interior of the door 50 and in a space between the plurality of glasses 53, 54 and 55 so that heated air flows.

As described above, the door 50 is composed of a first door 51 and a second door 52, but the first door 51 and the second door 52 can be connected to each other, so that one door passage 50a Can be formed.

As the external air introduced through the door inlet 58 is discharged to the outside through the door outlet 59 along the door flow path 50a inside the heated door 50, the interior of the door 50 may be cooled.

The blower fan 110 may inhale external air through the inlets 23a and 24a, cool the electric room 40, and discharge it through the outlet 150.

Specifically, when the width of the discharge passage 120 becomes relatively narrow as it goes toward the discharge port 150, the speed of the discharged air may be relatively increased so that the same amount of air passes through the discharge port 150.

As the speed of the air increases, the pressure of the air may be relatively lower than that of the atmospheric pressure, and through this, a venturi effect may occur in which the air of atmospheric pressure is naturally sucked into the position where the atmospheric pressure is lowered.

In this way, the upper portion of the door 50 from which the exhausted air exits is relatively lowered, so that the door 50 may be cooled by utilizing a phenomenon in which ambient air is collected to the upper portion of the door 50.

That is, as shown in FIGS. 4 and 5, the door outlet 59 and the outlet 150 of the door 50 may be disposed adjacent to each other. The outlet 150 is disposed on the upper side of the front frame 21 and the door outlet 59 of the door 50 is disposed on the upper side of the door 50. When the door 50 is closed, the front frame 21 The outlet 150 and the door outlet 59 may be disposed adjacent to each other.

An intermediate region 170 may be provided between the outlet 150 and the door outlet 59. The intermediate region 170 is a region in which the above-described suctioned venturi effect may occur.

An outlet 150 is formed at the rear of the intermediate region 170, a door outlet 59 is formed at the lower side of the intermediate region 170, and a lower end 41a of the battlefield cover 41 is formed in front of the intermediate region 170. A gap formed between the upper end 22a of the door 50 and the lower end 41a of the battlefield cover 41 and the upper end 22a of the door 50 may be provided.

The intermediate region 170 is a space in which air discharged from the discharge port 150 can temporarily stay. The air discharged from the discharge port 150 passes through the middle region 170 to the outside of the oven 1 through a gap formed between the lower end 41a of the battlefield cover 41 and the upper end 22a of the door 50. Can be discharged.

The intermediate region 170 is a space in which air flowing out from the door outlet 59 can temporarily stay. Air flowing in the door flow path 50a by the air discharged from the outlet 150 may flow out from the door 50 through the door outlet 59. Therefore, the air leaked from the door 50 through the door outlet 59 passes through the middle region 170 and is formed between the lower end 41a of the battlefield cover 41 and the upper end 22a of the door 50. It can be discharged to the outside of the oven (1) through.

That is, in the middle region 170, when the speed of air discharged from the outlet 150 increases, a low pressure may be formed by the flow of air, and when a low pressure is formed in the middle region 170, a venturi ( The air flowing inside the door 50 due to the ventury effect may flow to the intermediate region 170 through the door outlet 59.

Accordingly, the air inside the door 50 can be easily circulated. That is, in the cooling process of the door 50, outside air is introduced through the door inlet 58 provided at the lower end of the door 50, and the introduced air is flown along the door flow path 50a by the Venturi effect. It rises to the top of the door and flows out from the door 50 through the door outlet 59 to release the heat of the door 50.

Can cool.

In the case of the door 50, since the user must directly grip the door 50 or the handle 56 of the door 50, a stability problem may occur when the temperature of the door 50 increases.

In particular, as in the above-described embodiment, when the door 50 includes the first door 51 or the second door 52 and an additional hinge inside the door 50 is increased, the interior of the door 50 There is a concern that the temperature of the temperature will increase further.

In addition, as described above, when the oven 1 is arranged in one configuration of the system kitchen, a configuration such as a cabinet is arranged around the oven 1 to partially restrict the flow of external air flowing into the oven 1 The amount of air discharged from 150 may be reduced, and accordingly, the amount of air circulated inside the door 50 may be reduced.

In order to prevent this, the oven 1 according to an embodiment of the present invention increases the efficiency of the blower 100, and in detail, increases the speed of the air discharged from the outlet 150 so that it is effectively applied to the intermediate region 170. It is prepared to form a low pressure.

That is, the discharge passage 120 may be provided to increase the speed of discharged air irrespective of the amount of the introduced air, thereby forming a low pressure in the intermediate region 170. Accordingly, the air flowing from the inside of the door 50 along the door flow path 50a easily flows to the intermediate region 170 so that the air inside the door 50 can be easily circulated.

Hereinafter, the improved blowing device 100 will be described.

5 is a plan view of the oven in a state in which the upper surface of the main body is removed in the oven according to an embodiment of the present invention, and FIG. 6 is a side cross-sectional view of a part of a blowing device in the oven according to an embodiment of the present invention 7 is a plan view of the oven in a state in which the upper surface of the main body and the upper surface of the flow path cover are removed in the oven according to an embodiment of the present invention.

As shown in FIGS. 5 to 7, as described above, the discharge passage 120 may be formed by the passage base 130 and the passage cover 140.

The flow path base 130 may be provided in a plate shape disposed above the cooking chamber 30.

The flow path cover 140 may be coupled to the upper surface of the flow path base 140. An internal space formed by the flow path base 130 and the flow path cover 140 may form the discharge flow path 120.

Ends of the flow path base 130 and the front Z of the flow path cover 140 may be spaced apart from each other.

Ends of the flow path base 130 and the front surface Z of the flow path cover 140 may form an outlet 150.

As described above, the outlet 150 may be formed in the front panel 21. That is, the outlet 150 may be formed by an end portion of the flow path base 130 and the front Z of the flow path cover 140 and an opening formed in the front panel 21. Accordingly, it may be described that the outlet 150 is formed in the front panel 21, and it may be described that it is formed by the end portion of the flow path base 130 and the front Z of the flow path cover 140.

The opening of the front panel 21 and the end of the front (Z) and front (Z) of the flow path base 130 and the flow path cover 140 may be spaced apart, but the discharge port 150 is generally provided with the front panel 21 ), the flow path base 130, and the end of the front (Z) of the flow path cover 140 and a space formed at a distance from the front (Z).

The flow path cover 140 may include an upper plate 141 and a side wall 142 extending downward (Y) from the upper plate 141 and in contact with the flow path bar 130.

The discharge passage 120 may be provided in a space formed by an upper surface of the passage base 130, an inner surface of the upper plate 141, and an inner surface of the side wall 142.

The discharge passage 120 has a cross-sectional area (D1, represented by a line in the drawing, but substantially formed in 2 dimensions) formed in a horizontal direction (X) and an up-down direction (Y) perpendicular to the front (Z). It may include a reduction section 121 that decreases in the direction Z.

The discharge flow path 120 has a cross-sectional area (D2, represented by a line in the drawing, but substantially formed in 2 dimensions) formed in the horizontal direction (X) and the vertical direction (Y) perpendicular to the front (Z). It may include a maintenance section 122 maintained constant in the direction Z.

The discharge passage 120 has a cross-sectional area (D3, represented by a line in the drawing, but substantially formed in 2 dimensions) formed in a horizontal direction (X) and a vertical direction (Y) perpendicular to the front (Z). It may include a discharge section 123 formed less than the cross-sectional area (D2) of ).

The discharge section 123 is a section formed between the maintenance section 122 and the discharge port 150, and the air flowing in the discharge passage 120 is immediately before being discharged to the outside of the discharge passage 120 through the discharge port 150. Is the flow section.

The reduction section 121, the maintenance section 122, and the discharge section 123 are sections partitioned by the discharge passage 120, and each section 121, 122, and 123 may be provided to be connected to each other.

The reduction section 121 is a section provided so that the speed of the flowing air increases as the cross-sectional area D1 gradually decreases in the direction Z in which the air is discharged.

The holding section 122 is a section in which the cross-sectional area D2 is maintained in the direction Z in which air is discharged, and the pressure of the air inside the holding section 122 may be kept constant. As the air pressure inside the maintenance section 122 is kept constant, the flow direction Z of the air inside the discharge flow path 120 can be kept constant, and accordingly, the flow of air in the discharge flow path 120 is constant. Can be maintained.

As described above, the discharge section 123 may be provided such that the cross-sectional area D3 is smaller than the cross-sectional area D2 of the holding section 122.

The air flowing in the discharge passage 120 passes through the discharge section 123 before being discharged through the discharge port 150. At this time, the cross-sectional area D3 of the discharge section 123 is the cross-sectional area of the maintenance section 122 ( As it decreases from D2), the speed of air in the discharge section 123 may increase.

Accordingly, the air flowing in the discharge passage 120 may be discharged to the intermediate region 170 through the discharge port 150 in a state where the speed is temporarily increased while flowing along the discharge section 123.

The air is discharged to the intermediate region 170 while the speed is increased, so that air may rapidly flow from the intermediate region 170 to the outside of the oven 1, and accordingly, the intermediate region 170 will maintain a low pressure state. I can.

Accordingly, the air inside the door 50 can easily flow to the intermediate region 170, so that the air inside the door 50 can be efficiently circulated.

That is, the air flowing in the discharge passage 120 may increase the discharge speed while sequentially passing through the holding section 122 and the discharge section 123 to maintain a low pressure in the intermediate region 170.

It can be seen that the discharge section 123 is provided in one area of the maintenance section 122. However, the discharge section 123 may be disposed at an end of the holding section 122 toward the front (Z).

As the area where the discharge section 123 is located is spaced apart from the discharge port 150 with respect to the front (Z), the speed of the discharged air may decrease, and the discharge section 123 is preferably It can be placed on the front end.

In order to reduce the cross-sectional area (D3) of the discharge section (123) than the cross-sectional area (D2) of the maintenance section (122), the flow path cover (140) may include a bent portion (143) formed at the front end of the upper plate (141). have.

The bent part 143 may be bent in the vertical direction (Y). The bent portion 143 is a region bent in a downward direction at a portion adjacent to the front end of the upper plate 141 in the upper plate 141 extending forward (Z).

In detail, when the direction in which the upper plate 141 of the flow path cover 140 extends on the maintenance section 122 is defined as the first direction E1, the point at which the maintenance section 122 changes to the discharge section 123 In (C), the direction in which the upper plate 141 of the flow path cover 140 extends may be switched to the second direction E2.

The direction in which the upper plate 141 of the flow path cover 140 on the holding section 122 extends (E1) and the direction in which the upper plate 141 of the flow path cover 140 on the discharge section 123 extends (E2) ) Can be formed differently.

In detail, the inclination angle in the first direction E1 with respect to the front Z and the inclination angle in the second direction E2 may be set differently. The inclination angle in the first direction E1 may be larger than the inclination angle in the second direction E2.

That is, the extension angle of the upper plate 141 from the bent portion 143 may be provided to be changed at the point C where the maintenance section 122 is changed to the discharge section 123.

In the flow path base 130, the extension direction E3 on the holding section 122 and the discharge section 123 may be provided in the same manner. The extension direction E3 on the holding section 122 and the discharge section 123 in the flow path base 130 is approximately the extension direction of the upper plate 141 on the holding section 122 in the flow path cover 140 ( It can be provided parallel to E1).

However, as described above, as the respective extension directions E1 and E2 on the holding section 122 and the discharge section 123 in the upper plate 141 are formed differently by the bent part 143, the vertical direction ( Y) The height of the maintenance section 122 and the discharge section 123 may be formed differently.

In this case, the sidewall 142 of the flow path cover 140 may be provided such that the width w of the discharge section 123 and the holding section 122 is kept the same in the direction Z in which air is discharged. Accordingly, the cross-sectional area D3 of the discharge section 123 and the cross-sectional area D2 of the holding section 122 may be changed in proportion to the lengths of each of the heights h1 and h2.

That is, the height h1 of the discharge section 123 in the vertical direction (Y) is formed smaller than the height h2 of the maintenance section 122, so that the cross-sectional area D3 of the discharge section 123 is It may be formed smaller than the cross-sectional area D2.

Therefore, when the air flows in the discharge section 123 through the maintenance section 122, the speed increases as the cross-sectional area inside the discharge flow path 120 decreases, and the air with an increased speed passes through the discharge port 150 and the discharge flow path 120 ) It is discharged to the outside so that the intermediate region 170 may be maintained at a low pressure.

Hereinafter, a blowing device 100 of the oven 1 according to another embodiment of the present invention will be described. Configurations other than the configuration of the flow path cover 140 ′ and the discharge flow path 120 ′ described below are the same as the configuration of the oven 1 according to the above-described exemplary embodiment, and thus redundant descriptions will be omitted.

8 is a plan view of the oven in a state in which the upper surface of the main body and the upper surface of the flow path cover are removed in the oven according to another embodiment of the present invention. It is a side cross-sectional view of a part of a blower.

As shown in FIGS. 8 and 9, the flow path cover 140 ′ may include a curved portion 143 ′ disposed at the front end of the side wall 142 ′.

The curved portion 143 ′ may be disposed on the discharge section 123 ′ of the discharge passage 120 ′.

The curved portion 143 ′ may include a curved surface formed in a direction in which the width w1 of the discharge passage 120 ′ with respect to the left-right direction X decreases toward the front Z.

Accordingly, the width w1 of the discharge section 123 ′ may be provided to gradually decrease toward the front Z.

The curved portion 143 ′ may be provided to extend from the point C changed from the maintenance section 122 ′ to the discharge section 123 ′ to the discharge port 150 ′.

Conversely, the width w2 of the holding section 122 ′ in the left-right direction X may be kept constant.

Accordingly, the width w1 of the discharge section 123 ′ may be formed to be smaller than the width w2 of the sustain section 122 ′.

The extending direction E3 of the upper plate 141 ′ of the flow path cover 140 ′ may extend in a direction substantially parallel to the extending direction E3 of the flow path base 130.

In the upper plate 141 ′, the upper plate 141 ′ disposed on the holding section 122 ′ and the discharge section 123 ′ may all extend in the same extension direction E3. Accordingly, the cross-sectional area D3' of the discharge section 123' and the cross-sectional area D2' of the holding section 122' may be changed in proportion to the length of each of the widths w1 and w2.

That is, the width w1 of the discharge section 123' in the left-right direction X is formed smaller than the width w2 of the maintenance section 122', so that the cross-sectional area D3' of the discharge section 123' is the maintenance section. It may be formed to be smaller than the cross-sectional area D2' of (122').

Therefore, when the air flows in the discharge section 123' through the holding section 122', the speed increases and the air with the increased speed increases as the cross-sectional area inside the discharge passage 120' decreases. It is discharged to the outside of the discharge passage 120 ′ so that the intermediate region 170 may be maintained at a low pressure.

The technical idea of the present invention has been described above by a specific embodiment, but the scope of the present invention is not limited to this embodiment. Various embodiments that can be modified or deformed by a person of ordinary skill in the technical field of the present invention also belong to the scope of the present invention within the scope not departing from the gist of the present invention specified in the claims. something to do.

1: oven 10: main body
20: inner case 21: front panel
23: side panel 30: cooking compartment
40: battlefield room 41: battlefield cover
50: door 58: door inlet
59: door inlet 100: blower
110: blower fan 120: discharge passage
121: reduction period 122: maintenance period
123: discharge section 130: euro base
140: euro cover 141: upper plate
142: side wall 143: bend
150: outlet 170: middle area

Claims (20)

A body having a front panel;
A cooking chamber provided inside the main body and opened to the front:
A door for opening and closing the cooking compartment;
A blowing fan disposed above the cooking chamber to blow air sucked in from the outside of the main body;
Includes; a discharge passage configured to discharge the air sucked by the blowing fan to the outside of the body,
The front panel includes a discharge port forming one end of the discharge passage,
The oven in which the cross-sectional area of the outlet is smaller than the vertical cross-sectional area with respect to the front of the discharge passage. The method of claim 1,
The discharge passage has a reduction section in which the vertical cross-sectional area with respect to the front decreases in the direction in which air flows,
And a maintenance section connected to the reduction section and maintaining a constant vertical cross-sectional area with respect to the front side, and a discharge section provided between the discharge port and the holding section and having a vertical cross-sectional area smaller than the cross-sectional area of the holding section Oven. The method of claim 2,
Further comprising a flow path base disposed above the cooking chamber and forming a part of the discharge flow path, and a flow path cover forming another part of the discharge flow path and covering the flow path base,
The flow path cover is an oven in which an extension angle in the front-rear direction in the holding section and an extension angle in the front-rear direction in the discharge section are different. The method of claim 3,
An oven in which an extension angle in the front-rear direction in the discharge section is smaller than an extension angle in the front-rear direction in the holding section. The method of claim 3,
The flow path base oven is provided with the same extension angle in the front-rear direction in the holding section and the same extension angle in the front-rear direction in the discharge section. The method of claim 2,
The oven is provided with a height in the vertical direction in the discharge section is smaller than the height in the vertical direction in the holding section. The method of claim 1,
A flow path base disposed above the cooking chamber and forming a part of the discharge flow path, and a flow path cover forming another part of the discharge flow path and covering the flow path base,
An oven in which the front end portion of the flow path cover is bent. The method of claim 1,
The door includes a door inlet and a door outlet disposed above the door and through which air flowing inside the door is discharged,
The door outlet is an oven disposed adjacent to the outlet. The method of claim 8,
Further comprising an intermediate region formed between the outlet and the door outlet,
The oven is provided such that the air pressure in the middle region is lower than the air pressure inside the outlet and the air pressure inside the door outlet when the blowing fan is driven. The method of claim 2,
The oven in which the width in the left-right direction in the discharge section is smaller than the width in the left-right direction in the holding section. The method of claim 10,
The oven in which the width in the left and right direction in the discharge section gradually decreases toward the front. The method of claim 3,
The flow path cover includes a side wall forming a side of the discharge flow path,
The sidewall is an oven including a curved portion positioned on the discharge section. The method of claim 2,
The reduction section is provided so that the speed of the air flowing in the reduction section increases toward the discharge port.
The holding section is provided so that the speed of air flowing in the holding section is constant,
The discharge section is an oven provided so that the speed of the air flowing in the discharge section is greater than the speed of the air flowing in the holding section. A body having a front panel;
A cooking chamber provided inside the main body and opened to the front:
A door for opening and closing the cooking compartment;
A blowing fan disposed above the cooking chamber to blow air sucked in from the outside of the main body;
A discharge passage configured to discharge the air sucked by the blowing fan to the outside of the main body;
A flow path base disposed above the cooking chamber and forming a part of the discharge flow path;
Further comprising; a flow path cover forming another part of the discharge flow path and covering the flow path base,
The front panel includes a discharge port forming one end of the discharge passage,
An oven in which a front end portion of the flow path cover connected to the outlet is bent. The method of claim 14,
The discharge passage has a reduction section in which the vertical cross-sectional area with respect to the front decreases in the direction in which air flows,
A maintenance section connected to the reduction section and maintaining a constant vertical cross-sectional area with respect to the front side,
An oven including a discharge section corresponding to the front end of the flow path cover in a vertical direction and having a vertical cross-sectional area smaller in the front side than the cross-sectional area of the holding section. The method of claim 15,
The flow path cover is an oven that is provided larger than an extension angle in the front-rear direction in the holding section and an extension angle in the front-rear direction in the discharge section. The method of claim 15,
Oven provided that the height in the vertical direction in the discharge section is smaller than the height in the vertical direction in the holding section The method of claim 15,
The oven in which the width in the left-right direction in the discharge section is smaller than the width in the left-right direction in the holding section. The method of claim 18,
The oven in which the width in the left and right direction in the discharge section gradually decreases toward the front. The method of claim 15,
The flow path cover includes a side wall forming a side of the discharge flow path,
The sidewall is an oven including a curved portion positioned on the discharge section.

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