BACKGROUND ART In general, a gas radiation oven range heats a radiator and cooks a foodstuff by using a radiant heat radiated from the heated radiator.

Figure 1 illustrates an example of a gas radiation oven range in accordance with a conventional art.

As shown in Figure 1, the gas radiation oven range (C) is formed in a hexahedral shape, including a top burner unit (TB) in which a plurality of burners are coupled to heat a container with a foodstuff therein is installed at the top layer of the burner, a grill unit (G) for making baked foodstuffs by using heat convection installed at a lower side of the top bunner unit (TB), and an oven unit (O) for cooking a barbecue cuisine by using a vertical direct-fire power and heat convection installed at a lower side of the grill unit (G).

The top burner unit (TB) includes : an outer case 10 formed to have a certain internal space with its upper side opened; a ceramic glass 20 coupled at the upper side of the outer case 10 to cover it, on which a foodstuff is placed ; a burner housing 30 coupled to be in contact with a lower surface of the ceramic glass 20 and forming an exhaust passage (F) together with the lower surface of the ceramic glass 20; and a radiant burner 40 coupled at one side of the burner housing 30 and generating a radiant wave while combusting a mixed gas.

An air suction hole 11 is formed at a front side into which air is introduced, and an exhaust port 12 is provided at a rear side of the burner.

The ceramic glass 20 is formed to have an area to cover the upper end of the outer case 10 and a certain thickness and made of a material that can transmit a radiant wave generated from the radiant burner 40.

A cooking area (A) is indicated at an upper side of the ceramic glass 20 so that a foodstuff can be placed at the position where the radiant wave radiated from the radiant burner 40 is transmitted.

As shown in Figure 2, the burner housing 30 includes : a lower plate unit 31 formed having a certain width and length; side plate units 32 bent and extended in a vertical direction at both sides of the lower plate unit 31; a connection plate unit 33 extended and bent so as to connect the both side plate units 32 to one side of the lower plate unit 31; a coupling face unit 34 extended and bent in a horizontal direction from the end of the both side plate unit 32 and the connection plate unit 33 and having a certain area; and a mounting hole 35 positioned at the side of the air suction hole 11 of the outer case 10 and

penetratingly formed so that the radiant burner 40 is mounted at one side of the lower plate unit 31 The connection plate unit 33 of the burner housing 30 is positioned at a front side of the outer case 10, and the opposite opened portion is positioned at the rear side of the outer case 10.

As the coupling face unit 34 is coupled being in contact with the lower surface of the ceramic glass 20, the exhaustion passage (F) for exhausting a combustion gas and the convection heat is formed together with the lower plate unit 31, the both side plate units 32 and the lower surface of the ceramic glass 20.

The radiant burner 40 is fixedly coupled so that a burner head 41 forming a mixing chamber (M) is positioned at the mounting hole 35 of the burner housing 30.

A mixed gas pipe 44 is coupled at one side of the burner head 41, and a burner mat 42, a radiator for radiating a radiant wave, is fixedly coupled at an upper side of the burner head 41 so as to cover the mixing chamber (M) as the gas mixed in the mixing chamber (M) is discharged, burned and heated.

An ignition and inflammation detecting unit 43 for igniting a mixed gas belched through the burner mat 42 and detecting a combustion state of the mixed gas is coupled at the lower plate unit 31 of the burner housing 30 so as to be adjacent to the burner mat 42.

The combustion fan 46 and a fan housing with a fan motor 47 inserted therein are coupled to communicate with the mixed gas pipe 44.

As shown in Figure 3, the mixed gas pipe 44 is coupled protruded inside

the radiant burner 40.

The radiant burner may be constructed by having a plurality of assembly of the burner housing 30 and the radiant burner 40 according to its use and size.

The operation of the gas radiation oven range will now be described.

First, a cooking container 50 with a foodstuff therein is placed on a cooking area (A) of the ceramic glass 20, and then, the gas radiation oven range is operated.

Then, as the combustion fan 46 is rotated, an external air is sucked through the air suction hole 11 and introduced into the mixed gas pipe 44 through the fan housing 45, and at the same time, a separately supplied gas is supplied to the mixed gas pipe 44 and mixed with the air. The mixed gas is discharged through the burner mat 42, and at the same time, ignited and burned by an ignition flame generated by the ignition and inflammation detecting unit 43.

At this time, as the mixed gas is belched through the burner mat 42 and at the same time burned, the burner mat 42 is heated and radiates a radiant wave.

The radiant wave radiated from the burner mat 42 is transmitted through the ceramic glass 20 to heat the cooking container 50, thereby cooking the foodstuff put therein.

The combustion gas and convection heat generated as the mixed gas is burned flow at a certain flow rate along the exhaustion passage (F) formed by the ceramic glass 20 and the burner housing 30 and are exhausted outside the gas radiation oven range through the exhaust port 12 formed at the rear side of the outer case 10.

The conventional gas radiation oven range uses two burners, showing structures of each component.

In general, if a mixture ratio between a fuel and an air is not constant, a combustion state is unstable in a mixed combustion.

That is, in the gas radiation oven range which cooks a foodstuff by using the radiant heat generated when a gas is burned around the burner mat 42, the combustion state works as a critical parameter in generating the radiant heat.

However, since the combustion fan 46 is adjacent to the side of the radiant burner 40, the air supplied to the combustion fan 46 typically has a higher temperature than that of the general room air.

In this respect, if the temperature of the air goes up, its oxygen density contained in the air is lowered down, failing to supply an air sufficient for combustion.

Then, combustion is incompletely made, and accordingly, when the mixed gas is burned in the burner mat 42, the burner mat 42 is not sufficiently heated, resulting in that a radiant wave of a short wavelength suitable for cooking can not be generated.

Resultantly, since the combustion is not completely made in the gas radiation oven range, the cooking performance of the burner-is considerably degraded.

In other words, the increase in the temperature of air supplied to the burner lowers down the air density to fail to supply the sufficient and accurate amount of air required for combustion. Thus, the rate of oxygen of the air is lowered down

to go beyond the a normal operation condition, causing a problem of attaining a reliability in a combustion controlling.

Figure 4 is a graph showing a change in an air density according to a temperature change.

As shown in Figure 4, the air density is rapidly dropped down at the temperature of 20°C ~1 00°C.

In addition, for a preferable combustion state, the gas supplied to the burner head 41 of the radiant burner 40 and a direction in which the air is injected are also critical factors.

Moreover, in the conventional the gas radiation oven range, the mixed gas pipe 44 is coupled at the side of the burner head 41 and its end is formed in a general tube shape, so that a mixed gas flowing inside the burner head 41 is inclined to one side and injected and thus the behavior of the mixed gas is not uniform.

DISCLOSURE OF THE INVENTION Therefore, it is an object of the present invention to provide a combustion fan installation structure of a gas radiation oven range that is capable of improving a combustion performance of a gas radiation oven range and maintaining a better combustion form by supplying air with enough and uniform oxygen density in a gas radiation oven range having a combustion fan supplying air.

To achieve these objects, there is provided a combustion fan installation

structure of a gas radiation oven range including: an outer case formed with its upper side opened and having an internal space which is sectioned to at least more than one space therein; a ceramic glass coupled to cover the outer case at the upper end, on which a foodstuff is placed to be cooked; a burner housing coupled to be in contact with a lower surface of the ceramic glass and forming an exhaustion passage together with the lower surface of the ceramic glass ; a radiant burner coupled at one side of the burner housing and generating a radiant wave while burning a gas; a mixed gas pipe of which one end is coupled at one side of the radiant burner and the other end downwardly penetrating each section wall formed inside the outer case; a gas supply pipe coupled at one side of the mixed gas pipe; and a combustion fan positioned at some distance from the sectioned space of the uppermost part where the burner housing is coupled thereto and coupled to the other end of the mixed as pipe.

To achieve the above object, there is also provided a combustion fan installation structure of a gas radiation oven range including: a top burner unit with its upper side opened and having a burner assembly coupled therein; an outer case including a grill unit coupled at a lower side of a top case and performing a baking or roasting and an oven unit coupled at a lower side of the grill unit and performing a barbecue cooking; a ceramic glass coupled at the upper end of the top burner unit, covering it, on which a foodstuff is placed for cooking; a burner housing coupled to be in contact with the lower surface of the ceramic glass and forming an exhaust passage together with the lower surface of the ceramic glass ; a radiant burner coupled at one side of the burner housing and generating a

radiant wave while burning a gas; a mixing pipe of which one end is coupled at one side of the radiant burner and the other end downwardly penetrates the grill unit and an oven unit forming the outer case; a gas supply pipe coupled at one side of the mixing pipe; and a combustion fan positioned at some distance from the top burner unit where the burner housing is coupled and coupled to the other end of the mixing pipe.

To achieve the above object, there is also provided a combustion fan installation structure of a gas radiation oven range including : a top burner unit with its upper side opened and having a burner assembly coupled therein; an outer case including a grill unit coupled at a lower side of a top case and performing a baking or roasting and an oven unit coupled at a lower side of the grill unit and performing a barbecue cooking; a ceramic glass coupled at the upper end of the top burner unit, covering it, on which a foodstuff is placed for cooking; a burner housing coupled to be in contact with the lower surface of the ceramic glass and forming an exhaust passage together with the lower surface of the ceramic glass ; a radiant burner coupled at one side of the burner housing and generating a radiant wave while burning a gas; and a combustion fan coupled at one side of the radiant burner, wherein the combustion fan is coupled at the oven unit at some distance from the top burner unit where the burner housing is positioned.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a perspective view showing an example of a gas radiation oven range in accordance with a conventional art;

Figure 2 is a sectional view showing a combination state of a combustion fan of the gas radiation oven range in accordance with the conventional art; Figure 3 is a plan view showing a gas mixing pipe of the gas radiation oven range in accordance with the conventional art; Figure 4 is a graph showing a distribution of an air density according to a temperature state; Figure 5 is a perspective view showing a combustion fan installation structure of a gas radiation oven range in accordance with the present invention; Figure 6 is a vertical sectional view showing the combustion fan installation structure of a gas radiation oven range in accordance with the present invention; and Figure 7 is a plan view showing a mixing gas pipe of the combustion fan installation structure of a gas radiation oven range in accordance with the present invention; and MODES FOR CARRYING OUT THE PREFERRED EMBODIMENTS A combustion fan installation structure of a gas radiation oven range of the present invention will now be described in detail with reference to accompanying drawings.

The same reference numerals were given to the same elements as in the conventional art.

As shown in Figures 5 and 6, in the combustion fan installation structure of a gas radiation oven range, a gas radiation oven range (C) is formed in a

hexahedral shape, including a top burner unit (TB) in which a plurality of burners are coupled to heat a container with a foodstuff therein is installed at the top layer of the burner, a grill unit (G) for making baked foodstuffs by using heat convection installed at a lower side. of the top burner unit (TB), and an oven unit (O) for cooking a barbecue cuisine by using a vertical fire power and heat convection installed at a lower side of the grill unit (G).

The top burner unit (TB) includes: an outer case 10 formed to have a certain internal space with its upper side opened; a ceramic glass 20 coupled at the upper side of the outer case 10 to cover it, on which a foodstuff is placed ; a burner housing 30 coupled to be in contact with a lower surface of the ceramic glass 20 and forming an exhaust passage (F) together with the lower surface of the ceramic glass 20; and a radiant burner 40 coupled at one side of the burner housing 30 and generating a radiant wave while combusting a mixed gas.

The ceramic glass 20 is formed to have an area to cover the upper end of the outer case 10 and a certain thickness and made of a material that can transmit a radiant wave generated from the radiant burner 40.

A cooking area (A) is indicated at an upper side of the ceramic glass 20 so that a foodstuff can be placed at the position where the radiant wave radiated from the radiant burner 40 is transmitted.

As shown in Figure 5 and 6, the burner housing 30 includes: a lower plate unit 31 formed having a certain width and length ; a side plate unit 32 bent and extended in a vertical direction at both sides of the lower plate unit 31; a connection plate unit 33 extended and bent so as to connect the both side plate

unit 32 to one side of the lower plate unit 31; a coupling face unit 34 extended and bent in a horizontal direction from the end of the both side plate unit 32 and the connection plate unit 33 and having a certain area; and a mounting hole 35 penetratingly formed at one side of the lower plate unit 31 so as to be positioned at the side of the air suction hole 11 of the outer case 10 so that the radiant burner 40 can be mounted therein.

The connection plate unit 33 of the burner housing 30 is positioned at a front side of the outer case 10, and the opposite opened portion is positioned at the rear side of the outer case 10.

As the coupling face unit 34 is coupled being in contact with the lower surface of the ceramic glass 20, the exhaustion passage (F) for exhausting a combustion gas and the convection heat is formed together with the lower plate unit 31, the both side plate unit 32 and the lower surface of the ceramic glass 20.

The radiant burner 40 is fixedly coupled so that a burner head 41 forming a mixing chamber (M) is positioned at the mounting hole 35 of the burner housing 30.

A mixed gas pipe 144 is coupled at one side of the burner head 41, and a burner mat 42, a radiator for radiating a radiant wave, is fixedly coupled at an upper side of the burner head 41 so as to cover the mixing chamber (M) as the gas mixed in the mixing chamber (M) is belched, burned and heated.

An ignition and inflammation detecting unit 43 for igniting a mixed gas belched through the burner mat 42 and detecting a combustion state of the mixed gas is coupled at the lower plate unit 31 of the burner housing 30 so as to be

adjacent to the burner mat 42.

As shown in Figure 6, the mixed gas pipe 144 includes a coupling pipe 144a penetratingly coupled at one side of the radiant burner 41, of which one end is protruded inside the radiant burner 41; and a flexible air convey pipe 144b coupled at the end of the coupling pipe 144a and penetrating the grill unit (G) and the oven unit (O) formed at a lower portion of the outer case 10.

The end of the air convey pipe 144b is coupled at a combustion fan 200 formed as a motor and a fan are integrally coupled, and the combustion fan 200 is coupled at one side of the lowermost portion of the outer case 10.

A gas supply pipe 145 is coupled at one side of the mixed gas pipe 144 with certain distances (a) and (b) sufficient to form an uniform mixed gas.

As shown in Figure 7, a plurality of injection holes 146 are formed at one side of the coupling pipe 144a of the mixed gas pipe 144 coupled protruded inside the radiant burner 40, in order to uniformly spray the mixed gas in every direction.

A plurality of suction holes 61 are formed at the bottom 60 of the outer case 10 to suck a low temperature air distributed at the lower portion of the burner.

The flexible air convey pipe 144b is made of insulated material in order to block a heat transmission from the ambient.

The mixed gas pipe 144 and the combustion fan 200 may be installed inside a cooling convey duct 400 formed to cool the exhaust gas discharged form the rear side of the outer case 10.

A separating plate 300 may be additionally formed to section a space at the lower side from the middle portion of the oven unit (O) at the side of the oven unit (O) positioned at the lowermost portion of the outer case 10, in order to maintain a low temperature air and pruniformt transmission of heat generated from the grill unit (G) and the oven unit (O) of the burner.

A reference numeral 1 Oa is a cover to cover the side of the outer case 10.

The radiant burner may be constructed by including a plurality of assemblies formed by coupling the burner housing 30 and the radiant burner 40 according to its use and size.

The operation of the gas radiation oven range constructed as described above will now be explained.

First, a cooking container 50 with a foodstuff put therein is placed at a cooking area (A) of the ceramic glass 20 and the gas radiation oven range is operated. Then, as the combustion fan 200 is rotated, the low temperature air formed at the bottom of the space where the burner is placed is sucked through the suction holes 61 and introduced into the mixed gas pipe 144 through a fan housing (not shown) integrally coupled at the combustion fan 200. And, at the same time, a gas is supplied from the mixed gas pipe 144 from the gas supply pipe 145 coupled at one side of the mixed gas pipe 144 with the distances (a) and (b) from the radiant burner 40 and mixed with the air. The mixed air is discharged through the burner mat 42, and at the same time, ignited and burned by the ignition spark generated by the ignition and inflammation detecting unit

43.

At this time, as the mixed gas is discharged through the burner mat 42 and simultaneously burned, the burner mat 42 is heated so that a radiant wave is radiated from the burner mat 42. The radiant wave radiated from the burner mat 42 is transmitted through the ceramic glass 20 to heat the cooking container 50, thereby cooking the foodstuff put therein.

The combustion gas generated as the mixed gas is burnt and convection heat flow with a certain flow rate along the exhaust passage (F) formed by the ceramic glass 20 and the burner housing 30 and discharged outwardly of the gas radiation oven range through the exhaust port 12 formed at the rear side of the outer case 10.

INDUSTRIAL APPLICABILITY As so far described, according to the combustion fan installation structure of a gas radiation oven range, since the temperature of the sucked air for combustion is constantly maintained, an air with a sufficient air density can be supplied. Thus, it can have a stable combustion performance.

In addition, a problem that an oxygen density in the air according to an influence of a temperature change of an inflow air generated when the oven or the grill is operated can be solved. Accordingly, a reliability of a combustion performance of the gas radiation oven range to be mainly used in kitchens or in hotels can be improved.