CN217285451U - Cooking utensil - Google Patents

Abstract

The utility model provides a cooking utensil, which comprises a cover body, a cooker body and an automatic gas exchange device. The automatic gas exchange device comprises an electric driving unit, a transmission device, a gas flow generating device and a gas inlet and outlet valve device. The transmission is connected to the electric drive unit so as to be driven in a reciprocating motion by the latter. The airflow generating device is provided with a flexible cavity, the flexible cavity is switched between a squeezed state and a restored state under the action of the reciprocating motion of the transmission device, and the side wall of the flexible cavity is constructed into a corrugated structure, and the corrugated structure is provided with a first end wall close to the transmission device. The air inlet and outlet valve device is connected with the flexible cavity and is provided with a valve air inlet and a valve air outlet, the valve air inlet is communicated with the outside atmosphere, and the valve air outlet is communicated with the cooking space. The wall thickness h2 of the first end wall is greater than the wall thickness h1 of the rest of the corrugated structure, and h2-h1 is more than or equal to 1.2 mm. This scheme can provide the gas exchange for the cooking space, and can avoid the flexible chamber to take place to deflect and rub and send out the noise.

Description

Cooking utensil

Technical Field

The utility model relates to the technical field of household appliances, more specifically, the utility model relates to a cooking utensil.

Background

In order to increase the cooking rate, the known cooking appliances (such as electric cookers) usually have high heating power, but in the actual use process, when the food materials are heated and boiled by continuous high fire, a large amount of foam is generated, so that the problem of overflowing is caused.

The known mode of blowing in cooking utensil's interior pot through the application air pump solves above-mentioned problem, but current air pump often can produce great noise at the during operation to influence user's use and experience.

Therefore, there is a need for a cooking appliance that at least partially solves the problems of the prior art.

SUMMERY OF THE UTILITY MODEL

In the summary section a series of concepts in a simplified form is introduced, which will be described in further detail in the detailed description section. The inventive content does not imply any attempt to define the essential features and essential features of the claimed solution, nor is it implied to be intended to define the scope of the claimed solution.

The utility model provides a cooking utensil. The cooking appliance includes:

a cover body;

the cover body is arranged on the cooker body, and when the cover body covers the cooker body, a cooking space is formed between the cover body and the cooker body; and

automatic gas exchange device, automatic gas exchange device set up in lid or a kind of deep pot body, it includes:

an electric drive unit;

a transmission device connected with the electric drive unit so as to be driven by the electric drive unit to reciprocate; the air flow generating device is connected with the transmission device and is provided with a flexible cavity, the flexible cavity is switched between a squeezed state and a reset state under the action of the reciprocating motion of the transmission device, the side wall of the flexible cavity is constructed into a corrugated structure, and the corrugated structure is provided with a first end wall close to the transmission device;

an air inlet and outlet valve device connected with the flexible cavity, the air inlet and outlet valve device having a valve air inlet and a valve air outlet, the valve air inlet communicating with the outside atmosphere, the valve air outlet communicating with the cooking space,

wherein the wall thickness h2 of the first end wall of the corrugated structure is greater than the wall thickness h1 of the rest of the main body part of the corrugated structure, and h2-h1 are more than or equal to 1.2 mm.

During cooking, the automatic gas exchange device is capable of drawing in gas through the valve inlet and delivering the gas into the cooking volume through the valve outlet when food in the cooking volume is in a boiling phase. The temperature difference between the delivered gas and the foam in the cooking space exists, so that the delivered gas can liquefy and shrink the steam in the foam to break after entering the cooking space and contacting the foam accumulated in the cooking space, and the overflow of the pot is prevented. The overflow can be avoided even under the condition of fast cooking with large fire.

In addition, in the scheme, the airflow generating device can realize the pressure and speed change of the airflow through the compression and the stretching of the flexible cavity with a certain volume, and can realize the automatic control of the airflow by combining the electric driving unit, the air inlet and outlet valve device and the like, thereby providing a gas exchange function for the cooking space. In addition, the scheme enables the flexible cavity to be compressed and stretched more easily, not to be easily broken and has reliable fatigue life by constructing the side wall of the flexible cavity into a corrugated structure. The solution described above allows a large air flow and is relatively inexpensive.

It can be understood that when the transmission device drives the flexible cavity to switch between the squeezed state and the restored state, the connection between the transmission device and the flexible cavity may slide relatively, which may also cause the flexible cavity to deflect, generate friction, and generate noise. Above-mentioned scheme is through making the wall thickness that is close to the first end wall of transmission's ripple column structure be greater than the wall thickness of the remaining main part of ripple column structure, can strengthen the intensity and the stability of first end wall department to relative deflection takes place when can avoiding flexible chamber to move, and then can reduce the friction between flexible chamber and the transmission and the noise that produces from this.

Optionally, the wall thickness h1 of the main body portion of the corrugated structure satisfies: h1 is more than or equal to 0.2mm and less than or equal to 1.2 mm. This scheme is through setting up the wall thickness in above-mentioned within range with flexible chamber, can prolong the fatigue life in this flexible chamber under the prerequisite of the elastic compression power of guaranteeing flexible chamber, avoids it to appear warping, influences the air flow.

Optionally, the corrugated structure comprises n peak configurations, wherein 2 ≦ n ≦ 8. The scheme can enable the structure of the flexible cavity to be more compact under the condition of realizing the atmospheric flow.

Optionally, the width L1 of an individual wave trough in the corrugated structure in the axial direction of the flexible cavity satisfies: l1 is more than or equal to 1mm and less than or equal to 2mm, and/or the minimum distance L2 between two adjacent wave crests satisfies 3mm and less than or equal to L2 and less than or equal to 4 mm. According to the scheme, the width of the single wave trough is set in the range, the contact area of two adjacent waves can be reduced, the adjacent wave troughs can be prevented from contacting while two adjacent wave crests are in maximum contact, the friction between the adjacent waves can be reduced, the service life of the adjacent waves can be prolonged, and the noise generated by the friction between the adjacent waves can be reduced. Further, by setting the minimum pitch between adjacent two peaks within the above range, the amount of air flow can be increased.

Optionally, a steam channel for communicating the cooking space with the outside of the cooking appliance is arranged on the cover body, and the steam channel is communicated with the outside of the cooking appliance through a steam outlet arranged on the cover body;

the cover body is also provided with a cover air inlet which is communicated with the valve air inlet, and the position of the steam outlet on the cover body is positioned on the outer peripheral side of the cover air inlet.

In this scheme, because the steam outlet sets up around the lid air inlet, consequently, steam via steam outlet exhaust can form around the lid air inlet and the top in the circumference in succession or confined steam curtain to filter the gas of inhaling the lid air inlet, avoided debris such as oil smoke, dust to inhale in the lid air inlet, thereby left greasy dirt or dirt and even blockked up in having avoided the gas pipeline, also avoided influencing the taste of food.

Optionally, the steam outlet is annular; or the steam outlet comprises a plurality of sub-steam outlets spaced around the lid air inlet.

Optionally, the lid air inlet communicates with the valve air inlet through an air inlet duct, the lid air inlet is disposed at a first end of the air inlet duct, the cooking appliance further comprises a stopper member covering the first end of the air inlet duct and forming an air inlet gap with the first end of the air inlet duct. The scheme can further ensure that other impurities cannot enter the air inlet pipeline together with the outside air, and avoids the blockage of the air inlet pipeline.

Optionally, the cooking appliance further comprises a water-proof structure disposed at least partially between the steam outlet and the lid air inlet to prevent liquid from entering the lid air inlet.

Optionally, the waterproof structure is a boss, and the boss is higher than the steam outlet.

In this way, condensate will not pass over the boss into the cover air inlet under the influence of gravity.

Optionally, the transmission device comprises an eccentric wheel and an eccentric connecting rod connected with the eccentric wheel, the eccentric wheel is connected with the electric driving unit, the electric driving unit can drive the eccentric wheel and the eccentric connecting rod to rotate, and the eccentric connecting rod is connected with the airflow generation device. The scheme is convenient to assemble and easy to realize.

Optionally, the air flow generating device includes a closed end and an air guide end respectively located at two ends of the flexible cavity, the closed end is connected to the first end wall, the eccentric link is connected to the closed end, and the air inlet and outlet valve device is connected to the air guide end. The scheme is convenient to assemble and easy to realize.

Optionally, the air valve inlet and outlet device comprises a first one-way valve, a second one-way valve and a one-way valve film arranged between the first one-way valve and the second one-way valve, the valve air inlet and the valve air outlet are respectively arranged on the second one-way valve, the first one-way valve is provided with an air inlet channel and an air outlet channel corresponding to the valve air inlet and the valve air outlet respectively, the one-way valve film comprises two flexible diaphragms corresponding to the valve air inlet and the valve air outlet respectively, and the flexible diaphragms can realize elastic deformation along with the air flow direction. The scheme is convenient to assemble, easy to realize and low in cost.

Optionally, the flexible diaphragm is connected to the one-way valve film through a connecting rib, and a through port is formed between the flexible diaphragm and the one-way valve film. The scheme is convenient to assemble, easy to realize and low in cost.

Optionally, a first check ring is arranged at a position of the first check valve corresponding to the valve air outlet, a second check ring is arranged at a position of the second check valve corresponding to the valve air inlet, and the first check ring and the second check ring respectively protrude towards the corresponding flexible diaphragm and abut against the flexible diaphragm. The scheme can conveniently realize the unidirectional inlet and outlet of gas.

Optionally, the automatic gas exchange device is generally horizontally recumbent in the lid. In this way, the space in the cover can be more fully utilized, making the structure of the cover more compact.

Drawings

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

fig. 1 is a schematic cross-sectional view of a portion of a cooking appliance according to an embodiment of the present invention;

FIG. 2 is a schematic top view of a portion of the lid of the cooking appliance shown in FIG. 1, with the face cover omitted to clearly show the structure of the interior of the lid;

FIG. 3 is a schematic sectional view of the cover shown in FIG. 2 taken along the direction A-B-C, in which a portion of the structure of the cover is omitted;

FIG. 4 is a schematic sectional view of the cover shown in FIG. 2 taken along the direction M-N-C, in which a portion of the structure of the cover is omitted;

FIG. 5 is a schematic cross-sectional view of an automatic gas exchange device of the cooking appliance shown in FIG. 1;

FIG. 6 is a schematic assembly view of the electric drive unit, transmission and gas flow generating device of the automatic gas exchange device shown in FIG. 5;

FIG. 7 is a schematic cross-sectional view of the gas flow generating device of the automatic gas exchange device shown in FIG. 5;

FIG. 8 is a schematic cross-sectional view of an inlet and outlet gas valve assembly of the automatic gas exchange device shown in FIG. 5;

fig. 9 is a schematic view of a portion of a lid of a cooking appliance according to an embodiment of the present invention;

fig. 10 is a perspective view of an automatic gas exchanging apparatus of the cooking appliance shown in fig. 1, in which a damper housing is provided outside the automatic gas exchanging apparatus.

Detailed Description

In the following description, numerous specific details are set forth in order to provide a more thorough understanding of the present invention. It will be apparent, however, to one skilled in the art, that the present invention may be practiced without one or more of these specific details. In other instances, well-known features have not been described in order to avoid obscuring the present invention.

In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the present invention. It is apparent that the practice of the invention is not limited to the specific details known to those skilled in the art. The following detailed description of the preferred embodiments of the invention, however, is not intended to limit the invention to the particular embodiments disclosed, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

The utility model provides a cooking utensil. The cooking appliance may be an electric cooker, an electric pressure cooker or other electric heating appliance. In addition, the cooking appliance may have other functions such as cooking porridge and cooking soup in addition to the function of cooking rice.

As shown in fig. 1, the cooking appliance 100 includes a pot body 110. The pot body 110 may have a generally rounded rectangular parallelepiped shape, a generally cylindrical shape, or any other suitable shape. The pot body 110 has a substantially cylindrical shape or any other suitable shape of the inner pot 130 disposed therein. The inner pot 130 can be freely put into or taken out of the inner pot receiving part of the pot body 110, so that the inner pot 130 can be conveniently cleaned. The inner pot 130 is used to store food to be cooked, such as rice, soup, etc. The top of the inner pot 130 has a top opening. The user can store food to be cooked in the inner pot 130 through the top opening or take cooked food out of the inner pot 130 through the top opening.

An inner pot heating means (not shown) for heating the inner pot 130 is further provided in the pot body 110. The inner pot heating means may heat the inner pot 130 at the bottom and/or the side of the inner pot 130. The inner pot heating device can be an electric heating tube, and can also be an induction heating device such as an electromagnetic coil.

As shown in fig. 1, the pot body 110 is provided with a lid 120. The shape of the cover 120 substantially corresponds to the shape of the pot body 110. For example, the cover 120 may have a rounded rectangular parallelepiped shape. The cover body 120 includes an inner cover 123, and the inner cover 123 may be a detachable inner cover so that the inner cover 123 can be detached for cleaning. The cover 120 is provided to the pot body 110 in an openable and closable manner, for covering the entire top of the pot body 110 or at least the inner pot 130 of the pot body 110. Specifically, in the present embodiment, the lid body 120 may be pivotably provided above the pot body 110 between the maximum open position and the closed position by, for example, a hinge. The hinged position of the cover 120 and the pot body 110 is usually located at the rear end of the cooking utensil 100, so that the user can operate the cooking utensil 100 at the front end. It should be noted that the terms "front" and "rear" are used herein with reference to the position where the user uses the cooking appliance. Specifically, a direction in which the cooking appliance faces the user is defined as "front", and a direction opposite thereto is defined as "rear".

As shown in fig. 1, when the cover 120 is closed over the pot body 110, a cooking space 140 is formed between the cover 120 and the pot body 110 (specifically, the inner pot 130 of the pot body 110). The cooking space 140 includes a food storage space 141 and a cavity space 142. Specifically, the food storage space 141 refers to a space where food is actually stored. The cavity space 142 is located above the food storage space 141. That is, when the cover 120 is covered on the pot body 110, the cavity space 142 is a space between the upper surface of the food and the cover 120. There is no strict distinction between the food storage space 141 and the cavity space 142, and the volume of the two spaces may change according to the specific change of the food material volume.

It should be noted that directional terms and positional terms used herein in describing the respective components and their positional relationships in the cover body 120, such as "above", "below", "upper side", "lower side", "upward", "downward", "above", "below", "high", "low", "horizontal distance", etc., are relative to the cover body 120 when in the covering position.

As shown in fig. 1, the lid 120 is provided with a lid air inlet 121. One end of the cover air inlet 121 communicates with the outside, and the other end communicates with an automatic air exchanging device 150 (as shown in fig. 2, more specifically, an air inlet end of the automatic air exchanging device 150) provided in the pot body 110 or the cover body 120, which will be described in detail later, to deliver the outside air (e.g., cold air) to the cooking space 140 (more specifically, the cavity space 142) through the automatic air exchanging device 150.

Hereinafter, an automatic gas exchange device according to an embodiment of the present invention will be described in detail.

The cooking appliance 100 further includes an automatic gas exchange device 150, and the automatic gas exchange device 150 is used for sucking gas (e.g., external cold air) outside the cooking appliance 100 into the cavity space 142. Preferably, the automatic gas exchange device 150 is provided in the cover 120.

The automatic gas exchange device 150 may be disposed at any suitable location of the cooking appliance 100. In a preferred embodiment of the present invention, as shown in fig. 1 to 4, an automatic gas exchange device 150 is provided in the cover body 120 so as to communicate with a cover air inlet 121 provided in the cover body 120 through an air inlet line. It is further preferred that the automatic gas exchange device 150 be generally horizontally recumbent in the cover 120 to reduce the size of the cover 120 in the vertical direction. For example, the automatic gas exchange device 150 may be disposed between the inner liner and the upper cover of the cover 120.

As shown in fig. 5, the automatic gas exchange device 150 includes an electric driving unit 151, a transmission 160, a gas flow generating device 170, and an inlet and outlet gas valve device 180 connected to the gas flow generating device 170. The electric drive unit 151 may be configured as a motor. The transmission 160 is connected to the electric drive unit 151 such that the electric drive unit 151 can drive the transmission 160 to reciprocate. The airflow generating device 170 has a flexible chamber 171, and the flexible chamber 171 is connected to the actuator 160 so as to be changed in shape by the reciprocating motion of the actuator 160. Specifically, the flexible chamber 171 can be switched between a squeezed state and a restored state, and when the flexible chamber 171 is switched between the two states, the volume of the flexible chamber 171 can be changed, so that a pressure change can be generated in the flexible chamber 171. The air inlet and outlet valve device 180 is connected with the flexible cavity 171, the air inlet and outlet valve device 180 is provided with a valve air inlet 181 and a valve air outlet 182 which can be communicated with the cavity of the flexible cavity 171, and the valve air inlet 181 and the valve air outlet 182 are both one-way through ports. The valve inlet port 181 is in communication with the ambient atmosphere such that ambient atmosphere may enter the flexible chamber 171 via the valve inlet port 181. Valve outlet 182 communicates with the cooking volume such that gas in flexible chamber 171 can enter the cooking volume via valve outlet 182. The structure of the air inlet and outlet valve device 180 will be described in detail later.

Specifically, the valve inlet port 181 communicates with the cap inlet port 121 through an inlet line (not shown) to allow the outside atmosphere to enter. A first end of the inlet line communicates with the lid inlet port 121 and a second end of the inlet line is connected to the valve inlet port 181. The valve outlet 182 communicates with the lid outlet 122 via an outlet conduit (outlet route can refer to fig. 4), and the lid outlet 122 can be disposed on the inner lid to allow the outside atmosphere to enter the cooking space. The inlet and outlet conduits may be made of an elastic material such as silicone.

As shown in fig. 5 and 6, the transmission device 160 includes an eccentric 161 and an eccentric connecting rod 162 connected to the eccentric 161, the eccentric 161 is connected to the electric driving unit 151, the electric driving unit 151 can drive the eccentric 161 to rotate, the eccentric 161 can drive the eccentric connecting rod 162 to rotate, and the eccentric connecting rod 162 is connected to the flexible chamber 171. Specifically, the airflow generating device 170 includes a closed end 172 and an air guiding end 173 respectively located at two ends of the flexible chamber 171, the eccentric link 162 is connected to the closed end 172, and the air inlet and outlet valve device 180 is connected to the air guiding end 173.

As shown in fig. 7, the closed end 172 of the flexible chamber 171 has a through hole 174, the through hole 174 penetrates in the longitudinal direction of the eccentric link 162, and the eccentric link 162 extends into the through hole 174. When the eccentric link 162 rotates, the flexible chamber 171 is reciprocated in the axial direction thereof.

In a preferred embodiment, the side wall of the flexible chamber 171 is configured as a corrugated structure, and the corrugated flexible chamber 171 may be brought to be compressed and stretched reciprocally when the eccentric link 162 rotates. As shown in fig. 5 and 7, the corrugated structure has a first end wall 171a adjacent the transmission 160. A closed end 172 is connected to the first end wall 171 a. The corrugated structure includes a plurality of peak configurations. This solution enables the flexible chamber 171 to be more easily compressed and stretched, and less easily broken, and has a reliable fatigue life by configuring the sidewalls of the flexible chamber 171 as a corrugated structure.

Because the air cavity quantity of flexible chamber and air flow size become the positive correlation's relation, for making the air flow be greater than 2L/min to satisfy the requirement of quick cooking, and for making this flexible chamber can more adapt to the size of current cooking utensil's inside lining (current cooking utensil's inside lining diameter is less than 245mm usually), in this scheme, make the quantity n of crest structure satisfy: n is more than or equal to 2 and less than or equal to 8. Further preferably, the number n of peak configurations satisfies: n is more than or equal to 2 and less than or equal to 4. Illustratively, the corrugated structure may include 3 wave peak configurations, which may be set by one skilled in the art according to actual needs.

In order to reduce the area where two adjacent corrugations contact during the reciprocating motion of the flexible chamber 171, thereby reducing friction and noise, it is preferable that, as shown in fig. 7, the width L1 of the individual wave troughs in the corrugated structure in the axial direction of the flexible chamber 171 satisfies: l1 is more than or equal to 1mm and less than or equal to 2mm, and the minimum distance L2 between two adjacent wave crests meets the requirement that L2 is more than or equal to 3mm and less than or equal to 4 mm. This scheme can minimize the area where the adjacent two corrugations contact by setting the width of the single wave trough in the axial direction of the flexible chamber 171 and the minimum distance between the adjacent two wave crests within the above-mentioned ranges, and can ensure that the adjacent two wave crests do not contact while contacting at the maximum, so that the friction between the adjacent corrugations can be reduced, the service life thereof can be improved, and the scheme can also reduce the noise generated by the friction between the adjacent corrugations. Further, by setting the interval between the adjacent two peaks within the above range, the air flow amount can be secured. For example, the width L1 of a single wave trough along the axial direction of the flexible cavity 171 may be set to 1.5mm, 1.8mm, etc., and the minimum distance L2 between two adjacent wave crests may be set to 3.5mm, 3.6mm, etc., which may be set by one skilled in the art according to actual needs.

It will be appreciated that as eccentric link 162 switches flex chamber 171 between the compressed and extended states, eccentric link 162 exerts a radially directed force on flex chamber 171 as well as axially directed forces F1 and F2, as shown in fig. 7. This may cause relative slippage at the junction of the closed ends 172 of the flexible chamber 171 and may also cause the flexible chamber 171 to deflect and rub, thereby generating noise. Therefore, in the cooking appliance according to the present invention, the wall thickness h2 of the first end wall 171a of the corrugated structure is made greater than the wall thickness h1 of the remaining main body portion of the corrugated structure, and h2-h1 is equal to or greater than 1.2 mm. Illustratively, h2 may be 1mm or 1.2mm, etc., larger than h 1.

The above-mentioned solution can enhance the strength and stability of the first end wall 171a by making the wall thickness of the first end wall 171a of the corrugated structure close to the eccentric link 162 greater than the wall thickness of the rest of the main body of the corrugated structure, so that the relative deflection of the flexible chamber 171 during the movement can be avoided, and the friction between the flexible chamber 171 and the eccentric link 162 and the noise generated thereby can be reduced. Further, this arrangement can prevent the first end wall 171a from rubbing against the valleys of the body portion to generate noise as much as possible during the movement.

Further preferably, the wall thickness h1 of the remaining body part of the corrugated structure satisfies: 0.2mm h1 ≦ 1.2mm, where the main body portion of the corrugated structure refers to the middle main body section of the corrugated structure and does not include the closed end 172 and the air guide end 173. Illustratively, the wall thickness h1 of the main body part can be set to 0.5mm, 0.8mm, 1mm, etc., which can be set by one skilled in the art according to actual needs. This scheme is through setting up the wall thickness of flexible chamber 171 in above-mentioned within range, can be under the prerequisite of guaranteeing the elasticity compressive force of flexible chamber 171, prolongs the fatigue life of this flexible chamber 171, avoids it to appear warping, influences the air flow.

Preferably, the relationship between the diameter D of the crest formation and the diameter D of the trough formation of the corrugated structure satisfies: d is more than or equal to 5mm and less than or equal to 50 mm. The applicant has found that by making the diameter D of the wave trough configuration greater than or equal to 5mm, it is possible to make the automatic gas exchange device 150 achieve a gas flow rate greater than 2L per minute, and moreover, by making the diameter D of the wave trough configuration less than or equal to 50mm, it is possible to make the structure of the flexible chamber 171 more compact, and thus easier to place in the cover of the cooking appliance 100, and it is possible to make the structure of the cooking appliance 100 more compact. Further preferably, the relationship between the diameter D of the crest formation and the diameter D of the trough formation of the corrugated structure satisfies: d is more than or equal to 10mm and less than or equal to D and less than or equal to 25 mm.

The gas inlet and outlet valve device 180 can realize the one-way passage of gas. Specifically, as shown in fig. 5 and 8, the air inlet and outlet valve device 180 includes a first check valve 178, a second check valve 179, and a check valve film 183 disposed between the first check valve 178 and the second check valve 179. The first check valve 178 is disposed closer to the flexible cavity 171, the first check valve 178 is provided with an inlet channel 184 and an outlet channel 185, the inlet channel 184 and the outlet channel 185 correspond to the valve inlet 181 and the valve outlet 182, respectively, and the valve inlet 181 and the valve outlet 182 are disposed on the second check valve 179, respectively.

Be provided with the diaphragm 186 that admits air and the diaphragm 187 of giving vent to anger that corresponds with valve air inlet 181 and valve gas outlet 182 respectively on the check valve membrane 183, admit air diaphragm 186 and the diaphragm 187 of giving vent to anger are the flexibility, and two flexible diaphragms pass through the splice bar and connect on check valve membrane 183, and have the through-hole between flexible diaphragm and the check valve membrane 183. Preferably, as shown in fig. 8, the portion of the check valve film 183 where the inlet diaphragm 186 and the outlet diaphragm 187 are provided is thinner than the other portion of the check valve film 183. In one embodiment, this is accomplished by providing a recess in the check valve membrane 183. Specifically, the recess at inlet diaphragm 186 opens toward first check valve 178, and the recess at outlet diaphragm 187 opens toward second check valve 179. This arrangement makes it easier for inlet diaphragm 186 and outlet diaphragm 187 to deform during inlet and outlet of gas, thereby facilitating the passage of gas.

Further, in order to realize one-way passage of gas, the first one-way valve 178 is provided with a first retainer ring 188 at a position corresponding to the valve outlet 182, and the first retainer ring 188 protrudes toward the outlet diaphragm 187 and abuts on the outlet diaphragm 187. A second stopper 189 is provided at a position of the second check valve 179 corresponding to the valve inlet 181, and the second stopper 189 protrudes toward the intake diaphragm 186 and abuts on the intake diaphragm 186.

When ambient air flows from the valve inlet 181 into the flexible chamber 171, the air flow will bend the inlet diaphragm 186 so that it can enter the flexible chamber 171 through the inlet passage 184. At this time, the air flow also enters the valve outlet 182C, but the air flow cannot pass through because the air outlet diaphragm 187 is blocked by the first retaining ring 188 and cannot be bent; similarly, when the airflow in the flexible cavity 171 enters the cooking space through the valve outlet 182, the outlet diaphragm 187 is bent by the airflow and flows out through the valve outlet 182, and meanwhile, the airflow in the flexible cavity 171 also passes through the inlet channel 184, but the inlet diaphragm 186 is blocked by the second baffle 189 and cannot be bent, so that the airflow cannot pass through. The purpose of single channel one-way passing can be achieved through the mode.

During cooking, when the temperature of the food cooked in the inner pot is critically boiled or just before the boiling time is over, or when the temperature in the inner pot reaches a set value, viscous substances such as starch in the food are separated into water, and steam is wrapped to form a large amount of foam, which is accumulated in the cavity space 142 above the food storage space 141. The electric driving unit 151 can be controlled to drive the transmission 160 to reciprocate, so as to compress and stretch the flexible chamber 171. When the eccentric 161 is in a position close to the flexible chamber 171, the flexible chamber 171 is compressed, the chamber volume is reduced, the pressure of the air inside the chamber is greater than the pressure outside the chamber, forcing the air out through the air outlet passage and the valve outlet. When the eccentric 161 is in a position away from the flexible cavity 171, the flexible cavity 171 is stretched, the cavity volume is increased instantaneously, the air pressure inside the cavity is small, and the air with the external large pressure enters the flexible cavity 171 through the valve air inlet 181 and the air inlet passage 184. The compression and extension of the flexible chamber 171 is accomplished in a cycle of motion, such that there is a continuous flow of gas out of the valve outlet 182 into the chamber volume 142. Generally, the temperature difference between the delivered gas and the foam in the chamber space 142 exists, so that the delivered gas can liquefy and shrink the steam in the foam to be broken after entering the chamber space 142 and contacting the foam accumulated in the chamber space 142, thereby preventing the overflow. The overflow can be avoided even under the condition of fast cooking with large fire.

As shown in fig. 1, 3 and 9, the cover body 120 is further provided with a steam valve assembly 190, the steam valve assembly 190 includes a steam passage 191 communicating the cooking space with the outside of the cooking appliance, a steam inlet 192 and a steam outlet 193, and the steam outlet 193 may be provided on the decorative cover of the cover body 120 for discharging steam. The steam inlet 192 communicates with the cavity space 142. The steam inlet 192 may be provided on the inner lid 123.

As described above, the gas supplied from the automatic gas exchange device 150 can liquefy and contract the vapor in the foam accumulated in the chamber space 142 and break the vapor after entering the chamber space 142. The transferred gas can be discharged to the outside together with or in the form of steam through the steam inlet 192, the steam channel 191 and the steam outlet 193 after striking the bubbles, taking away a part of heat, so that the generation of bubbles can be suppressed, and the pressure can be lowered to further prevent overflowing.

In a preferred embodiment, as shown in FIG. 9, the vapor outlet 193 is disposed around the lid air inlet 121. I.e., the steam outlet 193 is disposed around the lid air inlet 121. During the operation of the cooking appliance 100, when the food in the food storage space 141 is in the boiling stage, a large amount of steam is generated in the cavity space 142, and the steam is discharged through the steam inlet 192, the steam channel 191 and the steam outlet 193. At the same time, the automatic gas exchange device 150 also starts to operate to suck gas from the cap gas inlet 121 and to transfer the sucked gas into the chamber space 142 through the cap gas outlet 152, as described above. Because the steam outlet 193 is disposed around the cover inlet 121, the steam discharged through the steam outlet 193 forms a circumferentially continuous or closed steam curtain around and above the cover inlet 121 to filter the air sucked into the cover inlet 121, thereby preventing impurities such as oil smoke and dust from being sucked into the cover inlet 121, avoiding oil stains or dirt from remaining in the gas pipeline and even blocking the gas pipeline, and also avoiding affecting the taste of food.

Specifically, in one embodiment of the present invention, as shown in fig. 9, the steam outlet 193 is disposed around the cap air inlet 121. The steam outlet 193 includes a plurality of (e.g., 2, 3, or more) sub-steam outlets arranged at intervals in a circumferential direction thereof. The plurality of sub-steam outlets may or may not be equally spaced. The sub-vapor outlets may be in any suitable shape, such as arc, circle, rectangle, etc. The plurality of sub-steam outlets may be identical in shape or different in shape.

In a further embodiment of the invention, which is not shown, the steam outlet 193 is designed as a circumferentially closed ring which surrounds the cover air inlet 121. It should be noted that the term "annular" as used herein refers to any suitable shape that is closed or end-to-end in the circumferential direction and is hollow, and the outer contour may be any suitable shape such as circular, rectangular, pentagonal, hexagonal, etc.

Preferably, the cap body 120 further includes a stopper member (not shown). The stopper member covers a first end of the intake pipe, i.e., an end communicating with the cover intake port 121, and forms an intake gap with the first end of the intake pipe. On the one hand, the backstop component can cover the first end of air inlet pipe way, has avoided the first end of air inlet pipe way to expose outside, and other debris (such as water, cockroach etc.) can not get into the air inlet pipe way like this, have avoided the air inlet pipe way to block up, can not influence and carry external gas to the cavity space at the culinary art in-process. On the other hand, an intake gap is formed between the stopper member and the first end of the intake pipe, so that the intake pipe can communicate with the cap intake port 121, and the external air can enter the intake pipe through the cap intake port 121. The stop member may be configured, for example, as a decorative cover that covers the first end of the intake conduit at the outer surface of the cover 120. Specifically, in one embodiment of the present invention, the stop member comprises a steam valve trim cover located on an outer surface of steam valve assembly 190. A steam valve trim cover covers a first end of the air intake duct, i.e., the end communicating with the cover air intake 121.

Since the steam outlet 193 is disposed around the lid air inlet 121, the steam from the steam outlet 193 easily forms a small amount of condensed water around the lid air inlet 121. Preferably, the cover 120 may further include a waterproof member to prevent liquid from flowing into the cover inlet port 121.

In one embodiment of the present invention, the waterproofing member may be configured as a boss located between the cover air inlet 121 and the steam outlet 193. The boss is spaced apart from the vapor outlet 193. Preferably, the boss is higher than the steam outlet 193. In this way, the bosses are blocked between the steam outlets 193 and the cover inlet 121, and since the bosses are higher than the steam outlets 193, the condensate does not pass over the bosses into the cover inlet 121 under the force of gravity.

When the cover body according to the above-mentioned scheme is used in a cooking appliance, since the steam outlet 193 is arranged around the cover air inlet, the steam discharged through the steam outlet 193 forms a circumferentially continuous or closed steam curtain around and above the cover air inlet 121 to filter the air sucked into the cover air inlet 121, thereby preventing impurities such as oil smoke, dust and the like from being sucked into the cover air inlet 121, avoiding oil stains or even blocking from remaining in the air pipeline, and also avoiding affecting the taste of food.

In order to further reduce the noise of the automatic gas exchange device 150 during operation, as shown in fig. 10, a damping sleeve 199 is further sleeved outside the automatic gas exchange device 150, and the damping sleeve 199 may be made of a flexible material such as silicone rubber, and the like.

Unless defined otherwise, technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. Terms such as "part," "member," and the like, when used herein, can refer to either a single part or a combination of parts. Terms such as "mounted," "disposed," and the like, as used herein, may refer to one component as being directly attached to another component or one component as being attached to another component through intervening components. Features described herein in one embodiment may be applied to another embodiment, either alone or in combination with other features, unless the feature is otherwise inapplicable or otherwise stated in the other embodiment.

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 (15)

1. A cooking appliance, comprising:

a cover (120);

the cooker body (110), the cover body (120) is arranged on the cooker body (110), and when the cover body (120) covers the cooker body (110), a cooking space is formed between the cover body (120) and the cooker body (110); and

an automatic gas exchange device (150), the automatic gas exchange device (150) disposed in the lid (120) or the pot body, comprising:

an electric drive unit (151);

-a transmission (160) connected to said electric drive unit (151) so as to be driven by the latter in a reciprocating motion;

an air flow generating device (170) connected to the actuator (160), the air flow generating device (170) having a flexible chamber (171), the flexible chamber (171) being switchable between a squeezed state and a restored state under the reciprocating action of the actuator (160), a side wall of the flexible chamber (171) being configured as a corrugated structure having a first end wall adjacent to the actuator;

an air inlet and outlet valve device (180), the air inlet and outlet valve device (180) being connected to the flexible chamber (171), the air inlet and outlet valve device (180) having a valve air inlet (181) and a valve air outlet (182), the valve air inlet (181) being in communication with the outside atmosphere and the valve air outlet (182) being in communication with the cooking space,

wherein the wall thickness h2 of the first end wall of the corrugated structure is greater than the wall thickness h1 of the rest of the main body part of the corrugated structure, and h2-h1 are more than or equal to 1.2 mm.

2. The cooking appliance according to claim 1, wherein the wall thickness h1 of the main body portion of the corrugated structure satisfies: h1 is more than or equal to 0.2mm and less than or equal to 1.2 mm.

3. The cooking appliance of claim 1, wherein the corrugated structure includes n wave peak configurations, wherein 2 ≦ n ≦ 8.

4. The cooking appliance according to claim 1, wherein the width L1 of the individual wave troughs in the corrugated structure in the axial direction of the flexible chamber (171) satisfies: l1 is more than or equal to 1mm and less than or equal to 2mm, and/or the minimum distance L2 between two adjacent wave crests satisfies 3mm and less than or equal to L2 and less than or equal to 4 mm.

5. The cooking appliance according to claim 1, wherein the cover (120) is provided with a steam channel (191) communicating the cooking space with the outside of the cooking appliance, the steam channel (191) communicating with the outside of the cooking appliance (100) through a steam outlet (193) provided on the cover (120);

the lid body (120) is further provided with a lid inlet port (121), the lid inlet port (121) communicates with the valve inlet port (181), and the position of the steam outlet (193) on the lid body (120) is located on the outer peripheral side of the lid inlet port (121).

6. The cooking appliance according to claim 5, wherein the steam outlet (193) is annular; or the steam outlet (193) comprises a plurality of sub-steam outlets spaced around the lid air inlet (121).

7. The cooking appliance according to claim 5, wherein the lid air inlet (121) communicates with the valve air inlet (181) through an air inlet duct, the lid air inlet (121) being provided at a first end of the air inlet duct, the cooking appliance further comprising a stop member covering the first end of the air inlet duct and forming an air inlet gap with the first end of the air inlet duct.

8. The cooking appliance according to claim 5, further comprising a water-proof structure disposed at least partially between the steam outlet (193) and the lid air inlet (121) to prevent liquid from entering the lid air inlet (121).

9. The cooking appliance of claim 8, wherein said water-resistant structure is a boss, said boss being higher than said steam outlet.

10. The cooking appliance according to claim 1, wherein the transmission means (160) comprises an eccentric (161) and an eccentric connecting rod (162) connected to the eccentric (161), the eccentric (161) being connected to the electric drive unit (151), the electric drive unit (151) being capable of driving the eccentric (161) and the eccentric connecting rod (162) in rotation, the eccentric connecting rod (162) being connected to the air flow generating means (170).

11. The cooking appliance according to claim 10, wherein the air flow generating device (170) comprises a closed end (172) and an air guide end (173) at each end of the flexible chamber (171), the closed end being connected to the first end wall, the eccentric link (162) being connected to the closed end (172), and the air inlet and outlet valve device (180) being connected to the air guide end (173).

12. The cooking appliance according to claim 1, wherein the air inlet and outlet valve device (180) comprises a first check valve (178), a second check valve (179) and a check valve film (183) disposed between the first check valve (178) and the second check valve (179), the valve air inlet (181) and the valve air outlet (182) are respectively disposed on the second check valve (179), an air inlet channel (184) and an air outlet channel (185) corresponding to the valve air inlet (181) and the valve air outlet (182) respectively are disposed on the first check valve (178), and the check valve film (183) comprises two flexible diaphragms corresponding to the valve air inlet (181) and the valve air outlet (182) respectively, and the flexible diaphragms are capable of elastically deforming along with the air flow direction.

13. The cooking appliance according to claim 12, wherein the flexible membrane is connected to the one-way valve membrane (183) by a connecting rib, and a through port is provided between the flexible membrane and the one-way valve membrane (183).

14. The cooking appliance according to claim 12, wherein the first one-way valve (178) is provided with a first retaining ring (188) at a position corresponding to the valve outlet (182), and the second one-way valve (179) is provided with a second retaining ring (189) at a position corresponding to the valve inlet (181), the first retaining ring (188) and the second retaining ring (189) respectively projecting toward and abutting against the corresponding flexible membrane.

15. The cooking appliance of claim 1, wherein the automatic gas exchange device (150) is generally horizontally recumbent in the lid (120).

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