CN108444206B - Self-control intelligent refrigerator system based on time simulation - Google Patents

Abstract

The invention relates to a self-control intelligent refrigerator system based on time simulation, which comprises: the food preparation system comprises a space module, a time module, a processing module and a control module, wherein the space module provides a food storage space and a temporary storage space, the time module obtains the preparation time and the step-by-step preparation time of food, the method comprises the steps of recording the using time of a refrigerator, taking the preparation time and the step preparation time as time intervals, taking the using time of the refrigerator as time scales, confirming the formal using time of food materials by a processing module according to the using time, confirming the time scales for starting preparation of the food materials by the processing module according to the formal using time of the food materials, the preparation time of the food materials and the step preparation time, confirming the time scales for the step preparation time by the processing module according to the step preparation time and the time scales for starting preparation of the food materials, sending a control instruction with the time scales for starting preparation of the food materials and the time scales for the step preparation to the control module by the processing module, and preparing the food materials.

Description

Self-control intelligent refrigerator system based on time simulation

Technical Field

The invention relates to the field of intelligent home furnishing, in particular to a self-control intelligent refrigerator system based on time simulation.

Background

At present, a refrigerator is a refrigerating device keeping constant low temperature, and is also a civil product keeping constant low temperature and cold state of food or other articles, a cabinet or a box for freezing is arranged in a box body, an ice maker is arranged in the box body, a storage box with a refrigerating device is arranged, the volume of the household refrigerator is usually 20-500L, the first compression type refrigerating household refrigerator is published in the United states in the world in 1910, a household absorption refrigerator is developed by Swedish Lidu corporation in 1925, a totally enclosed refrigerator is developed by American general electric corporation in 1927, air cooling continuous diffusion absorption refrigerators adopting different heating modes are put on the market in 1930, a novel refrigerant Freon 12 is successfully developed in 1931, the household thermoelectric refrigerator is produced from the latter half of the 50 s, the refrigerator is produced from the 50 s in China, and the existing refrigerator has the problem of low intellectualization.

In addition, the preparation work before the cooking of the food materials can last for a period of time, and in working days, people often can take out the food materials from the refrigerator in the morning for unfreezing, and when the air temperature is higher, the food materials can deteriorate due to long-time unfreezing.

Disclosure of Invention

The purpose of the invention is as follows:

the invention provides a self-control intelligent refrigerator system based on time simulation, aiming at the problems that people often take food materials out of a refrigerator in the morning for thawing and the food materials are deteriorated due to long-time thawing when the temperature is high.

The technical scheme is as follows:

a self-controlled intelligent refrigerator system based on time simulation comprises: the food processing system comprises a space module, a time module, a processing module and a control module, wherein the space module and the time module are respectively connected with the processing module, the processing module is connected with the control module, the control module is connected with the space module, the space module provides a food storage space and a temporary storage space, the time module obtains preparation time and step preparation time of food and records refrigerator using time, the preparation time and the step preparation time are time intervals, the refrigerator using time is time scales, the processing module confirms the formal using time of food according to the using time, confirms the time scales of starting preparation of food according to the formal using time of food and the preparation time of food and the step preparation time, and the processing module confirms the time scales of the step preparation time according to the step preparation time and the time scales of starting preparation of food, the processing module sends a control instruction with time scales for starting preparation of food materials and time scales for step-by-step preparation to the control module, and the control module performs food material preparation according to the control instruction.

As a preferred mode of the present invention, the present invention further includes an information module and a terminal module, wherein the information module is connected to the terminal module, the terminal module is configured to set a recipe, and the information module is configured to obtain the recipe and food materials required by the recipe from the terminal module.

As a preferred aspect of the present invention, the time module is connected to the information module and the processing module, respectively, the time module obtains the preparation time and the step preparation time of the food material from the information module, and the processing module obtains the food material information from the information module.

As a preferable mode of the present invention, the food material temporary storage space corresponds to preparation time and step preparation time of the food material.

As a preferable mode of the present invention, the time module is further configured to record the actual usage time of the refrigerator on each day of the week in a cycle of one week, and classify the actual usage time of the refrigerator on the same day of the week.

As a preferable mode of the present invention, the processing module acquires the classification of the refrigerator actual use time of the same date every week from the time module, calculates the degree of dispersion of the refrigerator actual use time of the same date every week according to the classification condition, and estimates the refrigerator use time of the current date according to the degree of dispersion corresponding to the current date.

In a preferred embodiment of the present invention, the processing module calculates a time scale for starting preparation of the food material and a time scale for stepwise preparation of the food material according to the estimated usage time.

As a preferable mode of the present invention, the refrigerator further includes a feedback module, the feedback module is connected to the time module and the processing module, respectively, the feedback module obtains the actual usage time recorded by the time module and the refrigerator usage time of the current day to estimate the accuracy, and the processing module corrects the refrigerator usage time estimation according to the estimation accuracy.

As a preferred mode of the present invention, the time module is further configured to record an actual preparation time of the food material.

As a preferred aspect of the present invention, the feedback module is further connected to the information module, the feedback module obtains the actual preparation time recorded by the time module, the feedback module corrects the original preparation time according to the actual preparation time and the original preparation time in the time module, the feedback module transmits the correction result to the information module, and the information module performs coverage of the correction result.

The invention realizes the following beneficial effects:

by means of the presumption of the using time of the food materials and the calculation of the time according to the preparation time of the food materials and the preparation time step by step, the time point of the application of the food materials can be intelligently deduced, the preparation work of the food materials is carried out according to the time point, the food materials can be prepared in time, and meanwhile, the food materials cannot deteriorate and be damaged due to overlong preparation time.

Drawings

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

FIG. 1 is a system framework diagram;

FIG. 2 is a diagram illustrating a step of the embodiment;

FIG. 3 is a diagram of two steps of the embodiment

FIG. 4 is a diagram showing three steps of the embodiment.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

The first embodiment is as follows:

the reference figures are figure 1 and figure 2. A self-controlled intelligent refrigerator system based on time simulation comprises: the food preparation system comprises a space module 1, a time module 2, a processing module 3 and a control module 4, wherein the space module 1 and the time module 2 are respectively connected with the processing module 3, the processing module 3 is connected with the control module 4, the control module 4 is connected with the space module 1, the space module 1 provides a food storage space and a temporary storage space, the time module 2 obtains preparation time and step preparation time of food and records refrigerator using time, the preparation time and the step preparation time are time intervals, the refrigerator using time is time scales, the processing module 3 confirms formal using time of food according to the using time, the processing module 3 confirms time scales for starting preparation of food according to the formal using time of food and the preparation time of food and the step preparation time scales, and the processing module 3 confirms the time scales of starting preparation of step preparation according to the formal using time of food and the step preparation time scales And the processing module 3 sends a control instruction with a time scale for starting preparation of food materials and a time scale for step-by-step preparation to the control module 4, and the control module 4 prepares the food materials according to the control instruction.

As a preferred mode of the present invention, the food recipe setting system further includes an information module 5 and a terminal module 6, the information module 5 is connected to the terminal module 6, the terminal module 6 is configured to set a recipe, and the information module 5 is configured to obtain the recipe and food materials required by the recipe from the terminal module 6.

As a preferred aspect of the present invention, the time module 2 is connected to the information module 5 and the processing module 3, respectively, the time module 2 obtains the preparation time and the step preparation time of the food material from the information module 5, and the processing module 3 obtains the food material information from the information module 5.

As a preferable mode of the present invention, the food material temporary storage space corresponds to preparation time and step preparation time of the food material.

In the specific implementation process, when the food preparation is required, the information module 5 obtains the recipe and the food materials required in the recipe, selects the corresponding food materials, after selecting the corresponding food material, the information module 5 further obtains the preparation time and the step preparation time of all the food materials in the recipe, the time module 2 further obtains the real-time preparation time and the step preparation time from the information module 5, the processing module 3 obtains the refrigerator use time, the preparation time and the step preparation time in the time module 2, for example, the use time is four points, the preparation time is one hour, the step preparation time is a first step lasting for half an hour and a second step lasting for half an hour, the processing module 3 regards the use time as approximately the formal use time of the food material, and therefore, the starting preparation time scale of the food material is presumed to be three points, and the step time scales are presumed to be three and a half according to the continuous length of the step preparation time. When the time scale reaches three points, the processing module 3 sends a control instruction with the time scale for starting preparation of the food material and the time scale for preparing the food material step by step to the control module 4, and simultaneously sends the control instruction prepared in the first step, the control module 4 controls the system to select the food material and formally start preparation of the food material, when the time scale reaches half of the three points, the processing module 3 sends the control instruction prepared in the second step to the control module 4, and the system further controls the food material in the second step. It is worth mentioning that, in the food material temporary storage space, for the multi-step preparation, the food material temporary storage space is divided into a plurality of parts, each part corresponds to a different preparation environment, and the control module 4 controls the system to feed the food material into the corresponding different parts under different step-by-step preparation steps. The system performs primary number setting on food materials, sets primary numbers corresponding to the food materials in information of preparation time and step preparation time corresponding to the food materials, so as to perform correspondence of the food materials to the food material preparation time and the step preparation time according to the primary numbers, performs secondary number on the food materials based on a recipe for the same food materials with different preparation time and step preparation time in different recipes, and also performs correspondence of the food materials to the food material preparation time and the step preparation time based on the secondary numbers.

Example two:

the reference figures are figure 1 and figure 3. For the first embodiment, the present embodiment is different in that:

as a preferred mode of the present invention, the time module 2 is further configured to record the actual usage time of the refrigerator on each day of the week in a period of one week, and classify the actual usage time of the refrigerator on the same day of the week.

As a preferable mode of the present invention, the processing module 3 acquires the classification of the refrigerator actual use time of the same date every week from the time module 2, calculates the degree of dispersion of the refrigerator actual use time of the same date every week according to the classification, and estimates the refrigerator use time of the current date according to the degree of dispersion corresponding to the current date.

In a preferred embodiment of the present invention, the processing module 3 calculates a time scale for starting preparation of the food material and a time scale for stepwise preparation of the food material according to the estimated usage time.

In a specific implementation process, for the use time of the refrigerator, the time module 2 records the actual use time of each day in each week, classifies the actual use time of the same day of the week, such as monday classification, tuesday classification, and the like, and the processing module 3 obtains the classification information and the time data in each classification. The processing module 3 calculates the dispersion degree of the actual using time of the refrigerator in each category, presumes the dispersion degree of the day according to the historical distribution of the dispersion degree, corrects the using time according to the dispersion degree, and calculates the time scale for starting the preparation of the food material and the scale of the step-by-step preparation time according to the correction result.

Example three:

the reference figures are figure 1 and figure 4. For the first embodiment, the present embodiment is different in that:

as a preferable mode of the present invention, the refrigerator further includes a feedback module 7, the feedback module 7 is connected to the time module 2 and the processing module 3, respectively, the feedback module 7 obtains the actual usage time recorded by the time module 2 and the refrigerator usage time on the day to calculate the estimation accuracy, and the processing module 3 corrects the refrigerator usage time estimation according to the estimation accuracy.

As a preferred mode of the present invention, the time module 2 is further configured to record an actual preparation time of the food material.

As a preferred aspect of the present invention, the feedback module 7 is further connected to the information module 5, the feedback module 7 acquires the actual preparation time recorded by the time module 2, the feedback module 7 corrects the original preparation time according to the actual preparation time and the original preparation time in the time module 2, the feedback module 7 transmits the correction result to the information module 5, and the information module 5 covers the correction result.

In the implementation process, the feedback module 7 calculates the estimation accuracy of the actual use time by taking the estimation time of the use time of the refrigerator on the current day as a reference, and the accuracy is fed back to the processing module 3, the processing module 3 carries out the correction of the refrigerator using time estimation according to the accuracy, the accuracy is calculated by the ratio of the difference value between the estimated time and the actual using time to the estimated time, the correction is carried out by subtracting the product of the estimated time and the accuracy from the estimated time, when the estimated time is four points, the actual using time is three points, the accuracy is +/-0.25, when the presumed time is four points and the actual using time is five points, the accuracy is-0.25, by analogy, the processing module 3 calculates the average value of the accuracy within a period of time to obtain the average accuracy, and performs secondary correction by using the correction presumed by the dispersion degree and used time of the refrigerator.

The time module 2 records the actual preparation time of the food material and transmits the actual preparation time to the feedback module 7, the feedback module 7 corrects the preparation time according to the method and feeds the correction result back to the information module 5, and the information module 5 corrects the preparation time and the step-by-step preparation time stored in the information module.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and are intended to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the scope of the present invention. All equivalent changes or modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (7)

1. A self-controlled intelligent refrigerator system based on time simulation comprises: space module, time module, processing module, control module, space module and time module connect respectively processing module, processing module connects control module, control module connects the space module, the space module provides and eats material storage space and the space of keeping in, its characterized in that: the time module obtains the preparation time and the step-by-step preparation time of food materials and records the using time of a refrigerator, the preparation time and the step-by-step preparation time are time intervals, the using time of the refrigerator is time scales, the processing module confirms the formal using time of the food materials according to the using time, the processing module confirms the time scales of the starting preparation of the food materials according to the formal using time of the food materials and the preparation time of the food materials and the step-by-step preparation time, the processing module confirms the time scales of the step-by-step preparation time according to the step-by-step preparation time and the time scales of the starting preparation of the food materials, the processing module sends a control instruction with the time scales of the starting preparation of the food materials and the time scales of the step-by-step preparation to the control module, the control module prepares the food, the information module is connected with the terminal module, the terminal module is used for setting recipes, the information module is used for acquiring the recipes and food materials required by the recipes from the terminal module, the time module is respectively connected with the information module and the processing module, the time module acquires the preparation time and the step-by-step preparation time of the food materials from the information module, the processing module acquires food material information from the information module, the food material temporary storage space corresponds to the preparation time and the step-by-step preparation time of the food materials, for the same food materials with different preparation time and step-by-step preparation time in different recipes, the system numbers the food materials secondarily based on the recipes, the preparation time and the step preparation time are also provided with the same secondary number, and the food material preparation time and the step preparation time are corresponding according to the secondary number.

2. The self-controlled intelligent refrigerator system based on time simulation of claim 1, wherein: the time module is also used for recording the actual use time of the refrigerator every day in one week as a cycle and classifying the actual use time of the refrigerator on the same date every week.

3. The self-controlled intelligent refrigerator system based on time simulation of claim 2, wherein: the processing module acquires the classification of the actual refrigerator use time of the same date every week from the time module, calculates the discrete degree of the actual refrigerator use time of the same date every week according to the classification condition, and conjectures the refrigerator use time of the current date according to the discrete degree corresponding to the current date.

4. The self-controlled intelligent refrigerator system based on time simulation of claim 3, wherein: and the processing module calculates the time scale for starting the preparation of the food material and the time scale for preparing the food material step by step according to the estimated using time.

5. The self-controlled intelligent refrigerator system based on time simulation of claim 3, wherein: the refrigerator service time estimation system further comprises a feedback module, the feedback module is respectively connected with the time module and the processing module, the feedback module obtains the actual service time recorded by the time module and the refrigerator service time on the day, the estimation accuracy is calculated, and the processing module carries out the correction of the refrigerator service time estimation according to the estimation accuracy.

6. The self-controlled intelligent refrigerator system based on time simulation of claim 5, wherein: the time module is further configured to record an actual preparation time of the food material.

7. The self-controlled intelligent refrigerator system based on time simulation of claim 6, wherein: the feedback module is further connected with the information module, the feedback module acquires the actual preparation time recorded by the time module, the feedback module corrects the original preparation time according to the actual preparation time and the original preparation time in the time module, the feedback module transmits the correction result to the information module, and the information module covers the correction result.

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