CN217604088U - Combustor and gas stove comprising same - Google Patents

Abstract

The utility model provides a combustor and contain its gas cooking utensils, box, control by temperature change probe, draw and penetrate pipe and wind power system at the bottom of the cooking utensils, be formed with the cavity at the bottom of the cooking utensils box, the lower extreme of control by temperature change probe is located in the cavity just the periphery side of the upper end of control by temperature change probe with the cavity intercommunication, wind power system with draw and penetrate the pipe intercommunication and to draw and penetrate the pipe confession air, its characterized in that, wind power system still with the cavity intercommunication and to supply air in the cavity. The utility model discloses a wind power system supplies air in to the cavity to realize that wind power system not only can realize the function of preventing blockking up of the fire hole of combustor to the rapid cooling function of control by temperature change probe, can effectively cool down to the control by temperature change probe moreover, with the assurance under the condition of continuous use combustor, the control by temperature change probe homoenergetic at every turn can be in normal operating condition before the combustor starts, prevents because of the overheated condition such as unexpected flame-out of combustor that arouses of control by temperature change probe.

Description

Combustor and gas stove comprising same

Technical Field

The utility model relates to a combustor and contain its gas cooking utensils.

Background

At present, a household gas cooker can be influenced by overflowing liquid of a cooker when in use, so that a fire hole of the gas cooker is blocked by the overflowing liquid and flameout is caused, or the cooker is directly placed on the gas cooker after being cleaned for use, water at the bottom of the cooker can slide along the cooker and drip on the fire hole, so that the gas cooker is failed to ignite.

In order to overcome the defects, a gas stove is improved, and a technical scheme for blowing air to a fire hole to prevent the fire hole from being blocked is provided, for example, in the Chinese patent with application number 201410076533.8, a gas stove with high-efficiency combustion efficiency is provided, the technical scheme is characterized in that the air outlet end of a fan is respectively in fluid communication with the air inlet port of an injection pipe and the secondary air outlet hole, so that the air flows to the fire hole from the injection pipe and is prevented from being blocked, meanwhile, the air is blown to the secondary air outlet hole to effectively dredge overflowing liquid on the outer peripheral side of the fire hole, but a temperature control probe of the gas stove cannot be cooled by the air blown out from the fire hole or the air blown out from the secondary air outlet hole due to the fact that the temperature control probe is arranged on the side part of the fire hole and a gap exists between the temperature control probe and the fire hole, the temperature control probe cannot be rapidly cooled to further influence the dry combustion prevention detection effect of a burner, and a dry combustion signal is triggered due to high temperature during normal cooking of a cooker, so that a burner is extinguished, and a user experience is not good.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to provide a combustor and contain its gas cooking utensils in order to overcome the unable rapid cooling's of control by temperature change probe defect among the prior art.

The utility model discloses a solve above-mentioned technical problem through following technical scheme:

a combustor comprises a stove bottom box, a temperature control probe, an injection pipe and a wind power system, wherein a cavity is formed in the stove bottom box, the lower end of the temperature control probe is located in the cavity, the outer peripheral side of the upper end of the temperature control probe is communicated with the cavity, the wind power system is communicated with the injection pipe and supplies air to the injection pipe, and the wind power system is further communicated with the cavity and supplies air to the cavity.

In this scheme, wind power system is through to drawing intraductal confession air so that the air is along drawing the fiery hole that draws a tub flow direction combustor, and then solves the jam problem of fiery hole when receiving the pan overflow, and simultaneously, wind power system is through supplying air in to the cavity, and in the lower extreme of control by temperature change probe stretched into the cavity, periphery side and the cavity intercommunication of the upper end of control by temperature change probe, and the air flows to the periphery side of the upper end of control by temperature change probe along the cavity, and then realizes the rapid cooling of control by temperature change probe.

Preferably, the air system is communicated with the ejector pipe through a first air outlet, the air system is communicated with the cavity through a second air outlet, and the air system further comprises an air source which is respectively communicated with the first air outlet and the second air outlet.

In this scheme, wind power system is equipped with first air outlet, second air outlet and air supply, through with first air outlet and air supply intercommunication and to drawing intraductal confession air of penetrating, through with second air outlet and air supply intercommunication and to supplying the air in the cavity, and then make wind power system realize to drawing to penetrate to supply the air respectively in pipe or the cavity, this is a preferred structure setting of this application.

Preferably, the burner further comprises a gas nozzle, and a gas outlet of the gas nozzle is arranged towards an inlet of the injection pipe;

the first air outlet surrounds the air outlet of the gas nozzle and is arranged towards the inlet of the injection pipe.

In this scheme, first air outlet can supply the air to gas nozzle's air outlet to make the pan overflow in the gas nozzle blown off, simultaneously, first air outlet can also supply the air to the entry of drawing penetrating pipe, and the overflow in order to realize the fiery hole is blown off, this structure setting for a preferred of this application.

Preferably, when the second air outlet is disposed around the first air outlet, an air opening of the second air outlet is larger than an inlet of the ejector tube.

In this scheme, the second air outlet sets up around first air outlet, and when wind power system started, first air outlet and second air outlet homoenergetic supplied air, and the air flow of first air outlet draws ejector tube and gas nozzle, and the second air outlet makes the air can flow to the interior cavity at the bottom of the cooking utensils box because the size is great, and then drives the air acceleration of the periphery side of temperature control probe through the air flow rate in the cavity with higher speed and flows to realize the cooling function of temperature control probe.

Preferably, the air source is a fan.

In this scheme, the air supply is under the condition of fan, and the fan rotates and to drive the air flow, and the fan drives air flow rate increase moreover and is bigger from the air strength that the fan flows out, and the cooling effect of blowing to the control by temperature change probe is better.

Preferably, an air inlet of the fan is arranged on the stove bottom box, and the air inlet faces the outside of the cavity.

In this scheme, connect the income wind gap of fan outside the cavity, and then make the fan can be continuous supply the air outside the cavity to the cavity or draw in the injection pipe when using to realize wind power system repetitious usage, wind power system can last to drawing penetrate pipe or cavity in supply air, improved wind power system's rate of reuse.

Preferably, the combustor further comprises a control system, the control system is electrically connected with the wind power system, and when the gas nozzle supplies gas, the control system can start the wind power system.

In this scheme, control system can control wind power system's break-make, and when gas nozzle supplied the gas, when the combustor was igniteed promptly, control system opened wind power system and in order to carry out timely and quick cooling to making used control by temperature change probe, this structure setting for a preferred of this application.

Preferably, when the gas nozzle stops supplying gas, the control system can close the wind power system.

In this scheme, when the gas nozzle stops supplying gas, when the combustor is closed a fire promptly, when the combustor is closed a fire, close wind-force system through control system to reduce the energy consumption of combustor, practice thrift the use cost of combustor.

Preferably, the combustor further comprises a gas knob, the gas knob is used for igniting or closing a fire hole of the combustor, and the control system is in signal connection with the gas knob.

In the scheme, the switch is in signal connection with the control system, when the switch is turned off, the signal of turning off the fire is transmitted to the control system, the control system correspondingly turns on the wind power system to cool the temperature control probe, and meanwhile, the wind power system can supply air to the ejector pipe to prevent the fire hole of the burner from being blocked by overflowing liquid after the burner is used, so that the next ignition failure caused by the blockage of the fire hole is avoided; the switch can give control system with signal transmission before the ignition, and control system is corresponding opens wind power system, and at this moment, wind power system to drawing penetrate intraductal confession air, the air blows off from the fire hole to avoid the pan just wash remaining water droplet in clean back pan bottom to drip on the fire hole and the ignition failure that arouses, wind power system can blow away the water droplet that drips on the fire hole before the fire hole is igniteed, this structure setting for a preferred of this application.

A gas hob including a burner as claimed in any one of the above mentioned.

In this scheme, gas cooking utensils are including the combustor that has above-mentioned air force system and control system etc. its aim at can be simultaneously to drawing penetrating pipe and cavity in the confession air to realize preventing blockking up and the rapid cooling of control by temperature change probe in the flame vent, of course, according to the communicating state of difference, air force system also can supply the air in order to make control by temperature change probe can rapid cooling in the cavity alone, and can draw penetrating intraductal confession air so that the flame vent of combustor realizes preventing blockking up alone.

The utility model discloses an actively advance the effect and lie in: the utility model discloses a wind power system supplies air in to the cavity to realize that wind power system not only can realize the function of preventing blockking up of the fire hole of combustor to the rapid cooling function of control by temperature change probe, can effectively cool down to the control by temperature change probe moreover, in order to guarantee under the condition of continuous use combustor, the control by temperature change probe homoenergetic at every turn can be in normal operating condition before the combustor starts, prevents because of the overheated condition such as unexpected flameout of combustor that arouses of control by temperature change probe.

Drawings

Fig. 1 is a schematic structural diagram of a burner according to an embodiment of the present invention.

Fig. 2 is a schematic diagram of a position of a temperature control probe according to an embodiment of the present invention.

Fig. 3 is a schematic view of the internal structure of the bottom case of the cooking stove according to an embodiment of the present invention.

Fig. 4 is a partially enlarged view of fig. 3.

Fig. 5 is a schematic structural view of a wind power system according to an embodiment of the present invention.

Fig. 6 is a schematic view illustrating a position relationship between the first outlet and the second outlet according to an embodiment of the present invention.

Fig. 7 is a schematic view of an internal structure of a wind power system according to an embodiment of the present invention.

Description of reference numerals:

stove bottom box 1

Cavity 11

Temperature control probe 2

Gap 21

Ejector pipe 3

Wind power system 4

First air outlet 41

The second air outlet 42

Gas source 44

Kitchen range top 5

Gas nozzle 6

Nozzle holder 7

Inner ring fire cover 8

Outer ring fire cover 9

Fire hole 100

Detailed Description

The present invention will be more clearly and completely described below with reference to the accompanying drawings, which are given by way of illustration of preferred embodiments, but are not intended to limit the scope of the present invention.

Example 1

The embodiment provides a combustor, as shown in fig. 1 and 2, the combustor includes a stove bottom box 1, a temperature control probe 2, an injection pipe 3 and a wind power system 4, in addition, the combustor is further provided with an inner ring fire cover 8 and an outer ring fire cover 9, the injection pipe 3 is communicated with the inner ring fire cover 8 and the outer ring fire cover 9 and supplies gas to the inner ring fire cover 8 and the outer ring fire cover 9, so that the fire holes 100 of the inner ring fire cover 8 and the outer ring fire cover 9 can be combusted normally. In this embodiment, the position relationship between the temperature control probe 2 and the cavity 11 is shown in fig. 3 and 4, the cavity 11 is formed in the stove bottom case 1, the temperature control probe 2 is arranged in the vertical direction, the lower end of the temperature control probe 2 is located in the cavity 11, the outer peripheral side of the upper end of the temperature control probe 2 is communicated with the cavity 11, as shown in fig. 5, the wind power system 4 is communicated with the ejector pipe 3 and supplies air to the ejector pipe 3, and the wind power system 4 is further communicated with the cavity 11 and supplies air to the cavity 11.

The structure of the burner is shown in fig. 2 and 3, a cavity 11 is sealed by a stove table 5, an inner ring fire cover 8 and an outer ring fire cover 9 of the burner are positioned above the stove table 5, that is, fire holes 100 are positioned above the stove table 5, an ejector tube 3 and a wind power system 4 are positioned in the cavity 11, the upper end of the temperature control probe 2 is movably connected in an annular hole formed by the inner ring fire cover 8, a gap 21 exists between the outer periphery side of the temperature control probe 2 and the annular hole, the cavity 11 is communicated with the gap 21, that is, air in the cavity 11 can flow to the gap 21, meanwhile, the wind power system 4 is communicated with the cavity 11 and supplies air to the cavity 11, the air flows to the gap 21 along the inside of the cavity 11, that is, the wind power system 4 can blow air to the gap 21, and further takes away heated air on the outer periphery side of the temperature control probe 2, the temperature of the air flowing to the gap 21 is lower than the temperature of the outer surface of the gas probe 2, so that the surface temperature of the temperature control probe 2 is reduced, the outer surface temperature of the temperature control probe 2 is not too high to cause the burner to cook, and accidental flameout caused by high temperature of the temperature control probe 2 is avoided.

In addition, the wind power system 4 is communicated with the injection pipe 3, the other end of the injection pipe 3 is communicated with the fire hole 100, when the wind power system 4 supplies air into the injection pipe 3, the air is blown out of the fire hole 100, and then the fire hole 100 can blow the overflowing liquid out of the fire hole 100 through the wind power system 4 under the condition that the fire hole 100 is blocked by the overflowing liquid of a cookware, so that the anti-blocking function of the fire hole 100 is realized.

As shown in fig. 4 and 5, a closed space is formed in the wind power system 4, the space is communicated with the first air outlet 41 and the second air outlet 42, the burner is further provided with a gas nozzle 6 and a nozzle holder 7, the gas nozzle 6 and the nozzle holder 7 are arranged in the cavity 11, the nozzle holder 7, the gas nozzle 6 and the ejector pipe 3 are sequentially connected, the gas nozzle 6 is positioned between the nozzle holder 7 and the ejector pipe 3, in addition, the wind power system 4 is connected to one side of the nozzle holder 7, and air is supplied to the nozzle holder 7 so that the air flows from the first air outlet 41 to the gas nozzle 6 and the ejector pipe 3, so that the liquid overflow blocking prevention function of the gas nozzle 6 and the liquid overflow blocking prevention function of the fire hole 100 are respectively realized; as shown in fig. 6 and 7, the first air outlet 41 is an annular opening, the first air outlet 41 is sleeved on the outer peripheral side of the gas nozzle 6, the first air outlet 41 is communicated with the inner cavity of the nozzle holder 7, air blown out from the first air outlet 41 flows to the ejector tube 3 along the outer peripheral side of the gas nozzle 6, a pipeline is connected to the gas nozzle 6, one end of the pipeline is communicated with the gas valve body of the burner, the other end of the pipeline extends into the inner cavity of the nozzle holder 7 and is communicated with the gas nozzle 6, so that the inner cavity of the nozzle holder 7 is not communicated with the gas nozzle 6, thereby preventing leakage of gas in the flowing process, the second air outlet 42 is located at the bottom of the nozzle holder 7, the second air outlet 42 is communicated with the inner cavity of the nozzle holder 7, the casing of the nozzle holder 7 extends downwards, the second air outlet 42 is a strip-shaped opening and is communicated with the inner cavity of the nozzle holder 7, of the second air outlet 42 can also be located at other positions of the nozzle holder 7, and the second air outlet 42 can also be open-holed in other shapes, which is used in the prior art, and the purpose is that the second air outlet 42 is communicated with the inner cavity of the air holder 7 through the temperature control system 11, so as to increase the air flow speed of the probe 11, and the probe system can be quickly cooled by the probe 11, and the probe 11, so as to accelerate the air flow speed of the air flow system 2. Further, wind power system 4 still includes air supply 44, air supply 44 locates in wind power system 4's the enclosure space and air supply 44 all communicates with first air outlet 41 and second air outlet 42, when air supply 44 starts, synchronous outflow air in first air outlet 41 and the second air outlet 42, furthermore, air supply 44 can supply air to ejector tube 3 and cavity 11 in step, both realized the function of preventing blockking up of fire hole 100, realized the rapid cooling of temperature control probe 2, and can realize above-mentioned function in one operation, not only be applicable to the fire hole 100 of combustor after the long-time culinary art and prevent blockking up and the cooling demand of temperature control probe 2, and be applicable to the prevention fire hole 100 before the culinary art and influenced by the water droplet that the pan bottom drips, simultaneously through cooling down in advance to temperature control probe 2 in order to guarantee that the temperature of temperature control probe 2 accords with the culinary art demand that follows, and temperature control probe 2 just can not appear just too high before the culinary art before the ignition, appear dry combustion misjudgement and unexpected flame-out after the ignition.

In other embodiments, the air source 44 may also be a fan. Fan self rotates and drives the air and flows, demand and the demand of the 2 rapid cooling of control by temperature change probe that prevent blockking up according to fire hole 100, the fan can set up higher rotational speed, its aim at is faster through the velocity of flow of the air of air source 44 and flow direction first air outlet 41 or second air outlet 42, the velocity of flow of air appears drawing the air that shows in tub 3 or cavity 11 in the air and flows greatly from fire hole 100 or the power that clearance 21 flowed out soon, fire hole 100 prevents blockking up the effect more obviously and better to the cooling effect of blowing of control by temperature change probe 2. Of course, the air source 44 may be other active air supply devices, which are well known in the art and will not be described in detail herein.

Further, the air inlet (not shown in the figure) of the fan is located outside the cavity 11, one end of the air inlet is communicated to the fan, the other end of the air inlet extends to the outside of the stove bottom box 1 and the air inlet is not communicated with the cavity 11, when the fan is started, the air inlet sucks air from the outside of the cavity 11 and correspondingly supplies the air to the first air outlet 41 and the second air outlet 42, the air inlet can continuously supply the air outside the cavity 11 to the inside of the cavity 11 or the ejector tube 3, compared with the condition that the air inlet is communicated with the cavity 11, the air inlet is arranged outside the cavity 11, the situation that the burner is repeatedly blocked by the fire hole 100 for many times and the temperature control probe 2 is continuously cooled is met, and therefore user experience of frequently using the burner is improved.

In this embodiment, the burner further includes a control system (not shown in the figure), the control system is electrically connected to the wind power system 4, the control system can transmit an ignition signal of the burner to the wind power system 4, the wind power system 4 is correspondingly opened and supplies air to the first air outlet 41 through the nozzle holder 7, the air flows to the gas nozzle 6 and the ejector pipe 3, so that the overflowing liquid generated in the use process of the burner is blown off by the wind power system 4, namely, the anti-clogging function of the gas nozzle 6 and the fire hole 100 is realized, the air is supplied to the cavity 11 through the second air outlet 42, the air in the cavity 11 flows and flows to the outer peripheral side of the temperature control probe 2, and further flows out of the cavity 11 from the gap 21, so that the temperature control probe 2 is prevented from being mistakenly opened due to the influence of high-temperature flue gas in the cooking and using process of the burner, accidental flameout of the burner is avoided, in addition, the control system can transmit a fire-off signal of the burner to the wind power system 4, and the wind power system 4 is correspondingly closed, so that the probe stops supplying air for cooling of the temperature control probe 2 after the burner is used, and the burner is reduced, and the use cost is saved.

And, the burner also includes the gas knob (not shown in the figure), the gas knob is used for lighting or closing the fire hole 100, the control system is connected with the gas knob signal, the control system correspondingly receives the fire-off signal of the gas knob and starts the wind power system 4, at this moment, the gas nozzle 6 no longer sprays the gas to the ejector tube 3, namely the burner is turned off, the wind power system 4 supplies air to the nozzle base 7, the air flows to the gas nozzle 6 through the first air outlet 41, the function of preventing blockage of the gas nozzle 6 is realized, in addition, the air further flows out from the gas nozzle 6 and flows to the ejector tube 3, and flows to the fire hole 100 through the ejector tube 3, the function of preventing blockage of the fire hole 100 of the burner after the fire is turned off and the function of preventing blockage of the gas nozzle 6 are realized, the next time of ignition failure caused by the blockage of the gas nozzle 6 or the fire hole 100 is avoided, so as to promote the service life of the burner, and the use experience of using the burner many times of the user is improved.

Of course, under the 4 on-state of wind power system, second air outlet 42 supplies the air in to cavity 11, the velocity of flow of the air originally in the cavity 11 accelerates, and to the periphery side of control by temperature change probe 2, flow out from clearance 21 at last, the air that is heated by control by temperature change probe 2 is taken away to the in-process that the air flows, the air that the higher air of temperature is blown off by second air outlet 42 takes away promptly, control by temperature change probe 2's surface obtains the cooling, control by temperature change probe 2 after using to the combustor ignition carries out timely and quick cooling, in order to start the combustor in the short time again, control by temperature change probe 2 can detect the temperature of pan bottom with normal temperature, satisfy the user demand of combustor.

Before the burner is used and the gas knob is operated to ignite, the control system can also start the wind power system 4 after receiving a signal, and the aim is that before the fire hole 100 burns, water drops dropping from the fire hole 100 or other impurities such as residual overflowing liquid are blown away through the wind power system 4, air is supplied into the injection pipe 3 through the first air outlet 41 of the wind power system 4 and flows out of the fire hole 100 along the injection pipe 3, so that ignition failure caused by the fact that the water drops remaining at the bottom of a pot drop on the fire hole 100 after the pot is just washed and cleaned with water is avoided, the wind power system 4 can blow away the water drops dropping from the fire hole 100 before the fire hole 100 is ignited, smooth ignition of the fire hole 100 is ensured, and the ignition success rate is improved, in addition, the wind power system 4 is started before the ignition, the second air outlet 42 of the wind power system 4 can correspondingly supply air into the cavity 11, the air flows towards the cavity 11 and flows out along the gap 21, and then surface air on the temperature control probe 2 can be taken away, and the burner is suitable for continuous use, and the condition that the temperature control probe 2 is not used for cooking completely, and the initial lower temperature of the probe 2 is recovered from the condition that the initial temperature control probe 2 is heated last time.

The present embodiment also provides a gas hob including a burner as in any of the above.

Specifically including the combustor that has above-mentioned wind power system 4 and control system etc. its aim at can supply the air to ejector tube 3 and cavity 11 simultaneously to realize that the jam of burner port 100 and the rapid cooling of temperature control probe 2, of course, according to the in-time service behavior of the continuous ignition turn-off of combustor, wind power system 4 also can supply the air in cavity 11 before the combustor ignition so that temperature control probe 2 can adapt to the combustor in-time continuous use cooks and temperature control probe 2 has not yet recovered the initial lower operating temperature's of initial condition after last time of cooking completely, and can supply the air to ejector tube 3 so that burner port 100 of combustor in order to avoid the remaining water droplet of pan bottom to drip on burner port 100 and the ignition that arouses failure just after the water washing of pan.

Example 2

The structure in this embodiment is substantially the same as that in embodiment 1, and the difference is that the axes of the first air outlet 41 and the second air outlet 42 are coincident, the second air outlet 42 is disposed around the outer peripheral side of the first air outlet 41, and the axis of the second air outlet 42 is the same as that of the first air outlet 41, that is, the second air outlet 42 is sleeved outside the first air outlet 41, the first air outlet 41 is connected to the nozzle base 7 and is also sleeved on the outer peripheral side of the gas nozzle 6, the first air outlet 41 can achieve the anti-blocking function of the gas nozzle 6 and the fire hole 100, one end of the second air outlet 42 is connected to the nozzle base 7, and the other end of the second air outlet 42 is larger than the nozzle size of the corresponding ejector tube 3, that is, the second air outlet 42 is larger than the first air outlet 41 and the nozzle size of the second air outlet 42 is larger than the nozzle size of the ejector tube 3, so that the second air outlet 42 is communicated with the cavity 11, and air is supplied into the cavity 11 through the second air outlet 42, which can also achieve the rapid air flow speed acceleration of the air flow rate of the air flow in the cavity 11 and the temperature control of the probe 2, thereby achieving the rapid temperature reduction of the temperature control of the probe 2.

Although specific embodiments of the present invention have been described above, it will be understood by those skilled in the art that this is by way of example only and that the scope of the invention is defined by the appended claims. Various changes and modifications to these embodiments may be made by those skilled in the art without departing from the spirit and the principles of the present invention, and these changes and modifications are all within the scope of the present invention.

Claims (10)

1. A burner comprises a stove bottom box, a temperature control probe, an injection pipe and a wind power system, wherein a cavity is formed in the stove bottom box, the lower end of the temperature control probe is positioned in the cavity, the outer peripheral side of the upper end of the temperature control probe is communicated with the cavity, the wind power system is communicated with the injection pipe and supplies air to the injection pipe, and the burner is characterized in that the wind power system is also communicated with the cavity and supplies air to the cavity.

2. The burner of claim 1, wherein the air system is in communication with the eductor tube through a first air outlet and the air system is in communication with the cavity through a second air outlet, the air system further comprising an air supply in communication with the first air outlet and the second air outlet, respectively.

3. The burner of claim 2, further comprising a gas nozzle having an outlet disposed toward the inlet of the eductor tube;

the first air outlet surrounds the air outlet of the gas nozzle and is arranged towards the inlet of the injection pipe.

4. The burner of claim 3, wherein the second outlet is disposed around the first outlet, and wherein the second outlet has a size greater than the inlet of the eductor tube.

5. A burner as in any one of claims 2 to 4, wherein the air source is a fan.

6. The burner of claim 5, wherein an air inlet of the fan is disposed on the cooktop bottom box, the air inlet facing outside the cavity.

7. The burner according to any one of claims 1 to 4, further comprising a control system, wherein the control system is electrically connected to the pneumatic system, and wherein the control system is capable of activating the pneumatic system when the gas nozzle is supplied with gas.

8. The burner of claim 7, wherein the control system is capable of shutting down the wind system when the gas nozzle stops supplying gas.

9. The burner of claim 7, further comprising a gas knob for igniting or shutting a fire port of the burner, wherein the control system is in signal communication with the gas knob.

10. Gas hob, characterized in, that the gas hob comprises a burner according to any one of the claims 1-9.

Images