CN107788817B - Cooking utensil - Google Patents

Abstract

The invention discloses a cooking utensil, which comprises a cooker body, a cover body for covering the cooker body, a sensing module and a control module, wherein the sensing module is arranged on the cooker body and/or the cover body and is used for detecting whether an object exists in a preset range, and the sensing module comprises a transmitting unit for transmitting waves and a receiving unit array for receiving the waves reflected by the object; the surface of the pot body and/or the surface of the cover body are/is provided with a panel, the inner side surface of the panel is provided with a concave part formed by material digging, the sensing module is at least partially contained in the concave part, the cooking utensil further comprises a display module and/or a sound prompting module, and the control module processes signals from the sensing module and controls the display module to execute display action and/or the sound prompting module to execute prompting action. According to the cooking utensil provided by the invention, non-contact operation can be realized, better user experience is brought to a user, and the problem of energy waste in the prior art can be solved.

Description

Cooking utensil

Technical Field

The invention belongs to the field of household appliances, and particularly relates to a cooking appliance.

Background

Along with the continuous improvement of living standard, the energy-saving and environment-friendly consciousness of people is continuously enhanced, various household electrical appliances have certain requirements on energy consumption, and small household electrical appliances are no exception. When the existing cooking appliance is in cooking or standby, a user often does not operate or observe the cooking state, and in the process, a display module or an operation module of the cooking appliance is always in a lighting state, so that electric energy is continuously consumed, and energy waste is caused.

Accordingly, there is a need for a cooking appliance to at least partially solve the above-mentioned problems.

Disclosure of Invention

To at least partially solve the above technical problem, according to an aspect of the present invention, there is provided a cooking appliance, characterized by comprising:

a pot body;

the cover body is used for covering the cooker body;

the sensing module is arranged on the pot body and/or the cover body and used for detecting whether an object exists in a preset range or not, and comprises a transmitting unit used for transmitting waves and a receiving unit array used for receiving the waves reflected by the object;

the sensing module is electrically connected with the control module;

wherein, the surface of the pot body and/or the surface of the cover body is provided with a panel, the inner side surface of the panel is provided with a concave part formed by material excavation, the sensing module is at least partially contained in the concave part, the cooking utensil further comprises a display module and/or a sound prompt module, and the control module processes the signal from the sensing module and controls the display module to execute a display action and/or controls the sound prompt module to execute a prompt action.

The cooking utensil provided by the invention is provided with the sensing module comprising the transmitting unit and the receiving unit array and the control module connected with the sensing module, wherein the sensing module is arranged in the concave part of the panel, and the control module controls the cooking utensil through the signal sensed by the sensing module, so that non-contact operation can be realized, better user experience is brought to a user, and the problem of energy waste in the prior art can be solved.

Optionally, the panel includes a substrate and a transparent film layer covering an upper surface of the substrate, and the recess is formed by cutting out the substrate. Thus, the sensor module can be protected by removing the transparent film layer from the substrate.

Optionally, a distance between an upper surface of the sensor module and a lower surface of the transparent thin film protective layer is less than 0.4mm. This can make the detection effect better.

Optionally, the predetermined range is an area less than or equal to 80cm from the sensing module. Thus, it is possible to detect whether an object is present within 80cm, and not to detect a range exceeding the distance, so as to avoid misrecognition.

Optionally, the thickness of the transparent film protective layer is less than 0.7mm. Thus, the detection effect can be made better.

Optionally, the panel is an IMD panel.

Optionally, the upper surface of the area corresponding to the sensing module on the panel is provided with prompt characters or patterns. Therefore, the position of the sensing module can be reminded to the user so as to improve the use experience.

Optionally, the transmitting unit is an infrared LED tube for transmitting infrared light, and the receiving unit is a photoelectric tube array. Thus, an infrared LED tube may be used to emit infrared light and a photodiode array may be used to receive the reflected infrared light to sense whether an object is present within a predetermined range.

Optionally, the cooking appliance further includes a driving circuit for driving the infrared LED tube to emit infrared light, a signal processing circuit for processing the infrared signal received by the photoelectric tube array, and a signal output circuit for outputting the processed signal to the control module. Therefore, the control module can control the infrared LED tube to emit infrared light through the driving circuit, the signal processing circuit is used for processing infrared signals received by the photodiode, and the signal output circuit can convey the processed signals to the control module.

Optionally, the transmitting unit is an ultrasonic transmitter for transmitting ultrasonic waves, and the receiving unit is an ultrasonic receiver array. Thus, an ultrasonic transmitter may be used to transmit ultrasonic waves and an ultrasonic receiver array may be used to receive reflected ultrasonic waves to sense whether an object is present within a predetermined range.

Optionally, the cooking appliance further includes a driving circuit for driving the ultrasonic transmitter to transmit ultrasonic waves, a signal processing circuit for processing ultrasonic signals received by the ultrasonic receiver array, and a signal output circuit for outputting the processed signals to the control module. Therefore, the control module can control the ultrasonic transmitter to transmit ultrasonic waves through the driving circuit, the signal processing circuit is used for processing ultrasonic signals received by the ultrasonic receiver, and the signal output circuit can convey the processed signals to the control module.

Optionally, the control module has an a/D conversion interface, the signal from the signal output circuit is converted into a digital signal via the a/D conversion interface, and the control module determines whether an object exists in the predetermined range according to the size of the digital signal and/or the size of the change amount of the digital signal. Therefore, the control module can judge whether an object exists in a preset range according to the converted digital signal.

Optionally, the control module controls the cooking appliance to perform a predetermined operation when the control module determines that there is an object motion within the predetermined range according to a signal from the sensing module. Thus, the control module may perform a predetermined operation according to the movement of the object.

Optionally, the association relationship between a predetermined action and a predetermined operation is stored in the control module, and when the control module determines that the movement of the object within the predetermined range is the same as a certain predetermined action according to the signal from the sensing module, the control module performs the predetermined operation associated with the predetermined action. Thus, the control module may identify different predetermined actions and perform predetermined operations associated with the predetermined actions.

Optionally, the predetermined action includes moving in a first direction, moving in a second direction perpendicular or opposite to the first direction, moving closer to the sensing module, and moving away from the sensing module. Thus, the control module can recognize a predetermined motion such as a linear motion, a near or far motion, etc.

Optionally, the cooking appliance further comprises a power module for supplying power to the display module and/or the sound prompt module, and the power module is electrically connected with the control module. Thus, the control module may perform the display action and/or the prompting action by controlling the power module.

Optionally, the display module is at least one of a display screen and an operation screen. Thus, the display module can be configured as a display screen and/or an operation screen as needed.

Optionally, the cooking appliance is an electric rice cooker or an electric pressure cooker.

Drawings

In order that the advantages of the invention will be readily understood, a more particular description of the invention briefly described above will be rendered by reference to specific embodiments that are illustrated in the appended drawings. Understanding that these drawings depict only typical embodiments of the invention and are not therefore to be considered to be limiting of its scope, the invention will be described and explained with additional specificity and detail through the use of the accompanying drawings. In the drawings:

fig. 1 is a perspective view of a cooking appliance according to a preferred embodiment of the present invention;

fig. 2 is a cross-sectional view of a cover of the cooking appliance shown in fig. 1;

fig. 3 is an enlarged view of a portion B in fig. 2;

FIG. 4 is an enlarged perspective view of the sensing module of FIG. 3; and

fig. 5 is a control block diagram of a cooking appliance according to a preferred embodiment of the present invention.

Reference numerals illustrate:

10: cover 11: injection molding layer

12: panel decoration portion 13: sensing module

14: face cover 15: peripheral circuit board

16: transparent film layer 17: mounting circuit board

18: display section 19: pot body

100: cooking utensil

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 embodiments of the invention may be practiced without one or more of these details. In other instances, well-known features have not been described in detail in order to avoid obscuring embodiments of the invention.

In the following description, a detailed structure will be presented for a thorough understanding of embodiments of the present invention. It will be apparent that embodiments of the invention may be practiced without limitation to the specific details that are set forth by those skilled in the art. Preferred embodiments of the present invention are described in detail below, however, the present invention may have other embodiments in addition to these detailed descriptions.

Generally, as shown in fig. 1, the cooking appliance 100 includes a cover 10 and a pot 19. The pot body 19 has a substantially rounded rectangular parallelepiped shape and has a cylindrical inner pot receiving portion, and the cover body 10 may have substantially the same shape as the pot body 19 and is for covering the pot body 19. The inner pot can be freely placed in or taken out from the inner pot containing part, so that the inner pot can be conveniently cleaned. The upper surface of the inner pot has a circular opening for holding materials to be heated, such as rice, soup, etc., in the inner pot. The pot 19 includes therein heating means for heating the inner pot. It is understood that the cooking appliance 100 according to the present invention may be an electric rice cooker, an electric pressure cooker, or other cooking appliances 100, and the cooking appliance 100 according to the present invention may have various functions of cooking porridge, etc., in addition to the function of cooking rice.

In addition, the cooking appliance 100 may further include a display module 18 such as a display screen or an operation screen and an audible cue module (not shown) such as a buzzer. A display module 18 may be provided on the pot 19 and/or the lid 10 for displaying information such as cooking mode, operating state, etc., as desired. And the voice prompt module can execute prompt actions by making different voices. For energy savings, it may be desirable to extinguish display module 18 when no user is approaching, and to illuminate display module 18 and/or sound an audible cue module when someone is approaching.

The cooking appliance 100 may further include a sensing module 13 and a control module. In the embodiment shown in fig. 1, the sensing module 13 is provided on the cover 10 and faces upward or obliquely upward of the cooking appliance 100 for detecting whether an object (e.g., a human hand) exists within a predetermined range. Of course, the sensing module 13 may be provided on the pot 19 of the cooking appliance 100 or at other locations as desired.

As shown in fig. 1 to 3, the cover 10 may include a panel on an upper surface, a panel decoration 12 under the panel, and a face cover 14 surrounding the panel and the panel decoration 12. The sensing module 13 may be disposed under the panel, and the panel decoration part 12 at this position is provided with an accommodation space for disposing the sensing module 13.

Specifically, the panel of the cover 10 may be an IMD (In-Mold decoding) panel. The IMD panel includes a substrate such as an ABS injection molded layer 11 and a transparent film layer 16 (e.g., made of PET material) covering the upper surface of the ABS injection molded layer 11. And the IMD panel may be provided with a recess, for example, an 8mm diameter region, which is formed by cutting out the base material, in other words, where only the transparent thin film layer 16 remains without the injection molding layer 11. The sensor module 13 may be disposed in this area. The transparent film layer 16 of the IMD panel can prevent foreign matters such as water drops and oil stains from entering the sensing module 13 and the circuit board from the IMD panel.

Further, the panel decoration portion 12 at this position is provided with a receiving portion for disposing the sensor module 13.

The sensing module 13 includes a transmitting unit for transmitting a wave and a receiving unit for receiving a wave reflected by the object. It is noted that the term "wave" as used herein refers to a mechanical wave (e.g., ultrasonic wave) or an electromagnetic wave (e.g., infrared light). Thus, the sensing module 13 may be, for example, an infrared sensing module or an ultrasonic sensing module 13. Since the measurement principles of the sensing module 13 (e.g., triangulation principles) are well known in the art, they will not be described in detail herein for brevity.

In the embodiment shown in fig. 2 and 3, the sensing module 13 is an infrared sensing module such as an infrared proximity sensor (infrared gesture sensor), the emitting unit of the infrared sensing module is an infrared LED tube for emitting infrared light, and the receiving unit is a photo tube array. It will be appreciated that the array of photodiodes may include a plurality of photodiodes arranged in an order that may receive the reflected infrared light from different directions, such that the control module may determine whether an object is present within the predetermined area, whether the object that reflected infrared light is moving, and the specific direction of movement thereof, based on the order (or strength) in which the infrared light is received by the different photodiodes in the array of photodiodes.

Further, the infrared sensing module is electrically connected with the control module, and the infrared sensing module can transmit the detected signal to the control module. The control module is capable of processing (e.g., filtering or computing, etc.) the signals from the infrared sensing module and controlling the human-machine interaction modules, such as the display module 18 and the voice prompt module, to wake-up.

Specifically, the control module is capable of processing the signal from the infrared sensing module, and when the control module determines that an object exists within a predetermined range according to the signal from the infrared sensing module, the control module may control the display module 18 to perform a display action. For example, the control module may control display module 18 to illuminate for a period of T1. Of course, the control module may also control the voice prompt module to execute the prompt action. For example, the voice prompt module is controlled to sound for a T2 period.

The cooking appliance provided by the invention is provided with the sensing module 13 comprising the transmitting unit and the receiving unit array and the control module connected with the sensing module 13, wherein the sensing module 13 is arranged below the panel, and the control module controls the cooking appliance through signals sensed by the sensing module 13, so that non-contact operation can be realized, better user experience is brought to a user, and the problem of energy waste in the prior art can be solved.

In order to make the detection effect better, the distance between the upper surface of the infrared sensing module and the lower surface of the transparent film layer 16 of the IMD panel is preferably less than 0.4mm. So that as much of the infrared light emitted from the infrared LED tube as possible passes through the transparent film layer 16 and as much of the infrared light reflected back by the object as possible is received by the array of photocells. While the thickness of the transparent film layer 16 is preferably less than 0.7mm. In addition, for the infrared sensing module, it should be ensured that infrared rays having a wavelength of about 940nm can pass through the transparent thin film layer 16 of the above IMD panel.

The upper surface of the panel corresponding to the installation position of the infrared sensing module can be printed with a character or a pattern of a screen sensor (or infrared sensing or motion sensing) so as to be convenient for a user to identify and operate. In the present embodiment, a spatial region about 80cm above a word such as "screen sensor" is an infrared sensing region. That is, the sensing range of the infrared sensing module is a range of less than or equal to 80cm from the infrared sensing module. Thus, it is possible to detect whether an object is present within 80cm, and not to detect a range exceeding the distance, so as to avoid misrecognition. That is, the cooking appliance 100 in the present embodiment is set to a predetermined range within an induction distance of 80cm from the infrared sensor module. However, it should be noted that the sensing distance of the infrared sensing module is not limited thereto, and in other embodiments, the sensing distance may be adjusted according to specific needs.

The operation principle of the infrared sensing module and the control module will now be described.

The infrared light emitted by the infrared LED tube is reflected by a reflecting object (a hand of a user), and the reflected infrared light is received by the photoelectric tube array and simultaneously generates an electric signal (analog signal). This electrical signal may vary with the distance of the reflecting object (the user's hand), with the closer the distance the stronger the electrical signal and the farther the distance the weaker the electrical signal.

The cooking appliance 100 further includes a driving circuit for driving the infrared LED tube to emit infrared light, a signal processing circuit for processing infrared signals received by the photo-transistor array, and a signal output circuit for outputting the processed signals to the control module. Therefore, the control module can control the infrared LED tube to emit infrared light through the driving circuit, the signal processing circuit is used for processing infrared signals received by the photoelectric tube array, and the signal output circuit can convey the processed signals to the control module.

As shown in fig. 4, the infrared proximity sensor and mounting circuit board 17 and the peripheral circuit board 15 (PCB board) having the above-described driving circuit, signal processing circuit, and signal output circuit may be integrated into one modular member. Compared with an infrared pyroelectric sensor only provided with a receiving unit, the infrared proximity sensor has higher reliability and stronger anti-interference capability. And is not affected by the color of the object to be measured, i.e. the invention is not affected by the color of the clothing worn by the user.

The control module has an a/D (analog/digital) conversion interface, and the signal from the signal output circuit is converted into a digital signal, which may also be referred to as an AD value, via the a/D conversion interface. For example, in the sensing range of an infrared proximity sensor, the closer the distance of a reflecting object (a user's hand) is, the larger the AD value is; the farther the distance of the reflecting object (the user's hand) is, the smaller the AD value is.

According to the signal intensity, the control module can judge whether an object exists in a preset range according to the size of the digital signal and/or the size of the change amount of the digital signal. For example, in the case of weak signal strength, the control module may detect the AD value once at intervals (e.g., 40 ms), compare the detected AD value with the last AD value (the current value is greater than the last value), and calculate the change amount of the AD value. If the variation exceeds a preset value (threshold), the control module judges that an object (a hand of a user) exists in the sensing range. Otherwise, no user's hand is considered to be present.

Alternatively, for the case where the signal is strong, if the following condition is satisfied: if the X < AD value < Y, judging that the hand of the user approaches in the infrared sensing area, outputting a detection motion signal to the control module by the infrared proximity sensor so that the control module controls the lighting display module 18; if one of the following conditions is satisfied: if the AD value < X, or the AD value > Y, it is determined that there is no hand approach of the user in the infrared sensing area, the infrared proximity sensor outputs a detection unmanned signal to the control module to cause the control module to control the extinction display module 18.

Cooking appliance 100 also includes a power module that provides power to display module 18 and/or the audible prompts module, the power module being electrically connected to the control module. Thus, the control module may perform the display action and/or the prompting action by controlling the power module.

When the control module determines that an object exists in the predetermined area, the control module may control to light the display module 18 and delay for a period of time T1 (e.g., 30 seconds), where the display module 18 is always lit during the period of time T1; when the control module determines that no object is present in the predetermined area after time T1, the control module controls the extinction display module 18. Of course, as shown in fig. 4, the infrared sensing module may also control the sound prompting module to sound according to the signal detected by the infrared sensing module, for example, to prompt the user with a beep for a period of time T2.

Alternatively, the control module may control the display module 18 to at least partially extinguish and/or control the audible cue module to mute when the control module detects that no object is present within the predetermined range for more than a period of time T3. Therefore, the control module can control the display module 18 to be turned on or off and the sound prompting module to sound or mute according to the information sensed by the sensing module, so that energy sources can be saved and the observation by a user is convenient.

Further, as described above, due to characteristics such as an infrared light cell array, the control module may determine whether an object is present within a predetermined area, whether an object reflecting infrared light is moving, and a specific direction of movement thereof, according to the order (or intensity) of infrared light received by different photodiodes in the cell array. Thus, the control module is able to recognize the actions of the user.

To enhance the user experience, the control module may store an association between a predetermined action of an object (e.g., a user's hand) and a predetermined operation, i.e., the control module may store several predetermined operations, such as starting heating, stopping heating, suspending heating, etc. These predetermined operations are associated with predetermined actions that can be recognized by the cooking appliance 100.

Here, the predetermined action described above may also be referred to as a "gesture". Taking the example that the infrared photoelectric tube array is disposed on the upper surface of the cover body 10, the predetermined action preferably includes such as movement in a first direction (e.g., movement from left to right), movement in a second direction perpendicular or opposite to the first direction (e.g., movement from front to back or movement from right to left), movement close to the infrared sensor module (e.g., movement downward), movement away from the infrared sensor module, and the like. Here, the first direction and the second direction are both parallel to the infrared phototransistor array.

For example, the infrared photodiode array may be composed of four photodiodes in total of two rows and two columns, specifically, the four photodiodes are referred to as a first photodiode a, a second photodiode B, a third photodiode C, and a fourth photodiode D, respectively, and are arranged as follows (wherein the second photodiode B is arranged to the left of the first photodiode a, and the third photodiode C and the fourth photodiode D are arranged in front of the second photodiode B and the first photodiode a, respectively):

B	A
		C	D

the principle of operation of the infrared light array in horizontal movement of the object will first be described. The above-described movements in the first direction and the second direction are referred to as horizontal movements of the object. While moving horizontally, the object sweeps the infrared array of photodiodes from a plane substantially parallel to the infrared array of photodiodes, and the direction of movement of the object can be determined by the order in which each photodiode in the infrared array receives infrared light reflected by the object, as will now be discussed in detail: when the object moves from left to right, the second photodiode B and the third photodiode C first receive the infrared light reflected by the object, and then the first photodiode a and the fourth photodiode D receive the infrared light reflected by the object, so that the control module can judge that the object moves from left to right through the sequence in which the four photodiodes generate signals.

When the object moves from right to left, the first photodiode a and the fourth photodiode D first receive the infrared light reflected by the object, and then the second photodiode B and the third photodiode C receive the infrared light reflected by the object, so that the control module can judge that the object moves from right to left through the sequence in which the four photodiodes generate signals.

When the object moves from back to front, the second photodiode B and the first photodiode a first receive the infrared light reflected by the object, and then the third photodiode C and the fourth photodiode D receive the infrared light reflected by the object, so that the control module can judge that the object moves from back to front through the sequence of signals generated by the four photodiodes.

When the object moves from front to back, the third photodiode C and the fourth photodiode D first receive the infrared light reflected by the object, and then the second photodiode B and the first photodiode a receive the infrared light reflected by the object, so that the control module can judge that the object moves from front to back through the sequence of signals generated by the four photodiodes.

It will be appreciated by those skilled in the art that the control module may perform a logical operation based on the receipt of infrared light by the infrared photodiode, in other words, based on a change (e.g., a rising edge) from not receiving infrared light to receiving infrared light by the infrared photodiode. Of course, the change (e.g., falling edge) of the infrared photodiode from receiving infrared light to not receiving infrared light may also be used as a basis. Of course, the two variations can be combined to serve as the basis of logic operation.

The principle of operation of the infrared photoelectric array upon vertical movement of the object will now be described, the vertical movement of the object including movement of the object along a direction substantially perpendicular to the infrared photoelectric array from a position far from the infrared photoelectric array toward the near-infrared photoelectric array (from far to near), and movement of the object from the near-infrared photoelectric array away from the infrared photoelectric array (from near to far).

When the object moves from far to near, the intensity of the infrared light received by the first photodiode A, the second photodiode B, the third photodiode C and the fourth photodiode D gradually increases, and when the object moves from near to far, the intensity of the infrared light received by the first photodiode A, the second photodiode B, the third photodiode C and the fourth photodiode D gradually decreases, so that the control module can judge that the object moves from far to near or from near to far according to the sequence of signals generated by the four photodiodes.

In fact, taking the example of an object moving from far to near, the infrared light received by the four first, second, third, and fourth photodiodes a, B, C, and D may not be average, and in some cases (e.g., too far from the infrared sensor array, uneven reflection due to the construction of the object, and differences in sensitivity of the photodiodes, etc.), one or more of the four first, second, third, and fourth photodiodes a, B, C, and D may not receive the infrared light reflected by the object. But as the object moves from far to near, the first photodiode a, the second photodiode B, the third photodiode C, and the fourth photodiode D are each capable of receiving infrared light.

Thus, throughout the movement of the object, there may be an irregular signal sequence for the first, second, third and fourth photodiodes a, B, C and D, for example, the second, third and fourth photodiodes B, C and D receive infrared light, after which the first photodiode a receives infrared light again, and by the end of the movement, the first, second, third and fourth photodiodes a, B, C and D can each receive infrared light.

For the movement of the object from near to far, at the beginning of the movement, the first photodiode a, the second photodiode B, the third photodiode C and the fourth photodiode D can all receive infrared light, and when the object moves far, the first photodiode a, the second photodiode B, the third photodiode C and the fourth photodiode D receive infrared light which is not reflected by the object at the same time or approximately the same time, and the change (for example, a falling edge) from receiving infrared light to not receiving infrared light can be used as a basis for logic operation through the infrared photodiodes.

Of course, in some cases, it is also possible to determine whether the object is moving from far to near or from near to far by the intensity of the infrared light received by the infrared photodiode.

Although the operation principle of the infrared photoelectric tube array as the receiving unit is described in detail herein, these operation principles are also applicable to an ultrasonic receiver array to be described below.

Accordingly, the control module may preset or store some predetermined operations and associate the predetermined operations with predetermined actions (gestures).

Thus, when the control module determines that the movement of the object within the predetermined range is a certain predetermined movement according to the signal from the infrared sensing module, the control module performs a predetermined operation associated with the predetermined movement, for example, when it is detected that the object (for example, a user's hand) is present within the predetermined range in the first direction, the control module may perform an operation of starting heating, so that a non-contact operation can be realized, which is convenient for the user.

Of course, a user may set a predetermined operation and a predetermined motion as needed, whereby the infrared sensing module can recognize various motions, and thus a non-contact operation can be better achieved. Further, when the control module judges that the movement of the object sensed by the infrared sensing module is different from the predetermined action, the control module does not perform the predetermined operation, or the control module performs only some specific actions, such as lighting the display module 18 or sounding the sound prompt module, which will be described later.

In another embodiment, not shown, the sensor module 13 is an ultrasonic sensor module 13, the transmitting unit of which is an ultrasonic transmitter for transmitting ultrasonic waves, and the receiving unit is an ultrasonic receiver array. Thus, the ultrasonic transmitter may be used to transmit ultrasonic waves and the ultrasonic waves reflected back from the ultrasonic receiver array may be used to sense the presence of an object, the movement of an object, and the direction of movement within a predetermined range. It is understood that, since the ultrasonic wave is used as the detection wave, the ultrasonic wave sensing module 13 is less affected by the environment such as light.

Further, similar to the foregoing embodiment, the cooking appliance 100 may further include a driving circuit for driving the ultrasonic transmitter to transmit ultrasonic waves, a signal processing circuit for processing ultrasonic signals received by the ultrasonic receiver array, and a signal output circuit for outputting the processed signals to the control module.

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 pertains. The terminology used herein is for the purpose of describing particular implementations only and is not intended to be limiting of the invention. Terms such as "component" as used herein may 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 being directly attached to another component or to one component being attached to another component through an intermediary. Features described herein in one embodiment may be applied to another embodiment alone or in combination with other features unless the features are not applicable or otherwise indicated in the other embodiment.

The present invention has been described in terms of the above embodiments, but it should be understood that the above embodiments are for purposes of illustration and description only and are not intended to limit the invention to the embodiments described. Those skilled in the art will appreciate that many variations and modifications are possible in light of the teachings of the invention, which variations and modifications are within the scope of the invention as claimed.

Claims (16)

1. A cooking appliance, comprising:

a pot body;

the cover body is used for covering the cooker body;

the sensing module is arranged on the pot body and/or the cover body and is used for detecting whether an object exists in a preset range, whether the object moves and the direction of the object movement, the sensing module comprises a transmitting unit for transmitting waves and a receiving unit array for receiving the waves reflected by the object, and the receiving unit array comprises a plurality of receiving units which are arranged in a certain order and are used for receiving the reflected waves from different directions;

the control module is electrically connected with the sensing module and judges whether an object exists in the preset range, whether the object moves and the direction of the object movement according to the sequence and/or intensity of waves received by different receiving units in the receiving unit array;

wherein the surface of the cooker body and/or the surface of the cover body is provided with a panel, the inner side surface of the panel is provided with a concave part formed by material cutting, the panel comprises a base material and a transparent film layer covered on the upper surface of the base material, the concave part is formed by cutting the base material, the sensing module is at least partially contained in the concave part, the cooking utensil further comprises a display module and/or a sound prompt module, and the control module processes signals from the sensing module and controls the display module to execute display action and/or the sound prompt module to execute prompt action;

when the control module determines that the object moves within the preset range according to the signal from the sensing module, the control module controls the cooking appliance to execute preset operations, wherein the preset operations comprise heating start, heating stop and heating pause.

2. The cooking appliance of claim 1, wherein a distance between an upper surface of the sensing module and a lower surface of the transparent film protective layer is less than 0.4mm.

3. The cooking appliance of claim 1, wherein the predetermined range is an area less than or equal to 80cm from the sensing module.

4. The cooking appliance of claim 1, wherein the transparent film protective layer has a thickness of less than 0.7mm.

5. The cooking appliance of claim 1, wherein the faceplate is an IMD faceplate.

6. The cooking appliance of claim 1, wherein the upper surface of the area of the panel corresponding to the sensing module has a hint text or pattern.

7. The cooking appliance according to claim 1, wherein the emitting unit is an infrared LED tube for emitting infrared light, and the receiving unit is a photocell array.

8. The cooking appliance of claim 7, further comprising a driving circuit for driving the infrared LED tube to emit infrared light, a signal processing circuit for processing infrared signals received by the array of photocells, and a signal output circuit for outputting the processed signals to the control module.

9. Cooking appliance according to claim 1, wherein the transmitting unit is an ultrasonic transmitter for transmitting ultrasonic waves and the receiving unit is an array of ultrasonic receivers.

10. The cooking appliance of claim 9, further comprising a driving circuit for driving the ultrasonic transmitter to transmit ultrasonic waves, a signal processing circuit for processing ultrasonic signals received by the ultrasonic receiver array, and a signal output circuit for outputting the processed signals to the control module.

11. Cooking appliance according to claim 8 or 10, wherein the control module has an a/D conversion interface, the signal from the signal output circuit is converted into a digital signal via the a/D conversion interface, and the control module judges whether an object is present within the predetermined range according to the magnitude of the digital signal and/or the magnitude of the change of the digital signal.

12. The cooking appliance according to claim 1, wherein the control module has stored therein an association between a predetermined action and a predetermined operation, and wherein the control module performs the predetermined operation associated with the predetermined action when the control module determines from the signal from the sensing module that the movement of the object within the predetermined range is identical to a certain predetermined action.

13. The cooking appliance of claim 12, wherein the predetermined action comprises moving in a first direction, moving in a second direction perpendicular or opposite to the first direction, moving closer to the sensing module, and moving away from the sensing module.

14. The cooking appliance of claim 1, further comprising a power module that powers the display module and/or the audible cue module, the power module being electrically connected with the control module.

15. The cooking appliance of claim 1, wherein the display module is at least one of a display screen and an operation screen.

16. The cooking appliance of claim 1, wherein the cooking appliance is an electric rice cooker or an electric pressure cooker.