Patent Grant
7895997
The present application claims priority under 35 U.S.C. 119 and 35 U.S.C. 365 to Korean Patent Application No. 10-2006-0130607 (filed on Dec. 20, 2006), which is hereby incorporated by reference in its entirety.
The present disclosure relates to a heating cooking appliance, and more particularly, to a heating cooking appliance and a burner system of the same, which are configured to have a small size, achieve high burning efficiency, reduce air-flow resistance, and facilitate assembly thereof.
Heating cooking appliances are devices that cook food by heat. Particularly, a gas cooktop among the heating cooking appliances cooks food by heat generated through gas combustion. The cooktop is also called a hot plate or a hob, and is being increasingly used.
A burner system is employed in the cooktop operating by gas combustion. The burner system mixes a combustible gas with air to generate combustion. The burner system sprays a gaseous fuel through a nozzle, and introduces air together with the gaseous fuel into a mixing tube, using a decrease in air pressure around the sprayed gaseous fuel. A gas mixture introduced into a burner pot through the mixing tube is mixed again uniformly within the burner pot, and then combusts on a glow plate. Heat generated by the combustion is transferred to food by heat radiation and conduction to heat and cook the food.
To improve operational reliability of the burner system, the mixing tube, the nozzle and the burner pot must be precisely concentrically aligned, and the mixing tube and the nozzle must be installed and maintained at the same preset distance. If the components are not concentrically aligned or the distance between the components is different from the set value, the gas and air cannot be uniformly introduced, and the ratio of air to gas is reduced. This causes incomplete combustion, increasing emissions of carbon monoxide.
In the case of the general burner system, to meet the aforementioned requirements, the mixing tube is coupled to the burner pot, and the nozzle is firmly coupled to a case of a heating cooking appliance.
In order to improve user satisfaction and reduce material cost, heating cooking appliances are becoming more compact, and especially in the case of cooktops, compactness is essential to prevent a cooktop from protruding upward from a counter.
Embodiments provide a heating cooking appliance and a burner system of the same, which can allow a nozzle and a mixing tube to be stably fixed even in a narrow heating cooking appliance, and can allow relative positions of components to be aligned with high precision.
Embodiments also provide a heating cooking appliance, and a burner system of the same, which can prevent misalignment of components and can allow a nozzle, a mixing tube, and a burner pot to be placed at preset positions with high precision by allowing an operator to easily align components of the burner system relative to one another.
In one aspect, a heating cooking appliance comprises: a case; a plate covering a top side of the case; a burner system in an internal space defined by the plate and the case; and an exhaust part at one edge of the plate, wherein the burner system includes: a nozzle unit provided with at least one nozzle to spray gas; a mixing tube unit provided with at least one mixing tube through which the gas and air are introduced, the mixing tube maintained a predetermined distance apart from the nozzle; a burner pot to uniformly mix the gas and air which are introduced through the mixing tube unit; a nozzle coupling part fixing a position of the nozzle; and a mixing tube coupling part fixing a position of the mixing tube.
In another aspect, a burner system comprises: a nozzle configured to spray gas; a mixing tube spaced apart from the nozzle to introduce the gas and air; a burner pot providing a mixing space in which the gas and air introduced through the mixing tube are uniformly mixed; a nozzle leg configured to fix a position of the nozzle; a mixing tube leg configured to fix a position of the mixing tube; and a coupling member to partially connect the nozzle leg with the mixing tube leg.
In a further aspect, a burner system comprises: a nozzle unit provided with at least one nozzle configured to spray gas; a mixing tube unit provided with at least one mixing tube apart from the nozzle to introduce air together with the gas therein; a burner pot providing a mixing space in which the gas and air introduced through the mixing tube unit are uniformly mixed; a nozzle coupling part configured to fix a position of the nozzle; a mixing tube coupling part configured to fix a position of the mixing tube; and a guide unit configured to align at least a part of the nozzle coupling part with at least a part of the mixing tube coupling part so that a relative positional relation between the nozzle unit and the mixing tube unit is precisely set.
Accordingly, the heating cooking appliance can be easily assembled, and components of the burner system can be precisely placed, so that the burner system can be stably and efficiently operated, and the components of the burner system can be placed at desired positions even when the heating cooking appliance has a compact structure.
The details of one or more embodiments are set forth in the accompanying drawings and the description below. Other features will be apparent from the description and drawings, and from the claims.
Reference will now be made in detail to the embodiments of the present disclosure, examples of which are illustrated in the accompanying drawings.
Referring to
A plurality of components for gas combustion and gas exhaust, and control of the heating cooking appliance are received in an internal space defined by the case 2 and the ceramic plate 1. This will now be described in detail.
In
A burner frame 11 is placed on the burner pot 4. The burner frame 11 supports the burner pot 4, and provides an exhaust path of a combustion gas having combusted on a glow plate 12.
An exhaust part 10 and the exhaust grill 13 are placed at the rear of the burner frame 11. The exhaust part 10 and the exhaust grill 13 on the exhaust part 10 serve to exhaust the combustion gas to the outside.
The glow plate 12 on each burner pot 4 is heated by high-temperature heat generated when the gas mixture combusts. When the glow plate 12 is heated, radiation energy of a frequency band corresponding to a physical property of the glow plate 12, preferably, a frequency band of infrared light, is emitted. The radiation energy of the glow plate 12 includes at least a frequency band of visible light, which allows a user to recognize that the heating cooking appliance is in operation. Of course, food is heated by radiation heat of the glow plate 12 and conduction heat of the ceramic plate 1.
A structure of gas supply to the nozzle unit 5 will now be described.
A gas is supplied through a main gas supply tube 8 from the outside of the heating cooking appliance. A gas valve 7 controlled by the switch 14 controls the gas supply toward each burner system. The gas having passed through the gas valve 7 is supplied to the nozzle unit 5 through the gas supply tube 9.
In
In the relatively small burner pot 4 placed at the center of the case 2, a gas mixture is mixed again while supplied from a front side toward a rear side of the burner pot 4. After the gas mixture combusts on the glow plate 12, the gas is exhausted rearwardly, that is, toward the exhaust part 10. In the two relatively large burner pots 4 placed on both sides of the case 2, a gas mixture is mixed again while supplied from a rear side toward a front side thereof. Then, the gas mixture combusts on the glow plate 12, and is exhausted rearwardly of the burner pot 4.
The disposition of the burner pots 4 is for implementing an optimum heating burner system.
The positioning of components within the heating cooking appliance can be easily observed through
A burner system of the heating cooking appliance according to a first embodiment has a structure that allows stable flow of the gas and air while maintaining minimal heights of the burner system and the heating cooking appliance, can stably maintain a ratio of the air to the gas (hereinafter, referred to as an air ratio), and can ensure assemblability of the burner system.
The structure and operation of the burner system of the heating cooking appliance will now be described in detail.
Referring to
The operation of the burner system will now be described. A gas sprayed from the nozzle unit 5 is introduced into the mixing tube unit 6 at a high speed. The gas passes through the inlet of the mixing tube unit 6 at such a high speed that an adjacent space to the inlet of the mixing tube unit 6 becomes a low-pressure state according to Bernoulli's Theorem. Therefore, ambient air is introduced into the mixing tube 62 together with the gas, and thus a fluid passing through the mixing tube 62 becomes a gas mixture of the gas and air. The gas mixture having passed through the mixing tube unit 6 is introduced into an internal space of the burner pot 4 through an opening 42, and is mixed again and combusts on the glow plate 12. Combustion heat of the gas mixture heats the glow plate 12 to make the plate 12 red, and then radiation heat is generated from the glow plate 12.
In order to introduce a maximum quantity of air when the gas sprayed from the nozzle unit 5 is introduced into the mixing tube unit 6, it is important to concentrically align the nozzle unit 5 and the mixing tube unit 6 to maintain the distance between the nozzle 5 and the mixing tube unit 6. Even though the nozzle unit 5 and the mixing tube unit 6 are designed to maintain the proper relative positional relation therebetween, this positional relation may be deviated during a manufacturing process or in use. If the positional relation is deviated, the amount of air being suctioned may decrease, flow resistance of the burner system may increase, and incomplete combustion may occur.
Therefore, a support structure is proposed, which allows the nozzle unit 5 and the mixing tube unit 6 to be placed at preset positions with high precision.
Referring to
In such a burner system, the mixing tube unit 6 and the burner pot 4 may be aligned at desired positions by slightly inserting discharge ends of the mixing tubes 62 to the burner pot 4. After this alignment, the burner pot 4 and the mixing tube unit 6 may be firmly coupled with each other by a separate coupling member such as a screw. Here, the mixing tube unit 6 is already in a state where the plurality of mixing tubes 62 are coupled to the mixing tube support 61.
To align the mixing tube unit 6 and the nozzle unit 5 at desired positions, each mixing tube leg 63 includes a modification portion 64 at an end portion, and each nozzle leg 54 includes a corresponding modification portion 55 at an end portion, corresponding to the modification portion 64. The modification portion 64 and the corresponding modification portion 55 each have modified parts from which modifications to respective original shapes of the legs 63 and 54 begin, and the modified parts contact each other, so that the nozzle unit 5 and the mixing tube unit 6 can be positioned at the desired positions with high precision.
The modification portion 64 and the corresponding modification portion 55 will now be described in more detail. For example, the modification portion 64 has a vertical height difference from an original shape of the mixing tube leg 63 by perpendicularly stepping the original shape of the mixing tube leg 63. In more detail, the modification portion 64 is provided by stepping perpendicularly downwardly the original shape of the mixing tube leg 63. The corresponding modification portion 55 corresponds to the modification portion 55, and is provided by upwardly stepping an original shape of the nozzle leg 54. When the modification portion 64 and the corresponding modification portion 55 are aligned at corresponding positions in a vertical direction, the stepped parts thereof contact each other, so that the mixing tube leg 63 and the nozzle leg 54 can be aligned vertically with high precision.
As mentioned above, the modification portion 64 and the corresponding modification portion 55 guide vertical relative placement of the mixing tube leg 63 and the nozzle leg 54 with high precision. Thus, from a functional perspective, the modification portion 63 and the corresponding modification portion 55 may be named vertical guides.
Of course, the mixing tube leg 63 and the nozzle leg 54 are automatically aligned in a forward and rear direction because of the respective height differences in the modification portion 64 and the corresponding modification portion 55. When vertical and horizontal alignment is precisely made, the distance between the nozzle 53 and the inlet of the mixing tube 62 can be precisely set.
The modification portion 64 and the corresponding modification portion 55 can allow the legs 63 and 54 to be reliably and stably placed at the preset positions with high precision. Furthermore, the legs 63 and 54 also contribute to precisely aligning the relative positions between the nozzle 53 and the mixing tube 62. For this reason, stable combustion performance of the burner system can be achieved, and stable performance of the mixing tube unit 6 and the nozzle unit 5 can be obtained despite compactness of the heating cooking appliance. Also, assembly of the mixing tube unit 6 and the nozzle unit 5 can be facilitated. Since the legs 63 and 54 are coupled so that the nozzle 53 and the mixing tube 62 are placed at the precise relative positions, the legs 63 and 54 can be named coupling parts.
After the modification portion 64 and the corresponding modification portion 55 precisely align the legs 63 and 54, the nozzle unit 5 and the mixing tube unit 6 may be finally coupled with each other by inserting screws 69 into screw holes correspondingly formed in the respective legs 63 and 54. The coupling of the legs 63 and 54 using the screws 69 may contribute to facilitating operations such as nozzle exchange or repair. The coupling method of the nozzle unit 5 and the mixing tube unit 6 is not limited to the insertion of the screws 69 into the screw holes, and various coupling methods such as rivet coupling, bolt-nut coupling, and coupling using clips may be employed provided that the coupling method allows separation between the nozzle unit 5 and the mixing tube unit 6 for repair to be performed later.
Referring to
As in the burner system according to the first embodiment, reliability of alignment according to the current embodiment can be improved by the legs 63 and 54 and the modification portions 64 and 55 when the nozzle unit 5 and the mixing tube unit 6 are coupled with each other.
Referring to
According to the third embodiment, when the legs 63 and 54 are aligned with each other, the horizontal modification portion 72 and the horizontal corresponding modification portion 74 contact each other, thereby stopping and supporting the legs 63 and 54 at the contacting position. Accordingly, the legs 63 and 54 can stably guide the relative positions of the mixing tube unit 6 and the nozzle unit 5 in a horizontal direction.
Since the alignment of the legs 63 and 54 is guided in a vertical direction, in a forward and rearward direction, and in a left and right direction, the mounting process of the legs 63 and 54 is facilitated, and reliability of the alignment of the nozzle 53 and the mixing tube 62 can be improved. Of course, in the current embodiment, the nozzle unit 5 can be separated from the mixing tube unit 6 by lifting up the nozzle unit 5.
Referring to
A base portion of the modification portion 81 where the recessing begins may have a shape fitting in at least a base portion of the corresponding modification portion 82. Thus, when the pair of legs 63 and 54 is aligned, they can be placed at preset positions with high precision.
Since the rounded shapes are provided according to the current embodiment, there is no need to additionally provide the vertical modification portion and the horizontal modification portion according to the third embodiment. Accordingly, the rounded shapes allow the legs 63 and 54 to be conveniently aligned in every movement direction, that is, in a forward and rearward direction, a vertical direction, and a left and right direction.
Referring to
Accordingly, the relative positions of the mixing tube 62 and the nozzle 53 can be aligned with high precision.
Embodiments are not limited to the aforementioned embodiments, the following embodiments may be further provided.
Although the nozzle legs and the mixing tube legs are respectively provided in pairs in the aforementioned embodiments, one nozzle leg and one mixing tube leg may be provided, or three or more nozzle legs and three or more mixture pip legs may be provided. One leg may be provided when one opening and one mixing tube are provided, but if one leg is provided in the case where a plurality nozzles and a plurality of mixing tubes are respectively provided for the nozzle unit and the mixing tube unit, the alignment may become difficult. When three or more nozzles and three or more mixing tubes are provided, three or more legs are provided to improve reliability of the alignment between the nozzle unit and the mixing tube unit.
Although the modification portion and the corresponding modification portion are respectively formed in bar-shaped legs of the nozzle unit and the mixing tube unit extending to face each other in the aforementioned embodiments, the modification portion and the corresponding modification portion may be respectively provided in plate-shaped parts corresponding to each other, or may be respectively provided in any portions that widely expand from respective ends of the legs. Any portion extending from any member fixed to the mixing tube and any portion extending from any member fixed to the nozzle may be modified at a position where the portions overlap each other, and be aligned with each other, so that the functions of the modification portion and the corresponding modification portion can be performed.
Although the legs extend to face each other from a lower side of the mixing tube support to which a plurality of mixing tubes are aligned and fixed, and from a lower of the nozzle holder to which a plurality of nozzles are fixed in the aforementioned embodiments, the legs may directly extend from the mixing tube, and may directly extend from the nozzle by modifying the nozzle or may extend from the a distribution tube. Particularly, in the case where one mixing tube and one nozzle are formed, a mixing tube leg extending from the mixing tube may be considered convenient. Of course, convenience is improved when the legs extend from the mixing tube support and the nozzle holder to face each other with regard to factors associated with a distance and convenient manufacturing.
The modification portion and the corresponding modification portion are described as portions formed by modifying original shapes of the legs for convenient coupling of the legs.
According to embodiments, even if a heating cooking appliance includes a narrow internal space, a nozzle and a mixing tube can be stably fixed, and relative positions of components of the heating cooking appliance can be precisely aligned, thereby improving operational reliability of the heating cooking appliance.
Also, an operator can easily assemble the burner system so that the components are prevented from being mistakenly misaligned, and a nozzle, a mixing tube and a burner pot can be placed at preset positions with high precision.
For example, when the nozzle needs to be repaired, the nozzle unit can be separated just by unfastening a coupling member such as a screw, and the nozzle unit can be coupled precisely at a desired position after being repaired.
Any reference in this specification to “one embodiment,” “an embodiment,” “example embodiment,” etc., means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the invention. The appearances of such phrases in various places in the specification are not necessarily all referring to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with any embodiment, it is submitted that it is within the purview of one skilled in the art to effect such feature, structure, or characteristic in connection with other ones of the embodiments.
Although embodiments have been described with reference to a number of illustrative embodiments thereof, it should be understood that numerous other modifications and embodiments can be devised by those skilled in the art that will fall within the spirit and scope of the principles of this disclosure. More particularly, various variations and modifications are possible in the component parts and/or arrangements of the subject combination arrangement within the scope of the disclosure, the drawings and the appended claims. In addition to variations and modifications in the component parts and/or arrangements, alternative uses will also be apparent to those skilled in the art.
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