阅读说明：本技术 一种智能米桶及其工作方法 (Intelligent rice bucket and working method thereof ) 是由 林昱 于 2019-09-29 设计创作，主要内容包括：本发明提供一种智能米桶及其工作方法,该智能米桶包括桶体、底板、盖板、连接件,底板设置在桶体的底部,连接件的第一端与桶体的顶部相连接,连接件的第二端与盖板相连接,盖板通过连接件设置在桶体的顶部,在底板内设置有称重模块、存储模块、计算模块和通信模块,称重模块用于检测桶体内的剩余米量,存储模块用于存储桶体内的剩余米量,计算模块用于计算每一次的取米量,通信模块用于向外界传输运送信息。该工作方法包括由通信模块向粮站发送配送信息,由粮站及时配送。该智能米桶可以随时对于桶内剩余米量进行检测,并且可以在桶内剩余米量不多时及时通知粮站进行配送。(The invention provides an intelligent rice bucket and a working method thereof, the intelligent rice bucket comprises a bucket body, a bottom plate, a cover plate and a connecting piece, wherein the bottom plate is arranged at the bottom of the bucket body, the first end of the connecting piece is connected with the top of the bucket body, the second end of the connecting piece is connected with the cover plate, the cover plate is arranged at the top of the bucket body through the connecting piece, a weighing module, a storage module, a calculation module and a communication module are arranged in the bottom plate, the weighing module is used for detecting the residual rice quantity in the bucket body, the storage module is used for storing the residual rice quantity in the bucket body, the calculation module is used for calculating the rice taking quantity each time, and the communication module. The working method comprises the steps that the communication module sends distribution information to the grain station, and the grain station distributes the information in time. The intelligent rice bucket can detect the amount of remaining rice in the bucket at any time, and can inform a grain station to deliver when the amount of remaining rice in the bucket is not large.)

1. The utility model provides an intelligence rice bucket, includes staving, bottom plate, apron, connecting piece, the bottom plate sets up the bottom of staving, the first end of connecting piece with the top of staving is connected, the second end of connecting piece with the apron is connected, the apron passes through the connecting piece sets up the top of staving, its characterized in that:

a weighing module is arranged in the bottom plate and used for detecting the amount of remaining rice in the barrel body;

a storage module is arranged in the bottom plate and used for storing the residual rice in the barrel body;

a calculation module is arranged in the bottom plate and used for calculating the rice taking amount each time;

the barrel body is provided with a communication module which is used for transmitting and transmitting information to the outside.

2. The intelligent rice bucket of claim 1, wherein:

the intelligent rice bucket further comprises a built-in bucket, the built-in bucket is arranged inside the bucket body, the built-in bucket is cylindrical, a containing cavity is formed inside the built-in bucket, and the containing cavity is cylindrical.

3. The intelligent rice bucket of claim 1, wherein:

the connecting piece is a circular-arc plate body, and first through holes are formed in the first end and the second end of the connecting piece.

4. The intelligent rice bucket of claim 3, wherein:

the barrel body is characterized in that a first connecting plate is arranged at the top of the barrel body, a second through hole is formed in the first connecting plate, a fixed shaft is arranged at the first end of the connecting piece, and the fixed shaft sequentially penetrates through the second through hole and the first through hole to connect the connecting piece with the first connecting plate.

5. The intelligent rice bucket of claim 3, wherein:

the top of the cover plate is provided with a second connecting plate, a third through hole is formed in the second connecting plate, a rotating shaft is arranged at the second end of the connecting piece, and the rotating shaft sequentially penetrates through the third through hole and the first through hole.

6. An operating method of the intelligent rice bucket is applied to the intelligent rice bucket according to any one of claims 1 to 5, and is characterized by comprising the following steps:

the weighing module measures the amount of remaining rice in the barrel;

the weighing module stores the measured data into the storage module;

the calculation module calculates the rice taking amount at this time;

the calculation module calculates the preset rice taking amount;

the calculation module judges whether the amount of remaining rice in the barrel is more than four times of the preset amount of rice to be taken, if so, the operation is finished; if not, the communication module sends replenishment information to a preset grain station.

Technical Field

The invention relates to the technical field of household articles, in particular to an intelligent rice bucket and a working method thereof.

Background

The existing household rice bucket only has the function of containing rice and does not have the detection function, so that people cannot easily find the amount of residual rice in the rice bucket, rice always exists in the rice bucket when cooking at noon, and the situation that no rice or insufficient rice exists can be found when cooking at night. The existing rice bucket is divided into a traditional rice bucket, a rice bucket with scales and the like, the user cannot be automatically prompted by the rice buckets, namely, the user cannot be timely reminded to buy rice when the remaining rice amount is insufficient by the existing rice bucket, and new rice cannot be supplemented when the remaining rice amount is insufficient.

Disclosure of Invention

The invention aims to provide an intelligent rice bucket capable of monitoring the rice quantity in the bucket at any time.

The second purpose of the invention is to provide a working method capable of automatically reminding a grain station to carry out distribution when the rice amount in the barrel is insufficient.

In order to achieve the first purpose, the intelligent rice bucket provided by the invention comprises a bucket body, a bottom plate, a cover plate and a connecting piece, wherein the bottom plate is arranged at the bottom of the bucket body; a storage module is arranged in the bottom plate and used for storing the residual rice in the barrel body; a calculating module is arranged in the bottom plate and used for calculating the rice taking amount each time; the barrel body is provided with a communication module which is used for transmitting and transmitting information to the outside.

According to the scheme, the weighing module can weigh the residual rice in the barrel body at any time. After the user finishes taking the rice from the barrel body, the weighing device measures the amount of the remaining rice in the barrel body and stores the measured data in the storage module. And then the calculation module reads the residual rice amount after the rice is taken and the residual rice amount before the rice is taken from the storage module, and then the residual rice amount in the barrel body before the rice is taken is subtracted from the residual rice amount in the barrel body after the rice is taken so as to obtain the rice taking amount of the rice taken at this time. The calculation module removes the maximum value and the minimum value in the rice-taking quantity obtained by each calculation, and then calculates the average value of the remaining measured rice-taking quantities, wherein the obtained average value is the preset rice-taking quantity. The calculation module judges whether the amount of remaining rice in the barrel is more than four times of the preset amount of rice, and if so, the operation is stopped; if not, the communication module sends replenishment information to nearby grain stations to inform the grain stations to distribute new rice in time. Therefore, the grain station can be timely reminded of supplying and delivering when the amount of remaining rice in the barrel is insufficient, and the phenomenon that the rice in the barrel is used up but no new rice is supplied is avoided.

Preferably, intelligence rice bucket still includes built-in bucket, and the built-in bucket setting is in the inside of staving, and the shape of built-in bucket is the cylinder, is formed with in built-in bucket inside and holds the chamber, and the shape that holds the chamber is the cylinder.

In the scheme, the accommodating cavity in the built-in barrel plays a role in accommodating rice.

The further scheme is that the connecting piece is a circular arc-shaped plate body, and first through holes are formed in the first end and the second end of the connecting piece.

The top of the barrel body is provided with a first connecting plate, the first connecting plate is provided with a second through hole, the first end of the connecting piece is provided with a fixed shaft, and the fixed shaft sequentially penetrates through the second through hole and the first through hole to connect the connecting piece with the first connecting plate.

The top of the cover plate is provided with a second connecting plate, the second connecting plate is provided with a third through hole, the second end of the connecting piece is provided with a rotating shaft, and the rotating shaft sequentially penetrates through the third through hole and the first through hole.

In the above scheme, the cover plate is arranged at the top of the barrel body. The cover plate can rotate around the second end of the connecting piece through the rotating shaft, so that the rice bucket is opened and closed. When the rice needs to be taken from the rice bucket, the rice bucket can be opened only by rotating the cover plate. After the rice is taken out, the cover plate is covered.

In order to achieve the second object, the present invention provides a working method, which comprises the following steps:

step S1: the weighing module measures the amount of remaining rice in the barrel;

step S2: the weighing module stores the measured data into the storage module;

step S3: the calculation module calculates the rice taking amount at this time;

step S4: the calculation module calculates the preset rice taking amount;

step S5: the calculation module judges whether the amount of remaining rice in the barrel is more than four times of the preset rice taking amount, if so, the operation is finished; if not, go to step S6;

step S6: and sending replenishment information to a preset grain station by the communication module.

According to the scheme, in the process of executing the step S3, the calculation module reads the remaining rice amount after the current rice fetching and the remaining rice amount before the current rice fetching from the storage module, and then subtracts the remaining rice amount in the barrel body before the current rice fetching from the remaining rice amount in the barrel body after the current rice fetching, so that the rice fetching amount of the current rice can be obtained. In the process of executing step S4, the calculation module removes the maximum value and the minimum value of the rice-taking quantities obtained by each calculation, and then calculates the average value of the remaining measured rice-taking quantities, where the obtained average value is the preset rice-taking quantity.

Drawings

Fig. 1 is a first view of an embodiment of the intelligent rice bucket of the present invention.

Fig. 2 is a second view of an embodiment of the intelligent rice bucket of the present invention.

FIG. 3 is a view showing the internal structure of the intelligent rice bucket of the present invention with the cover plate hidden.

Fig. 4 is a flow chart of the operation of an embodiment of the operating system of the present invention.

The invention is further explained with reference to the drawings and the embodiments.

Detailed Description

Referring to fig. 1 to 3, the intelligent rice bucket provided by the embodiment comprises a bucket body 1, a bottom plate 2, a cover plate 3 and a connecting piece 4, wherein the bottom plate 2 is arranged at the bottom of the bucket body 1, the first end of the connecting piece 4 is connected with the top of the bucket body 1, the second end of the connecting piece 4 is connected with the cover plate 3, and the cover plate 3 is arranged at the top of the bucket body 1 through the connecting piece 4. The barrel body 1 is internally provided with the built-in barrel 5, the built-in barrel 5 is cylindrical, the built-in barrel 5 is internally provided with the accommodating cavity 6, and the accommodating cavity 6 is cylindrical. The connecting piece 4 is a circular arc-shaped plate body, and first through holes (not shown in the figure) are formed in the first end and the second end of the connecting piece 4. The top of the barrel body 1 is provided with a first connecting plate 11, the first connecting plate 11 is provided with a second through hole 12, the first end of the connecting piece 4 is provided with a fixed shaft 41, and the fixed shaft 41 sequentially penetrates through the second through hole 12 and the first through hole to connect the connecting piece 4 with the first connecting plate 11. The top of the cover plate 3 is provided with a second connecting plate 31, the second connecting plate 31 is provided with a third through hole 32, the second end of the connecting piece 4 is provided with a rotating shaft 42, and the rotating shaft 42 sequentially penetrates through the third through hole 32 and the first through hole. The cover plate 3 is arranged at the top of the barrel body 1. The cover plate 3 can rotate around the second end of the connecting piece 4 through the rotating shaft 42, so that the rice bucket is opened and closed. When rice needs to be taken out of the rice bucket, the rice bucket can be opened only by rotating the cover plate 3. After the rice is taken out, the cover plate 3 is covered.

In the present embodiment, a weighing module (not shown in the figure) is provided in the bottom plate 2, and the weighing module is used for detecting the remaining rice amount in the barrel body; a storage module (not shown in the figure) is arranged in the bottom plate 2 and is used for storing the residual rice in the barrel body; a calculating module (not shown in the figure) is arranged in the bottom plate 2 and is used for calculating the rice taking amount each time; the barrel body 1 is provided with a communication module which is used for transmitting and transmitting information to the outside.

Referring to fig. 4, the workflow provided by this embodiment includes the following steps:

firstly, step S1 is executed, and the weighing module measures the weight of the remaining rice in the barrel body 1; then, step S2 is executed, and the weighing module stores the measured data in the storage module; then, step S3 is executed, and the calculating module calculates the weight of the rice taken this time; then, step S4 is executed, and the calculating module calculates the weight of the preset rice; then, step S5 is executed, the calculation module determines whether the remaining rice in the barrel 1 is greater than four times of the preset rice-fetching amount, if yes, the operation is ended, otherwise, step S6 is executed.

In step S6, the communication module sends replenishment information to the predetermined grain station. Preferably, the communication module may pre-store a contact way of one or more grain stations, and when the grain stations are notified to deliver new rice, the delivery request information may be sent through the pre-stored contact way. Furthermore, the user can input the contact information of a specific grain station by himself.

In this embodiment, in the process of executing step S3, the calculation module reads the remaining rice amount after the current rice fetching and the remaining rice amount before the current rice fetching from the storage module, and then subtracts the remaining rice amount in the barrel before the current rice fetching from the remaining rice amount in the barrel after the current rice fetching, so as to obtain the current rice fetching amount. In the process of executing step S4, the calculation module removes the maximum value and the minimum value of the rice-taking quantities obtained by each calculation, and then calculates the average value of the remaining measured rice-taking quantities, where the obtained average value is the preset rice-taking quantity.

While the present invention has been particularly shown and described with reference to the present embodiments and preferred versions thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.