CN218820579U - Cooking utensil module and integrated kitchen - Google Patents

Abstract

The embodiment of the utility model provides a cooking utensils module and integrated kitchen. The stove module comprises a panel assembly, a bottom shell assembly, a burner, a control module, an air guide module and a temperature detection device, wherein the panel assembly and the bottom shell assembly of the stove module surround to form a stove cavity, the temperature detection device is arranged in the cavity, and a heat dissipation port is arranged at the rear part of the cavity; the control module is used for controlling the air guide module according to the temperature information detected by the temperature detection device, and the air guide module can open and close the heat dissipation port. The stove module can timely discharge heat in the stove cavity. The cooling requirement of the stove module is met, and the aging of parts in the stove can be delayed. After cooling, the gas pipeline can be effectively protected, and potential safety hazards are avoided. When the temperature in the cavity is lower, the air guide module can close the heat dissipation opening, so that oil stains are effectively prevented from accumulating in the cavity.

Description

Cooking utensil module and integrated kitchen

Technical Field

The utility model relates to a kitchen appliances's technical field specifically, relates to a cooking utensils module and integrated kitchen.

Background

With the pursuit of people for high-quality life, the requirements of users on kitchens are continuously improved, and the performance requirements of people on the stove modules are higher and higher.

Some of the cooking appliance modules are used independently, and some of the cooking appliance modules are integrated in an integrated cooking appliance. But in any case the space occupied by the hob module is continuously compressed in order to expect more space around the hob module. The reduced volume of the hob module leads to a reduced surface area, and therefore the heat generated during operation can accumulate therein, leading to an excessive internal temperature of the hob module. The inside gas pipeline that has of cooking utensils module, the risk that the high temperature can increase the gas and leak brings the potential safety hazard.

Especially in integrated cookers, functional cabinets such as steam ovens or microwave ovens are also usually integrated below the hob module, and these functional cabinets also generate heat during operation, so that the heat generated by the hob module cannot be diffused downwards. In the prior art, a heat radiation fan is arranged in an interlayer between a cooker module and a function cabinet, when the cooker module and/or the function cabinet work, a part of heat can be taken away through the heat radiation fan, but the heat radiation fan arranged in the interlayer can occupy the space of the cooker module and the function cabinet.

SUMMERY OF THE UTILITY MODEL

In order to at least partially solve the problems existing in the prior art, according to one aspect of the present invention, a cooking appliance module is provided. The cooker module comprises a panel assembly, a bottom shell assembly and a burner, the bottom shell assembly is positioned below the panel assembly and surrounds to form a cooker cavity, the bottom of the burner is positioned in the cooker cavity, the head of the burner is positioned above the panel assembly, a temperature detection device is arranged in the cooker cavity, and a heat dissipation port is arranged at the rear part of the cooker cavity; the stove module further comprises a control module and an air guide module with a openable heat dissipation port, and the control module is used for controlling the air guide module according to temperature information detected by the temperature detection device.

The utility model provides a cooking utensils module can real time monitoring cooking utensils cavity's inside temperature through setting up temperature-detecting device. The control module can control the air guide module to open or close the heat dissipation opening according to the temperature information detected by the temperature detection device. Therefore, the heat in the cavity of the stove can be discharged in time, and the aging of parts in the stove module is delayed to a certain extent. The gas pipeline can be effectively protected by timely reducing the temperature in the cavity of the stove, and potential safety hazards are avoided. When the temperature in the stove cavity is lower, the air guide module can close the heat dissipation opening, so that oil stains are effectively prevented from accumulating in the stove cavity.

Illustratively, the air guide module comprises an air guide plate and a driver, the driver is in transmission connection with the air guide plate, the control module is electrically connected to the driver, and the air guide plate is driven by the driver to move between an opening position for opening the heat dissipation opening and a closing position for closing the heat dissipation opening. So set up, air guide module can control the degree of opening of thermovent according to temperature information more nimble under the drive of driver, and is energy-efficient. Moreover, the cooling control mode of the stove module is more refined, and the experience of the user is improved.

Exemplarily, the air guide module further comprises an air guide seat, the air guide seat is arranged through the heat dissipation port, an air guide channel communicated with the inside and the outside of the stove cavity is arranged in the air guide seat, and the air guide plate is connected to an air inlet end of the air guide seat extending into the stove cavity. So set up, can avoid carrying out too much change to the structure of current panel components and drain pan subassembly, only need set up the thermovent on panel components and/or drain pan subassembly. The air guide seat can be inserted into the heat dissipation opening in an interference fit mode, and then the flange is arranged on the outer side of the air guide seat and clamped to the outer side of the heat dissipation opening. The air deflector does not need to be connected to the panel assembly or the bottom shell assembly, so that the universality of the air deflector module can be improved. In addition, the air deflector is connected to the air inlet end of the air guide seat, so that the air deflector can be positioned in the cavity of the stove. Besides the burner, an additional unoccupied space is left in the stove cavity, and the air deflector is arranged in the space to avoid occupying the space outside the stove module. Space utilization can be improved. If the air deflector is arranged at the air outlet end, the air deflector can generate a blocking effect on the air flow in the external space of the stove module when being opened, for example, when the stove module is applied to an integrated stove, the air deflector can generate a blocking effect on the air flow in a smoke collection channel or an air inlet channel of the integrated stove when being opened.

Illustratively, the bottom surface of the wind guide channel is gradually inclined downwards along the direction from the air inlet end to the air outlet end of the wind guide channel. Illustratively, the bottom surface may include an acute angle α of not more than 10 ° with respect to a horizontal plane. For example, the included angle α may be 3 °, 4 °, 5 °, 6 °, 7 °, 8 °, 9 °, 10 °, and the like. So set up, greasy dirt among the high-temperature gas in the cooking utensils cavity can be discharged to the cooking utensils cavity along the bottom surface under the action of gravity, avoids the greasy dirt to enter into the cooking utensils cavity.

Illustratively, the temperature detection device is connected to the outer wall of the air guide seat. Due to the arrangement, the air guide seat can be used as a carrier of the temperature detection device, the temperature detection device is better supported and fixed, and the air guide module can be modularized as much as possible and is convenient to install and maintain. And the temperature detection device is positioned on the outer wall of the air guide seat, so that the temperature detection device can avoid a flow guide channel, the temperature detection device is prevented from being damaged by the impact of high-temperature gas on the flow guide channel, and the service life of the temperature detection device is prolonged.

Exemplarily, the air guide seat comprises a top wall, a bottom wall and a pair of side walls connected between the top wall and the bottom wall, the top wall, the bottom wall and the pair of side walls surround to form an air guide channel, the pair of side walls respectively extend obliquely outwards along a direction from an air inlet end to an air outlet end of the air guide channel, and the temperature detection device is arranged on one of the pair of side walls. So set up, the wind-guiding seat can be the flaring shape, like this, more does benefit to the high-temperature gas in the cooking utensils cavity and collects at the inlet end, also more is favorable to the high-temperature gas to spread the emission at the end of giving vent to anger. Moreover, the flaring shape can reduce the flow velocity of high-temperature gas, avoid the gas to erode or impact other parts in the stove module, and protect the parts on the high-temperature gas discharge path to a certain extent. In addition, the side wall is obliquely arranged, so that enough space can be reserved on two sides of the air guide seat for installing the temperature detection device, and the temperature detection device can be prevented from being too close to the combustor.

Illustratively, the bottom wall is gradually sloped downward in a direction from the gas inlet end to the gas outlet end. The bottom wall is obliquely arranged, so that the oil stain can flow back into the fan box body, and the guide seat can be inserted into the heat dissipation opening to play a role in guiding. Therefore, the air guide seat can be more conveniently installed.

Exemplarily, the panel assembly comprises a supporting frame and a panel, the panel is connected to the top of the supporting frame, the bottom shell assembly is connected to the bottom of the supporting frame, the heat dissipation opening is arranged on the supporting frame, the air guide seat is arranged through the heat dissipation opening, and the air outlet end of the air guide seat is connected with the supporting frame. So set up, the structure of panel and drain pan subassembly can design more simply, be convenient for manufacturing between them. Moreover, as long as the supporting frame has enough strength, the panel can be made of materials convenient for daily maintenance, so that the practicability of the stove module can be greatly improved. Moreover, the formation of the heat dissipation opening is easier.

Illustratively, the driver is mounted on the bottom shell assembly and is located at the side of the air guide seat. So set up, the drain pan subassembly can support the driver, and the installation of driver can be more firm. And the driver is positioned on the side surface of the air guide seat, so that the driver can drive the air guide plate and does not shield the flow guide channel of the air guide seat, and the circulation of the flow guide channel is ensured.

Illustratively, the combustor is a plurality of, and the wind guide module is located between the combustor. So can make full use of the space between the combustor for the cooking utensils module is compacter. And this air guide module can cool down the cooking utensils cavity between the combustor that is located its both sides, and air guide module's utilization ratio is higher, has saved the manufacturing cost of cooking utensils module, reaches the effect of cost reduction increase.

The utility model discloses another aspect still provides an integrated kitchen. The integrated kitchen includes aforementioned cooking utensils module and fan module, the thermovent and the fan module intercommunication of cooking utensils module. So set up, can form the negative pressure environment around the thermovent of cooking utensils cavity through the fan module for the heat dissipation of high-temperature gas in the cooking utensils cavity has improved the cooling rate of cooking utensils module, and is energy-conserving high-efficient. Moreover, the integrated cooker can utilize the fan module of the integrated cooker to dissipate heat, and the installation of an additional fan to occupy space can be avoided.

Exemplarily, the integrated cooker further comprises a functional cabinet positioned below the cooker module, the functional cabinet is provided with a heating unit, the bottom shell assembly is provided with a vent hole, and an interlayer space between the bottom shell assembly and the top wall of the functional cabinet is communicated with the cooker cavity through the vent hole. So set up, the space of intercommunication is formed through air vent and cooking utensils cavity in intermediate layer space, and the high-temperature gas in intermediate layer space can circulate to the cooking utensils cavity through the air vent, and under the effect of control module and fan module, the high-temperature gas in intermediate layer space can be fast through thermovent effluvium. Compared with a mode that high-temperature gas in the interlayer space is cooled only through a heat transfer mode through the bottom shell assembly, the cooling of the interlayer space is accelerated, and the cooling efficiency of the integrated cooker is improved.

Illustratively, the functional cabinet includes one or more of a steam box, an oven, a steam oven, a microwave oven, and a sterilizer. So set up, the function of integrated kitchen can be more diversified, can satisfy user's multiple demand.

Exemplarily, the integrated cooker further comprises a smoke collection module located above the cooker module, the smoke collection module is communicated with the fan module, and the heat dissipation port is communicated to the fan module through the smoke collection module. So set up, the high-temperature gas who flows out by the thermovent conductance can be arranged away in the lump through collection cigarette module, that is to say, the high-temperature gas of thermovent conductance flow can with the oil smoke sharing passageway by collection cigarette module suction, like this, can need not additionally to lay or open a passageway that links to each other with the thermovent in integrated kitchen, both saved manufacturing cost, can save more installation space for other modules of integrated kitchen again, also do benefit to the miniaturization of integrated kitchen.

A series of concepts in a simplified form are introduced in the disclosure, which will be described in further detail in the detailed description section. The summary of the invention is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.

The advantages and features of the present invention are described in detail below with reference to the accompanying drawings.

Drawings

The following drawings of the utility model are used as part of the utility model for understanding the utility model. There are shown in the drawings, embodiments and descriptions thereof, which are used to explain the principles of the invention. In the drawings, there is shown in the drawings,

fig. 1 is an isometric view of an integrated cooker according to an exemplary embodiment of the present invention;

fig. 2 is a sectional view of the integrated cooker shown in fig. 1 (illustrating a conduction direction of heat);

fig. 3 is an exploded view of a hob module and a wind guide module of the integrated cooker shown in fig. 2;

fig. 4 is an isometric view of the air deflection module shown in fig. 2 with the air deflection plates in an open position;

fig. 5 is an isometric view of the air deflection plates of the air deflection module shown in fig. 2 in a closed position;

fig. 6 is a cross-sectional view of the cooktop module and the air guide module shown in fig. 2 (showing the direction of heat conduction); and

fig. 7 is a sectional view of the wind guide module shown in fig. 2.

Wherein the figures include the following reference numerals:

100. an integrated stove; 200. a stove module; 201. a stove cavity; 202. a heat dissipation port; 210. a panel assembly; 211. a first mounting hole; 212. a second mounting hole; 213. a support frame; 214. a panel; 215. an operation panel; 220. a bottom housing assembly; 221. a vent hole; 230. a burner; 240. a pot; 250. a pot frame; 300. a fan module; 400. a temperature detection device; 500. a wind guide module; 501. an air guide channel; 502. an air inlet end; 503. an air outlet end; 510. an air deflector; 520. a driver; 530. a wind guide seat; 531. a top wall; 532. a bottom wall; 533. a side wall; 534. a flange; 540. a connecting rod; 600. a functional cabinet; 700. a smoke collection module; 800. and a control module.

Detailed Description

In the following description, numerous details are provided to provide a thorough understanding of the present invention. One skilled in the art, however, will understand that the following description illustrates only a preferred embodiment of the invention and that the invention may be practiced without one or more of these details. In addition, some technical features that are well known in the art are not described in detail in order to avoid obscuring the present invention.

In the following description, a detailed structure will be presented for a thorough understanding of embodiments of the invention. It is apparent that the implementation of the embodiments of the present invention is not limited to the specific details familiar to those skilled in the art. The following detailed description of the preferred embodiments of the invention, however, the invention is capable of other embodiments in addition to those detailed.

The utility model provides a cooking utensils module 200. As shown in fig. 2, the hob module 200 may include a panel assembly 210, a bottom case assembly 220, a burner 230, a control module 800, a wind guide module 500 and a temperature detection device 400.

The bottom chassis assembly 220 may be located below the panel assembly 210. The bottom shell assembly 220 and the face plate assembly 210 may enclose to form a cooktop cavity 201. The panel assembly 210 may have a generally flat plate-like structure, or the edges of the panel assembly 210 may be provided with downwardly extending flanges. The structure of the panel assembly 210 may be various, and is not limited herein. The edges of the bottom shell assembly 220 may be provided with upwardly extending flanges, or the bottom shell assembly 220 may have a generally flat plate configuration. The structure of the bottom housing assembly 220 may be various, and is not limited herein. Regardless of the specific structures of the bottom case assembly 220 and the panel assembly 210, as long as the bottom case assembly 220 and the panel assembly 210 can surround to form the cooktop cavity 201. The bottom of the burner 230 may be located within the cooktop cavity 201, and the head of the burner 230 may be located above the panel assembly 210. In a specific embodiment, the panel assembly 210 may be provided with a first mounting hole 211, and the head of the burner 230 may pass through the first mounting hole 211 to be exposed above the panel assembly 210. The panel assembly 210 may also be provided with a second mounting hole 212. The ignition knob of the cooktop module 200 can protrude out of the cooktop cavity 201 through the second mounting hole 212. A wok stand 250 may be provided above the burner 230, and the wok stand 250 may be supported on the panel assembly 210. In some examples, the wok stand 250 may be a concentrator wok stand.

The temperature detection device 400 may be disposed within the cooktop cavity 201. The temperature detection device 400 may be used to detect a temperature within the cooktop cavity 201 of the cooktop module 200. The temperature sensing device 400 may employ various types of temperature sensing devices known in the art or that may come into existence in the future, including, but not limited to, bimetallic thermometers, thermocouples, thermal resistors, and radiation thermometers, among others.

The rear of the hob cavity 201 may be provided with a heat sink 202. It should be noted that the directional term "rear" as used herein and hereinafter refers to the side of the cooktop module 200 that is away from the user in the application scenario. The front of the hob cavity 201 refers to the side of the hob module 200 that is close to the user in the application to the scene. In one particular embodiment where the cooktop module 200 is applied to a kitchen, the rear of the cooktop cavity 201 is closer to the wall of the kitchen than the front. In some embodiments, when the panel assembly 210 has a rear flange, the rear flange of the panel assembly 210 may be open to form the heat sink 202. Alternatively, in other embodiments, when the bottom housing 220 has a rear flange, the rear flange of the bottom housing 220 may be opened to form the heat dissipation opening 202. Alternatively, in still other embodiments, the rear portion of the panel assembly 210 may have a first recess, and the rear portion of the bottom case assembly 220 may have a second recess, and the two recesses surround to form the heat sink 202. The heat dissipation opening 202 can be located at a position on the left of the rear portion of the cooker cavity 201, or at a position on the right of the rear portion, or at a position in the middle of the rear portion, which is not limited herein. The directional term "left" as used herein and hereinafter refers to the left hand direction of the user when the cooktop module 200 is in application to a scene and when the user is facing the cooktop module 200. Naturally, the directional term "right" as used herein and hereinafter refers to the right-hand direction of the user when the cooktop module 200 is in application to a scene, and when the user is facing the cooktop module 200. The number of the heat dissipation openings 202 may be one or more, and is not limited herein. When the number of the heat radiating holes 202 is plural, the plural heat radiating holes 202 may be uniformly arranged in a length direction along the cooktop module 200. The front of the hob module 200 generally has an ignition knob of the burner 230, and the middle of the hob module 200 generally is provided with the burner 230. The center is not narrowly defined as the middle of the cooker module 200, but refers to a portion of the cooker module 200 other than the edge. For example, in one embodiment, the number of the burners may be three, two of the burners may be arranged side by side, and the three burners may be arranged in a triangular arrangement as a whole.

The air guide module 500 can open and close the heat dissipation opening 202. The air guide module 500 may be located in the stove cavity 201, may also be located outside the stove cavity 201, or partially located in the stove cavity 201, which is not limited herein. No matter where the air guiding module 500 is located, the heat dissipating opening 202 can be opened or closed. Exemplary embodiments of the wind guide module 500 will also be described in detail below.

In one embodiment, the control module 800 may be located at a lower and forward position of the bottom case assembly 220, such that the control module 800 may be located away from the high temperature zone. This may extend the life of the control module 800. It should be noted that the control module 800 may also be located at other positions of the cooker module 200, for example, on the panel assembly 210, without limiting the aforementioned positions.

The control module 800 may control the air guide module 500 according to the temperature information detected by the temperature detection device 400. The temperature information detected by the temperature detecting device 400 can be acquired by the control module 800 in real time. The specific control process is as follows: when the control module 800 determines that the temperature in the stove cavity 201 is high based on the temperature information detected by the temperature detection device 400, the air guide module 500 may be controlled so that the air guide module 500 may open or expose the heat dissipation port 202. In this way, the high-temperature gas in the stove cavity 201 can be exhausted out of the stove cavity 201 through the heat-dissipating port 202. As the high temperature gas is gradually exhausted or sucked away, the temperature in the cooktop cavity 201 will decrease. When the control module 800 determines that the temperature in the cooker cavity 201 is low based on the temperature information detected by the temperature detection device 400, the control module 800 may control the air guide module 500 to close or cover the heat dissipation port 202, so that oil smoke may be prevented from entering the cooker cavity 201.

The stove module 200 of this application can real time monitoring stove cavity 201's inside temperature through setting up temperature-detecting device 400. The control module 800 may control the air guiding module 500 to open or close the heat dissipating port 202 according to the temperature information detected by the temperature detecting device 400. Therefore, heat in the stove cavity 201 can be discharged in time, and aging of parts in the stove module 200 is delayed to a certain extent. The gas pipeline can be effectively protected by timely reducing the temperature in the stove cavity 201, and potential safety hazards are avoided. When the temperature in the stove cavity 201 is lower, the air guide module 500 can close the heat dissipation port 202, so that oil stains are effectively prevented from being accumulated in the stove cavity 201.

When the cooktop module 200 is used in an integrated cooktop, heat is more likely to accumulate within the cooktop cavity 201 during use of the cooktop module 200 due to: the hot air around the burner 230 and the heat generated from the bottom of the pot 240 are radiated to the panel assembly 210 when the burner is burned, as indicated by arrows in fig. 2. The inventor finds that timely heat dissipation of the stove cavity 201 can effectively avoid heat accumulation inside the integrated stove. The inventor finds that the cooling demand of the integrated cooker can be basically met by radiating the position with the highest temperature in the integrated cooker, so that the aging of parts in the integrated cooker can be delayed to a certain extent.

For example, as shown in fig. 2 to 6, the wind guide module 500 may include a wind guide plate 510 and a driver 520. In one embodiment, the air deflector 510 may have a flat plate shape, and the air deflector 510 may have two states of opening and closing the heat dissipating port 202. In another embodiment, the air deflector 510 may also be louver-shaped. Besides the above two structures, the wind guide module 500 may also have a plurality of structures, which are not described herein. The driver 520 may take the form of any of a variety of known and future drivers including, but not limited to, motors, cylinders, etc. The driver 520 may be drivingly connected to the air deflection plates 510. The drive connections may take the form of any of a variety of known and future drive connections including, but not limited to, belt drives, gear drives, chain drives, worm drives, screw drives, and the like. Alternatively, the upper, lower, front, or rear ends of the air deflectors 510 may be directly or indirectly connected to the panel assembly 210, the bottom case assembly 220, or other components around the heat dissipation opening 202. The driver 520 may be drivingly connected to the free end of the air deflection 510. Alternatively, the air deflector 510 may be connected to only the driver 520, and the driver 520 may drive the air deflector 510 to move between a closed position closing the heat sink 202 and an open position away from the heat sink 202. The shape of the air deflection plate 510 may be various. It is understood that the air deflector 510 may have a structure adapted to the heat dissipation opening 202. The control module 800 may be electrically connected to the driver 520. For example, in some embodiments, the drive end of the motor can be coupled to the free end of the air deflection plate 510 by a linkage 540. The air deflection plate 510 is movable between an open position and a closed position under the drive of the driver 520. It is understood that the air deflector 510 does not only have two positions, i.e. an open position and a closed position, and the air deflector 510 can also control the opening degree of the heat dissipating opening 202 under the driving of the driver 520, for example, the air deflector can be fully opened, half opened, opened to 1/3, and so on. When the control module 800 determines that the temperature in the cooker cavity 201 is extremely high according to the temperature information detected by the temperature detection device 400, the driver 520 may be controlled to enable the air deflector 510 to be in the open position, so that the heat dissipation port 202 is completely opened. When the temperature in the stove cavity 201 is high, the control module 800 may control the driver 520 to make the air deflector 510 in a half-open or other open position. With such an arrangement, the air guide module 500 can more flexibly control the opening degree of the heat dissipating port 202 according to the temperature information under the driving of the driver 520, thereby being efficient and energy-saving. Moreover, the cooling control mode of the stove module 200 is more refined, and the experience of the user is improved.

For example, referring to fig. 2 and 4-6 in combination, the wind guide module 500 may further include a wind guide base 530. The wind guide seat 530 may have various structures, such as a circular ring, a trapezoid, a horn, and the like, which are not limited herein. The air guiding seat 530 may be disposed through the heat dissipating opening 202. The air guide seat 530 may be provided therein with an air guide channel 501. The air guide channel 501 may communicate the inside and outside of the hob cavity 201. The wind guide seat 530 may have an inlet end 502 and an outlet end 503. The inlet end 502 may extend into the cooktop cavity 201. The gas outlet 503 may be located outside the cooktop cavity 201. The deflector 510 may be coupled to the inlet end 502 of the deflector seat 530. The wind deflector 510 can be coupled to a wind deflector seat 530, and the wind deflector seat 530 provides a support carrier for the wind deflector 510. With such an arrangement, excessive changes to the structures of the existing panel assembly 210 and the existing bottom case assembly 220 can be avoided, and only the heat dissipation opening 202 needs to be formed in the panel assembly 210 and/or the bottom case assembly 220. The wind guide seat 530 can be inserted into the heat sink 202 by interference fit, and then the flange 534 is disposed on the outer side of the wind guide seat 530 and is clamped to the outer side of the heat sink 202. The air deflection plates 510 do not need to be connected to the panel assembly 210 or the bottom case assembly 220, thereby improving the versatility of the air deflection module 500. In addition, the air deflector 510 is connected to the air inlet 502 of the air deflector seat 530, so that the air deflector 510 is located in the stove cavity 201. Besides the burner 230, an additional unoccupied space is left in the stove cavity 201, and the air deflector 510 is arranged in the space to avoid occupying the space outside the stove module 200. Space utilization can be improved. If the air deflector 510 is disposed at the air outlet end 503, when the air deflector 510 is opened, an obstruction may be generated on the air flow in the space outside the stove module 200, for example, when the stove module 200 is applied to an integrated stove, when the air deflector 510 is opened, an obstruction may be generated on the air flow in a smoke collection channel or an air inlet channel of the integrated stove.

For example, as shown in fig. 7, the bottom surface of the air guiding channel 501 may be gradually inclined downward along a direction from the air inlet end 502 to the air outlet end 503. Illustratively, the bottom surface may include an acute angle α of not more than 10 ° with respect to a horizontal plane. For example, the included angle α may be 3 °, 4 °, 5 °, 6 °, 7 °, 8 °, 9 °, 10 °, and the like. So set up, greasy dirt among the high temperature gas in the cooking utensils cavity 201 can be along bottom surface discharge to cooking utensils cavity 201 downwards under the action of gravity, avoids the greasy dirt to enter into in the cooking utensils cavity 201.

For example, as shown in fig. 4 and 5, the temperature detection device 400 may be connected to an outer wall of the wind guide seat 530. With such an arrangement, the air guide seat 530 can be used as a carrier of the temperature detection device 400, so as to better support and fix the temperature detection device 400, and also make the air guide module 500 modularized as much as possible, thereby facilitating installation and maintenance. Moreover, the temperature detection device 400 is located on the outer wall of the air guide seat 530, so that the air guide channel can be avoided, the temperature detection device 400 is prevented from being damaged by the impact of the high-temperature gas on the air guide channel, and the service life of the temperature detection device 400 is prolonged.

Illustratively, as shown in fig. 4, the wind-guiding seat 530 may include a top wall 531, a bottom wall 532, and a pair of side walls 533. A pair of side walls 533 may be connected between the top wall 531 and the bottom wall 532. The top wall 531, the bottom wall 532 and the pair of side walls 533 may surround to form the wind guiding channel 501. The pair of side walls 533 may extend obliquely outward in a direction from the air inlet end 502 to the air outlet end 503 of the air guide passage 501, respectively. The temperature detection device 400 may be disposed on one of the pair of sidewalls 533. Due to the arrangement, the air guide seat 530 can be in a flaring shape, so that the high-temperature gas in the stove cavity 201 can be collected at the air inlet end 502 more favorably, and the high-temperature gas can be diffused and discharged at the air outlet end 503 more favorably. Moreover, the flared shape may reduce the flow rate of the high temperature gas, avoid it from cavitation erosion or impacting other components within the cooktop module 200, and protect the components located on the high temperature gas discharge path to some extent. In addition, the sidewall 533 is inclined to leave enough space on both sides of the wind guide seat 530 for installing the temperature detecting device 400, so that the temperature detecting device 400 is prevented from being too close to the burner 230.

Illustratively, the bottom wall 532 may be gradually sloped downward in a direction from the gas inlet end 502 to the gas outlet end 503. The bottom wall 532 is inclined, so that oil contamination can flow back to the blower box body, and the guiding function can be achieved when the air guide seat 530 is inserted into the heat dissipation opening 202. Thus, the wind guide seat 530 can be more conveniently installed.

Illustratively, as shown in fig. 6, the panel assembly 210 may further include a support frame 213 and a panel 214. The structure of the support frame 213 may be various, and may be, for example, a rectangular frame. The panel 214 may be connected to the top of the support frame 213. Typically, the face plate 214 is made of steel or glass. The panel 214 may be adhesively attached to the top of the support frame 213. Alternatively, the panel 214 may be detachably seated on top of the support frame 213, which may facilitate maintenance and cleaning. In some embodiments, the top edge of the support frame 213 may be bent downward into an L-shape, the peripheral edge of the panel 214 may be supported on the edge of the L-shape and the upper surface of the panel 214 is flush with the upper surface of the support frame 213. The bottom housing assembly 220 may be attached to the bottom of the support frame 213 by various known and future attachments, including but not limited to welding, gluing, snapping, fasteners, and the like. The heat dissipation port 202 may be provided on the support frame 213. In general, the support frame 213 may be made of a material having high strength, so that the strength of the support frame 213 is not reduced even if the support frame is perforated or grooved. The air guiding seat 530 may be disposed through the heat dissipating opening 202. The air outlet 503 of the air guiding seat 530 can be connected to the supporting frame 213 by various known and future connection methods, including but not limited to fasteners, plug-in connection, and the like. So configured, the structure of the panel 214 and the bottom case assembly 220 can be designed to be simpler and facilitate the manufacturing of the two. Moreover, as long as the supporting frame 213 has sufficient strength, the panel 214 may be made of a material that is convenient for routine maintenance, and thus, the practicability of the cooker module 200 may be greatly improved. Further, the formation of the heat dissipation port 202 is easier.

The first mounting hole 211 may be provided on the panel 214. Optionally, the panel assembly 210 may further include an operation panel 215 disposed on the support frame 213, and the second mounting hole 212 may be disposed on the operation panel 215.

For example, as shown in fig. 4, the air outlet end 503 of the air guiding seat 530 may be provided with a flange 534. The flange 534 may extend outward toward the side of the wind guide channel 501. The air inlet end 502 of the air guiding seat 530 can pass through the heat dissipating opening 202 of the supporting frame 213. The flange 534 may be located on the exterior of the support frame 213 and abut the exterior side of the support frame 213. So set up, wind-guiding seat 530 can insert to in supporting frame 213 to through flange 534 and the spacing connection of supporting frame 213, like this, the dismouting of wind-guiding seat 530 and supporting frame 213 is more simple and convenient, the operation of being convenient for.

For example, as shown in fig. 2 and 6, the driver 520 may be mounted on the bottom case assembly 220 and may be positioned at a side of the wind guide 530. So configured, the bottom housing assembly 220 may support the driver 520, and the installation of the driver 520 may be more stable. Moreover, the driver 520 is located at the side of the wind guide seat 530, so that the driver 520 can drive the wind guide plate 510 without shielding the flow guide channel of the wind guide seat 530, and the flow conductivity of the flow guide channel is ensured.

For example, as shown in fig. 3, when there are a plurality of burners 230, the wind guide module 500 may be located between the burners 230. In this way, the space between the burners 230 can be fully utilized, making the cooktop module 200 more compact. Moreover, the air guide module 500 can cool down the stove cavity 201 between the burners 230 on two sides of the air guide module 500, the utilization rate of the air guide module 500 is higher, the manufacturing cost of the integrated stove 100 is saved, and the effects of cost reduction and efficiency improvement are achieved.

The utility model discloses another aspect still provides an integrated kitchen. As shown in fig. 2, integrated cooktop 100 may include cooktop module 200 and fan module 300 previously described. Fan module 300 may be located above or below cooktop module 200. For example, in some embodiments in which the fan module 300 is located above the cooktop module 200, the fan module 300 may be located in a ceiling of an application scene, so that noise generated when the fan module 300 operates may be reduced, and a user experience is better. In other embodiments where fan modules 300 are located above cooktop module 200, fan modules 300 may be located below the ceiling, above cooktop module 200. In other embodiments, fan module 300 may be located below cooktop module 200, which is currently more of such applications. Heat sink 202 of cooktop module 200 can be in communication with fan module 300. The integrated hob 100 has the same technical effect as the hob module 200 described previously. When the integrated cooker 100 includes the aforementioned cooker module 200 and the fan module 300, the control module 800 may also control the fan module 300 to start the fan of the fan module 300. In this way, the high-temperature gas in the cooktop cavity 201 can be exhausted out of the cooktop cavity 201 through the heat dissipation port 202 under the suction action of the fan module 300. So set up, can form the negative pressure environment around the thermovent 202 of cooking utensils cavity 201 through fan module 300 for the heat dissipation of high-temperature gas in cooking utensils cavity 201, improved cooking utensils module 200's cooling speed, it is energy-conserving high-efficient. Moreover, the integrated cooker 100 may use its own fan module 300 to perform heat dissipation, and may avoid installing an additional fan to occupy space.

Exemplarily, as shown in fig. 2, the integrated cooker 100 may further include a functional cabinet 600. The functional cabinet 600 may be located below the cooktop module 200. The functional cabinet 600 may have a heat generating unit. Illustratively, the functional cabinet 600 may include one or more of a steam box, an oven, a steam oven, a microwave oven, and a sterilizer. So set up, integrated kitchen 100's function can be more diversified, can satisfy user's multiple demand. The bottom case assembly 220 may be provided with a vent hole 221. The interlayer space between the bottom shell assembly 220 and the top wall of the functional cabinet 600 can be communicated with the cooker cavity 201 through the vent hole 221. So set up, the space of intercommunication is formed through air vent 221 and cooking utensils cavity 201 in the intermediate layer space, and the high-temperature gas in intermediate layer space can circulate to cooking utensils cavity 201 through air vent 221, and under control module 800 and fan module 300's effect, the high-temperature gas in intermediate layer space can be passed through thermovent 202 fast and effused. Compared with a mode that the high-temperature gas in the interlayer space is cooled only through the heat transfer mode through the bottom shell assembly 220, the cooling of the interlayer space is accelerated, and the cooling efficiency of the integrated cooker 100 is improved.

Exemplarily, the integrated cooker 100 may also generally comprise a smoke collection module 700. Smoke collection module 700 may be located above cooktop module 200. The smoke collection module 700 is communicated with the fan module 300, and when the fan module 300 works, the smoke collection module 700 can suck smoke in the environment, convey the smoke to the fan module 300 and then discharge the smoke to the outside. Illustratively, the heat dissipation vent 202 may be communicated to the fan module 300 through the smoke collection module 700. So set up, the high-temperature gas who flows out by thermovent 202 conductance can be discharged in the lump through collection cigarette module 700, that is to say, the high-temperature gas of thermovent 202 conductance play can with the oil smoke sharing passageway by collection cigarette module 700 suction, so, can need not additionally to lay in integrated kitchen 100 or open a passageway that links to each other with thermovent 202, both saved manufacturing cost, can save more installation space for other modules of integrated kitchen 100 again, also do benefit to integrated kitchen 100's miniaturization. Alternatively, the heat sink 202 may also communicate directly with the fan module 300.

In the description of the present invention, it is to be understood that the orientation or positional relationship indicated by the orientation words such as "front", "rear", "upper", "lower", "left", "right", "horizontal", "vertical", "horizontal" and "top", "bottom", etc. are usually based on the orientation or positional relationship shown in the drawings, and are only for convenience of description and simplification of description, and in the case of not making a contrary explanation, these orientation words do not indicate and imply that the device or element referred to must have a specific orientation or be constructed and operated in a specific orientation, and therefore, should not be interpreted as limiting the scope of the present invention; the terms "inner" and "outer" refer to the interior and exterior relative to the contours of the components themselves.

For convenience of description, relative terms of regions such as "over 8230; \8230" "," ' over 8230; "\8230;", "' over 8230;", \8230;, "' over 8230" "," "over surface", "over", etc. may be used herein to describe the regional positional relationship of one or more components or features to other components or features as illustrated in the figures. It is to be understood that the relative terms of the regions are intended to encompass not only the orientation of the element as depicted in the figures, but also different orientations in use or operation. For example, if an element in the drawings is turned over in its entirety, the articles "over" or "on" other elements or features will include the articles "under" or "beneath" the other elements or features. Thus, the exemplary terms "at 8230; \8230; 'above" may include both orientations "at 8230; \8230;' above 8230; 'at 8230;' below 8230;" above ". Further, these components or features may also be positioned at various other angles (e.g., rotated 90 degrees or other angles), all of which are intended to be encompassed herein.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of exemplary embodiments according to the present application. As used herein, the singular forms "a", "an" and "the" are intended to include the plural forms as well, and it should be understood that when the terms "comprises" and/or "comprising" are used in this specification, they specify the presence of stated features, steps, operations, elements, components, and/or combinations thereof, unless the context clearly indicates otherwise.

It should be noted that the terms "first," "second," and the like in the description and claims of this application and in the drawings described above are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the application described herein are capable of operation in other sequences than those illustrated or described herein.

The present invention has been described in terms of the above embodiments, but it is to be understood that the above embodiments are for purposes of illustration and description only and are not intended to limit the invention to the described embodiments. Furthermore, it will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that many more modifications and variations are possible in light of the teaching of the present invention and are within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (14)

1. A kitchen range module comprises a panel component, a bottom shell component and a burner, wherein the bottom shell component is positioned below the panel component and surrounds to form a kitchen range cavity, the bottom of the burner is positioned in the kitchen range cavity, and the head of the burner is positioned above the panel component,

a temperature detection device is arranged in the stove cavity, and a heat dissipation port is arranged at the rear part of the stove cavity;

the stove module further comprises a control module and an air guide module capable of opening and closing the heat dissipation opening, and the control module is used for controlling the air guide module according to temperature information detected by the temperature detection device.

2. The cooktop module of claim 1, wherein the air deflection module comprises an air deflection plate and a driver drivingly connected to the air deflection plate, wherein the control module is electrically connected to the driver, and wherein the air deflection plate is movable between an open position opening the heat sink and a closed position closing the heat sink upon actuation of the driver.

3. The range module of claim 2, wherein the air guide module further comprises an air guide seat, the air guide seat is arranged through the heat dissipation opening, an air guide channel communicating the inside and the outside of the range cavity is arranged in the air guide seat, and the air guide plate is connected to an air inlet end of the air guide seat extending into the range cavity.

4. The cooktop module of claim 3, wherein a bottom surface of the air-directing channel is gradually sloped downward in a direction from an air inlet end to an air outlet end thereof.

5. The cooktop module of claim 3, wherein the temperature detection device is connected to an outer wall of the air guide seat.

6. The cooktop module of claim 5, wherein the air guide seat comprises a top wall, a bottom wall, and a pair of side walls connected between the top wall and the bottom wall, the top wall, the bottom wall, and the pair of side walls surround to form the air guide channel, the pair of side walls respectively extend obliquely outward along a direction from an air inlet end to an air outlet end of the air guide channel, and the temperature detection device is disposed on one of the pair of side walls.

7. The cooktop module of claim 6, wherein the bottom wall is gradually sloped downward in a direction from the inlet end to the outlet end.

8. The cooktop module of claim 3, wherein the panel assembly comprises a support frame and a panel connected to a top of the support frame, the bottom case assembly connected to a bottom of the support frame, the heat sink disposed on the support frame,

the air guide seat penetrates through the heat dissipation opening, and the air outlet end of the air guide seat is connected with the supporting frame.

9. The cooktop module of claim 3, wherein the drive is mounted to the bottom shell assembly and is located to a side of the air guide seat.

10. The cooktop module of claim 1, wherein the burner is a plurality of burners, and the air guide module is located between the burners.

11. An integrated cooker, characterized by comprising:

the cooktop module of any of claims 1-10; and

and the heat dissipation port of the stove module is communicated with the fan module.

12. The integrated cooker of claim 11, further comprising a functional cabinet located under the cooker module, the functional cabinet having a heat generating unit, the bottom case assembly of the cooker module being provided with a vent hole, and an interlayer space between the bottom case assembly and a top wall of the functional cabinet being communicated with the cooker cavity through the vent hole.

13. The integrated cooker of claim 12, wherein the functional cabinet comprises one or more of a steam box, an oven, a steam oven, a microwave oven, and a sterilizing cabinet.

14. The integrated cooker of claim 11, further comprising a smoke collection module located above the cooker module, the smoke collection module being in communication with the fan module, the heat vents being in communication with the fan module through the smoke collection module.

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