CN212394626U - Camera control assembly and electric cooker - Google Patents

Abstract

The present disclosure relates to a camera control assembly and an electric rice cooker. This camera control assembly includes the camera and shelters from the module. The shielding module is matched with the camera and used for moving from an original position to a preset position when the camera is confirmed to enter a working state, so that shielding does not exist in front of the camera; when the camera is confirmed to return to the non-working state, the camera returns to the original position from the preset position, and the camera is isolated from the external environment; the camera is arranged on the inner side of the upper cover of the electric cooker and is used for shooting pictures of food to be cooked placed in the inner container of the electric cooker when the working state is confirmed. The technical scheme that this disclosed embodiment provided shelters from the module through setting up for this camera only just shoots when operating condition, keeps apart with external environment completely when non-operating condition, has avoided the vapor that the culinary art in-process after shooting produced the food to cause the influence to the camera, has improved the life of camera, and user experience preferred.

Description

Camera control assembly and electric cooker

Technical Field

The disclosure relates to the technical field of terminal control, in particular to a camera control assembly and an electric cooker.

Background

Along with the continuous improvement of the living standard of people, the intelligent kitchen ware becomes a necessary product in the life of people, and the use frequency is higher and higher.

In the correlation technique, the intelligent electric cooker can adopt the camera to shoot the photo of waiting to cook the edible material and preserve to the user carries out the contrast after cooking.

However, the food material may generate water vapor during the cooking process, and the water vapor may condense on the lens of the camera, thereby affecting the shooting effect of the camera and causing poor user experience.

SUMMERY OF THE UTILITY MODEL

To overcome the problems in the related art, embodiments of the present disclosure provide a camera control assembly and an electric rice cooker. The technical scheme is as follows:

according to a first aspect of the embodiments of the present disclosure, a camera control assembly is provided, which includes a camera and a shielding module;

the shielding module is matched with the camera and used for moving from an original position to a preset position when the camera is confirmed to enter a working state, so that shielding does not exist in front of the camera; when the camera is confirmed to return to the original position from the preset position when the camera is confirmed to return to the non-working state, the camera is isolated from the external environment;

the camera is arranged on the inner side of the upper cover of the electric cooker and is used for shooting a picture of food to be cooked placed in the inner container of the electric cooker when the working state is confirmed.

The technical scheme provided by the embodiment of the disclosure can have the following beneficial effects: the shielding module is arranged, so that the camera can only be shot when in a working state, the camera is completely isolated from the external environment when in a non-working state, the influence of steam generated by food materials in the cooking process after shooting on the camera is avoided, the service life of the camera is prolonged, and the user experience is better.

In one embodiment, the camera control assembly comprises a processing device connected with the shielding module and the camera respectively;

the processing device is used for sending a moving signal to the shielding module and sending an opening signal to the camera after confirming that the upper cover and the base of the electric cooker are closed;

the shielding module is used for confirming that the camera enters a working state according to the moving signal;

the camera is used for confirming that the food to be cooked is in a working state according to the starting signal and sending the picture to the processing device after the food to be cooked is shot.

In one embodiment, the processing device is configured to send a return signal to the occlusion module after receiving the picture;

the shielding module is used for confirming that the camera recovers the non-working state according to the return signal.

In one embodiment, the shielding module comprises an electromagnetic valve and a shielding sheet;

the shielding piece is arranged in front of the camera and is connected with the ejector rod of the electromagnetic valve;

the electromagnetic valve is connected with the processing device and used for driving the shielding piece to move from the original position to the preset position when the moving signal sent by the processing device is received; and when the return signal sent by the processing device is received, the shielding sheet is driven to move from the preset position to the original position.

In one embodiment, the shielding module further comprises a micro switch connected with the processing device;

the micro switch is fixed at a position which can be triggered when the shielding piece moves to the preset position, and is used for sending a confirmation signal to the processing device when the shielding piece is determined to be triggered, so that the processing device can conveniently send the opening signal to the camera head after confirming that the upper cover and the base of the electric cooker are closed and receiving the confirmation signal.

In one embodiment, the shielding module further comprises a camera fixing bracket;

the camera fixing support is used for fixing the camera, so that the shooting angle of the camera is fixed at a preset angle.

In one embodiment, the camera control assembly further comprises a proximity detection module connected to the processing device;

the approach detection module is used for detecting whether the upper cover and the base of the electric cooker are closed or not and sending a detection result to the processing device.

In one embodiment, the proximity detection module comprises a hall switch arranged on the upper cover and an induction magnet arranged on the base.

According to a second aspect of the embodiments of the present disclosure, there is provided an electric cooker including the camera control assembly according to any one of the embodiments of the first aspect.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the disclosure.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the present disclosure and together with the description, serve to explain the principles of the disclosure.

Fig. 1 is a schematic structural diagram of a camera control assembly according to an exemplary embodiment.

FIG. 2 is an operational schematic diagram of a camera control assembly shown in accordance with an exemplary embodiment.

FIG. 3 is an operational schematic diagram of a camera control assembly shown in accordance with an exemplary embodiment.

Fig. 4 is a schematic structural diagram of a camera control assembly according to an exemplary embodiment.

Fig. 5 is a flow chart illustrating a cooking method according to an exemplary embodiment.

Fig. 6 is a flow chart illustrating a cooking method according to an exemplary embodiment.

Fig. 7 is a block diagram illustrating a structure of a cooking apparatus according to an exemplary embodiment.

Fig. 8 is a block diagram illustrating a structure of a cooking apparatus according to an exemplary embodiment.

Fig. 9 is a block diagram illustrating a structure of a cooking apparatus according to an exemplary embodiment.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The implementations described in the exemplary embodiments below are not intended to represent all implementations consistent with the present disclosure. Rather, they are merely examples of apparatus and methods consistent with certain aspects of the present disclosure, as detailed in the appended claims.

The embodiment of the present disclosure provides a camera control assembly, as shown in fig. 1, the camera control assembly includes a camera 101 and a shielding module 102;

the shielding module 102 is arranged in cooperation with the camera 101 and is used for moving from an original position to a preset position when the camera 101 is confirmed to enter a working state, so that shielding does not exist in front of the camera 101; and when the camera 101 is confirmed to return to the non-working state, the camera 101 returns to the original position from the preset position, so that the camera 101 is isolated from the external environment.

The camera 101 is arranged inside the upper cover 10a of the rice cooker and is used for shooting a picture of the food to be cooked placed in the inner container of the rice cooker when the rice cooker is confirmed to be in the working state.

For example, when the shielding module 102 is in the original position, the camera 101 is completely isolated from the external environment, similar to being in a sealed state, and the influence of external water vapor on the camera 101 is isolated, for example, the water vapor is prevented from condensing on the lens to affect the shooting effect, or the water vapor is prevented from entering the inside of the lens to affect the service life of the camera 101, and the like.

When sheltering from module 102 and being in preset position, there is not sheltering from in front of the camera 101's the camera lens, does not have the shelter between camera 101 and the food material of waiting to cook that waits to shoot promptly, and this moment camera 101 can shoot this photo of waiting to cook the food material.

In the technical scheme that this disclosed embodiment provided, shelter from module 102 through setting up for this camera 101 only just shoots when operating condition, keeps apart with external environment completely when non-operating condition, has avoided the vapor that the culinary art in-process food produced after shooting to cause the influence to camera 101, has improved camera 101's life, and user experience preferred.

In one embodiment, the camera control assembly further comprises a processing device connected to the occlusion module 102 and the camera 101, respectively.

Wherein, the processing device is used for sending a moving signal to the shielding module 102 and sending an opening signal to the camera 101 after confirming that the upper cover 10a and the base 10b of the electric cooker are closed.

The shielding module 102 is configured to confirm that the camera 101 enters the working state according to the moving signal.

The camera 101 is configured to confirm that the cooking appliance is in the operating state according to the turn-on signal, and send the picture to the processing device after shooting the food to be cooked.

For example, when a user uses an electric rice cooker, the upper cover 10a and the base 10b of the electric rice cooker can be closed after food to be cooked is placed in the inner container of the electric rice cooker. At this time, the processing device can confirm that the upper cover 10a and the base 10b of the electric cooker are closed, and respectively send a moving signal and an opening signal to the shielding module 102 and the camera 101. Alternatively, the user may then select a cooking mode for the material to be cooked after closing the upper lid 10a and the base 10b of the rice cooker. The processing device can also determine whether the user selects the cooking mode after detecting that the upper cover 10a and the base 10b of the electric cooker are closed, and respectively send a moving signal and an opening signal to the shielding module 102 and the camera 101 after confirming that the user selects the cooking mode.

After receiving the moving signal, the shielding module 102 can confirm that the camera 101 enters a working state, and at this time, the camera 101 can move from an original position to a preset position, so that the camera 101 can shoot a picture of the food material to be cooked conveniently.

After receiving the start signal, the camera 101 may be powered on to enter a working state, and then take a picture of the food material to be cooked, and send the taken picture to the processing device.

In one embodiment, the processing device may send a return signal to the occlusion module 102 after receiving the photograph.

After receiving the return signal, the shielding module 102 may determine that the camera 101 is restored to the non-operating state, and at this time, may return to the original position from the preset position, thereby implementing isolation between the camera 101 and the external environment.

Optionally, after receiving the picture, the processing device may also send a close signal to the camera 101. After receiving the shutdown signal, the camera 101 confirms to return to the non-operating state, and at this time, the power can be cut off to enter the standby state, so that the power consumption of the camera 101 is reduced.

For example, after sending the return signal to the blocking module 102, the processing device may instruct the electric cooker to start cooking according to the cooking mode selected by the user. Alternatively, the processing device may instruct the electric cooker to start cooking according to the cooking mode selected by the user after confirming that the shielding module 102 returns to the original position and the camera 101 enters the standby state.

In one embodiment, as shown in FIG. 2, the shade module 102 includes a solenoid valve 1021 and a shade tab 1022.

The shutter 1022 is provided in front of the camera 101 and connected to the plunger of the solenoid valve 1021.

The electromagnetic valve 1021 is connected with a processing device (not shown in fig. 2) and is used for driving the shielding piece 1022 to move from the original position to the preset position when receiving a moving signal sent by the processing device; when receiving a return signal sent by the processing device, the blocking piece 1022 is driven to move from the preset position to the original position.

For example, fig. 2 is a schematic view of the shielding piece 1022 in the original position, where the shielding piece 1022 isolates the camera 101 from the external environment, so as to prevent water vapor in the external environment from affecting the camera 101.

After the solenoid valve 1021 receives the moving signal sent by the processing device, as shown in fig. 3, fig. 3 is an enlarged view of the shielding module 102. As shown in fig. 3, after the solenoid valve 1021 receives the moving signal, the plunger 1021a moves upward to drive the shielding piece 1022 to move upward, so that the shielding piece 1022 moves from the original position to the predetermined position.

When the solenoid valve 1021 receives the return signal, the plunger 1021a moves downward to drive the shutter 1022 to move downward, so that the shutter 1022 returns to the original position from the predetermined position.

In one embodiment, as shown in FIG. 2, the shutter module 102 further comprises a micro-switch 1023 connected to the processing device.

The micro switch 1023 is fixed at a position that can be triggered when the shielding piece 1022 moves to a preset position, and is used for sending a confirmation signal to the processing device when the triggering is confirmed, so that the processing device can send an opening signal to the camera 101 after confirming that the upper cover 10a and the base 10b of the electric cooker are closed and receiving the confirmation signal.

Referring to fig. 3, when the plunger 1021a of the solenoid valve 1021 moves upward to a maximum displacement, the shielding piece 1022 moves from a home position to a predetermined position, and the shielding piece 1022 triggers the micro switch 1023, that is, the micro switch 1023 is fixed at a position corresponding to the maximum displacement of the plunger 1021 a. When the microswitch 1023 is triggered, an acknowledgement signal can be sent to the processing means.

When the closing of the upper cover 10a and the base 10b of the rice cooker is confirmed, the processing device can monitor whether the confirmation signal sent by the micro switch 1023 is received in real time. If so, it indicates that the shielding piece 1022 has moved from the original position to the preset position, and at this time, the processing device can send an opening signal to the camera 101, so that the camera 101 can conveniently take a picture of the food to be cooked; if not, it indicates that the shielding piece 1022 has not moved to the preset position, and at this time, the processing device may continue to monitor, and when the confirmation signal is not received for a long time, a prompt signal may be sent out, so that the user can check whether a fault occurs in time.

When the processing device receives the photo sent by the camera 101, it can send a return signal to the electromagnetic valve 1021, at this time, the plunger 1021a of the electromagnetic valve 1021 moves downward to drive the shielding piece 1022 to move downward, and at this time, the micro switch 1023 resets, so as to be triggered next time.

In one embodiment, referring to FIG. 2, the blocking module 102 further comprises a camera fixing bracket 1024.

The camera fixing bracket 1024 is used to fix the camera 101 so that the shooting angle of the camera 101 is fixed at a preset angle.

In an example, an included angle exists between the shooting angle of the camera 101 and the horizontal angle, and the included angle can be adjusted according to the shape of the inner container and the shape of the electric cooker, so that the camera can shoot the food to be cooked as a limit, and a scale capable of completely shooting the identification of the inner container of the electric cooker is preferred.

In order to avoid the situation that the shooting angle changes due to the fact that the camera 101 shakes or rotates in the using process, a camera fixing support 1024 can be arranged on the back face of the camera, one face of the camera fixing support 1024 is fixed with the upper cover 10a of the electric cooker, and the other face of the camera fixing support 1024 is fixed with the camera 101, so that the shooting angle of the camera 101 is enabled to be coincident with a preset angle.

In one embodiment, the camera control assembly further includes a proximity detection module 104 coupled to the processing device.

The proximity detection module 104 is used for detecting whether the upper cover 10a and the base 10b of the rice cooker are closed or not, and sending a detection result to the processing device. Optionally, as shown in fig. 4, the proximity detection module 104 includes a hall switch 1041 disposed on the top cover 10a and an induction magnet 1042 disposed on the base 10 b.

For example, after the user closes the upper cover 10a and the base 10b of the electric cooker, the distance between the hall switch 1041 of the upper cover 10a and the induction magnet 1042 of the base 10b is small, so that the hall switch 1041 can induce the induction magnet 1042, and at this time, the hall switch 1041 can send a closing confirmation signal to the processing device. After receiving the closing confirmation signal, the processing device can confirm that the upper cover 10a and the base 10b of the electric cooker are closed.

The embodiment of the present disclosure provides a camera control assembly applied to an electric cooker, which includes a shielding module 102 and a camera 101, the shielding module 102 is arranged, so that the camera 101 only shoots when in a working state, the camera is completely isolated from an external environment when in a non-working state, the influence of vapor generated by food materials in a cooking process after shooting on the camera 101 is avoided, the service life of the camera 101 is prolonged, and the user experience is better.

The embodiment of the disclosure provides an electric cooker which comprises the camera control assembly in any one of the embodiments.

The electric cooker comprises an upper cover 10a and a base 10b, and the camera control assembly comprises a camera 101 arranged on the upper cover 10a of the electric cooker and a shielding module 102 matched with the camera 101.

The shielding module 102 is arranged in cooperation with the camera 101 and is used for moving from an original position to a preset position when the camera 101 is confirmed to enter a working state, so that shielding does not exist in front of the camera 101; and when the camera 101 is confirmed to return to the non-working state, the camera 101 returns to the original position from the preset position, so that the camera 101 is isolated from the external environment.

The camera 101 is arranged inside the upper cover 10a of the rice cooker and is used for shooting a picture of the food to be cooked placed in the inner container of the rice cooker when the rice cooker is confirmed to be in the working state.

The embodiment of the disclosure provides an electric cooker with a camera 101, which is provided with a shielding module 102 through setting, so that the camera 101 is only shot in a working state, and is completely isolated from an external environment in a non-working state, thereby avoiding the influence of water vapor generated by food materials on the camera 101 in a cooking process after shooting, prolonging the service life of the camera 101 and ensuring better user experience.

The embodiment of the present disclosure provides a cooking method, as shown in fig. 5, the cooking method includes steps 501 to 503:

in step 501, after confirming a target cooking mode of a food material to be cooked, a photo of the food material to be cooked is obtained, wherein the food material to be cooked comprises at least two food materials.

In step 502, it is determined whether the food material ratio of the at least two food materials meets the preset standard of the target cooking mode according to the photo of the food material to be cooked.

In step 503, if the ratio of the at least two food materials meets the preset standard, the food material to be cooked is cooked according to the target cooking mode.

For example, after the food to be cooked is placed in the inner container of the electric rice cooker, the user closes the upper cover and the base of the electric rice cooker and selects a target cooking mode of the food to be cooked on an operation interface of the electric rice cooker.

After confirming the target cooking mode of the food to be cooked, the electric cooker can indicate the shielding module arranged on the electric cooker to move to a preset position from an original position and indicate the camera arranged on the electric cooker to shoot a picture of the food to be cooked.

After the photo of the food material to be cooked is obtained, the electric rice cooker can determine the food material proportion of at least two food materials included in the food material to be cooked according to the identification of each food material in the photo. For example, if a user needs to cook congee, the food to be cooked includes two kinds of food, namely water and rice, and the electric cooker can recognize the proportion of water and rice in the photo according to the photo of the food to be cooked, for example, recognize the positions of the scales arranged on the inner containers respectively corresponding to water and rice to determine the proportion of water and rice.

The electric rice cooker can determine whether the ratio meets a preset standard corresponding to the porridge cooking mode. Specifically, the electric rice cooker may pre-store preset standards of food material ratios corresponding to different cooking modes, for example, the preset standard corresponding to the porridge cooking mode is that the water-rice ratio is greater than or equal to H1 and less than or equal to H2; the preset standard corresponding to the rice steaming function is that the water-rice ratio is greater than or equal to H3 and less than or equal to H4.

If the porridge cooking mode selected by the user is confirmed, and the ratio of water to rice placed in the inner container is cut to be H according to the obtained picture of the food to be cooked, the electric cooker can judge whether the H is within the range of being more than or equal to H1 and less than or equal to H2. If so, the proportion of the food materials to be cooked in the inner container meets the preset standard, and the electric cooker can cook the food materials to be cooked according to the porridge cooking mode.

Alternatively, if it is confirmed that the user selects the rice steaming mode and the ratio of water to rice placed in the inner pot is cut off as H according to the obtained photograph of the food to be cooked, the rice cooker may determine whether H is within a range of H3 or more and H4 or less. If so, the proportion of the food materials to be cooked in the inner container meets the preset standard, and the electric cooker can cook the food materials to be cooked according to the porridge cooking mode.

In one embodiment, the method further comprises step 504:

in step 504, if the ratio of the at least two food materials does not satisfy the preset standard, a prompt message is displayed so that the user can adjust the ratio of the at least two food materials.

For example, if it is determined that the porridge cooking mode is selected by the user, and the rice cooker determines that the ratio H of water to rice is smaller than H1 or larger than H2, it indicates that the ratio of the food materials to be cooked placed in the inner container does not meet the preset standard, and at this time, the rice cooker may display a prompt message on the operation interface so that the user can adjust the ratio of the food materials of the water to rice. Or the electric cooker can push the prompt information like a terminal so as to be convenient for looking up the prompt information through the terminal and timely adjusting the food material proportion of the rice and water.

Or, if the rice steaming mode selected by the user is confirmed, and the electric cooker determines that the ratio H of water to rice is smaller than H3 or larger than H4, it indicates that the ratio of the food materials to be cooked placed in the inner container does not meet the preset standard, and at this time, the electric cooker can display prompt information on an operation interface so that the user can adjust the ratio of the food materials of water to rice. Or the electric cooker can push the prompt information like a terminal so as to be convenient for looking up the prompt information through the terminal and timely adjusting the food material proportion of the rice and water.

In an embodiment, as shown in fig. 6, step 503, namely, if the ratio of the at least two food materials meets the preset criterion, the step of cooking the food material to be cooked according to the target cooking mode can be implemented by steps 5031 and 5032:

in step 5031, if the food material ratio of the at least two food materials meets the predetermined criterion, adjusting the cooking parameter of the target cooking mode according to the food material ratio, wherein the cooking parameter includes at least one of a heating temperature, a heating time, and a cooking sequence.

In step 5032, the food material to be cooked is cooked according to the adjusted cooking parameters.

For example, even if the food material ratio is within the preset standard, the final taste of the food may be affected by the difference of the specific values, and in order to achieve the perfect taste as much as possible, the electric rice cooker may adjust the cooking parameters of the target cooking mode according to the specific values of the food material ratio. Taking the porridge cooking mode as an example, if the ratio H of the water to the rice is larger, which indicates that more water is available, the cooking sequence in the target cooking mode can be adjusted to firstly soak for half an hour, and then the target cooking mode enters a heating state, and the heating temperature is set to be higher, and the heating time is set to be longer; if the ratio H of water to rice is small, indicating that there is less water, the cooking sequence in the target cooking mode may be adjusted to enter the heating state directly, and the heating temperature may be set to a lower temperature and the heating time may be set to a shorter time.

The embodiment of the disclosure provides a cooking method, which includes determining a food material ratio of at least two food materials included in a food material to be cooked through an obtained photo of the food material to be cooked, and reasonably adjusting cooking parameters according to the food material ratio, so that the intelligence of an electric cooker is improved, and the user experience is better.

The embodiment of the present disclosure provides a cooking apparatus 60, as shown in fig. 7, the cooking apparatus 60 includes an obtaining module 601, a determining module 602, and a cooking module 603.

The obtaining module 601 is configured to obtain a photo of a food material to be cooked after a target cooking mode of the food material to be cooked is confirmed, where the food material to be cooked includes at least two food materials.

A determining module 602, configured to determine whether a food material ratio of the at least two food materials meets a preset standard of the target cooking mode according to the photo of the food material to be cooked.

And a cooking module 603, configured to cook the food material to be cooked according to the target cooking mode if the food material ratio of the at least two food materials meets the preset standard.

In one embodiment, as shown in FIG. 8, the apparatus 60 further comprises a display module 604.

The display module 604 is configured to display a prompt message if the food material ratio of the at least two food materials does not meet a preset standard, so that a user can adjust the food material ratio of the at least two food materials.

In one embodiment, as shown in fig. 9, the cooking module 603 includes an adjustment sub-module 6031 and a cooking sub-module 6032.

The adjusting submodule 6031 is configured to, if the food material ratio of the at least two food materials meets the preset standard, adjust a cooking parameter of the target cooking mode according to the food material ratio, where the cooking parameter includes at least one of a heating temperature, a heating time, and a cooking sequence.

And a cooking sub-module 6032 for cooking the food material to be cooked according to the adjusted cooking parameters.

The embodiment of the disclosure provides a cooking device, which determines the food material proportion of at least two food materials contained in the food material to be cooked through an acquired photo of the food material to be cooked, and reasonably adjusts cooking parameters according to the food material proportion, so that the intelligence of an electric cooker is improved, and the user experience is better.

The disclosed embodiment provides a cooking apparatus, which includes:

a processor;

a memory for storing processor-executable instructions;

wherein the processor is configured to:

after confirming a target cooking mode of food materials to be cooked, acquiring photos of the food materials to be cooked, wherein the food materials to be cooked comprise at least two food materials;

determining whether the food material proportion of the at least two food materials meets the preset standard of the target cooking mode according to the photo of the food material to be cooked;

and if the food material proportion of the at least two food materials meets the preset standard, cooking the food material to be cooked according to the target cooking mode.

In one embodiment, the processor is configured to: and if the food material proportion of the at least two food materials does not meet the preset standard, displaying prompt information so that a user can conveniently adjust the food material proportion of the at least two food materials.

In one embodiment, the processor is configured to: if the food material proportion of the at least two food materials meets the preset standard, adjusting the cooking parameters of the target cooking mode according to the food material proportion, wherein the cooking parameters comprise at least one of heating temperature, heating time and cooking sequence;

and cooking the food material to be cooked according to the adjusted cooking parameters.

The disclosed embodiments provide a non-transitory computer-readable storage medium, wherein when instructions in the storage medium are executed by a processing device of an electric rice cooker, the electric rice cooker is enabled to execute the above cooking method, and the method comprises:

after confirming a target cooking mode of food materials to be cooked, acquiring photos of the food materials to be cooked, wherein the food materials to be cooked comprise at least two food materials;

determining whether the food material proportion of the at least two food materials meets the preset standard of the target cooking mode according to the photo of the food material to be cooked;

and if the food material proportion of the at least two food materials meets the preset standard, cooking the food material to be cooked according to the target cooking mode.

In one embodiment, the method further comprises:

and if the food material proportion of the at least two food materials does not meet the preset standard, displaying prompt information so that a user can conveniently adjust the food material proportion of the at least two food materials.

In an embodiment, if the food material ratio of the at least two food materials meets the preset criterion, the cooking the food material to be cooked according to the target cooking mode includes:

if the food material proportion of the at least two food materials meets the preset standard, adjusting the cooking parameters of the target cooking mode according to the food material proportion, wherein the cooking parameters comprise at least one of heating temperature, heating time and cooking sequence; and cooking the food material to be cooked according to the adjusted cooking parameters.

Other embodiments of the disclosure will be apparent to those skilled in the art from consideration of the specification and practice of the disclosure disclosed herein. This application is intended to cover any variations, uses, or adaptations of the disclosure following, in general, the principles of the disclosure and including such departures from the present disclosure as come within known or customary practice within the art to which the disclosure pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the disclosure being indicated by the following claims.

It will be understood that the present disclosure is not limited to the precise arrangements described above and shown in the drawings and that various modifications and changes may be made without departing from the scope thereof. The scope of the present disclosure is limited only by the appended claims.

Claims (9)

1. The camera control assembly is characterized by comprising a camera and a shielding module;

the shielding module is matched with the camera and used for moving from an original position to a preset position when the camera is confirmed to enter a working state, so that shielding does not exist in front of the camera; when the camera is confirmed to return to the original position from the preset position when the camera is confirmed to return to the non-working state, the camera is isolated from the external environment;

the camera is arranged on the inner side of the upper cover of the electric cooker and is used for shooting a picture of food to be cooked placed in the inner container of the electric cooker when the working state is confirmed.

2. The camera control assembly according to claim 1, comprising processing means connected to the mask module and the camera respectively;

the processing device is used for sending a moving signal to the shielding module and sending an opening signal to the camera after confirming that the upper cover and the base of the electric cooker are closed;

the shielding module is used for confirming that the camera enters a working state according to the moving signal;

the camera is used for confirming that the food to be cooked is in a working state according to the starting signal and sending the picture to the processing device after the food to be cooked is shot.

3. The camera control assembly of claim 2,

the processing device is used for sending a return signal to the shielding module after receiving the photo;

the shielding module is used for confirming that the camera recovers the non-working state according to the return signal.

4. The camera control assembly of claim 3, wherein the shutter module includes a solenoid valve and a shutter piece;

the shielding piece is arranged in front of the camera and is connected with the ejector rod of the electromagnetic valve;

the electromagnetic valve is connected with the processing device and used for driving the shielding piece to move from the original position to the preset position when the moving signal sent by the processing device is received; and when the return signal sent by the processing device is received, the shielding sheet is driven to move from the preset position to the original position.

5. The camera control assembly of claim 4, wherein the shutter module further comprises a micro switch connected to the processing device;

the micro switch is fixed at a position which can be triggered when the shielding piece moves to the preset position, and is used for sending a confirmation signal to the processing device when the shielding piece is determined to be triggered, so that the processing device can conveniently send the opening signal to the camera head after confirming that the upper cover and the base of the electric cooker are closed and receiving the confirmation signal.

6. The camera control assembly of claim 4 or 5, wherein the shutter module further comprises a camera fixing bracket;

the camera fixing support is used for fixing the camera, so that the shooting angle of the camera is fixed at a preset angle.

7. The camera control assembly of any one of claims 2 to 5, further comprising a proximity detection module connected to the processing device;

the approach detection module is used for detecting whether the upper cover and the base of the electric cooker are closed or not and sending a detection result to the processing device.

8. The camera control assembly of claim 7, wherein the proximity detection module comprises a hall switch disposed on the top cover and an induction magnet disposed on the base.

9. An electric rice cooker comprising the camera control assembly of any one of claims 1 to 8.

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