RU2419748C2 - Built-in electric stove - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: built-in electric stove includes upper panel, the main housing located under upper panel, cabinet including the main housing, upper frame located above the space formed between at least the angle of upper panel and cabinet, which is designed for closing the above space, air outlet hole allowing to remove inside air of the main housing through upper frame; at that, air outlet hole includes the first outlet hole for fluid medium made in the main housing in order to ensure the removal of inside fluid medium from the main housing; the second outlet hole for fluid medium made in surface of upper frame to provide the flow of fluid medium through the first hole for fluid medium to upper frame, and the third outlet for fluid medium made at least in side surface on the edge of upper frame in the direction of the length in order to provide the removal of fluid medium through the second hole for fluid medium to outer side of upper frame in the direction of length of upper frame.

EFFECT: improving cooling efficiency of electric stove, improving safety and operating convenience of electric stove.

9 cl, 21 dwg

Description

FIELD OF THE INVENTION

This document relates to a built-in electric stove, namely to a built-in electric stove having a top panel on which food is cooked.

BACKGROUND OF THE INVENTION

The built-in electric stove is a kitchen appliance installed in the cabinet. That is, the built-in electric stove is connected to the kitchen furniture in such a way that the user can easily use it. Built-in electric stove decorates the kitchen interior.

In recent years, a built-in electric stove has been created that has a top panel on which it is possible to cook food using heat transferred to the cooked food through this top panel. Such a built-in electric stove with a top panel is called a stove, hob, stove or hob. Regardless of the name, the concept of the present disclosure can be attributed to any electric stoves having a top panel. In the following description, the term "electric stove" means the actual stove having a top panel.

To control the components in a stable thermal regime, a typical electric stove is designed so that air passes both inside and inside the electric stove. For this, the upper panel is made protruding above the upper surface of the cabinet to a predetermined height. In this case, cleaning the area around the top panel is difficult, and this affects the appearance.

In a typical electric stove, water can be poured into the main body of the electric stove through the air passage hole made in the upper panel or in the area around the upper panel. In this case, water poured into the main body of the electric stove may cause a short circuit or malfunction of the electric stove. This problem should be taken into account when developing an electric stove, since the electric stove works in the kitchen, where water is often used.

SUMMARY OF THE INVENTION

Technical problem

The proposed options for the implementation of the built-in electric stove, made with the possibility of effective cooling of the internal cavity of the electric stove, having a minimum height of the protrusion of the electric stove relative to the cabinet and a lower likelihood of water flowing into the electric stove.

Technical solution

In an embodiment, the built-in electric stove contains: a top panel; main body located under the top panel; a cabinet incorporating a main body; an upper frame located above the space formed between at least the angle of the upper panel and the cabinet, designed to close this space; and an air outlet allowing the internal air of the main body to be discharged through the upper frame, wherein the air outlet includes: a first fluid outlet made in the main body to provide an outlet from the main body of the internal fluid of the main body; a second fluid outlet made in the surface of the upper frame to allow fluid to pass through the first fluid inlet to the upper frame, and a third fluid outlet made at least in a side surface on an edge of the upper frame in a length direction, to allow fluid to exit through the second fluid opening to the outside of the upper frame in the length direction of the upper frame.

Preferably, the upper frame comprises: a supporting part holding at least one surface of the upper panel, and a contact part in contact with the cabinet.

The support portion is preferably in contact with the lower and upper surfaces of the upper panel, so that it wraps around the upper panel.

The connecting part connecting the support part and the contact part preferably covers the space for air flow.

The contact portion is preferably in contact with the upper surface of the cabinet.

The lower surface of the upper panel is preferably located at the same horizontal level as the upper surface of the cabinet.

An air outlet is formed inside the upper frame and is made longitudinally in the upper frame, while the air outlet opens air in a direction extending to the upper panel.

Positive effects

In accordance with the above options, the cooling efficiency of the electric stove can be increased, in addition, the safety and convenience of working with the electric stove can be increased.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 is a perspective view of a built-in electric stove in accordance with the present invention when the stove is installed.

Figure 2 is a perspective view of the built-in electric stove of figure 1, when the stove is fully installed.

Figure 3 shows a partially cutaway perspective view of the integrated electric stove of figure 1.

Figure 4 is a section taken along the line I-I 'shown in figure 2.

Figure 5 is an enlarged view of part A in figure 4.

6 is a local section of an example of a modified built-in electric stove according to the first embodiment.

7 is a perspective view of a built-in electric stove in accordance with a second embodiment of the present invention when the stove is installed.

Fig. 8 is an exploded schematic perspective view of the integrated electric stove of Fig. 7.

Fig.9 is a perspective view in partial section of a built-in electric stove in Fig.7.

Figure 10 is a section along the line II-II 'of Fig.9.

11-14 are examples of modified embodiments of the built-in electric stove according to the second embodiment of the present invention.

Fig is a perspective view in partial section of a built-in electric stove in accordance with a third embodiment.

Fig.16 is a perspective view of the upper frame shown in Fig.15.

Fig. 17 is a section taken along line III-III 'shown in Fig. 5.

On Fig presents a perspective view of an example of another embodiment of the upper frame.

On Fig and 20 shows a cross section of most of the elements of the fourth embodiment.

21 is an example of a modified third embodiment.

PREFERRED EMBODIMENTS OF THE INVENTION

Next will be described in detail embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

[First embodiment]

Figure 1 is a perspective view of the built-in electric stove in accordance with the present invention, when the stove is installed, and Figure 2 is a General view of the built-in electric stove in figure 1, when the stove is fully installed.

Shown in figures 1 and 2, the built-in electric stove in this embodiment includes a cabinet 1 installed in the kitchen, a recessed part 2 made in the upper surface of the cabinet, a water outlet 4 formed in one place of the recessed part 2 of the cabinet 1, and a stove 5 having the first part, placed in the deepened part 2, and the second part mounted on the upper surface of the cabinet 1.

In more detail, the recessed part 2 is performed in the upper surface of the cabinet 1 to a certain depth for receiving the first part of the plate 5.

The recessed part 2 is less than the area of the upper surface of the plate 5. Therefore, when the plate 5 is placed in the recessed part 2, the end part of the plate 5 rests on the upper surface of the cabinet 1.

In more detail, in the upper part of the plate 5 there is an upper panel 51 (see figure 3), which is installed on the upper surface of the cabinet 1.

Therefore, since the upper panel 51 is mounted on the upper surface of the cabinet 1, only this upper panel 51 protrudes above the upper surface of the cabinet. Therefore, the height of the portion of the plate 5 protruding from the cabinet 1 may be minimal.

When the plate 5 is installed in the cabinet 1, the back of the upper panel 51 does not rest on the upper surface of the cabinet 1. That is, since between the rear end of the plate 5 and the cabinet 1 it is necessary to create a space for the output of the internal heated air of the plate 5, the rear end of the upper panel 51 is not mounted on the upper surface of cabinet 1, but is spaced from it.

That is, if the rear end portion of the upper panel 51 is mounted on the cabinet 1, then there is no space through which the internal heat of the plate 5 could come out. Therefore, the rear end part of the upper panel 51 must be spaced from the upper surface of the cabinet 1. In this case, the rear end part of the upper panel 51 is supported by the supporting element 7 mounted on the cabinet 1.

Since the upper panel 51 is mounted on the cabinet 1 in the manner described above, it is possible to stably place the dishes on the upper surface of the upper panel 51. In addition, since only the upper panel 51 protrudes above the upper surface of the cabinet 1, the appearance of the electric stove can be significantly improved.

However, although the bottom of the recessed part 2 is closed, air can pass into the recessed part 2 through other gaps of the cabinet, and this air can be directed into the plate 5.

Further, right below the passage through which water flows from the plate 5, an opening 4 may be provided for discharging water. If the bottom of the recessed part 2 is inclined, then the water outlet 4 is made in the lowest part of the inclined bottom of the recessed part 2.

Figure 3 shows a partially cut away perspective view of the built-in electric stove of figure 1, figure 4 is a section taken along the line I-I 'shown in figure 2, and figure 5 is an enlarged view of part a on figure 4.

As shown in FIGS. 3-5, the stove 5 comprises an upper panel 51 that acts as a base plate on which the cooking utensils are located and a main body 52 located under the upper panel 51.

The appearance of the main body 52 is determined by the frame of the body. In the main body 52, a heater 54 is provided for generating heat and a fan 53 for discharging hot air from the main body 52 to the outside. As a heater, any type of heaters can be used: direct heaters or induction heaters.

As described above, since the front and side edge parts of the upper panel 51 rest on the upper surface of the cabinet 1, only the upper panel 51 protrudes above the cabinet.

On the other hand, the rear edge part of the upper panel 51 is supported by a support element 7 mounted on the cabinet 1. In more detail, the support element 7 is mounted on the cabinet 1 and fastened to a surface forming the recessed part 2 of the cabinet 1. The fastening of this support element can be performed by a fixing element or with glue. However, the present invention is not limited to this configuration.

It should be understood that the space through which hot air is discharged to the outside is eliminated by this supporting element 7. But in this embodiment, the role of such a space is played by the hole for the air flow formed by the supporting element 7.

Next, the support element 7 is described in more detail.

The supporting element 7 comprises a supporting part 72 supporting the rear edge part of the upper panel 51, a connecting part 74 connected to the cabinet 1, and a connecting part 76 connecting the supporting part 72 to the fixing part 74.

In more detail, the cross section of the support portion 72 is a □ -shaped shape that supports the upper panel 51. Further, by this shape of the support portion 72, the rear edge portion of the upper panel 51 is partially inserted into the support portion 72.

In this case, the supporting part 72 supports at least one of two corresponding surfaces (upper and lower) of the upper panel 51. That is, the supporting part 72 has a space into which the upper panel 51 is partially inserted. When this space of the supporting part 72 is higher than the upper panel 51, one of the two corresponding surfaces of the upper panel 51 is in close contact with the supporting part 72. In this case, the upper surface of the upper panel 51 is in tight contact with the supporting part 72 so as to prevent the ingress of foreign objects through the space formed between the upper panel 51 and the support part 72. It is preferable that the support part 72 supports at least three surfaces of the upper panel 51. Namely, as shown in FIG. 5, a curved plate is provided and the upper panel 51 is firmly supported. provided by three surfaces of this curved plate in contact with it.

Since at least the front and both side edge parts of the upper panel 51 rest on the upper surface of the cabinet 1, the upper panel 51 can stably support the cabinet 1 even if the rear edge of the upper panel 51 is not supported by the supporting part 72. However, in order to hold the upper panel 51 more securely, the supporting part 72 can also support its upper and lower surfaces and on the sides.

At the same time, the fastening part 74 is located on that part of the support element 7, which is remote from the support part 72, in this place it rests on the cabinet 1 to form a passage through which air is discharged outward from the main body 52.

The connecting part 76 "softly" connects the supporting part 72 with the mounting part 74. The connecting part 76 projects above the upper panel 51 to a predetermined height. Therefore, when the cookware slides back, its sliding is stopped by the connecting part 76.

Only the connecting part 76 of the supporting element 7 is open into the external space. Therefore, it should be understood that the connecting part 76 also performs the function of “inner shielding” of the supporting part 72 and the fastening part 74. A gap defined by the reference is established between the upper panel 51 and the cabinet element 7, and the connecting part functions as an upper frame covering this gap.

Next, the installation process of the stove 5 will be described.

First of all, the support element 7 is installed on the cabinet 1. In this case, the support element 7 is installed in the place where it should support the back of the plate 5. That is, after the connecting part 74 is installed on the cabinet 1, the support element 7 is connected to the cabinet 1 using the connecting element.

In this position, the lower part of the plate 5, that is, the main body 52 of the plate 5, is inserted into the recessed part 2. Then, the front and both side edges of the upper panel 51 are installed on the cabinet 1. Next, the plate 5 is pushed in the rear direction. After that, the rear edge part of the upper panel 51 is inserted into the supporting part 72, which completes the installation of the plate 5.

Next will be described the course of the air flow cooling the interior of the plate 5.

First, when the fan 53 is operating, cold air is introduced into the stove 5. Cold air can be introduced through the air inlet made in the bottom of the main body 52 coaxially with the fan.

Cold air introduced through the air inlet 55 may be sucked through the gap of the cabinet 1, which is formed in front of the recessed portion 2 of the cabinet. Needless to say, when the bottom of the recessed part 2 is formed with an opening, cold air can be sucked in through the bottom of the recessed part 2.

The air sucked in by the fan 53 is discharged through an air outlet 56 formed in the rear of the main body 52, bypassing the control unit (not shown) and the heater 54. The air discharged from the air outlet 56 is led out further through the air flow hole 75.

In order for the air discharged from the air outlet 56 not to go to other areas of the recessed part 2, but to go only to the air hole 75, an air flow guide 65 can be installed in the rear of the main body 52.

The following describes the relationship between the water trapped in the stove 5 and this embodiment.

First, since the stove 5 is installed in a place such as a kitchen where water is often used, it is necessary to prevent water from flowing into the hob 5. To do this, the lower surface of the upper panel 51, as well as the surface of the cabinet 1 are jointly sealed on the front and both sides of the upper panels 51 with a sealing element. Therefore, the weak point through which an external stream of water can penetrate the plate 5 is only the upper element 6, in which the hole 61 is formed.

That is, water can enter the plate 5 through the hole 61. However, since the water entering the plate 5 flows downward through the air flow hole 77 made in the support member 72, it does not go to the main body 52.

In more detail, the air flow hole 77 provided in the support member 7 functions as a passage through which externally penetrated water can flow downward without entering the main body 52, while at the same time fulfilling a passage through which air is discharged to the outside, coming out of the main body 52.

The water flowing down can be discharged through the opening 4 for water outlet, or it can evaporate due to the heat generated by the stove 5.

The following describes a modified example of this embodiment of the invention.

First, when the recessed part 2 is closed, the water outlet 4 serves to discharge the water accumulated in the recessed part 2. When the recessed part 2 is not closed but opened, a water collecting container may be installed under the recessed part 2, which will collect water flowing down from stove 5, and then drain it out.

The upper frame can be designed so that its first side is fixed to the cabinet 1, and the second side would be removed from the upper surface of the upper panel. In this case, a front hole is formed between the upper panel and the upper frame, and air can pass through this front hole.

In this case, since the air exiting from the inner space is divided into two streams, its efficiency can be improved by decreasing the resistance to the air stream. In addition, the noise caused by this air flow can be reduced.

In addition, the air exiting through the front opening can provide rapid dissipation of a large amount of heat from the upper surface of the upper panel. Therefore, when using the stove, heat can be quickly removed from the top panel. This increases safety when using the stove.

There is no need to say that when you start working on the stove, when all the dishes are on the top panel, the air leaving the front hole can transfer heat from the top panel to this tableware. In this case, since the top panel is in close contact with the dishes, air cannot pass into the places of their contact between the top panel and the dishes. Therefore, the problem of heat dissipation is not serious. In addition, the implementation of the front hole and the rear hole with the optimal ratio of their sizes can eliminate the drop in thermal efficiency while ensuring safe operation with the stove 5.

Next, the cooling process by the air flow of the internal cavity of the plate 5 will be described.

First, when the fan 53 is operating, cold air is introduced into the hob 5. Cold air can pass through an air inlet made in the bottom of the main body 52 coaxially with the fan 53.

Cold air entering through the air inlet 55 can be sucked through the gap of the cabinet 1, which is formed in front of the recessed portion 2 of the cabinet. Needless to say, when the bottom of the recessed part 2 is formed with an opening, cold air can be sucked in through the bottom of the recessed part 2.

The air sucked by the fan 53 exits through the air outlet 56 made in the rear of the main body 52, bypassing the control unit (not shown) and the heater 54. The air exiting the air outlet 56 is directed into the space between the support element 7 and the upper element 6 through hole 77 for airflow. Air directed into this space exits through the opening 61 in the upper element 6.

In order for the air leaving the air outlet 56 not to go to other spaces of the recessed part 2, but to go only to the air flow hole 75, an air flow guide 65 can be installed in the rear of the main body 1.

Although several airflow guides 65 are shown in the drawing, corresponding to several airflow openings 56, only one airflow guide 65 can be provided having a protrusion in the direction of the airflow opening 75.

As described previously, since holes 77 for air flow are formed in the support member 7, a hole 61 is formed on the top member 6, hot air from the plate 5 can exit through the air flow hole 77 and the hole 61.

The following describes the relationship between the fluid around the plate 5 and this embodiment of the invention.

First, since the stove 5 is installed in a place such as a kitchen where water is often used, it is necessary to prevent water from flowing into the hob 5. To do this, the lower surface of the upper panel 51, as well as the surface of the cabinet 1 are jointly sealed on the front and both sides of the upper panels 51 with a sealing element. Therefore, the weak point through which the external flow of water can penetrate the hob 5 is only the supporting element 7, in which the hole 75 for the air flow is made.

That is, water can enter the plate 5 through the air flow opening 75. However, since water entering the hob 5 flows downwardly along the gap formed between the support member 72 and the fastening part 74, it does not flow towards the main body 52.

In more detail, the gap between the mounting portion 74 and the support portion 72 functions as a passage that allows outside water to flow downward without flowing into the main body 52, while also designating a passage through which air exiting the main body 52 is outwardly discharged.

The water flowing down can be discharged out through the water outlet 4, or it can evaporate due to the heat generated by the hob 5.

Fig.6 is a local section of a modified example of a built-in electric stove shown in Fig.1-5.

With reference to FIG. 6, only features other than those of the previously described embodiment will be described.

As shown in FIG. 6, the support member 8 includes a support portion 81 supporting the rear edge portion of the upper panel 51, a seating portion 82 resting on the cabinet 1, and a connecting portion 84 connecting the support member to the seating portion 82. In the seating portion 82, a hole 83 for air flow through which air can exit.

That is, in this modified example, the landing portion 82 is not connected to the cabinet 1, but simply relies on it. Therefore, the structure linking the support member 8 to the cabinet 1 can be omitted, and thus the design of the support member 8 can be simplified. In addition, since in this case there is no need to perform the operation of fastening the support element 8 to the cabinet 1, the installation process of the plate 5 can also be simplified and can be performed very quickly.

[Second embodiment]

In accordance with the hallmark of the first embodiment, the support element supports the edge of the upper panel, while allowing air to go out. Next, another embodiment of the upper frame will be described.

7 is a perspective view of a built-in electric stove in accordance with a second embodiment of the present invention when the stove is installed.

In accordance with Fig.7 cabinet 100 is installed in the kitchen. In the cabinet 100, a receiving portion 120 is formed defining the interior of the cabinet 100 and recessed downward to provide space for installing at least a portion of the plate. This plate is partially inserted in the receiving part 120.

The stove is part of the cabinet 100 and can be inserted with the microwave.

When the plate is partially inserted into the receiving part 120, the upper panel 200, which determines the front appearance of the plate, is supported by the cabinet 100. The receiving part 120 may be equipped with a seating part on which the upper panel 200 is supported. The seating part is recessed along the upper end edge of the receiving part 120 for supporting the edge of the lower surface of the upper panel 200.

That is, the landing part is recessed in the edge part of the receiving part 120 by an amount that can vary depending on the installation method of the plate.

When the upper panel 200 is mounted so that it protrudes above the upper surface of the cabinet 100, there is no need to form a landing portion, or the depth of the landing portion is very small. If the upper panel 200 is installed in such a way that it is located below the upper surface of the cabinet 100, then the landing part is recessed by an amount greater than the thickness of the upper panel 200.

When the upper panel 200 sits on the landing portion, the front and both side edges of the upper panel 200 are supported by the landing portion. However, the rear edge of the upper panel 200 is not supported to form a gap through which hot air generated in the plate can exit.

On Fig shows an exploded perspective image of the built-in electric stove in Fig.7, and Fig.9 shows a perspective view with a partial section of the built-in electric stove in Fig.7.

On Fig and 9, the upper panel for determining the appearance of the upper part of the hob, as well as for direct or indirect support of cookware is installed on the upper edge of the stove. An interior space is formed in the lower part of the upper panel 200, and a main body 300, in which a plurality of components are located, is provided in the interior space. The general view of the plate is determined by the upper panel 200 and the main body 300.

The upper panel 200 is formed by a tempered rectangular glass panel having a predetermined thickness such that it can withstand the heat generated by the heater installed in the main body 300.

The upper panel 200 is supported by a seat recessed in the extreme part of the receiving part 120, or by the upper surface of the cabinet 100. In this embodiment, the lower surface of the upper panel 200 is supported by a seat so that the upper surface of the upper panel 200 and the upper surface of the cabinet 100 can be located in the same horizontal plane. However, the present invention is not limited to such a configuration.

The upper frame 210 is located between the edge of the upper panel 200 and the upper surface of the cabinet 100. Therefore, the space between the edge of the upper panel 200 and the upper surface of the cabinet 100 is blocked by this frame 210. Moreover, regardless of whether there is between the edge of the upper panel 200 and the upper surface of the cabinet 100 a gap or not, the upper frame 210 is set to determine the boundary between the upper surface of the upper panel 200 and the upper surface of the cabinet 100. But the upper frame 200 is not located in the part through which the internal hot ozduh, i.e. between the rear of the top panel 200 and the cabinet 100. Even if the upper frame 200 installed between the rear portion of the upper panel 200 and the cabinet 100, vozduhovyvodnoe opening for hot air outlet formed. Moreover, under the upper frame located between the rear of the upper panel 200 and the cabinet 100, the main body 300 and the cabinet 100 are separated from each other with a given gap. Air or water may pass through this gap.

The place where the dishes can be located is indicated on the upper front end part of the upper panel 200 so that the user can lay it correctly. A control unit 220, allowing the user to control the operation of the plate, is located in the upper front end portion of the upper panel 200.

In accordance with this embodiment, the upper surface of the upper panel 200 and the upper surface of the cabinet 100 are located in the same horizontal plane, which improves the appearance of the plate.

At least one heater 310, which generates heat used for cooking, and a fan 320, which forcibly draws hot air generated in the main body 300 from this main body 300 to cool the inner cavity of the main body 300, are installed in the main body 300. As a heater 310, all types of heaters can be used — direct or indirect heaters, as well as combinations thereof.

When it is understood that the user location of the electric stove is on its front side, the rear end portion of the upper panel 200 located above the main body 300 is located closer to the front than the rear surface of the receiving part 120. That is, the length from the front to the rear edge of the upper panel 200 less than the length from the leading to the trailing edge of the receiving portion 120, so that a predetermined space is formed between the rear surface of the upper panel 200 and the rear end portion of the receiving portion 120.

The upper panel 210 is mounted above the space formed between the rear end portion of the upper panel 200 and the rear end portion of the receiving part 120 to cover this space between the upper panel 200 and the cabinet 100.

Between the rear surface of the upper panel 200 and the cabinet 100, a support member is mounted holding the upper panel 200. The support member 400 is formed of a rectangular plate of a predetermined thickness. The portion of the support member 400 that is associated with the cabinet 100 is folded laterally to form a surface associated with the cabinet 100.

The support member 400 has a first end portion located beneath the top panel 200 to support the top panel 200, and a second end portion attached to the cabinet 100 by a fastener, such as a screw, to prevent the top panel 200 from coming down.

Figure 10 is a section along the line II-II 'in figure 9.

As shown in FIG. 10, the support member 40 is formed of a rectangular plate of a predetermined thickness. The rear half of the support member 40 is bent down so that, when viewed from the right, the support member is □-shaped. To hold the upper panel 200, a plurality of support elements 400 are used, which are mounted spaced apart from one another at a predetermined distance. Alternatively, only one support member 400 can be mounted to hold the top panel 200.

The support member 400 has a horizontal portion formed by a rear half bent downward and partially located below the upper panel 200 to hold the upper panel 200, and a vertical portion bonded to the cabinet 100.

The horizontal portion of the support member 400 supports the lower surface of the upper panel 200. The vertical portion is integral with the horizontal portion and is attached to the vertical portion of the cabinet 100 by a screw. The vertical portion of the support member 400 has a screw hole by which it is attached to the vertical portions of the cabinet 100. The screw hole is oval so that the height of the support member 400 can be adjusted.

The screw hole may be multi-stage so that the height of the support member 400 can be adjusted within a predetermined range. That is, in this case, in the inner circumference of the screw hole, support projections are formed for stopping the screw. A plurality of screw holes can be made along the vertical line so that the screws can be screwed into one of them in accordance with the position of the support member 400.

When the height of the support member 400 is adjusted as described above, the tilt and position of the upper panel 200 held by the support member 400 can be precisely set.

The support member 400 may be fastened to the cabinet 100 in a variety of ways, such as using glue, screws, hooks, and the like. In this embodiment, the screws are used as fasteners for example.

When the supporting member 400 is bonded to the cabinet 100 to hold the upper panel 200, its separation downward from the receiving portion 120 is thereby eliminated.

The following describes how internal hot air is withdrawn from the main body.

Hot air (containing other fluids) formed in the interior of the main body 300 has a first opening 330 for its outlet through which it is discharged from the main body 300.

In this embodiment, a first hole 330 is formed in the rear surface of the main body 300 to discharge hot air generated in the interior of the main body 300 to a vertical portion of the cabinet 100. A first hole 330 may be formed in the side surface of the main body.

At the same time, in the horizontal section of the support element 400, a second hole 520 is made, through which hot air passing through the first hole 330 comes out.

The shape of the second hole 520 is not limited to any one special view, provided that it removes air. For example, the second hole 520 may be oval, elongated in the horizontal direction, or may be slit-like. The second hole 520 may be made in the form of multiple holes. When a plurality of support elements 400 are used in this embodiment, the gaps between it may form a second hole 520.

When the second hole 520 is formed in a horizontal portion of the support member 400, the second hole 520 is located between the rear end portion of the upper panel 200 and the vertical portion of the cabinet 100.

The following describes the design corresponding to the case when water is poured onto the upper surface of the plate.

First of all, a sealing element is used to seal the contact surface between the lower surface of the upper panel 200 and the portion of the receiving part 120 on which the upper panel is mounted in the front and both side parts of the upper panel 200. Therefore, the external fluid flow into the main body 300 cannot penetrate. But the external fluid may leak from the outside inward through the rear edge of the upper panel.

Fluid flowing through the space formed between the rear edge portion of the upper panel 200 and the cabinet 100 flows downward through the second opening 520. Water flowing downward through the second opening 520 is discharged from the cabinet 100 through an outlet formed in the cabinet 100 located under the receiving part 120. To ensure this, the rear edge of the upper panel 200 is located at a predetermined distance from the cabinet 100, and the cross-sectional area of the main body 300 located under the upper panel 200 is less than the cross-sectional area of the upper panel 200. Therefore, the water flowing downwardly through the second opening, can not penetrate into the main body 300.

In addition, an upper frame is additionally provided above the support element 400, and a small hole is made in this upper frame, through which water can also flow, which even more reliably prevents external water from flowing inward. Moreover, the upper frame in this embodiment is somewhat different from the upper frame of the first embodiment. That is, in this case, the upper frame is not used as a support element, but only as a cover covering the space formed by the support element.

11-14 are views of altered examples of the built-in electric stove according to the second embodiment of the present invention.

In the example of the modified embodiment of FIG. 11, the method of holding the upper panel 200 using the support member 400 is changed. In more detail, the extreme part of the main body 300 is curved outward and fixed under the lower surface of the upper panel 200. The support member 400 is fixed to the lower surface of the edge part of the main body .

12-14 show examples of another embodiment of the second hole 520 in the support member. 12, a plurality of support elements are shown, and a second hole 520 is defined between the support elements. On Fig shows one second hole 520 oval, made in a single support element. On Fig shows several second holes 520, made in a single support element.

[Third embodiment]

In the first and second embodiments, a large air outlet is provided on the support element or on the upper frame. In this case, water may flow into the main body from the outside. This can lead to malfunction of the stove. The third embodiment is intended to solve this problem. Next, only those parts of the third embodiment that are different from the previously described parts will be described.

An upper frame 210 is mounted above the space formed between the rear end part of the upper panel 200 and the rear end part of the receiving part. In accordance with a feature of this embodiment, the upper frame 210 is for laterally discharging internal hot air from the main body 300.

On Fig shows a perspective view in partial section of a built-in electric stove in accordance with the third embodiment, and on Fig presents a perspective view of the upper frame shown in Fig.

As shown in FIGS. 15 and 16, the upper frame 210 is used as a cover covering the space formed between the rear edge of the upper panel 200 and the cabinet 100. The upper frame 210 comprises a upper panel 211 defining the appearance of the upper part, a lower panel 212 defining the appearance of the lower part, a rear panel defining the appearance of the rear part, and side panels 214 defining the appearance of the side parts.

The upper panel 211 is formed from a horizontally rectangular panel having a predetermined thickness. The rear panel 213 is formed by the bent back of the upper panel 211. The rear panel 213 tilts downward as it is removed. The rear panel 213 is formed from a horizontally located rectangular panel having a predetermined thickness. The bottom panel 212 is formed by the forward portion of the rear panel 213 bent forward. The bottom panel 212 is formed from a horizontally positioned rectangular panel having a predetermined thickness. The bottom panel 212 is larger than the top panel 211.

Side panels are located between the upper and lower panels 211 and 212. Each of the side panels 214 is formed from a rectangular panel having a predetermined thickness. The right surface of each of the side panels 214 goes down as it moves away.

The front end of each of the side panels 214 is located behind the front end parts of the upper and lower panels 211 and 212. The length of the upper surface of the side panel 214 is less than the length from the front to the rear of the upper panel 211. The length of the lower surface of the side panel 214 is less than the length from the front to the rear of the bottom panel 212. Moreover, when the rear surface of the side panel 214 is located in the same plane as the rear surface of the rear panel 213, the front end portion of the side panel 214 is located behind the front the front parts of the upper and lower panels 211 and 213.

The distance between the lower surface of the upper panel 211 and the upper surface of the lower panel 212 corresponds to the thickness of the upper panel 200. Therefore, the height of the side panel 214 is set in accordance with the thickness of the upper panel 200. Moreover, the length from left to right of the upper panel 211 and the length from left to right of the lower panel 212 are selected in accordance with the length from left to right of the upper panel 200.

The top frame has an open front. The rear end portion of the upper panel 200 is inserted into the upper frame 210 through its open front portion. When the upper panel 200 is inserted between the upper and lower panels 211 and 212, the front end portion of the upper frame 210 supports the opposite surface of the upper panel 200, and the front surface of the side panels 214 supports the rear surface of the upper panel 200.

A feature of this embodiment is that the lower panel 212 of the upper frame 210 has a second air outlet 430 through which hot air exiting the first air outlet 330 enters the interior of the upper frame 210. The hot air entering the upper frame 210 through the second the air outlet 430 is brought out through the third air outlet 450, made in the side panels 214.

In the above construction, air escapes through air outlets formed in both side surfaces of the upper frame 210. In this case, the area through which external water can flow inward is small. Therefore, the malfunctioning of the plate due to the ingress of water into it can be prevented.

Fig. 17 is a section taken along line III-III 'shown in Fig. 5.

Next, with reference to Fig.7 will be described the operation of the third embodiment.

An air outlet 330 is provided in the rear surface of the main body 300 for discharging hot air heated by a heater 310 installed in the main body 300 from this main body 300.

The first air outlet 330 may be formed in both side surfaces, in the front surface or in the lower surface of the main body 300. In this case, the air outlet efficiency, however, is reduced. Therefore, it is preferable that the first air outlet 330 is formed in the rear surface of the main body 300. Alternatively, the first air outlet 330 may be absent. In this case, a special passage is formed to remove hot air from the main body 300.

As described above, when the first air outlet 330 is formed in the main body 300, the hot air formed in the main body 300 leaves the main body 300, that is, flows in the direction of the space between the main body 300 and the cabinet through the first air outlet 330.

Hot air flows in the direction of the space between the rear surface of the main body 300 and the cabinet 100 and rises up under the influence of a phenomenon called convective flow. The air going up is directed to the upper frame 210.

In this case, a second air outlet 430 is made in the upper frame 210, through which hot air passing through the first air outlet 330 is directed to the upper frame 210. Each of the side panels defining both side surfaces of the upper frame 210 has a third air outlet 450, so that air can escape through both side surfaces of the upper frame 210.

A third air outlet 450 is formed behind the rear surface of the upper panel 200 supported by the front end portion of the upper frame 210. In addition, a second oval air outlet 430 may be formed in each of the rectangular side panels 214.

On Fig presents a perspective view of an example of another design of the upper frame.

18, the length from the front to the rear of the side panel 214 is greater than the length from the front to the rear of the upper and lower panels 211 and 212. The left and right side surfaces of the upper panel 200 are supported by the side panels 214. In this design, the position of the upper panel 200 and the upper frame 210 relative to each other can be precisely set.

The panels of the upper frame 210 may be formed by independent elements assembled with each other. Alternatively, the panels of the upper frame 210 may be formed as a result of processing a single element.

According to an example of another modification of the third embodiment, the second air outlet 430 is formed in a lower panel 212 defining the lower part of the upper frame 210. The second air outlet 430 may be rectangular or in the form of slots formed in the lower panel at predetermined intervals. Instead of forming a second air outlet, a special passage can be formed that directs hot air into the upper frame.

In the above description, a third air outlet 450 is provided in each of the side panels 214. But the present invention is not limited to this configuration. For example, a third air outlet 450, which is designed to discharge hot air from the upper frame 210, can be formed in the rear panel 213 and / or in the upper panel 211, as well as in the side panels 214. In this case, since the area of the output air increases, hot air can be discharged more efficiently. However, when the air discharge area increases, the area through which water can penetrate increases. The air outlets formed in the rear panel 213 and the upper panel 211 do not form a continuous zone, but are spaced. In this case, the manufacturing process of the upper frame 210 becomes more complex. However, the efficiency of hot air removal has increased. That is, a relatively large amount of hot air can now be removed in a limited time interval.

Alternatively, the side panels 214 can be made protruding forward to a greater extent, with a third air outlet 450 can be made in the protruding part of each of the side panels 214 to increase the area of this third air outlet 450. In this case, since the upper panel and the cabinet is sealed together on each side, water cannot flow into the main body. Thus, while the area through which the air is discharged has increased, water cannot enter the main body through the side panels 214. As a result, since hot air can be effectively discharged, the safety of using the stove can be improved. In this case, the third air outlet 450 can be made in a place located above the upper surface of the cabinet 100. Therefore, the reliability of preventing water from flowing into the main body 300 through the air outlet formed in the upper frame 210 can be improved.

In the above description, the upper frame 210 is located along the upper edge of the upper panel 200. But the present invention is not limited to this configuration. The upper frame 210, for example, can be mounted on the front and both side edge parts of the upper panel 200.

In addition, the upper frame 210 located on the rear edge of the upper panel 200 is formed so that a surface bent downward from the front edge of the lower panel 212 is bonded to the rear surface of the main body 300.

In the above embodiment, an air outlet formed in the upper frame 210 maintains its open state. But the present invention is not limited to this configuration. For example, an air outlet cover may be provided for selectively opening and closing the air outlet. In this case, however, the appearance of the electric stove as a product may be impaired.

[Fourth embodiment]

The fourth embodiment is substantially identical to the first and third embodiments, with the exception of the design of the support elements and the mounting method. Next, only the distinguishing parts will be described.

On Fig and 20 shows a cross section of most of the elements of the fourth embodiment.

As shown in FIGS. 19 and 20, the rear edge of the upper panel 200 is located at a distance from the cabinet 100. The support member 400 is located in the space between the rear edge of the upper panel 200 and the cabinet 100.

The support member 400 supports the rear end portion of the lower surface of the upper panel 200 and the rear surface of the upper panel 200. The lower and rear surfaces of the upper panel 200 can be attached to the support member 400 with either glue or simply elastic force. Cabinet 100 and support member 400 are connected to each other by screws. The main body 300 is made of a frame, the upper edge of which is curved and extends in the direction of extension of the upper panel 200 or in the opposite direction to the direction of extension of the upper panel 200. The bent portion of the main body is rigidly connected with the supporting element 400.

The supporting member 400 has a lower supporting portion 410 holding the rear edge portion of the lower surface of the upper panel 200, a rear surface supporting portion 420 holding the rear surface of the upper panel 200, and a binding portion 430 that is bent backward from the upper end portion of the rear supporting portion 420, passes to a given length and then bends down.

The lower supporting part 410 is formed from a horizontally rectangular panel having a predetermined thickness. The lower support portion 410 is located at the rear edge portion of the lower surface of the upper panel 200. The flange portion curved back along the upper edge portion of the rear surface of the main body is located between the upper surface of the lower support portion 410 and the lower surface of the upper panel 200. Therefore, the lower support portion 410 supports the back of the lower surface of the upper panel 200 (see Fig. 19).

In addition, the flange portion of the main body 300 may be located between the rear portion of the lower surface of the upper panel 200 and the lower support portion 410. The upper surface of the lower support portion 410 that is in contact with the rear portion of the lower surface of the upper panel 200, and the flange of the main body 300 can be located under the rear of the lower surface of the upper panel 200 (see Fig.20).

When the upper surface of the lower support portion 410 is below the rear edge portion of the lower surface of the upper panel 200, downward separation of the rear edge portion of the upper panel can be prevented.

The supporting part 420 of the rear surface is formed by a protruding rectangular element having a predetermined thickness and extending in the horizontal direction. The rear surface of the upper panel is in contact with the front surface of the rear surface support portion 420, which prevents the upper panel 200 from separating in the rear direction. Meanwhile, the rear surface of the upper panel 200 is in contact with the front surface of the rear surface support portion 420. The back surface support portion 420 may support the upper panel 200 without touching the back surface of the upper panel 200. However, for stability in holding the upper panel 200, the back surface support portion 420 should preferably be in contact with the upper panel 200.

The connecting part 430, which is bent back relative to the upper part of the supporting part 420 of the rear surface, extends to a predetermined length and then bends down, has a rear surface that is fixedly connected to the cabinet 100. The design of the connecting part 430 allows you to keep the same specified distance between the rear surface of the upper panel 200 and cupboard 100.

The rear surface of the connecting part 430 and the front surface of the cabinet 100 are fixedly connected to each other and fastened by fastening means such as glue, screws, hooks, etc. In this embodiment, the screws are used as fasteners for example.

When the rear surface of the connecting portion 430 is attached to the cabinet by screws, the upper panel 200 is held by the support member 400. Therefore, the separation of the upper panel 200 down and back can be prevented.

To support the lower and rear surfaces of the rear of the upper panel 200, the lower supporting portion 410 and the supporting portion 420 of the rear surface form an ┘-shape when viewed from the side. The connecting part 430 to maintain the same distance between the rear surface of the upper panel 200 and the cabinet 100 is ┐-shaped. The rear surface of the connecting part 430 is fixedly connected to the cabinet 100.

The connecting portion 430 has a second hole 520 through which hot air below the support member 400 exits the cabinet 100. The second hole 520 is in any form.

The second hole 520 can be made on any horizontal or vertical section of the connecting part 430. If the second hole 520 is located on the horizontal section, then hot air from under the supporting element 400 goes up and out of the cabinet 100. If the second hole 520 is located on the vertical section , then hot air goes towards the back of the stove and leaves the cabinet 100.

The supporting element 400 is made with predetermined dimensions. Between the rear of the upper panel 200 and the cabinet 100, several support elements 400 may be installed at predetermined intervals to support the upper panel 200. Alternatively, one large support element may be installed to support the upper panel.

At the rear of the main body 300, a first opening 330 is made through which hot air exits from the main body 300. Air leaving the main body 300 is directed to the second opening 520. The second opening 520 is preferably made in a vertical portion of the connecting portion 430 for air to exit in the direction from the top panel 200, thereby protecting the user from the hot air coming out. In this case, the second hole 520 does not come out.

On Fig shows an example of a modified version of this design. Here, in addition, an upper frame 210 is provided for closing the space between the rear of the upper panel 200 and the upper surface of the cabinet 100. When the upper frame 210 is located above the support element 400, a third air outlet 550 is made in the upper frame 210 through which hot air from the main body 300 may exit.

21, the third air outlet 550 is formed in the same direction as the air outlet in the support member 400. However, the present invention is not limited to such a configuration. The third air outlet may be directed backward.

Many examples of other modifications to this embodiment may be given. For example, the second air outlet 520 in FIG. 19 may be laterally directed, the third air outlet 550 may be directed upward. Since the second and third air outlet openings are directed in different directions, leakage of water from the outside to the inside of the plate can be prevented.

Although embodiments have been described herein with reference to a number of examples illustrating these embodiments, it should be understood that numerous other modifications and variations may be devised by those skilled in the art that are consistent with the idea and scope of this disclosure. In particular, various variations and modifications of the construction of parts of the components and / or their arrangements, as well as their mutual combinations, are possible within the scope of this disclosure, as defined by the description, drawings and appended claims. In addition to constructive options and modifications of parts of components and / or their layouts, specialists in this field will be obvious and alternative options for its use.

Industrial applicability

In accordance with the built-in electric stove of the present invention, the cooling efficiency of the hot plate can be increased, as well as the safety when working with it. In addition, the convenience of cleaning the product and its reliability can be increased.

Claims (9)

1. Built-in electric stove containing
top panel
main body located under the top panel,
a cabinet incorporating a main body,
the upper frame located above the space formed between at least the angle of the upper panel and the cabinet, designed to close this space,
an air outlet that allows the internal air of the main body to be discharged through the upper frame,
wherein the air outlet includes
a first fluid outlet made in the main body to provide an outlet from the main body of the internal fluid of this main body,
a second fluid outlet formed in the surface of the upper frame to allow fluid to pass through the first fluid opening into the upper frame, and
a third fluid outlet made at least in a lateral surface on the edge of the upper frame in the length direction to allow fluid to flow through the second fluid hole to the outside of the upper frame in the length direction of the upper frame. 2. The built-in electric stove according to claim 1, in which the upper frame contains
a supporting part holding at least one surface of the upper panel, and a contact part in contact with the cabinet. 3. The built-in electric stove according to claim 2, in which the supporting part is in contact with the lower and upper surfaces of the upper panel so that it covers the upper panel. 4. The built-in electric stove according to claim 2, in which the connecting part connecting the supporting part and the contact part covers the space for air flow. 5. The built-in electric stove according to claim 2, in which the contact part is in contact with the upper surface of the cabinet. 6. The built-in electric stove according to claim 2, in which the lower surface of the upper panel is located at the same horizontal level as the upper surface of the cabinet. 7. The built-in electric stove according to claim 1, in which an air outlet is formed inside the upper frame. 8. The built-in electric stove according to claim 1, in which the air outlet is made longitudinally in the upper frame. 9. The built-in electric stove according to claim 1, wherein the air outlet vents air in a direction extending to the upper panel.

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