CN112198337A - Method and device for displaying state of electric equipment, terminal and readable storage medium - Google Patents

Abstract

The application relates to a method, a device, a terminal and a readable storage medium for displaying the state of electric equipment, and relates to the field of smart home. The method comprises the steps of obtaining surge data and voltage data, wherein the surge data comprise the occurrence frequency of a surge phenomenon in a target time period in the electric equipment, and the voltage data comprise the working voltage of the electric equipment; determining the state identifier of the electric equipment according to the surge data and the voltage data; and displaying the state identification in the display screen. By the method for displaying the visual state identification corresponding to the surge data and the voltage data in the display screen after the surge data and the voltage data are obtained, the state identification can be visually embodied in the display screen for the state of the electric equipment, the socket can display the state of the electric equipment in real time in the using process of the electric equipment, a user can also know the state of the socket in real time according to the state identification, and the man-machine interaction efficiency in the state display of the electric equipment is improved.

Description

Method and device for displaying state of electric equipment, terminal and readable storage medium

Technical Field

The application relates to the field of smart home, in particular to a method and a device for displaying states of electric equipment, a terminal and a readable storage medium.

Background

The socket is a power supply device which is installed on a wall surface or a ground surface and supplies power to various household devices or industrial devices. During the use of the socket, it usually operates at a stable voltage, but during its operation, a sudden change in voltage occurs, which is called "surge". The surge phenomenon inevitably affects the service life of the socket.

In the related art, the socket is provided with an alarm device, and after the surge occurs, the socket counts the generated surge and displays the surge in a numerical value form. When the number of times of surge reaches the threshold value of the number of times, the alarm device in the socket gives an alarm to prompt a user that the number of times of surge reaches a certain number of times and the socket needs to be replaced.

However, in the socket of the related art, before the alarm device alarms, the user cannot determine the degree of influence of the generated surge on the socket. When the method is used for prompting, the socket can not accurately prompt the user of the self state, and the human-computer interaction efficiency is low when the state is displayed.

Disclosure of Invention

The application relates to a method, a device, a terminal and a readable storage medium for displaying the state of electric equipment, which can improve the efficiency of man-machine interaction during the display of the state of the electric equipment. The technical scheme comprises the following steps:

in one aspect, a method for displaying a state of a powered device is provided, and the method is applied to a powered device with a display screen, and includes:

the method comprises the steps of obtaining surge data and voltage data, wherein the surge data comprise the occurrence frequency of a surge phenomenon in a target time period in the electric equipment, and the voltage data comprise the working voltage of the electric equipment;

determining a state identifier of the electric equipment according to the surge data and the voltage data, wherein the state identifier is used for indicating the working state of the electric equipment, the state identifier corresponds to a first appearance element and a second appearance element, the first appearance element is determined by the surge data, and the second appearance element is determined by the voltage data;

and displaying the state identification in the display screen.

In another aspect, an apparatus for displaying a status of a powered device is provided, the apparatus including:

the acquisition module is used for acquiring surge data and voltage data, wherein the surge data comprises the occurrence frequency of a surge phenomenon in a target time period in the electric equipment, and the voltage data comprises the working voltage of the electric equipment;

the determining module is used for determining a state identifier of the electric equipment according to the surge data and the voltage data, the state identifier is used for indicating the working state of the electric equipment, the state identifier corresponds to a first appearance element and a second appearance element, the first appearance element is determined by the surge data, and the second appearance element is determined by the voltage data;

and the display module is used for displaying the state identifier in the display screen.

In another aspect, a computer device is provided, which includes a processor and a memory, where at least one instruction, at least one program, a code set, or a set of instructions is stored in the memory, and the at least one instruction, the at least one program, the code set, or the set of instructions is loaded and executed by the processor to implement the method for displaying the state of the electric device as provided in the embodiments of the present application.

In another aspect, a computer-readable storage medium is provided, in which at least one instruction, at least one program, a code set, or a set of instructions is stored, and the at least one instruction, the at least one program, the code set, or the set of instructions is loaded and executed by a processor to implement any one of the above-mentioned methods for displaying a status of a powered device.

In another aspect, a computer program product is provided, which when running on a computer, causes the computer to execute the method for displaying the status of an electric device as described in any of the embodiments of the present application.

The beneficial effect that technical scheme that this application provided brought includes at least:

by the method for displaying the visual state identification corresponding to the surge data and the voltage data in the display screen after the surge data and the voltage data are obtained, the occurrence frequency of the surge phenomenon in the electric equipment and the working voltage can be embodied in the display screen in a visual mode, the socket can display the state identification of the electric equipment in real time in the using process of the electric equipment, a user can also know the state of the socket in real time according to the state identification, and the man-machine interaction efficiency in the state display of the electric equipment is improved.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

FIG. 1 illustrates a circuit logic schematic provided by an exemplary embodiment of the present application;

FIG. 2 is a flow chart illustrating a method for displaying a status of a powered device according to an exemplary embodiment of the present application;

FIG. 3 is a diagram illustrating a state indicator displayed on a display screen according to an exemplary embodiment of the present application;

FIG. 4 is a flow chart illustrating a method for displaying a status of a powered device according to an exemplary embodiment of the present application;

FIG. 5 is a flow chart illustrating a state identifier being switched in a display screen according to an exemplary embodiment of the present application;

FIG. 6 is a flow chart illustrating a method for displaying a status of a powered device according to an exemplary embodiment of the present application;

FIG. 7 is a flow chart illustrating a status indicator switching in a display screen according to an exemplary embodiment of the present application;

FIG. 8 is a flowchart illustrating a method for displaying a status of a powered device according to an exemplary embodiment of the present application;

FIG. 9 is a process diagram illustrating a method for displaying a status of a powered device according to an exemplary embodiment of the present application;

fig. 10 is a block diagram illustrating a configuration of a device for displaying a status of a powered device according to an exemplary embodiment of the present application;

fig. 11 is a block diagram illustrating a configuration of a device for displaying a status of a powered device according to an exemplary embodiment of the present application;

fig. 12 is a schematic structural diagram of a terminal for performing a method for displaying a status of a powered device according to an exemplary embodiment of the present application.

Detailed Description

To make the objects, technical solutions and advantages of the present application more clear, embodiments of the present application will be described in further detail below with reference to the accompanying drawings.

First, the terms referred to in the embodiments of the present application will be briefly described:

surge is a phenomenon that occurs in an electric device and causes a peak current or an overcurrent, which is much larger than a steady-state current, in a circuit of the electric device. Surge phenomena are often represented by intense pulses that occur in the consumer over a short period of time. The reasons for the generation of the surge are various, and include at least one of instant power-on, abnormal circuit and lightning strike on the electric equipment. The surge phenomenon may cause equipment problems such as a capacitor being broken down, a resistance wire being blown, etc. to be generated at a moment using electrical equipment. Even if the problem does not occur instantaneously, the surge phenomenon causes irreversible damage to the electric equipment. In the electric equipment, the frequency of the socket affected by the surge equipment is high, and the socket is usually connected with other electric equipment, and when the socket is connected, the current needs to be suddenly changed, so that the condition of generating the surge phenomenon in the socket is inevitable.

Since the surge phenomenon occurring in the socket is the most common, the present application will be described by taking an electric device as an example of the socket. In addition, the electric devices in the embodiments of the present application also include, but are not limited to, various household electric devices and industrial electric devices.

First, circuit logic of the electric device according to the present application will be described. FIG. 1 illustrates a circuit logic diagram provided by an exemplary embodiment of the present application. Referring to fig. 1, when the power-driven device is powered on, a current first passes through the voltage detection unit 101 to perform real-time voltage detection. After the real-time voltage is determined, the current passes through the detection voltage comparison unit 102 to determine whether voltage adjustment is required, and when the voltage is not required to be adjusted, the voltage flows into the micro control unit 103, the output voltage is converted, and power is supplied to the display screen 104 in the electric equipment. When voltage adjustment is required, voltage adjustment is performed by the voltage stabilizing circuit unit 105 to ensure that the voltage output via the micro control unit is also the rated voltage.

In the process, data in the voltage detection unit and the voltage stabilizing circuit unit are required to be recorded so as to judge the state of the electric equipment according to the data. And the data needs to be displayed on a display screen of the electric equipment. Fig. 2 is a flowchart illustrating a method for displaying a status of a powered device according to an exemplary embodiment of the present application. Taking the application of the method to electric equipment with a display screen as an example for explanation, the method comprises the following steps:

step 201, surge data and voltage data are obtained, wherein the surge data comprise the occurrence frequency of a surge phenomenon in a target time period in the electric equipment, and the voltage data comprise the working voltage of the electric equipment.

In this embodiment, the electric device has a display screen, which may be a liquid crystal display, a Light-Emitting Diode (LED) display, or an Organic Light-Emitting Diode (OLED) display, and the display screen is used for displaying data related to the electric device. In one example, a name identifier of the electric equipment is displayed in the display screen and used for prompting a user of name information of the electric equipment; in another example, a status indicator of the electric equipment is displayed in the display screen for prompting the user of the operating status of the electric equipment.

In this application, an electrical device is taken as an example for description, so in this application, the electrical device is a socket configured with a display screen.

In the embodiment of the present application, the socket includes a circuit, a logic diagram of which is shown in fig. 1, that is, the socket includes a circuit configured with a voltage detection unit, a voltage comparison unit, a voltage stabilizing circuit unit, a micro control unit and a display screen.

The surge data comprises the number of times of surge data of the socket. The frequency can be counted by the voltage comparison unit or the voltage stabilizing circuit unit. The voltage comparison unit is used for measuring the voltage difference between the current time node and the last time node, counting for one time by a method of setting a voltage difference threshold when the voltage difference between the current time node and the last time node is greater than the voltage difference threshold when the surge data is counted by the voltage comparison unit, and indicating that a surge phenomenon occurs in the socket; the voltage stabilizing circuit unit is used for working when the working voltage exceeds the safe voltage range, the voltage is controlled within the safe voltage range, after the voltage stabilizing circuit works once, the voltage stabilizing circuit counts once, and once voltage stabilization is performed on the socket, namely, once surge phenomenon occurs in the socket to indicate that the voltage of the socket exceeds the safe voltage range once.

Optionally, the surge data further includes at least one of a time when a single surge phenomenon occurs, a time interval when two surge phenomena occur, and a maximum voltage generated at the time of a surge.

The voltage data is recorded by the voltage detection unit, and optionally, the voltage data is working voltage carried in the socket in a working state, and the voltage data is data changing in real time in response to actual conditions.

And step 202, determining the state identification of the electric equipment according to the surge data and the voltage data.

The surge phenomenon can cause irreversible damage to the electric equipment, so that the electric equipment is not used after the surge phenomenon is specified to generate certain times in actual conditions. In one example, a value of the number of times of occurrence of surge data causing damage to the electric device is determined as a threshold number of times of surge.

Illustratively, the voltage data may be indicative of a voltage range over which the operating voltage is present. In one example, the operating voltage is in a voltage range that includes 210V-215V (excluding 215V), 215V-220V (excluding 220V), 220V-225V (excluding 225V), and 225V-230V (excluding 230V). According to the magnitude of the working voltage, the voltage range where the current voltage is located can be determined, and then the subsequent process of the electric equipment is executed.

The status indicator is used to indicate an operating status of the powered device, and in one example, the operating status of the powered device is a status of the powered device when the powered device receives the number of surges and the detection of the voltage level. The state indicator corresponds to a first appearance element and a second appearance element, the first appearance element is determined by the surge data, and the second appearance element is determined by the voltage data.

Appearance elements are elements that determine the visualization state of the state indicator. In this application, the appearance elements include at least one of fill content, shape, position in the display screen.

The first appearance element and the second appearance element are used for reflecting the state of the socket from different dimensions. In one example, the first appearance element is determined by surge data, reflecting the degree of wear of the outlet; the second appearance element is determined by the voltage data, reflecting the real-time voltage of the socket. In another example, the first appearance element is determined by the voltage data, reflecting the real-time voltage of the outlet, and the second appearance element is determined by the surge data, reflecting the degree of wear of the outlet. The first appearance element and the second appearance element are not limited to the content of the reflection of the current state of the socket. In the embodiment of the present application, the first appearance element is determined from surge data, and the second appearance element is determined from voltage data.

As described above, the appearance elements include at least one of fill content, shape, and position in the display screen. The filling content corresponding to the state identifier comprises at least one of filling color, filling characters and filling effect, and the combination of at least two contents. In one example, the filling content is a filling color, and the filling color comprises three colors of yellow, orange and red; in another example, the filling content is filling characters, and the filling characters comprise three types of 'socket safety', 'socket has potential safety hazard' and 'socket is damaged'; in another example, the filling content is a filling effect, and the filling effect includes three types, namely a circular array filling effect, a square array filling effect and a triangular array tiling effect.

The shapes corresponding to the state identifiers comprise different shapes of the same type, or different shapes. In one example, the shape corresponding to the state identifier includes a rectangle, a square, a circle; in another example, the shape corresponding to the state indicator includes three rectangles with the same width and different lengths.

Step 203, displaying the state identifier in the display screen.

As described above, the surge data is used to determine the filling content of the status indicator, and the voltage data is used to determine the shape of the first indicator. Referring to fig. 3, in the example shown in fig. 3, the status indicators displayed in the display screen correspond to three filling contents, namely light blue, dark blue and purple. Wherein, the socket is instructed to light blue safe, dark blue and instructs the socket to have the potential safety hazard, purple indicates that the socket has damaged. Meanwhile, the state labels correspond to three shapes, i.e., a rectangle of 50 pixels by 100 pixels, a rectangle of 50 pixels by 200 pixels, and a rectangle of 50 pixels by 300 pixels. Wherein the rectangle of 50 pixels by 100 pixels indicates an operating voltage in the range of 210V-220V, the rectangle of 50 pixels by 200 pixels indicates an operating voltage in the range of 220V-225V (excluding 220V), and the rectangle of 50 pixels by 300 pixels indicates an operating voltage in the range of 225V-230V (excluding 225V). In the status indicator 310 displayed on the display panel 300, the corresponding first filling content is dark blue, and the corresponding first shape is a rectangle with 50 pixels by 200 pixels. The status flag 310 indicates that the socket is a safety hazard and that the operating voltage is in the range of 220V-225V (excluding 220V).

Optionally, the status indicator is displayed in a status display area of the display screen, or the status indicator occupies the entire display screen.

In summary, according to the method provided in this embodiment, after the surge data and the voltage data are obtained, the visual status identifier corresponding to the surge data and the voltage data is displayed in the display screen, the number of times of occurrence of the surge phenomenon in the electric device and the working voltage can be visually embodied in the display screen, during the use of the electric device, the socket can display the status identifier of the electric device in real time, and the user can also know the status of the socket in real time according to the status identifier, so that the efficiency of human-computer interaction during the status display of the electric device is improved.

In one embodiment of the present application, the first appearance element is a fill of the state indicator, the second appearance element is a shape of the state indicator, and the first appearance element is determined by the surge data and the second appearance element is determined by the voltage data. Under the condition that the shape of the state identifier is not changed, when surge data of the electric equipment is changed, filling content of the state identifier in a display screen of the electric equipment is correspondingly changed. Fig. 4 shows a flowchart of a method for displaying a status of a powered device according to an exemplary embodiment of the present application, where the process may alternatively be implemented after step 203, and the method includes:

step 401, in response to the number of times that the surge data indicates that the surge phenomenon does not reach the first number threshold, displaying a status identifier, where the status identifier corresponds to the first filling content.

The first number threshold is a number threshold preset in the terminal. Since the number of occurrences of the surge phenomenon is statistical data that monotonically increases, the phrase "the number of occurrences of the surge phenomenon reaches the first number threshold" means when the number of occurrences of the surge phenomenon reaches the first number threshold from a number smaller than the first number threshold. The process can intuitively reflect the increase of the number of times of the surge phenomenon.

The state identifier corresponds to one type of the filler content when the surge data does not reach the first quantity threshold, and corresponds to another type of the filler content when the surge data reaches the first quantity threshold. In one example, the fill content is a fill color.

And 402, responding to the number of times that the surge data indicate the surge phenomenon reaches a first quantity threshold value, and displaying a state identifier, wherein the state identifier corresponds to second filling content.

In one example, when the number of times of occurrence of the surge phenomenon in the socket does not reach 30 times, the corresponding loss state is a safe state; when the number of surging phenomena in the socket reaches 30 times and is less than 50 times, the corresponding loss state is a light loss state; when the occurrence frequency of the surge phenomenon reaches 50 times and is less than 100 times, the corresponding loss state is a medium loss state; when the occurrence frequency of the surge phenomenon reaches 100 times, the corresponding loss state is a severe loss state. Meanwhile, the filling color corresponding to the installation state is blue, the filling color corresponding to the light loss state is yellow, the filling color corresponding to the medium loss state is orange, and the filling color corresponding to the heavy loss state is red.

In the embodiment of the application, at least two thresholds are set for the number of times of occurrence of the surge phenomenon. Wherein the first quantity threshold is a quantity threshold indicating that the loss of the electric equipment is increased due to the surge phenomenon. In one example, the first number threshold is set to be 30 times, 50 times, and 100 times, respectively, of the occurrence of the surge phenomenon.

And 403, in response to the number of times that the surge data indicate the surge phenomenon reaches a second number threshold, displaying an alarm identifier in a flashing mode, wherein the second number threshold is larger than the first number threshold.

As mentioned above, the number of occurrence of the surge phenomenon is statistical data that monotonically increases, so the second number threshold is greater than all the first number thresholds, and at this time, it is determined that the electric equipment is damaged due to the surge phenomenon, that is, it is indicated that the degree of loss of the electric equipment is large, and the equipment needs to be replaced.

Alternatively, the electric device may pre-store a multiple relationship between the second quantity threshold and the first quantity threshold, and perform setting of the second quantity threshold by the user to determine the first quantity threshold. In one example, the second number threshold is set to be n in the electric device, the three first number thresholds are respectively n/10, n/6 and n/3, and when the user sets the second number threshold to be 300, the first number thresholds are respectively 30, 50 and 100.

The alarm tag is a tag corresponding to the alarm fill content and the alarm shape. Optionally, the alarm flag is different from any of the state flags. In one example, the fill content of the alarm banner is a combination of red and "warning" characters, and the alarm shape is a warning light shape.

Fig. 5 is a schematic diagram illustrating a process of a status indicator on a display screen changing due to a loss status according to an exemplary embodiment of the present application. Referring to fig. 5, in the example shown in fig. 5, the voltage state is unchanged, and the shape of the state indicator in the display screen 500 is always a rectangle of 50 pixels by 100 pixels. The filling content is filling characters. The second quantity threshold is 300 and the first quantity threshold is 30, 50 and 100.

When the number of times of occurrence of the surge phenomenon is less than 30, the corresponding filling content is 'socket safety', and a state identifier 501 is displayed in the display screen 500;

when the number of times of occurrence of the surge phenomenon reaches 30 times and is less than 50 times, the state identifier in the display screen is switched, the corresponding filling content is 'socket slight damage', and the state identifier 502 is displayed;

when the number of times of surging phenomenon reaches 50 times and is less than 100 times, the state mark in the display screen is switched, the corresponding filling content is 'moderate damage of socket', and the state mark 503 is displayed;

when the surge phenomenon occurs for 100 times and less than 300 times, the state identifier in the display screen is switched, the corresponding filling content is 'socket severe damage', and the state identifier 504 is displayed;

when the number of times of surging phenomenon reaches 300, the state mark in the display screen is switched to an alarm mark 505, the filling content corresponding to the alarm mark 505 is 'warning', and the warning mark is displayed in the shape of an alarm lamp, and meanwhile, the flashing display is carried out. The alarm flag 505 is used to prompt the user to switch the socket in time.

In summary, according to the method provided by this embodiment, under the condition that the voltage is not changed, through setting the first number threshold, the electric device can determine the loss condition of the electric device according to the number threshold, and the loss condition of the electric device is reflected on the display screen in a manner of different filling contents, so that the user can know the loss condition of the electric device, and the human-computer interaction efficiency of the electric device is further improved.

Through the setting of the second quantity threshold value, when the surge phenomenon of the electric equipment occurs for too many times, the warning mark is displayed, the user is requested to replace the electric equipment as soon as possible in an obvious prompting mode, and the human-computer interaction efficiency of the electric equipment is further improved.

In another embodiment of the present application, in a case that the surge data is not changed and the voltage data is changed, a second appearance element in a display screen of the electrical device, that is, a shape of the status indicator is changed correspondingly, fig. 6 shows a flowchart of a status display method for the electrical device according to an exemplary embodiment of the present application, where the process may alternatively be implemented after step 204, and the method includes:

step 601, responding to the voltage data indicating that the working voltage belongs to the first voltage range, displaying a state identifier, wherein the state identifier corresponds to the first shape.

The voltage range is a continuous range, or the voltage range is a discontinuous range. In one example, the voltage range may be 215V-220V; in another example, the voltage ranges may be 215V-220V, and 225V-230V. In this embodiment, the voltage range is described as a continuous range.

Each voltage range corresponds to a shape when the operating voltage is in a different voltage range. In one example, when the voltage in the socket is 210V-215V (excluding 215V), the corresponding shape is a rectangle of 50 pixels by 50 pixels; when the voltage in the socket is 215V-220V (excluding 220V), the corresponding shape is a rectangle of 50 pixels by 100 pixels; when the voltage in the socket is 220V-225V (excluding 225V), the corresponding shape is a rectangle of 50 pixels by 150 pixels; when the voltage in the socket is 225V-230V, the corresponding shape is a rectangle of 50 pixels by 200 pixels.

Step 602, in response to the voltage data indicating that the operating voltage does not belong to the first voltage range and belongs to the safe voltage range, displaying a status indicator, the status indicator corresponding to the second shape.

Optionally, the safe voltage range is a combination of voltage ranges corresponding to all voltage states. When the voltage of the socket is within the safe voltage range, the socket can normally work.

Since the loss state is unchanged in this embodiment, that is, the filling content of the state identifier is unchanged, at this time, when the operating voltage does not belong to the first voltage range and falls into another voltage range within the safe voltage range, the shape corresponding to the state identifier is displayed on the display screen.

Step 603, adjusting the working voltage to a rated working voltage in response to the voltage data indicating that the working voltage does not belong to the safe voltage range.

When the socket voltage is not within the safe voltage range, the socket cannot normally work and needs to be adjusted, and under the condition, the voltage is adjusted to be the rated working voltage preset in the socket.

And step 604, displaying the state identifier, wherein the state identifier corresponds to a rated shape.

Optionally, since the rated voltage is within the safe voltage range, the rated voltage shape corresponding to the rated voltage belongs to the second shape. In one example, the nominal voltage is 220V, and the shape corresponding to the nominal voltage is a rectangle of 50 pixels by 150 pixels when the voltage in the socket is 220V-225V (excluding 225V). In another example, the nominal shape is a predetermined shape corresponding to the nominal operating voltage.

Fig. 7 is a schematic diagram illustrating a process of a state indicator on a display screen changing due to a voltage state being entangled with the change according to an exemplary embodiment of the present application. Referring to fig. 7, in the example shown in fig. 7, the wear state is unchanged, and the fill content of the state indicator within the display screen 700 is color and always black. The safe voltage range is 215V-230V, and different voltage states in the safe voltage range respectively represent the state that the working voltage is 215V-220V (excluding 220V), the state that the working voltage is 220V-225V (excluding 225V) and the state that the working voltage is 225V-230V (excluding 230V). The initial voltage is 217V and the nominal voltage is 220V.

When the voltage is the initial voltage, 217V, the corresponding state is indicated by a rectangle 701 of 50 pixels by 100 pixels.

When the voltage increases to the range of 220V-225V (excluding 225V), the corresponding state indicator is switched to the rectangular indicator 702 of 50 pixels by 150 pixels.

When the voltage increases to the range of 225V-230V (excluding 230V), the corresponding state indicator is switched to the rectangular indicator 703 of 50 pixels by 200 pixels.

When the voltage increases to over 230V, the socket is stabilized, after the voltage is stabilized, the voltage is restored to 220V, and the corresponding state mark is switched to the rectangular mark 702 of 50 pixels by 150 pixels.

In summary, the method provided in this embodiment sets different shapes corresponding to different voltage states, and displays the voltage states through the shapes of the state identifiers, so that a user can know the voltage states of the socket according to the shapes of the state identifiers, thereby further improving the efficiency of human-computer interaction.

Through the setting to safe voltage range, carry out steady voltage operation when the voltage is not in safe voltage range, improved the security of socket use.

Fig. 8 is a flowchart illustrating a method for displaying a status of an electrical device according to an exemplary embodiment of the present application, which is described by way of example as being applied to an electrical device, and the method includes:

step 801, recording the occurrence frequency of the surge phenomenon through a surge counting module.

In the circuit inside the socket, the surge counting module is used for recording the occurrence frequency of the surge phenomenon inside the socket. Optionally, the surge counting module is disposed in a voltage stabilizing circuit unit inside the socket circuit, or the surge counting module is disposed in a detected voltage comparing unit inside the socket circuit.

And step 802, generating surge data according to the occurrence frequency of the surge phenomenon recorded by the surge counting module.

As described above, the surge data includes the number of occurrences of the surge phenomenon. Optionally, the surge data further includes at least one of the occurrence time of the surge phenomenon, the duration of the surge phenomenon, and the intensity of the surge phenomenon.

Step 803, determining a first appearance element of the state indicator according to the surge data.

In this embodiment, the first appearance element is the filling content of the state identifier.

Optionally, the display screen has a filler selection control, and in response to receiving a filler selection signal generated by the filler selection control, the display screen determines the type of filler and thus the first filler.

And step 804, detecting the working voltage in the electric equipment through a voltage detection module.

In the embodiment of the present application, steps 801 to 804 are performed simultaneously with steps 805 to 808, so as to obtain the number of times of occurrence of the surge phenomenon of the socket and the operating voltage of the socket at the same time.

The voltage detection module is arranged in a voltage detection unit in the socket circuit.

Step 805, generating voltage data according to the working voltage recorded in the voltage detection module.

As mentioned above, the voltage data includes the operating voltage. Optionally, at least one of a rated voltage, a safe voltage range, a peak voltage and a valley voltage is also included in the voltage data.

At step 806, a second appearance element of the state identification is determined from the voltage data.

Optionally, the display screen has a shape selection control, and in response to receiving a shape selection signal generated by the shape selection space, the display screen determines a type of a shape corresponding to the state identifier, and further determines a first shape of the state identifier.

Step 807, a status indicator is displayed, the status indicator having a first appearance element and a second appearance element.

In the embodiment of the present application, the first appearance element is the filling content, and the second appearance element is the shape.

In the embodiment, the state flag indicates that the operating voltage of the electric equipment is in a first voltage range, and the number of times of occurrence of the surge phenomenon does not reach a first count threshold.

After the first filling content and the first shape corresponding to the state identifier are determined, the state identifier is displayed under the condition that the socket is powered on.

Optionally, after the socket is powered on and starts to work, the first filling content is determined by the number of surges at the initial moment of power-on, and the first shape is determined by the voltage at the initial moment of power-on, so as to display the state identifier.

And 808, responding to the number of times that the surge data indicate the surge phenomenon reaches a first quantity threshold value, and displaying a state identifier, wherein the state identifier corresponds to second filling content.

As described above, the number of times of occurrence of the surge phenomenon may only monotonically increase, so that when the number of times of occurrence of the surge phenomenon reaches any one of the plurality of first number thresholds, the electric device switches the status indicator according to the first number threshold, and the status indicator corresponds to the second filling content.

Step 809, in response to the surge data indicating that the number of times of surge events reaches a second number threshold, displaying an alarm indication in a flashing manner.

When the number of times of occurrence of surge phenomenon reaches the second number threshold, it is determined that the work efficiency of the socket receives a serious impression because the number of times of occurrence of surge is too large, and at this moment, an alarm mark is displayed to indicate that the socket needs to be replaced urgently.

In this embodiment, still include sound production module in the circuit of socket, appear when the alarm sign to when scintillation shows, sound production module sends the police dispatch newspaper sound simultaneously, in order to carry out the suggestion that the socket needs to be changed.

Step 810, responding to the voltage data indicating that the working voltage does not belong to the first voltage range and belongs to the safe voltage range, displaying a state identifier, wherein the state identifier corresponds to a second shape.

And when the voltage data indicate that the working voltage of the electric equipment exceeds the voltage range where the original voltage is positioned and enters other voltage ranges, displaying the corresponding state identifier in the second shape.

Optionally, steps 810 to 812 are executed synchronously with steps 808 to 809, that is, in this embodiment, the filling content and the shape of the state identifier may be switched without affecting each other.

And when the voltage data indicate that the working voltage of the electric equipment exceeds the voltage range where the original voltage is positioned and enters other voltage ranges, determining a second voltage range corresponding to the voltage, and determining a second voltage state according to the second voltage range.

In one example, when the status indicator in the display screen is switched to the alarm indicator, it is displayed in the shape of the alarm indicator and the filling status of the alarm indicator, and at this time, the shape of the alarm status will not change even if the voltage changes.

Step 811, in response to the voltage data indicating that the operating voltage does not fall within the safe voltage range, adjusting the operating voltage to the rated operating voltage.

The rated voltage is a standard operating voltage set when the socket is shipped, and in a daily use state, the rated voltage should be 220V, so in this embodiment, the rated voltage is also set to be 220V.

And step 812, displaying a state identifier, wherein the state identifier corresponds to a rated shape.

In this embodiment, the shape of the rated voltage is the rated shape of the status indicator corresponding to the voltage range in which the voltage of 220V is located. After the voltage is stabilized in the circuit and the voltage is stabilized to the rated voltage, namely 220V, the shape of the state mark is switched to the shape of the state mark corresponding to the rated voltage.

In the present embodiment, the voltage stabilization of the circuit, that is, the counting of the occurrence of the surge phenomenon is performed every time.

In summary, according to the method provided in this embodiment, after the surge data and the voltage data are acquired, the visual status identifier corresponding to the surge data and the voltage data is displayed in the display screen, so that the status identifier can be visually represented in the display screen for the status of the electrical equipment.

Through the setting of the first quantity threshold, the electric equipment can determine the loss state of the electric equipment according to the quantity threshold, and the loss state of the electric equipment is reflected on the display screen in different filling content modes, so that a user can know the loss state, and the human-computer interaction efficiency of the electric equipment is further improved.

Through the setting of the second quantity threshold value, when the surge phenomenon of the electric equipment occurs for too many times, the warning mark is displayed, the user is requested to replace the electric equipment as soon as possible in an obvious prompting mode, and the human-computer interaction efficiency of the electric equipment is further improved.

Different shapes are set corresponding to different voltage states and are displayed through the shapes of the state marks, so that a user can know the voltage state of the socket according to the shapes of the state marks, and the human-computer interaction efficiency is further improved.

Through the setting to safe voltage range, carry out steady voltage operation when the voltage is not in safe voltage range, improved the security of socket use.

The accuracy of data acquisition is improved by respectively acquiring voltage data and surge data from different modules in the circuit.

Fig. 9 is a process diagram illustrating a method for displaying a status of an electrical device according to an exemplary embodiment of the present application, which is described by way of example as being applied to an electrical device, and the method includes:

step 901 begins.

The process is the starting process of the electric equipment. When the electric equipment is realized as a socket, the process is the process that the socket is electrified and enters a use state.

Step 902, detect an input voltage.

The process is a process of detecting the power utilization voltage through a voltage detection module in the voltage detection unit.

Step 903, judging whether the voltage is in the interval of 210V-230V.

This process is a process of detecting whether the input voltage is within the safe voltage range. In the present embodiment, the safe voltage range is 210V-230V.

When the voltage is between 210V and 230V, step 904 is executed, and when the voltage is not between 210V and 230V, step 912 is executed.

In step 904, it is determined whether the voltage is greater than or equal to 210V and less than 215V.

In the actual operation process, the specific magnitude of the voltage can be directly obtained through the voltage detection module, and in the embodiment, after the specific magnitude of the voltage is obtained, the specific magnitude of the voltage is still compared with a plurality of voltage ranges one by one so as to determine which voltage range the working voltage is in.

When the voltage is greater than or equal to 210V and less than 215V, step 905 is executed, and when the voltage is not within the voltage range, step 906 is executed.

Step 905, the energy bar displays 1 grid.

This step determines the shape of the status indicator corresponding to the socket status as the shape displaying the 1-grid energy bar.

In step 906, it is determined whether the voltage is greater than or equal to 215V and less than 220V.

When the voltage is equal to or greater than 215V and less than 220V, step 907 is executed, and when the voltage is not within the voltage range, step 908 is executed.

In step 907, the energy bar displays 2 cells.

This step determines the shape of the status indicator corresponding to the socket status as the shape displaying the 2-grid energy bar.

Step 908, determine if the voltage is greater than or equal to 220V and less than 225V.

When the voltage is greater than or equal to 220V and less than 224V, step 909 is executed, and when the voltage is not within the voltage range, step 910 is executed.

At step 909, the energy bar displays 3 cells.

This step determines the shape of the status indicator corresponding to the socket status as the shape displaying the 3 energy bars.

In step 910, it is determined whether the voltage is greater than or equal to 225V and less than 230V.

When the voltage is greater than or equal to 225V and less than 230V, step 909 is executed, and when the voltage is not within the voltage range, step 910 is executed.

At step 911, the energy bar displays 4 cells.

This step determines the shape of the status indicator corresponding to the socket status as the shape displaying the 4 energy bars.

And step 912, stabilizing the pressure to 220V.

This process is a process of stabilizing voltage inside the circuit to stabilize the voltage of the socket to the rated voltage, i.e. 220V. The process is mainly controlled and executed by a control circuit in the socket.

At step 913, the energy bar displays 3 cells.

The number of energy bars corresponding to the 220V voltage is 3, so the shape of the state mark is changed accordingly.

Step 914, record a voltage stabilizing action.

When the input voltage is not in the safe voltage range, the generation of a surge phenomenon is indicated, and at the moment, the voltage stabilizing action is recorded so as to count the generation of the surge phenomenon.

Step 915, detect the input voltage.

This process is a verification process for the input voltage.

In step 916, it is determined whether the number of times is equal to or less than 1/10 n.

In the actual operation process, the occurrence frequency of the surge phenomenon can be directly obtained through the surge counting module and then sequentially compared with each first time threshold value.

When the number of times is 1/10n or less, go to step 917; when the number of times is greater than 1/10n, step 918 is performed.

In step 917, the energy bar displays green.

This step determines that the filling content of the status indicator corresponding to the socket status is colored and displayed green.

In step 918, it is determined whether the number of times is greater than 1/10n and less than or equal to 5/10 n.

When the number of times is greater than 1/10n and less than 5/10n, perform step 919; when the number of times is not within the range, step 920 is performed.

In step 919, the energy bar appears blue.

This step determines that the filling content of the status indicator corresponding to the socket status is colored and displayed as blue.

In step 920, it is determined whether the number of times is greater than 5/10n and less than or equal to 9/10 n.

When the number of times is greater than 5/10n and less than 9/10n, perform step 921; when the number of times is not within the range, step 922 is performed.

At step 921, the energy bar displays yellow.

This step determines that the filling content of the status indicator corresponding to the socket status is colored and displayed yellow.

In step 922, it is determined whether the number of times is greater than 9/10n and less than or equal to n.

When the number of times is greater than 9/10n and less than n, execute step 923; when the number of times is not within the range, step 924 is performed.

At step 923, the energy bar displays red.

This step determines that the filling content of the status indicator corresponding to the socket status is colored and displayed in red.

Step 924, determine whether the number of times is greater than n.

The step is a process of judging whether the occurrence frequency of the surge phenomenon reaches a second frequency threshold value.

And step 925, alarming to prompt replacement.

And when the occurrence frequency of the surge phenomenon reaches a second frequency threshold value, carrying out alarm prompt, wherein the alarm prompt is used for prompting a user to replace the socket.

In summary, according to the method provided in this embodiment, after the surge data and the voltage data are acquired, the visual status identifier corresponding to the surge data and the voltage data is displayed in the display screen, so that the status identifier can be visually represented in the display screen for the status of the electrical equipment.

Fig. 10 is a block diagram illustrating a structure of an apparatus for displaying a status of a powered device according to an exemplary embodiment of the present application, where the apparatus includes:

the acquisition module 1001 is configured to acquire surge data and voltage data, where the surge data includes the number of times of occurrence of a surge phenomenon in a target time period in an electric device, and the voltage data includes a working voltage of the electric device;

the determining module 1002 is configured to determine a state identifier of the electrical device according to the surge data and the voltage data, where the state identifier is used to indicate a working state of the electrical device, and the state identifier corresponds to a first appearance element and a second appearance element, where the first appearance element is determined by the surge data and the second appearance element is determined by the voltage data;

and a display module 1003, configured to display the status identifier in a display screen.

In an alternative embodiment, the first appearance element is a fill content of the state identification;

the display module 1003 is further configured to display a status identifier in response to that the number of times that the surge data indicates that the surge phenomenon does not reach the first number threshold, where the status identifier corresponds to the first filling content;

and responding to the number of times that the surge data indicate the surge phenomenon reaches a first quantity threshold value, and displaying a state identifier, wherein the state identifier corresponds to the second filling content.

In an optional embodiment, the apparatus further comprises a display module 1003, and is further configured to display an alarm identifier in a flashing manner in response to the surge data indicating that the number of surge events reaches a second number threshold, where the second number threshold is greater than the first number threshold.

In an optional embodiment, the electric equipment corresponds to a safe voltage range, and the second appearance element is in the shape of the state identifier;

the display module 1003 is further configured to display a status identifier in response to the voltage data indicating that the operating voltage belongs to the first voltage range, where the status identifier corresponds to the first shape;

in response to the voltage data indicating that the operating voltage does not fall within the first voltage range and falls within the safe voltage range, displaying a status indicator, the status indicator corresponding to the second shape.

In an alternative embodiment, as shown in fig. 11, the electric device corresponds to a safe voltage range and a rated operating voltage, and the apparatus further includes an adjusting module 1004 for adjusting the operating voltage to the rated operating voltage in response to the voltage data indicating that the operating voltage does not belong to the safe voltage range;

and the display module 1003 is used for displaying a state identifier, wherein the state identifier corresponds to a rated shape, and the rated shape is a preset shape corresponding to a rated working voltage.

In an optional embodiment, the electric equipment further comprises a voltage detection module and a surge counting module;

the device also comprises a recording module 1005 for recording the occurrence frequency of the surge phenomenon through a surge counting module and detecting the working voltage in the electric equipment through a voltage detection module;

and the generation module 1006 is used for generating surge data according to the number of times of occurrence of the surge phenomenon recorded by the surge counting module, and generating voltage data according to the working voltage recorded in the voltage detection module.

In an alternative embodiment, the filling content of the status indicator includes at least one of filling color, filling text and filling effect.

According to the device provided by the embodiment, after the surge data and the voltage data are obtained, the visual state identification corresponding to the surge data and the voltage data is displayed in the display screen, the occurrence frequency of the surge phenomenon in the electric equipment and the working voltage can be embodied in the display screen in a visual mode, in the using process of the electric equipment, the socket can display the state identification of the electric equipment in real time, a user can also know the state of the socket in real time according to the state identification, and the man-machine interaction efficiency in the state display of the electric equipment is improved.

It should be noted that: the state display device of the electrical equipment provided in the above embodiment is only exemplified by the division of the above functional modules, and in practical applications, the above function distribution may be completed by different functional modules according to needs, that is, the internal structure of the equipment is divided into different functional modules to complete all or part of the above description.

Fig. 12 is a schematic structural diagram illustrating a terminal for performing a method for displaying a status of a powered device according to an exemplary embodiment of the present application, where the terminal includes:

the processor 1201 includes one or more processing cores, and the processor 1201 executes various functional applications and data processing by executing software programs and modules.

The receiver 1202 and the transmitter 1203 may be implemented as one communication component, which may be a communication chip. Optionally, the communication component may implement a communication connection between any two computer devices in the data synchronization system of the intelligent door lock. That is, the transmitter 1203 may be configured to transmit communication network signals and the receiver 1202 may be configured to receive communication network signals.

The memory 1204 is coupled to the processor 1201 via a bus 1205.

The memory 1204 may be used for storing at least one instruction for execution by the processor 1201 to perform the various steps in the above-described method embodiments. The embodiment of the present application further provides a computer-readable storage medium, where at least one instruction, at least one program, a code set, or a set of instructions is stored in the computer-readable storage medium, and the at least one instruction, the at least one program, the code set, or the set of instructions is loaded and executed by a processor to implement the above-mentioned method for displaying the state of the electric device.

The embodiment of the present application further provides a computer program product, which when running on a computer, causes the computer to execute the method for displaying the state of the electrical device provided in the above method embodiments.

Those skilled in the art will appreciate that all or part of the steps in the methods of the above embodiments may be implemented by hardware related to instructions of a program, which may be stored in a computer readable storage medium, which may be a computer readable storage medium contained in a memory of the above embodiments; or it may be a separate computer-readable storage medium not incorporated in the terminal. The computer readable storage medium stores at least one instruction, at least one program, a set of codes, or a set of instructions, which is loaded and executed by a processor to implement the above-mentioned method for displaying the status of a powered device.

Optionally, the computer-readable storage medium may include: a Read Only Memory (ROM), a Random Access Memory (RAM), a Solid State Drive (SSD), or an optical disc. The Random Access Memory may include a resistive Random Access Memory (ReRAM) and a Dynamic Random Access Memory (DRAM). The above-mentioned serial numbers of the embodiments of the present application are merely for description and do not represent the merits of the embodiments.

It will be understood by those skilled in the art that all or part of the steps of implementing the above embodiments may be implemented by hardware, or may be implemented by a program instructing relevant hardware, and the program may be stored in a computer-readable storage medium, and the above-mentioned storage medium may be a read-only memory, a magnetic disk or an optical disk, etc.

The above description is only exemplary of the present application and should not be taken as limiting, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (10)

1. A method for displaying the state of a powered device, wherein the method is applied to a powered device with a display screen, and the method comprises the following steps:

the method comprises the steps of obtaining surge data and voltage data, wherein the surge data comprise the occurrence frequency of a surge phenomenon in a target time period in the electric equipment, and the voltage data comprise the working voltage of the electric equipment;

determining a state identifier of the electric equipment according to the surge data and the voltage data, wherein the state identifier is used for indicating the working state of the electric equipment, the state identifier corresponds to a first appearance element and a second appearance element, the first appearance element is determined by the surge data, and the second appearance element is determined by the voltage data;

and displaying the state identification in the display screen.

2. The method of claim 1, wherein the first appearance element is a fill content of the state identifier;

the displaying the state identifier in the display screen includes:

responding to the surge data to indicate that the number of times of the surge phenomenon does not reach a first quantity threshold value, and displaying the state identification, wherein the state identification corresponds to first filling content;

and responding to the number of times that the surge data indicate the surge phenomenon reaches the first quantity threshold value, and displaying the state identification, wherein the state identification corresponds to second filling content.

3. The method of claim 2, further comprising:

in response to the surge data indicating that the number of times the surge phenomenon reaches a second number threshold, displaying an alarm indication in a blinking manner, the second number threshold being greater than the first number threshold.

4. The method of claim 1, wherein the powered device corresponds to a safe voltage range, and wherein the second appearance element is in the shape of the status indicator;

the displaying the state identifier in a display screen includes:

in response to the voltage data indicating that the operating voltage belongs to a first voltage range, displaying the status indicator, the status indicator corresponding to a first shape;

in response to the voltage data indicating that the operating voltage does not belong to a first voltage range and belongs to the safe voltage range, displaying the status indicator, the status indicator corresponding to a second shape.

5. The method of claim 4, wherein the powered device corresponds to a safe voltage range and a rated operating voltage, the method further comprising:

adjusting the operating voltage to the nominal operating voltage in response to the voltage data indicating that the operating voltage does not fall within the safe voltage range;

and displaying the state identification, wherein the state identification corresponds to a rated shape, and the rated shape is a preset shape corresponding to the rated working voltage.

6. The method according to any one of claims 1 to 5, wherein the electric device further comprises a voltage detection module and a surge counting module;

the acquiring surge data and voltage data comprises:

recording the occurrence frequency of the surge phenomenon through the surge counting module, and detecting the working voltage in the electric equipment through the voltage detection module;

and generating the surge data according to the occurrence frequency of the surge phenomenon recorded by the surge counting module, and generating the voltage data according to the working voltage recorded by the voltage detection module.

7. The method of claim 2, wherein the filling content of the status indicator comprises at least one of filling color, filling text and filling effect.

8. An apparatus for displaying a status of a powered device, the apparatus comprising:

the device comprises an acquisition module, a storage module and a processing module, wherein the acquisition module is used for acquiring surge data and voltage data, the surge data comprises the occurrence frequency of a surge phenomenon in a target time period in the electric equipment, and the voltage data comprises the working voltage of the electric equipment;

a determining module, configured to determine a status identifier of the electrical device according to the surge data and the voltage data, where the status identifier is used to indicate an operating status of the electrical device, and the status identifier corresponds to a first appearance element and a second appearance element, where the first appearance element is determined by the surge data and the second appearance element is determined by the voltage data;

and the display module is used for displaying the state identifier in the display screen.

9. A terminal, comprising a processor and a memory, wherein the memory stores at least one instruction, at least one program, a set of codes, or a set of instructions, and the at least one instruction, at least one program, a set of codes, or a set of instructions is loaded and executed by the processor to implement the method for displaying the status of the electric device according to any one of claims 1 to 7.

10. A computer-readable storage medium, wherein at least one instruction, at least one program, a set of codes, or a set of instructions is stored in the computer-readable storage medium, and the at least one instruction, at least one program, a set of codes, or a set of instructions is loaded and executed by a processor to implement the method for displaying the status of the electric device according to any one of claims 1 to 7.

Images