FOOD PROCESSOR AND INTERFACE DISPLAY CONTROL METHOD THEREOF
TECHNICAL FIELD
The present invention relates to the technical field of small household appliances, and more particularly to a food processor and a method for controlling an interface display thereof.
BACKGROUND
With the development of science and technology, there are more and more types of food processors. The food processors can be classified into ordinary food processors, ordinary soybean milk makers, raw soybean milk makers, wall-breaking food processors and other types of food processors according to their functions. However, the food processors can also be classified into food processors with a cooling cup and food processors with a heating cup according to the types of the cups.
At present, since food processors of different cups or functions are provided with different preset proceduresand have touch panels with limited area, the touch panelsof different food processors are printed withfunction options and control options corresponding to such functions. As a result, these food processors are sold separately.
In other words, the functions are too simple and the functional integration is too low forafood processor, resulting in that it is difficult to meet the diversified demand of the users.
SUMMARY OF THE PRESENT INVENTION
A main objective of the present invention is to provide a food processor and a method for controlling an interface display thereof, in order to solve the problem of low functional integration of the food processors in the prior art.
In order to achieve the above objective, in one aspect, the present
invention provides a food processor comprising
-two or more different types of cups;
-a base on which a utensil type detection element configured to identify the type of the cups is provided, the utensil type detection element sending a corresponding utensil type signal according to the type of the cup placed thereon; and
-a control unit configured to receive the utensil type signal so as to call a corresponding control program and display a corresponding control interface on a touch panel, the control interfaces being displayed respectively under the irradiation of light of different wavelengths.
The utensil type detection element may comprise a detection circuit having a detection terminal, and the cup may comprise a utensil marking structure coordinated with the detection terminal. After the interaction between the utensil marking structure and the detection terminal, electrical parameters in the detection circuit change to generate the utensil type signal, and the control unit receives the utensil type signal so as to call a corresponding control program.
The detection terminalmay comprise:
-a trigger switch, wherein the marking structure is a triggerelement by which the trigger switch is triggered to send the corresponding utensil type signal, and the control unit receives the utensil type signal so as to call the corresponding control program; and/or
-a sensor switch, wherein the marking structure is a sensing element, and wherein the sensor switchsenses the sensing element to send the corresponding utensil type signal, and the control unit receives the utensil type signal so as to call the corresponding control program; and/or
-wiring pins, wherein the marking structure is an electrical component, and the electrical parameters in the detection circuit change to generate the utensil type signal after the electrical component is connected to the wiring pins.
In one embodiment, the trigger switch is a push-type trigger switch and the trigger element is a bump structure provided on the cup. When the cup is placed on the base; the trigger switch is pressed by the bump structure so as to switch operation state of the detection circuit, and the control unit calls the corresponding control program according to the operation state of the detection circuit.
In another embodiment, the sensor switch is a magnetic switch and the sensing element is a magnetic device. When the cup is placed on the base; the magnetic device attracts the magnetic switch so as to switch the operation state of the detection circuit, and the control unit calls the corresponding control program according to the operation state of the detection circuit.
In another embodiment, the electrical component is a thermistor. When the cup is placed on the base; the thermistor is connected to the detection circuit by the wiring pins, the electrical parameters in the detection circuit change depending on different resistance values of the thermistor, and the control unit calls the corresponding control program.
There may be two wiring pins which are respectively a high level pin and a ground pin, and the electrical component is a coupler. When the coupler has the two connecting pins both connected to the two wiring pins of the detection circuit, the control unit receives a low level signal so as to call one control program. When the coupler is only connected to the high level pin, the control unit receives a high level signal so as to call another control program.
In one embodiment, one of the cups is not provided witha utensil marking structure. The control unit initially calls a control program by default. When the cup without a utensil marking structure is placed on the base, the electrical parameters in the detection circuit do not change andthe control unit calls the default control program. When the cup with a utensil marking structure is placed on the base, the electrical parameters in the detection circuit change to generate the utensil type signal, so as to call the corresponding control program.
The cups may comprise two or three of a cooling cup having a mixing cutter, a heating cup having a mixing cutter and a heater, and a raw milling cup having an extrusion crusher.
The touch panel may be provided on the base and comprise a display area and a number of touch keys. The display area may comprise a number of display positions which are all or partially provided with touch keys correspondingly. Display markers may beprovided in each display position, and at least two display markers may besuperposed or partially superposed or adjacently provided in at least one display position. The different display markers in the same display position may bedisplayed respectively under the irradiation of light of different wavelengths. The food processor may further comprise:
-a light source module configured to irradiate the touch panel, wherein the light source module is provided in the base and can selectively emit light of different wavelengths so as to enable one display marker in the same display position to be displayed at a same time by sensing light of corresponding wavelength and enable the display markers in all or part of the display positions to develop color at a same time, the control unit being connected to the light source module so as to adjust the light wavelength of the light source module, the control program comprising a control logic corresponding to the display marker displayed currently, and the touch keys being connected to the control unit; and
-an execution element provided in the cup or the base, wherein when the corresponding touch key is triggered, a control mode under the current control interface is executed to perform a corresponding cooking operation.
The execution element may comprise:
-a crushing element which is provided in the cup and connected to the control unit, wherein when the corresponding touch key is triggered, the crushing time and/or the crushing speed of the crushing element is controlled by the called control program to perform the corresponding cooking operation;
and/or
-a heating element which is provided in the base and connected to the control unit, wherein when the corresponding touch key is triggered, the heating time or/and the heating power of the heating element is controlled by the called control program to perform the corresponding cooking operation; and/or
-a vacuum-pumping assembly which is provided in the cup and connected to the control unit, wherein when the corresponding touch key is triggered, the vacuum-pumping operation of the vacuum-pumping assembly is controlled by the called control program; and/or
-a spill-proof assembly which is provided on a cup lid or the cup and connected to the control unit, wherein when the corresponding touch key is triggered, the spill-proof operation of the spill-proof assembly is controlled by the called control program; and/or
-an alarm device connected to the control unit, wherein when the corresponding touch key is triggered, the alarm operation of the alarm device is controlled by the called control program.
The crushing element may comprise the mixing cutter and the extrusion crusher.
The display area maybe provided with a display screen which is connected to the control unit and capable of displaying: the crushing time and/or the crushing speed of the crushing element; and/or the heating time or/and the heating power of the heating element; and/or the pump-down time or/and the vacuum degree of the vacuum-pumping assembly; and/or the alarm of the alarm device.
The control unit may comprise two or more interface control modules each having different control programs. When different interface control modules are called, the light wavelengths of the light source module are different.
Each display positionmay be coated with two display markers. The light source module may selectively display light of a first wavelength and light of a
second wavelength for respectively displaying the two display markers so as to display at least two control interfaces correspondingly.
The at least two control interfaces may comprise two or three of a cooling cup mode interface, a heating cup mode interface and a raw milling cup mode interface, wherein the light wavelength of the light source module is adjusted according to the utensil type signal so as to display the cooling cup mode interface, the heating cup mode interface and the raw milling cup mode interface corresponding thereto.
The cooling cup mode interface may comprise several function options and several control options, and a cooling cup icon is turned on under the cooling cup mode interface.
The several function options may comprise one or more of "Soft Fruit" , “Hard Fruit" , "Fruit Shake" , "Fruit and Vegetable Puree" , "Milk Shake" , "Clean" , "Mix” and "Vacuum" , and the several control options may comprise one or more of "Start" , "Cancel" , "+” and "—" .
The heating cup mode interface may comprise several function options and several control options, and a heating cup icon is turned on under the heating cup mode interface.
The several function options may comprise one or more of "Coarse Grain Paste" , "Soybean Milk" , "Corn Juice" , "Puree" , "Mill" , "Clean" , "Mix” and "Wet Heat" , and the severalcontrol options comprise one or more of "Start" , "Cancel" , "+” and "—" .
In another aspect, the present invention provides a method for controlling an interface display of a food processor, wherein the food processor is the food processor described above, and the method for controlling the interface display comprises the steps ofdetermining the type of the cup placed on the base; andcalling thematched control program according to the type of the cup and displaying thecorresponding control interface.
After the cup is placed on the base, the interaction between a utensil marking structure on the cup and a detection circuit may enable electrical
parameters in the detection circuit to change so as to determine the type of the cup.
There may be at least two control programs. The at least two control programs may comprise a cooling cup mode program, a heating cup mode program and a raw milling cup mode program, wherein the light wavelength of a light source module is adjusted according to the utensil type signal so as to display the cooling cup mode program, the heating cup mode program and the raw milling cup mode program corresponding thereto.
After the cooling cup mode program is called, the method for controlling the interface display may further comprise the steps of determining a cooling-cup operation program of the execution element according to a triggered function option; and determining an operation state of the execution element according to a triggered control option.
The function options may comprise one or more of "Soft Fruit" , “Hard Fruit" , "Fruit Shake" , "Fruit and Vegetable Puree" , "Milk Shake" , "Clean" , "Mix” and "Vacuum" , and the control options may comprise one or more of "Start" , "Cancel" , "+” and "—" .
After the heating cup mode program is called, the method for controlling the interface display may further comprise the steps of determining a heating-cup operation program of the execution element according to a triggered function option; and determining an operation state of the execution element according to a triggered control option.
The operation state of the execution element may comprise one or more of start operation, stop operation, operation time adjustment and power output adjustment.
The function options may comprise one or more of "Coarse Grain Paste" , "Soybean Milk" , "Corn Juice" , "Puree" , "Mill" , "Clean" , "Mix” and "Wet Heat" , and the control options comprise one or more of "Start" , "Cancel" , "+” and "—" .
By adopting the technical solution of the present invention, the utensil type detection element configured to identify the type of the cups is provided on the
base to send a corresponding utensil type signal according to the type of the cup placed thereon; and the control unit receives the utensil type signal so as to call a corresponding control program and display a corresponding control interface on thetouch panel, and the control interfaces are displayed respectively under the irradiation of light of different wavelengths.
Thus, the food processor can call the corresponding operation program depending on the type of the cup, so that the base can cooperate with different cups to achieve various operations. Moreover, the food processor breaks through the area limitation of the touch panel and adjusts the control interfaces depending on the type of the cup so as to ensure that the various functions of the food processor can be achieved reliably.
That is to say, the food processor of the present invention has the advantage of one machine for multiple purposes and high functional integration.
BRIEF DESCRIPTION OF THE DRAWINGS
The accompanying drawings, which constitute a part of the present application, are included to provide a further understanding of the present invention. The exemplary embodiments of the present invention and description thereof herein are only for explaining the present invention, but not for unduly limiting the present invention. In Figures:
FIG. 1 shows a structural diagram of a food processor having a cooling cup in one embodiment of the present invention;
FIG. 2 shows a structural diagram of the food processor having a heating cup in another embodiment of the present invention;
FIG. 3 shows a structural diagram of the food processor having a raw milling cup in another embodiment of the present invention;
FIG. 4 shows a schematic diagram illustrating an internal configuration of FIG. 3;
FIG. 5 shows a schematic diagram of display situation of a display panel
of the present invention under the irradiation of blue light;
FIG. 6 shows a schematic diagram ofdisplay situation of the display panel of the present invention under the irradiation of orange light;
FIG. 7 shows a schematic diagram ofdisplay situation of the display panel in FIG. 1;
FIG. 8 shows a schematic diagram of display situation of the display panel in FIG. 2;
FIG. 9 shows a schematic diagram of location relationship between two display markers in one display position of the display panel in one embodiment of the present invention;
FIG. 10 shows a schematic diagram of location relationship between two display markers in one display position of the display panel in another embodiment of the present invention;
FIG. 11 shows a schematic diagram of connection between components of the food processor in FIG. 1;
FIG. 12 shows a functional diagram of a utensil type detection element in one embodiment of the present invention;
FIG. 13 shows a functional diagram of the utensil type detection element in another embodiment of the present invention;
FIG. 14 shows a functional diagram of the utensil type detection element in another embodiment of the present invention;
FIG. 15 shows an operation flowchart of the food processor in one embodiment of the present invention; and
FIG. 16 shows an operation flowchart of the food processor in another embodiment of the present invention.
In which, the above figures include the following reference numbers:
10: Base; 11: Touch panel; 111: Display position; 112: Display marker; 12: Touch key; 20: Cooling cup; 30: Heating cup; 40: Raw milling cup; 50: Extrusion crusher; 60: Display screen.
DETAILED DESCRIPTION OF THE PRESENT INVENTION
It should be noted that the embodiments in the present application and the characteristics in the embodiments can be combined mutually in the case of no conflict. The present invention will be described in detail as below with reference to the accompanying drawings by the embodiments.
It should be noted that, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs unless specified otherwise herein.
In the present invention, unless otherwise stated oppositely, the terms used herein to directional relationships and movement, such as “top and bottom or upper and lower” , generally refer to the relationship and movement of the components in the orientation illustrated in the drawings, or refer to the orientation of the components themselves in the vertical, perpendicular or gravity directions. Similarly, in order to facilitate the description and understanding, the terms “inner and outer” used herein refer to the inside and outside with respect to the profiles of the components themselves, but the above-mentioned terms are not intended to limit the present invention.
The present invention provides a food processor and a method for controlling an interface display thereof, in order to solve the problem of low functional integration of the food processors in the prior art.
As shown in FIG. 1 to FIG. 10, the food processor comprises a base 10, a control unit and two or more different types of cups. A utensil type detection element configured to identify the type of cups is provided on the base 10 and sends a corresponding utensil type signal according to the type of the cup placed thereon. The control unit receives the utensil type signal so as to call a corresponding control program and display a corresponding control interface on a touch panel 11, and the control interfaces are displayed respectively under the irradiation of light of different wavelengths.
Thus, the food processor can call a corresponding operation program depending on the type of the cup, so that the base 10 can cooperate with the
different cups to achieve various operations. Moreover, the food processor breaks through the area limitation of the touch panel and adjusts the control interfaces depending on the type of the cup so as to ensure that the various functions of the food processor can be achieved reliably. The touch panel of such structure can enlarge the function menu by twice or three times or even more times in the limited display area. Moreover, the operation is simple and the interactive experience is very good.
That is to say, the food processor of the present invention has the advantage of one machine for multiple purposes and high functional integration.
According to the present invention, the cups comprise two or three of a cooling cup 20 having a mixing cutter, a heating cup 30 having a mixing cutter and a heater and a raw milling cup 40 having an extrusion crusher 50. The cooling cup 20 and the heating cup 30 may be wall-breaking cups. In other words, the user only needs to purchase a set of products to adapt to different processing requirements by changing the different types of the cups, and the control interface can be switched manually or automatically by changing the different cups. That is, the different operation requirements of many cups are met by using a small number of the touch keys12 in the same touch panel.
According to the present invention, the utensil type detection element comprises a detection circuit having a detection terminal, and the cup comprises a utensil marking structure coordinated with the detection terminal; after the interaction between the utensil marking structure and the detection terminal, electrical parameters in the detection circuit change to generate the utensil type signal, and the control unit receives the utensil type signal so as to call a corresponding control program. The type of the cup can be detected by the detection circuit so as to call a corresponding control program to display a corresponding control interface. Thus, the type of the cup is determined automatically by the detection circuit, so that the degree of automation of the food processor can be improved to meet the needs of the users at different
ages. When the user changes the cup, the corresponding control program will also be changed timely, thus greatly reducing the difficulty in operating the food processor and improving the operation reliability and convenience of the food processor. Of course, it can also be manually implemented by an additional change-over switch.
As shown in FIG. 11, the food processor also includes a power circuit through which the AC power supply is supplied to the control unit, so that the control unit supplies power to the electrical appliances to ensure the normal operation of each component in the food processor. The AC power supply is a mains electricity input converted to DC 5V by the power circuit so as to be supplied to the control unit for operation. The control unit when energized detects the type of the cup by the cup detection circuit (or manual setting) , and controls a display portion to display an interface corresponding to the cup, calls the corresponding program and then executes subsequent operations of the heating cup or the cooling cup.
Optionally, the control unit is an MCU control system.
According to the different detection principles, there are mainly three detection modes as below.
The first mode refers to a trigger type detection mode.
The detection terminal comprises a trigger switch, wherein the marking structure is a trigger element and wherein after the trigger switch is triggered by the trigger element, the trigger switch sends the corresponding utensil type signal, and the control unit receives the utensil type signal so as to call the corresponding control program. Such detection mode has a good fool-proof effect, and is not easy to be mistakenly triggered and also is not easy to fail.
Specifically, the trigger switch is a push-type trigger switch, the trigger element is a bump structure provided on the cup. When the cup is placed on the base 10, the trigger switch is pressed by the bump structure so as to switch operation state of the detection circuit, and the control unit calls the corresponding control program according to the operation state of the
detection circuit. The type of the cup is identified by mechanical pressing, which has the characteristics of easy operation and small errors.
The second mode refers to a sensor type detection mode.
The detection terminal comprises a sensor switch, wherein the marking structure is a sensing element. After the sensor switch senses thesensing element, the sensor switch sends the corresponding utensil type signal, and the control unit receives the utensil type signal so as to call the corresponding control program. Such detection mode has the characteristics of easy and simple operation. The user only needs to place the cup on the base 10 without other operations, so that the sensor switch senses the sensing element automatically to achieve automatic matching and calling of the programs.
Specifically, the sensor switch is a magnetic switch, the sensing element is a magnetic device. When the cup is placed on the base 10; the magnetic device attracts the magnetic switch so as to switch the operation state of the detection circuit, and the control unit calls the corresponding control program according to the operation state of the detection circuit.
As shown in FIG. 14, the sensor switch is a reed switch. The reed switchis provided in the base 10. No magnet is mounted on the heating cup 30 but a magnet is mounted on the bottom of the cooling cup 20. The high and low levels of a P1 pin of the control unit are determined by the detection circuit, thus determining which type of the cup is placed on the base 10.
When the cup is the heating cup 30, there is no magnet, the reed switch is not attracted to the heating cup and the P1 pin of the control unit is at high level. When the cup is the cooling cup 20, the magnet on the cup is close to the reed switch, the reed switch is closed, and the P1 pin of the control unit is at low level. It is easy for the user to detect, observe and operate by determining which type of the cup is placed by the P1 pin of the control unit and displaying the type of the cup by the display screen 60.
When classified by the functions of the cups, the cups may be classified into an ordinary cup (which may be a cooling cup or a heating cup) having a
mixing cutter and a raw milling cup 40 having an extrusion crusher 50. At this moment, in case the cupis a food processing cup, the magnet is not mounted on the food processing cup, the reed switch is not attracted to the cup, and the P1 pin of the control unit is at high level. When the cup is the raw milling cup 40, the magnet on the cup is close to the reed switch, the reed switch is closed, and the P1 pin of the control unit is at low level. Similarly, which type of the cup is placed is determined by determining the level of the P1 pin, and displayed through the display screen 60.
The third mode refers to an electric parameter change type detection mode.
The detection terminal comprises wiring pins, wherein the marking structure is an electrical component. The electrical parameters in the detection circuit change to generate the utensil type signal after the electrical component is connected to the wiring pins. The change in the electrical parameters here can be a change in current parameters or a change in the high and low levels.
In such detection mode, two specific embodiments which may be implemented are also specifically described as below.
Embodiment I
As shown in FIG. 12, the electrical component is a thermistor and the cup is placed on the base 10; the thermistor is connected to the detection circuit by the wiring pins, the electrical parameters in the detection circuit change depending on different resistance values of the thermistor, and the control unit calls the corresponding control program.
Specifically, a thermistor may be mounted on one cup and no thermistor is mounted on another cup. For example, when the cups are the cooling cup 20 and the heating cup 30, the NTC thermistor is not mounted on the cooling cup 20 but mounted on the heating cup 30. When energized, the control unit detects different AD conversion values through AD conversion to distinguish the cooling cup 20 from the heating cup 30 and displays which type of the cup is placed through the display screen 60.
In addition, thermistors of different resistances may also be provided on different cups. The ordinary food processing cup and the raw milling cup 40 are taken as an example. Two thermistors with different resistances are mounted on the ordinary food processing cup and the raw milling cup 40 respectively. When energized, the control unit detects different AD conversion values through AD conversion todistinguish the ordinary food processing cup from the raw milling cup 40 and displays which type of the cup is placed through the display screen 60.
Embodiment II
As shown in FIG. 13, there are two wiring pins which are respectively a high level pin and a ground pin, and the electrical component is a coupler. When the coupler has the two connecting pins both connected to the two wiring pins of the detection circuit, the control unit receives a low level signal so as to call one control program. When the coupler is only connected to the high level pin, the control unit receives a high level signal so as to call the other control program.
In other words, one pin of coupler of one of the cups is grounded while asame pin of another cup is suspended in midair, and the levels at the pins of the control unit are determined through the following circuit to determine which type of cup is placed.
When the cup is the heating cup 30, the P1 pin of the control unit is at high level. When the cup is the cooling cup 20, the P1 pin of the control unit is at low level. Which type of the cup is placed is determined by the P1 pin of the control unit and displayed through the display screen 60.
When the cup is the ordinary food processing cup, the P1 pin of the control unit is at high level. When the cup is the raw milling cup 40, the P1 pin of the control unit is at low level. Which type of the cup is placed is determined by the P1 pin of the control unit and displayed by the display screen 60.
From the foregoing, when the food processor with the above structure is used, a method for controlling an interface display comprises the following
steps of: determining the type of a cup placed on the base 10, calling a matched control program according to the type of the cup and displaying a corresponding control interface. Specifically, after the cup is placed on the base 10, the interaction between a utensil marking structure on the cup and a detection circuit enables electrical parameters in the detection circuit to change so as to determine the type of the cup.
In addition to the above mentioned method for calling the control program after detection, as shown in FIG. 15, one of the cups is not provided with a utensil marking structure. The control unit initially calls a control program by default. When the cup without a utensil marking structure is placed on the base 10, the electrical parameters in the detection circuit do not change and the control unit calls the default control program; when the cup with a utensil marking structure is placed on the base 10, the electrical parameters in the detection circuit change to generate the utensil type signal so as to call the corresponding control program. Thus, a certain commonly used control program will be on standby when energized. Unless the cup body placed thereon is changed, the current default control program will be executed.
According to the present invention, the touch panel 11 is provided on the base 10 and comprises a display area and a number of touch keys 12, the display area comprises a number of display positions 111 which are all or partially provided with the touch keys 12 correspondingly. Display markers 112 are provided in each display position 111, at least two display markers 112 are superposed or partially superposed or adjacently provided in at least one display position 111, and the different display markers 112 in the same display position 111 are displayed respectively under the irradiation of light of different wavelengths. Refer to FIG. 16 for specific processes.
In addition, the food processor further comprises an execution element and a light source module configured to irradiate the touch panel 11. The light source module is provided in the base 10 and can selectively emit light of different wavelengths so as to enable one display marker 112 in the same
display position 111 to be displayed at a same time by sensing light of corresponding wavelength and enable the display markers 112 in all or part of the display positions 111 to develop color at a same time. The control unit is connected to the light source module to adjust the light wavelength of the light source module, and the control program comprises a control logic corresponding to the display marker 112 displayed currently and the touch keys 12 are connected to the control unit. The execution element is provided in the cup or the base 10, when the corresponding touch key 12 is triggered, a control mode under the current control interface is executed to perform a corresponding cooking operation.
It should be noted that the term "develop color"referred to herein means "display color" . That is to say, when the light source module does not emit light, the display markers 112 are invisible to the naked eye. The display markers 112 can be visible to the naked eye only when the display markers 112 are illuminated by the light of the corresponding wavelength.
Optionally, the display marker 112 is formed by processing photosensitive medium material or filter medium material or chromophore material. For the photosensitive medium, the corresponding light is irradiated onto the medium to trigger the medium to develop color, thus displaying a pattern. For the filter medium, due to the different wavelengths of light, two or more optical materials are used in the same position and due tothe filter principle, the different wavelengths of the light source make different contents develop color. For the chromophore material, the optical material is a coating material containing different chromophores, so that this material is combined with a transparent material to allow only a certain wavelength of light to pass through. Optionally, the display markers 112 comprise display words and/or display patterns.
It should be noted that the touch keys12 do not necessarily correspond to all of the display positions 111.
Similarly, not all of the display positions 111 comprise necessarily two or
more touch keys12. As a result, it is possible that part of the display positions111 do not develop color over the same time period.
In the specific embodiment of FIG. 7 and FIG. 8, two display markers 112 are coated at each display position 111. The light source module may selectively display light of a first wavelength and light of a second wavelength for respectively displaying the two display markers 112. When the light source module emits the light of the first wavelength, the first display marker 112 develops color and the second display marker 112 is hidden in the same display position111. When the light source module emits the light of the second wavelength, the second display marker 112 develops color and the first display marker 112 is hidden in the same display position111. Specifically, the control interface corresponding to the cooling cup 20 is shown in FIG. 7. And, the control interface corresponding to the heating cup 30 is shown in FIG. 8.
Specifically, the light of the first wavelength may be set as blue light; and the light of the second wavelength may be set as orange light. Taking the chromophore material as an example, when the light source module emits light of long wavelength (orange light) , the display marker 112 made of the orange chromophore material is displayed, and the other parts do not develop color. When the light source module emits light of short wavelength (blue light) , the display marker 112 made of the blue chromophore material is displayed and the other parts do not develop color.
Taking FIG. 5 and FIG. 6 as an example, when orange light is emitted, the touch panel 11 is displayed as shown in FIG. 5, whereina to f are merely for illustrative purpose and may be set according to the actual product, such as "Mix" . When blue light is emitted, the touch panel 11 is displayed as shown in FIG. 6, whereinA to F are merely for illustrative purpose and may be set according to the actual product. When a and A are located in the same position or adjacent to each other, the displayed words are usually different but may also be the same individually.
Optionally, the display markers112 may also be progress display for each
control interface.
In the embodiment shown in FIG. 9, the two display markers 112 in the same display position 111 overlap with each other. Thus, when the light wavelength of the light source module is switched, the two display markers 112 may be switched to develop color.
In the embodiment shown in FIG. 10, the two display markers 112 in the same display position 111 are adjacent to each other. Thus, when the light wavelength of the light source module is switched, the two display markers 112 may be switched to develop color. The benefits of the adjacent setting will reduce the difficulty of coating, but the corresponding occupied size will become larger. The display markers are selected according to the actual needs of the actual product.
In the embodiment not shown, the two display markers 112 in the same display position 111 partially overlap with each other. Thus, when the light wavelength of the light source module is switched, the two display markers 112 may also be switched to develop color.
According to the type of the above cups, there are at least two control programs, comprising a cooling cup mode program, a heating cup mode program and a raw milling cup mode program, wherein the light wavelength of thelight source module is adjusted according to the utensil type signal so as to display the cooling cup mode program, the heating cup mode program and the raw milling cup mode program corresponding thereto. Accordingly, the control unit comprises two or more interface control modules each having different control programs. When different interface control modules are called, the light wavelengths of the light source module are different.
Additionally or alternatively, at least two control interfaces comprise two or three of a cooling cup mode interface, a heating cup mode interface and a raw milling cup mode interface, wherein the light wavelength of the light source module is adjusted according to the utensil type signal so as to display the cooling cup mode interface, the heating cup mode interface and the raw milling
cup mode interface corresponding thereto.
In other words, when the food processor is energized, the type of the cup is determined first, in case of the heating cup 30, the functions of the heating cup are executed during operation; in case of the cooling cup 20, the functions of the heating cup are executed during operation, so that one food processor has two different functions.
Taking a food processor usingthe cooling cup 20 as an example, when the cooling cup 20 is placed on the base 10, the display markers 112 in the display positions 111 of the food processor are displayed to form a cooling cup mode interface. The cooling cup mode interface comprises a number of function options and a number of control options, and a cooling cup icon is turned on under the cooling cup mode interface.
In practice, after the cooling cup mode program is called, the method for controlling an interface display further comprises the steps ofdetermining a cooling-cup operation program of the execution element according to a triggered function option; and determining an operation state of the execution element according to a triggered control option.
Alternatively, the operation state of the execution element comprises one or more of start operation, stop operation, operation time adjustment and power output adjustment.
In the specific embodiment as shown in FIG. 9, a number of the function options comprise one or more of "Soft Fruit" , “Hard Fruit" , "Fruit Shake" , "Fruit and Vegetable Puree" , "Milk Shake" , "Clean" , "Mix” and "Vacuum" , and a number of control options comprise one or more of "Start" , "Cancel" , "+” and "-".
Of course, the cooling cup 20 may also be replaced with a vacuum cup. Or, when the cooling cup 20 is vacuumized, the lid of the cold cup 20 has a light prompt of vacuumizing, and the vacuum icon flickers when vacuumizing.
Taking a food processor usingthe heating cup 30 as an example, when the heating cup 30 is placed on the base 10, the display markers 112 in the
display positions 111 of the food processor are displayed to form a heating cup mode interface. The heating cup mode interface comprises a number of function options and a number of control options, and a heating cup icon is turned on under the heating cup mode interface.
In practice, after the heating cup mode program is called, the method for controlling an interface display further comprises the steps: determining a heating-cup operation program of the execution element according to a triggered function option; and determining an operation state of the execution element according to a triggered control option.
In the specific embodiment as shown in FIG. 10, a number of the function options comprise one or more of "Coarse Grain Paste" , "Soybean Milk" , "Corn Juice" , "Puree" , "Mill" , "Clean" , "Mix” and "Wet Heat" , and a number of the control options comprise one or more of "Start" , "Cancel" , "+” and "—" .
The execution elements in the food processors of different functions are also not the same. In addition, in order to improve the degree of intelligence of the food processor and improve the user satisfaction, the display area 60 is provided with a display screen 60 connected to the control unit. Thus, it is easy for the user to check the current operation condition, understand the operation progress and feel more intuitive by taking the display screen 60 as an output device.
It should be noted that each interface control module has different control programs configured to determine that the display screen 60 can have different display interfaces. Of course, the display interface is not limited to the control interfaces listed above. The display interface may also be a cooking state interface, a cooking guide interface, a start-upwelcome interface or a fault alarm interface, etc.
As can be known from the analysis above, afood processor is mainly classified into a high speed blender and a raw soybean milk maker. Therefore, the following execution elements may be selected specifically according to the functions of the food processor.
The execution element may be a crushing element which is provided in the cup and connected to the control unit. When the corresponding touch key 12 is triggered, the crushing time and/or the crushing speed of the crushing element is controlled by the called control program to perform the corresponding cooking operation. The display screen 60 can display the crushing time and/or the crushing speed of the crushing element. The grains can be milled into powder by the crushing element. Or, the foods, such as fruits, are subject to wall-breaking treatment by mixing to drink fruit juice. The crushing time and the crushing speed are adjusted, so that not only the processing time of the food processor may be controlled, but also the processing effect of the food materials. For example, the degree of fineness of the milled grains may be controlled.
Further, the crushing element comprises amixing cutter oran extrusion crusher 50. Amixing cutter is a crushing element achieving the mixing and cutting functions in the form of blade, such as two-blade cutter, three-blade cutter, four-blade cutter, six-blade cutter, eight-blade cutter, etc., which are the most commonly used for mixing and cutting in a variety of occasions. However, anextrusion crusher 50 is a crushing element achieving the mixing and cutting functions in the form of coordinated static die head and movable die head which are generally used for processing cereals and other solid food materials, such as making soybean milk.
The execution element may also be a heating element which is provided in the base 10 and connected to the control unit. When the corresponding touch key 12 is triggered, the heating time or/and the heating power of the heating element is controlled by the called control program to perform the corresponding cooking operation. The display screen 60 can display the heating time or/and the heating power of the heating element. Taking the raw mill as an example, when the beans are crushed into powder and then heated by the heating element to cook the beans, it is quite convenient for the user to drink the cooked soy milk directly.
The execution element may also be a vacuum-pumping assembly which is provided in the cup and connected to the control unit. When the corresponding touch key 12 is triggered, the vacuum-pumping operation of the vacuum-pumping assembly is controlled by the called control program. The display screen 60 can display the pump-down time or/and the vacuum degree of the vacuum-pumping assembly. In order to ensure that the cup body has a certain degree of vacuum, the cup is vacuumized by the vacuum-pumping assembly, so that the food materials in the cup are not easy to leak out thusimprove the operation reliability of the food processor.
The execution element may also be a spill-proof assembly which is provided on a cup lid or the cup and connected to the control unit. When the corresponding touch key 12 is triggered, the spill-proof operation of the spill-proof assembly is controlled by the called control program. By providing the spill-proof assembly, spill-proof operation can be taken on by the food processor when the liquid level comes into contact with the spill-proof assembly, thus monitoring the operation state of the food processor and avoiding food spilling to result in security incidents or cleaning difficulties.
The execution element may also be an alarm device connected to the control unit. When the corresponding touch key (12) is triggered, the alarm operation of the alarm device is controlled by the called control program. The display screen 60 can display the alarm of the alarm device. The alarm device can alarm the spill of the food materials, or the faults of the electrical component or the improper operation of the user, which not only can remind the user to carry out standard operation, but also can display the fault condition of the food processor, so that the overall operation reliability of the food processor is improved.
The described embodiments are only a part of the embodiments of the present invention without covering all embodiments. All other embodiments obtained by those of ordinary skill in the art based on the embodiments of the present invention without creative efforts shall fall within the protection scope
of the present invention.
It should be noted that the terms used herein are merely for the purpose of describing specific embodiments and are not intended to be limiting of the exemplary embodiments according to the present application. The expression of a singular form used therein includes an expression of a plural form unless otherwise indicated obviously. Additionally, it should also be understood that the terms “comprise” , “comprises” and/or “comprising” when used in this specification, specify the presence of features, steps, operations, devices, components and/or combination thereof.
It should be noted that the terms “first” , “second” and the like in the specification and in the claims of the present application are used for distinguishing between similar elements and not necessarily for describing a sequential or chronological order. It is to be understood that the terms so used are interchangeable under appropriate circumstances and that the embodiments of the present invention described herein are capable of operation in other sequences than described or illustrated herein.
The above are only preferred embodiments of the present invention and are not intended to limit the present invention. For those skilled in the art, various modifications and variations can be made to the present invention. Any modification, equivalent replacement, improvement, etc. made according to the spirit and principle of the present invention shall be regarded as within the protection scope of the present invention.