CN108557258B - Smart container and application thereof - Google Patents

Abstract

The invention discloses a smart container and application thereof, wherein the smart container comprises a bottle body and a base unit, the base unit further comprises a sensor and a base body, wherein the base body comprises a cover film, the bottle body is arranged on the base body so as to close a lower end opening of the bottle body by the base body, a containing cavity is formed between the bottle body and the base body, at least one part of the cover film is kept in the containing cavity, and at least one part of the sensor is kept in the lower part of the cover film so as to press the sensor after the cover film is deformed.

Description

Smart container and application thereof

Technical Field

The invention relates to a container, in particular to an intelligent container and application thereof.

Background

The outer wall of the existing container is often provided with scale marks, and when the existing container is used for proportioning solution or taking substances quantitatively, the solution proportioning and the substance measuring are often realized by the aid of the scale marks, for example, in the chemical field, a user usually realizes the proportioning of chemical reagents by means of scales on the outer wall of a measuring cylinder, a volumetric flask and the like; in the medical field, a user usually utilizes scales on the outer wall of a plastic measuring cylinder to realize the proportion of medicine and water, and particularly for fluid medicines, the plastic measuring cylinder with scale marks is often matched; for example, in life, users often use milk bottles with scale marks to realize the preparation of milk powder; while fresh containers are dedicated to the preparation of coffee. Obviously, the influence of human factors on substances or blended solvents in two areas of the container is more or less utilized, so that the solution with accurate concentration cannot be blended, and the solution with accurate dosage cannot be taken, and the accuracy of the concentration of the solution in the chemical field is sometimes the key for determining the success or failure of an experiment; in the medical field, the concentration of the medicament is related to the physical health of the patient, especially for the infant just born, a slight excess of medicament may bring about the life risk for the infant; in the field of life, the blending of milk powder and breast milk relates to whether infants can grow healthily, and the coffee shade directly affects the taste of users, that is, the traditional container cannot realize accurate proportioning of solution concentration and accurate measurement of substances.

Taking the living field as an example, it is well known that the care of infants is not only of great concern for every family, but is also important for a country. However, for infants, the requirements of the nutrition matching of the consumed breast milk or milk powder are strict, because for infants in different ages, the ratio of the milk powder to the water is different when the infants need to consume the breast milk or prepare the milk powder each time, the frequency of consuming the breast milk or the milk powder is different, and as the infants grow up, the amount and the frequency of the milk powder consumed in different ages of the infants are also changed, for example, the concentration of the milk powder needed to be consumed by the infants just born may be higher, and for the infants just born, the concentration of the milk powder needed to be consumed by the infants just born may need to last for a longer period of time, for example, the concentration of the milk powder needed to be consumed in two months may need to be reduced in the next period of time, and the milk powder of the user's expected concentration cannot be prepared accurately only by using the scale arranged on the outer wall of the existing container, and the milk powder of almost the same concentration needed to be prepared each time cannot be ensured.

In addition, medical science proves that infants taking healthy breast milk have stronger resistance than infants taking aqueous milk powder, and with the acceleration of the pace of life, infants' mothers sometimes can not self-feed breast milk to infants due to tedious work when infants need to feed milk, at the moment, they can only order to take care of other caregivers of infants to feed milk to infants, while for those people who never feed infants at ordinary times, sometimes do not know what kind of milk powder is consumed by infants, even less how much the ratio of milk powder to water is, if the milk powder is prepared only by means of scales on the outer wall of a traditional milk bottle, the end result is likely to be too much or too little milk powder consumed by infants, and over time, the healthy growth of infants can be affected.

In addition, in order for the mother in lactation to consume healthy breast milk, it is common practice to take part of the breast milk by means of a conventional milk discharging device, i.e. a breast pump, and place it in a refrigerator before going to work every day, and then when they cannot personally feed their infants with breast milk, they order other caregivers who cared about her children to feed their children with breast milk previously taken by the breast pump and stored in the refrigerator through a remote information means, such as a web video, a mobile phone, etc., thereby ensuring that their children can always consume breast milk. Specifically, the conventional milk sucking device includes a milk pump and a milk bottle, wherein the milk bottle has a bottom wall and an outer wall integrally formed with the bottom wall, and graduation marks are provided on the outer wall in the same manner so that a user can estimate the approximate amount of milk sucked, wherein the outer wall of the milk bottle forms a receiving chamber having an opening at an upper end, wherein the upper portion of the outer wall can be communicated with the milk pump so that the milk pump can guide the milk to the opening of the milk bottle to be further guided into the receiving chamber of the milk bottle when the milk pump is operated to suck the milk, and simultaneously, when the user is sucking the milk, the sucked amount can be judged according to the graduation marks provided on the outer wall.

However, when sucking breast milk, the user often cannot directly observe the scale provided on the outer wall of the milk bottle, and usually the scale is overlooked even if the user can observe the scale, in other words, the user cannot suck the breast milk with accurate volume and weight by using the traditional milk discharging device. In addition, during the process of expressing breast milk, the user cannot know the rate of expressing breast milk, nor the amount of expressing breast milk; in medicine, the rate at which breast milk is sucked and the amount of breast milk after regular internal pregnancy can be used as one of the criteria for measuring the health of women during lactation, and the traditional breast pumping device cannot monitor the rate at which breast milk is sucked or the amount of breast milk sucked during use of a user at all, so that the health of the user cannot be monitored; in addition, if the amount of each suction is excessive, it will result in waste of breast milk.

In addition, the existing container cannot monitor the temperature of the material in the container, and the temperature of the solution in the container cannot be moderately kept above a preset temperature value, and in the chemical field, certain experimental reagents have temperature requirements, so that the existing container cannot solve the problems.

Disclosure of Invention

Object of the Invention

It is an object of the present invention to provide a smart container and its use, wherein the smart container can help a user to accurately control the amount of added substance.

It is an object of the present invention to provide a smart container and its use, wherein the smart container can help a user to accurately control the amount of added substance in a manner that measures the added substance.

It is an object of the present invention to provide a smart container and use thereof, wherein the smart container allows a user to remotely obtain the amount of substance added.

It is an object of the present invention to provide a smart container and use thereof, wherein the smart container provides a sensor, wherein the sensor is capable of helping a user to obtain the amount of substance added. Preferably, the sensor obtains the amount of the substance added in such a manner that the pressure received per unit area is detected. For example, the sensor may be a touch sensor, a load cell, a barometric sensor, or the like, such that after a substance is added to the smart container, the substance may subject the sensor to pressure.

It is an object of the present invention to provide a smart container and the use thereof, wherein the smart container is capable of preventing heat of an added substance from being transferred to the sensor, in such a way that the accuracy of the sensor and thus the reliability of the smart container when used can be ensured.

It is an object of the present invention to provide a smart container and its use, wherein the smart container provides a base body, the sensor is provided to the base body, and the base body forms the bottom of the base body, wherein when a substance is added to the smart container, the sensor is capable of receiving a pressure generated by the substance, and detecting the amount of the substance added to the smart container based on the pressure of the substance caused to the sensor.

It is an object of the present invention to provide a smart container and its use, wherein the base body comprises a cover film, at least a portion of the cover film being located in the receiving cavity of the smart container, the sensor being held in a lower portion of the cover film, the cover film being pressed when a substance is added to the receiving cavity of the smart container to deform the cover film, the deformed cover being capable of pressing the sensor, thereby stressing the sensor.

It is an object of the present invention to provide a smart container and its use, wherein at least one thermal insulation is provided between the cover film of the smart container and the sensor, so that heat of a substance added to the receiving chamber is prevented from being conducted to the sensor by the thermal insulation, thereby maintaining the operating temperature of the sensor in a suitable range, so that the accuracy of the sensor is prevented from being affected by heat.

It is an object of the present invention to provide a smart container and application thereof, in which the cover film and a base upper frame of the base body are integrally formed, in such a manner that the cover film can be stably held on the base upper frame, and it is advantageous to reduce manufacturing costs and process difficulties of the smart container.

An object of the present invention is to provide a smart container and application thereof, in which the cover film is integrally formed on the base upper frame, in such a manner that the cover film is prevented from falling off from the base body when the base unit formed of the base body and the cover film is washed, thereby ensuring reliability and stability of the smart container when used.

It is an object of the present invention to provide a smart container and use thereof, wherein the smart container provides a bottle, wherein the bottle is detachably mounted to the base unit, and at least a portion of the cover film is held in the accommodation chamber formed between the bottle and the base unit after the bottle is mounted to the base unit, in such a manner that a substance can press the cover film to deform the cover film after the substance is introduced into the accommodation chamber. In addition, the bottle body can be detachably arranged on the base unit, so that the bottle body and the base unit of the intelligent container can be cleaned conveniently and respectively.

It is an object of the present invention to provide a smart container and application thereof, in which the cover film is held between the bottle body and the base unit to prevent a gap from being generated between the bottle body and the base unit, in such a manner that sealability between the bottle body and the base unit can be ensured to prevent leakage of a substance added to the receiving chamber.

It is an object of the present invention to provide a smart container and its use, wherein the smart container is capable of monitoring in real time physical signals of a substance contained in the container such as: temperature, characterization information (e.g., mass, volume, etc.) so that the user can accurately measure the desired substance by means of the physical signal.

It is an object of the present invention to provide a smart container and its use, wherein the smart container is capable of monitoring in real time the physical signal of the substance contained in the container, and the smart container is capable of providing a user with a result signal, so that the user can determine whether to continue adding substance to the smart container or not by means of the result signal.

It is therefore an object of the present invention to provide a smart container and applications thereof, in which a user can set a physical signal of a substance dispensed by using the smart container as a reference signal, so that the user can measure the substance having substantially the same physical signal each time.

It is an object of the present invention to provide a smart container and use thereof, wherein the smart container is capable of monitoring in real time the characterization of the substance contained in the container, thereby enabling a user to dispense solutions of substantially the same concentration multiple times.

It is an object of the present invention to provide a smart container and an application thereof, wherein the smart container can monitor the temperature of a substance contained in the container, so that the smart container can automatically heat the substance contained in the container when the temperature of the substance is lower than a preset temperature value, and further the temperature of the substance in the smart container is always not lower than the preset temperature value.

It is an object of the present invention to provide a smart container and application thereof, wherein the smart container includes a container body and a smart device, wherein the smart device is detachably disposed at a bottom of the container body so that the container body is detached to be used alone.

It is an object of the present invention to provide a smart container and application thereof, wherein the smart device is capable of communicating a detected physical signal of a substance contained in the container to a user by means of wireless transmission.

According to one aspect of the present invention, there is provided a smart container comprising:

a bottle body, wherein the bottle body is provided with a high-end opening and a low-end opening corresponding to the high-end opening; and

a base unit, wherein the base unit further comprises a sensor and a base body, wherein the base body comprises a cover film, wherein the bottle is disposed on the base body to close the lower end opening of the bottle by the base body, thereby forming a receiving cavity between the bottle and the base body, wherein at least a portion of the cover film is held in the receiving cavity, and at least a portion of the sensor is held in a lower portion of the cover film to press the sensor after the cover film is deformed.

According to one embodiment of the invention, the base body further comprises a base upper frame having an upper frame perforation, wherein the cover film is disposed on the base upper frame, and the upper frame perforation of the base upper frame corresponds to the cover film.

According to one embodiment of the invention, the sensor comprises a sensor cantilever and a sensor body arranged at a free end of the sensor cantilever, a connection end of the sensor cantilever being arranged at the base body, and at least a part of the sensor being held in a suspended manner at the upper shelf perforation of the base upper shelf.

According to one embodiment of the invention, the sensor upper surface of the sensor body of the sensor is flush with the base upper surface of the base upper frame; or a sensor upper surface of the sensor body of the sensor is lower than a base upper surface of the base upper frame; or the sensor upper surface of the sensor body of the sensor is higher than the base upper surface of the base upper frame.

According to one embodiment of the present invention, the cover film is attached to the base upper surface of the base upper frame.

According to one embodiment of the present invention, the cover film is integrally formed on the base upper surface of the base upper frame.

According to one embodiment of the invention, the cover film and the base upper frame are integrally formed.

According to one embodiment of the invention, the bottle is detachably mounted to the base unit, so that the receiving chamber is formed between the bottle and the base unit.

According to one embodiment of the invention, the cover film is held between the bottle body and the base upper frame.

According to one embodiment of the invention, the base unit further comprises at least one insulation part, which insulation part is held between the cover film and the sensor.

According to another aspect of the present invention, there is further provided a method for manufacturing a smart container, wherein the method comprises the steps of:

(a) Providing a cover film on a base upper frame, wherein an upper frame perforation of the base upper frame corresponds to the cover film;

(b) Forming a receiving cavity between the bottle body and the base upper frame in such a manner that the base upper frame closes a lower end opening of the bottle body, wherein at least a portion of the cover film is held in the receiving cavity; and

(c) The sensor is arranged at the lower part of the cover film in such a way that the cover film presses against the sensor after deformation.

According to an embodiment of the present invention, in the step (c), the sensor is disposed at a lower portion of the cover film in such a manner that the sensor is suspended from the upper frame perforation of the base upper frame.

According to an embodiment of the present invention, in the step (a), further comprising the steps of:

providing the base upper shelf with the upper shelf perforations; and

and attaching the cover film to the upper surface of the base of the upper base frame so as to set the cover film on the upper surface of the base of the upper base frame.

According to an embodiment of the present invention, in the step (a), further comprising the steps of:

providing the base upper shelf with the upper shelf perforations; and

and forming the cover film on the base upper frame through an injection molding process so as to set the cover film on the base upper frame.

According to an embodiment of the present invention, in the step (a), the cover film and the base upper frame are integrally formed by an injection molding process.

According to an embodiment of the present invention, in the above method, further comprising the steps of: at least one insulating portion is held between the cover film and the sensor.

Drawings

FIG. 1A is a schematic diagram of a smart container according to a preferred embodiment of the present invention, wherein a container body of the smart container is detachable from a smart device of the smart container, and a processing apparatus of the smart device is modularized into a cloud processing program.

FIG. 1B is a schematic diagram of a smart container according to another preferred embodiment of the present invention, wherein a container body of the smart container is integrally provided with a smart device of the smart container, and a processing apparatus of the smart device is modularized into a cloud processing program.

Fig. 1C is a schematic perspective view of a smart container according to another preferred embodiment of the present invention.

FIG. 2 is an exploded view of the smart container according to the preferred embodiment of the present invention.

Fig. 3 is a schematic view showing an internal structure of the smart container according to the above preferred embodiment of the present invention, which is cut along the middle position.

FIG. 4 is a schematic view of a use state of the smart container according to the above preferred embodiment of the present invention.

FIG. 5 is a schematic view of another use state of the smart container according to the above preferred embodiment of the present invention.

FIG. 6 is a schematic diagram of one of the steps of manufacturing the smart container according to the preferred embodiment of the present invention.

FIG. 7 is a schematic diagram of a second step of manufacturing the smart container according to the above preferred embodiment of the present invention.

FIG. 8 is a schematic diagram of a third step of manufacturing the smart container according to the above preferred embodiment of the present invention.

FIG. 9 is a schematic diagram of a fourth step of manufacturing the smart container according to the preferred embodiment of the present invention.

FIG. 10 is a schematic diagram of a fifth step of manufacturing the smart container according to the preferred embodiment of the present invention.

FIG. 11 is a schematic diagram illustrating a sixth step in the manufacturing of the smart container according to the preferred embodiment of the present invention.

FIG. 12 is a schematic diagram of a seventh step of manufacturing the smart container according to the above preferred embodiment of the present invention.

FIG. 13 is a schematic diagram of a manufacturing step eight of the smart container according to the above preferred embodiment of the present invention.

Fig. 14 is a schematic diagram of an application example of the smart container according to the above preferred embodiment of the present invention.

Fig. 15 is a schematic cross-sectional view of a variant of the smart container according to the above preferred embodiment of the present invention.

Fig. 16 is a schematic cross-sectional view of another variant of the smart container according to the above preferred embodiment of the present invention.

Fig. 17 is a schematic cross-sectional view of another variant of the smart container according to the above preferred embodiment of the present invention.

Fig. 18 is a schematic cross-sectional view of another variant of the smart container according to the above preferred embodiment of the present invention.

Fig. 19 is a schematic cross-sectional view of another variant of the smart container according to the above preferred embodiment of the present invention.

Fig. 20 is a schematic cross-sectional view of another variant of the smart container according to the above preferred embodiment of the present invention.

Fig. 21 is a flowchart of the operation of the smart device according to the above embodiment of the present invention.

FIG. 22A is a schematic diagram of a smart container according to another embodiment of the present invention, wherein a container body of the smart container is detachable from the smart device of the smart container.

FIG. 22B is a schematic diagram of a smart container according to another embodiment of the present invention, wherein a container body of the smart container is integrally provided with the smart device of the smart container.

Fig. 23 is a flowchart of the operation of the smart device according to the above embodiment of the present invention.

FIG. 24A is a flowchart of a smart device monitoring physical signals of water addition in accordance with a preferred embodiment of the present invention.

FIG. 24B is another workflow diagram of a smart device monitoring physical signals added to milk powder in accordance with a preferred embodiment of the present invention.

Fig. 24C is another workflow diagram of a smart device monitoring the temperature of milk powder solution in the receiving chamber of the container body according to a preferred embodiment of the present invention.

FIG. 25 is a schematic view of a breast pump according to a preferred embodiment of the present invention.

FIG. 26 is a flowchart of a smart container management system according to a preferred embodiment of the present invention.

FIG. 27 is a flowchart of a management system according to the above preferred embodiment of the present invention.

Detailed Description

The following description is presented to enable one of ordinary skill in the art to make and use the invention. The preferred embodiments in the following description are by way of example only and other obvious variations will occur to those skilled in the art. The basic principles of the invention defined in the following description may be applied to other embodiments, variations, modifications, equivalents, and other technical solutions without departing from the spirit and scope of the invention.

It will be appreciated by those skilled in the art that in the present disclosure, the terms "longitudinal," "transverse," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," etc. refer to an orientation or positional relationship based on that shown in the drawings, which is merely for convenience of description and to simplify the description, and do not indicate or imply that the apparatus or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore the above terms should not be construed as limiting the present invention.

It is to be understood that the terms "a" and "an" are to be interpreted as referring to "at least one" or "one or more," i.e., in one embodiment, the number of elements may be one, while in another embodiment, the number of elements may be plural, and the term "a" is not to be construed as limiting the number.

Referring to fig. 1A to 4, 22A to 23 of the drawings, a smart container 100 according to a preferred embodiment of the present invention is disclosed and described in the following description, wherein the smart container 100 includes a container body 10 and a smart device 20, wherein the container body 10 is capable of containing a certain amount of a substance, such as water, milk powder, a mixture of water and milk powder, a solution, a reagent, etc., and the container body 10 may be provided to the smart device 20. For example, in this specific example of the smart container 100 shown in fig. 1A, the container body 10 is provided to the smart device 20 in such a manner that the container body 10 is held at the upper portion of the smart device 20. Preferably, the container body 10 may be placed on an upper portion of the smart device 20 so that the container body 10 can be removed from the smart device 20.

In one embodiment of the present invention, the container body 10 includes a bottom wall 11 and an outer wall 12 extending upward from the bottom wall 11, wherein the container body 10 further has a receiving cavity 110 and an opening 120 communicating with the receiving cavity 110, wherein the receiving cavity 110 is formed between the bottom wall 11 and the outer wall 12, wherein the receiving cavity 110 of the container body 10 is capable of containing a certain amount of substances such as solids and fluids (e.g., liquids and gases), particularly, but not limited to, water, powdered milk, a mixture of water and powdered milk, solutions, reagents, and the like.

In the embodiment shown in fig. 1A, the smart device 20 may also be detachably mounted on the container body 10, that is, the container body 10 may be used alone in the present invention, and the smart device 20 may be used with a plurality of container bodies 10 in sequence.

In another embodiment of the present invention, referring to fig. 1B, the container body 10 includes only one of the outer walls 12, wherein the outer wall 12 has an upper opening and a lower opening, and wherein the smart device 20 is disposed at the container body 10 such that the lower opening formed by the outer wall 12 of the container body 10 is covered by the smart device 20, thereby forming the receiving chamber 110 between the outer wall 12 of the container body 10 and the smart device 20, and at this time, the upper opening of the outer wall 12 of the container body 10 forms the opening 120 of the container body 10. That is, the smart device 20 forms the bottom wall of the container body 10 of the smart container 100 at this time, and the smart device 20 forms the accommodation chamber 110 having the opening 120 with the outer wall 12 of the container body 10.

Preferably, in the embodiment shown in fig. 1B, the smart device 20 may be integrally connected to the container body 10, or the smart device 20 may be detachably mounted to the container body 10.

Fig. 1C to 13 show another preferred embodiment of the smart container 100, wherein the smart container 100 comprises a bottle body 40 and a base unit 50 and has the receiving chamber 110 and the opening 120 communicating with the receiving chamber 110, wherein the bottle body 40 is mounted to the base unit 50 to form the receiving chamber 110 and the opening 120 between the bottle body 40 and the base unit 50, and a substance can be introduced into the receiving chamber 110 from the opening 120 of the smart container 100.

Further, the bottle 40 has a high end 41, a low end 42, a high end opening 410, and a low end opening 420, wherein the high end 41 and the low end 42 of the bottle 40 correspond to each other, and the high end opening 410 is formed at the Gao Duanbu, and the low end opening 420 is formed at the low end 42. The lower end 42 of the bottle 40 is mounted to the base unit 50 to close the lower end opening 420 of the bottle 40 by the base unit 50, and the receiving chamber 110 is formed between the bottle 40 and the base unit 50, wherein the upper end opening 410 of the bottle 40 forms the opening 120 communicating with the receiving chamber 110.

Preferably, the lower end 42 of the bottle 40 is detachably mounted to the base unit 50, so that the bottle 40 and the base unit 50 can be detached to clean the bottle 40 and the base unit 50, respectively, at a later time. Alternatively, the lower end 42 of the bottle 40 does not allow a user to disassemble the bottle 40 and the base unit 50 after being mounted to the base unit 50. Still alternatively, at least a portion of the structure of the bottle body 40 and the base unit 50 may be integrally formed.

It should be noted that in the following description, the contents and features of the smart container 100 of the present invention will be continuously disclosed and described by taking the example that the lower end portion 42 of the bottle body 40 is detachably mounted to the base unit 50, but those skilled in the art should understand that the smart container 100 shown in fig. 1C to 13 is only an example and should not be construed as limiting the contents and scope of the smart container 100 of the present invention.

Referring to fig. 2 and 3, the base unit 50 includes a base body 51, the base body 51 further includes a base upper frame 511, a base lower frame 512, and a cover film 513, wherein the base upper frame 511 and the base lower frame 512 are mounted to each other to form a mounting space 510 between the base upper frame 511 and the base lower frame 512, and the cover film 513 is provided to the base upper frame 511.

Specifically, the upper base frame 511 has an upper frame penetrating hole 5111, wherein the upper frame penetrating hole 5111 of the upper base frame 511 communicates with the installation space 510 after the upper base frame 511 and the lower base frame 512 are installed to each other to form the installation space 510 between the upper base frame 511 and the lower base frame 512. In other words, the base body 51 has the installation space 510 and the upper frame penetration 5111 communicating with the installation space 510. The cover film 513 is provided to the pedestal upper frame 511 such that at least a portion of the cover film 513 covers at least a portion of the pedestal upper surface 5112 of the pedestal upper frame 511, and such that the upper frame perforation 5111 of the pedestal upper frame 511 corresponds to the cover film 513. That is, the cover film 513 closes the upper shelf perforations 5111 at the base upper surface 5112 of the base upper shelf 511. Accordingly, the lower base frame 512 has a lower frame penetration 5121, wherein the lower frame penetration 5121 of the lower base frame 512 communicates with the installation space 510 formed between the upper base frame 511 and the lower base frame 512. In other words, the base body 51 has the installation space 510 and the upper shelf penetration 5111 and the lower shelf penetration 5121 communicating with the installation space 510, respectively.

Preferably, the cover film 513 is provided to the upper pedestal frame 511 in such a manner as to be formed on the upper pedestal surface 5112 of the upper pedestal frame 511. Alternatively, the cover film 513 is provided to the upper chassis 511 in such a manner as to be attached to the upper chassis surface 5112 of the upper chassis 511. In the following description, the disclosure and description of the contents and features of the smart container 100 of the present invention will be continued by taking the case where the cover film 513 is formed on the base upper surface 5112 of the base upper frame 511 and is disposed on the base upper frame 511 as an example.

It should be noted that the mounting manner of the base upper frame 511 and the base lower frame 512 is not limited in the smart container 100 of the present invention, for example, in one preferred example of the smart container 100 of the present invention, the base upper frame 511 and the base lower frame 512 can be mounted together in a screw-coupled manner, and in another preferred example of the smart container 100 of the present invention, the base upper frame 511 and the base lower frame 512 are mounted together in a glue-coupled manner.

The base unit 50 further comprises a sensor 52, wherein the sensor 52 comprises a sensor cantilever 521 and a sensor body 522 arranged at a free end of the sensor cantilever 521, wherein a connection end of the sensor cantilever 521 is arranged at the base lower frame 512. Preferably, the connection end of the sensor suspension 521 is provided to the base lower frame 512 in a mounted manner. Nevertheless, in other alternative examples of the smart container 100 of the present invention, the connection end of the sensor cantilever 521 of the sensor 52 may be provided to the base upper rack 511.

The sensor 52 is held in the mounting space 510 of the base body 51 formed between the base upper frame 511 and the base lower frame 512, and at least a portion of the sensor main body 522 of the sensor 52 is held in the upper frame penetration 5111 of the base upper frame 511, and the sensor upper surface 5221 of the sensor main body 522 is directed toward the cover film 513 so that the cover film 513 can be brought into contact with the sensor upper surface 5221 of the sensor main body 522 later. Preferably, the portion of the sensor body 522 held at the upper frame penetration 5111 of the upper frame base 511 is not in contact with the inner wall of the upper frame base 511 for forming the upper frame penetration 5111, in such a manner that the sensor 52 can accurately sense the pressure from the cover film 513. Preferably, the cover film 513 directly contacts the sensor upper surface 5221 of the sensor body 522 after the sensor body 522 is held at the upper shelf perforation 5111 of the base upper shelf 511. For example, the sensor upper surface 5221 of the sensor body 522 is flush with the base upper surface 5112 of the base upper frame 511, so that the cover film 513 formed on the base upper surface 5112 of the base upper frame 511 directly contacts the sensor upper surface 5221 of the sensor body 522. Or the sensor upper surface 5221 of the sensor body 522 protrudes from the base upper surface 5112 of the base upper frame 511 such that the cover film 513 formed on the base upper surface 5112 of the base upper frame 511 directly contacts the sensor upper surface 5221 of the sensor body 522. Alternatively, the sensor upper surface 5221 of the sensor body 522 may be lower than the base upper surface 5112 of the base upper frame 511, and may be in contact with the sensor upper surface 5221 of the sensor body 522 after the cover film 513 is deformed later.

Preferably, the sensor cantilever 521 of the sensor 52 has an "i" shape, and the sensor cantilever 521 may have at least one heat dissipation channel, in such a way that not only the fluidity of air at both sides of the sensor cantilever 521 can be increased, but also the heat dissipation area of the sensor cantilever 521 can be increased, so as to facilitate preventing or reducing the heat transfer of the substance added to the receiving chamber 110 of the smart container 100 to the sensor 52, thereby ensuring the accuracy of the sensor 52, in such a way that the stability and reliability of the smart container 100 can be further ensured.

In addition, the base unit 50 further includes a heat insulating part 53, wherein the heat insulating part 53 is formed on the surface of the cover film 513 and/or the sensor main body 522 of the sensor 52, for example, the heat insulating part 53 may be formed on the sensor upper surface 5221 of the sensor main body 522, in such a manner that heat of a substance added to the smart container 100 can be prevented from being transferred to the sensor 52 via the cover film 513, thereby maintaining the temperature of the sensor 52 in a proper range to avoid affecting the accuracy of the sensor 52. In addition, the heat insulating part 53 may be formed at least one of the upper base frame 511 and the lower base frame 512 to further prevent heat of the substance added to the smart container 100 from being transferred to the sensor 52 via the upper base frame 511 and the lower base frame 512.

In a specific example of the smart container 100 of the present invention, a heat insulating material may be sprayed on at least a portion of the surface of the cover film 513, the sensor 52, at least a portion of the surface of the base upper frame 511, and at least a portion of the surface of the base lower frame 512 to form the heat insulating portion 53 on at least a portion of the surface of the cover film 513, the sensor 52, at least a portion of the surface of the base upper frame 511, and at least a portion of the surface of the base lower frame 512 by the heat insulating material later.

With further reference to fig. 2 and 3, the base unit 50 includes a housing 54, wherein the base body 51 is mounted to the housing 54 to protect the base body 51 by the housing 54 in such a manner as to surround the outside of the base body 51. The housing 54 has a mounting passage 540, wherein the mounting passage 540 communicates with the mounting space 510 of the base body 51 via the lower frame penetration 5121 of the base lower frame 512, and wherein a battery 200 can be mounted to the mounting space 510 of the base body 51 via the mounting passage 540 of the housing 54 and the lower frame penetration 5121 of the base lower frame 512. The base unit 50 further includes a battery cover 55, wherein the battery cover 55 is mounted to the housing 54 to close the mounting channel 540 of the housing 54 by the battery case 55. Preferably, the battery case 55 is detachably mounted to the housing 54 such that the battery 200 mounted to the mounting passage 540 is replaceable.

In addition, the base unit 50 further includes a processor 56 and a display screen 57, wherein the processor 56 is disposed in the installation space 510 of the base body 51, the display screen 57 is disposed in the housing 54, and the display screen 57 and the sensor 52 are respectively connected to the processor 56 so that the display screen 57 can display information obtained by the sensor 52. Preferably, the base unit 50 includes a circuit board 58, wherein the circuit board 58 is disposed in the installation space 510 of the base body 51, and the sensor 52, the processor 56 and the display 57 are connected to the circuit board 58, respectively, such that the sensor 52 and the display 57 are connected to the processor 56 via the circuit board 58, respectively.

Referring to fig. 2 and 3, the housing 54 has an internal screw structure, and the lower end portion 42 of the bottle body 40 has an external screw structure, wherein the external screw structure of the lower end portion 42 of the bottle body 40 and the internal screw structure of the housing 54 can be engaged with each other so that the bottle body 40 is mounted to the base unit 50, thereby causing the base body 51 of the base unit 50 to close the lower end opening 420 of the lower end portion 42 of the bottle body 40, thereby forming the receiving chamber 110 between the bottle body 40 and the base unit 50. It will be appreciated by those skilled in the art that in this preferred example of the smart container 100 shown in fig. 2 and 3, the cover film 513 of the base unit 50 closes the lower end opening 420 of the bottle body 40, thereby forming the receiving cavity 110 between the base unit 50 and the bottle body 40. Alternatively, in other possible examples of the smart container 100, the base upper surface 5112 of the base upper frame 511 of the base body 51 of the base unit 50 may close the lower end opening 420 of the bottle body 40, thereby forming the accommodating chamber 110 between the base unit 50 and the bottle body 40, and at this time, the cover film 513 is held within the accommodating chamber 110.

Preferably, in this preferred example of the smart container 100 shown in fig. 2 and 3, the cover film 523 covers the base upper surface 5112 of the base upper frame 511 and further covers the base peripheral wall 5113 of the base upper frame 511, so that after the base body 51 is mounted to the housing 54, the cover film 523 is provided between the base body 51 and the housing 54 to secure sealability between the base body 51 and the housing 54. And the cover film 523 is provided between the bottle body 40 and the base upper frame 511 of the base body 51 after the lower end portion 42 of the bottle body 40 is mounted to the housing 54 in such a manner that the cover film 523 further covers the base peripheral wall 5113 of the base upper frame 511 to secure sealability between the bottle body 40 and the base upper frame 511, thereby preventing leakage of water or a mixture of water and milk powder added to the receiving chamber 110 of the smart container 100, thereby securing reliability of the smart container 100 when in use.

Fig. 4 and 5 show a state in which the smart container 100 is implemented as a feeding bottle, and the feeding bottle is used. Referring to fig. 4, after water is added to the receiving chamber 110 of the smart container 100, as the amount of water added to the receiving chamber 100 is changed, the water pressure deforms the portion of the cover film 513 corresponding to the upper frame penetration 5112 of the base upper frame 511 in the direction of the installation space 510 of the base body 51, and the deformed cover film 513 further presses the sensor 52 such that the sensor 52 obtains the amount of water added to the receiving chamber 110 by sensing the pressure or weighing, and can be digitally displayed on the display screen 57 for convenient viewing by a user. Referring to fig. 5, after milk powder is added to the receiving chamber 110 of the smart container 100, the pressure generated by water and milk powder further deforms the portion of the cover film 513 corresponding to the upper frame penetration 5112 of the base upper frame 511 toward the installation space 510 of the base body 51, and the deformed cover film 513 further presses the sensor 52 such that the sensor 52 obtains the amount of milk powder added to the receiving chamber 110 by sensing the pressure or weighing, and can be digitally displayed on the display screen 57 for convenient viewing by a user. It will be appreciated by those skilled in the art that after the amount of water and milk powder added to the receiving chamber 110 of the smart container 100 is obtained, the ratio of water and milk powder of the receiving chamber 110 of the smart container 100 can be precisely controlled and displayed on the display screen 57 in a digital manner for convenient viewing by a user, thereby advantageously ensuring healthy growth of infants and children.

Preferably, the base unit 50 of the smart container 100 further includes a memory 59, wherein the memory 59 is disposed in the installation space 510 of the base body 51, and the memory 59 is connected to the processor 56. After each use of the smart container 100, the data of the smart container 100 may be stored in the memory 59, for example, when the smart container 100 is implemented as the milk bottle, after each use of the smart container 100 implemented as the milk bottle for brewing milk powder, the amount of milk powder and the ratio of water and milk powder to be brewed can be stored in the memory 59 for subsequent review by the user through the display screen 57.

More preferably, the base unit 50 of the smart container 100 further comprises a communication mechanism 60, wherein the communication mechanism 60 is disposed in the installation space 510 of the base body 51, and the communication mechanism 60 is connected to the processor 56, wherein the communication mechanism 60 is communicably connected to an electronic device, for example, the communication mechanism 60 may be communicably connected to a smart phone, a tablet computer, a smart bracelet, a notebook computer, a personal digital assistant, an electronic book, or the like, which is used by a user. When infusing milk powder with the smart container 100 implemented as the feeding bottle, the smart container 100 may send the amount of water, the amount of milk powder, and the ratio of water and milk powder, which are obtained by the communication mechanism 60 and added to the receiving cavity 110 of the smart container 100, to the electronic device for the user to view through the electronic device. That is, the smart container 100 implemented as the feeding bottle allows a user to remotely obtain the amount of milk powder, and the ratio of water and milk powder infused with the smart container 100, for example, the smart container 100 allows the user to remotely obtain the amount of milk powder, and the ratio of water and milk powder infused with the smart container 100 through the electronic device, in such a way that it is particularly advantageous to ensure physical health of infants and children.

Referring to fig. 6 to 13 of the drawings, which are illustrative of the description of the present invention, a process for manufacturing the smart container 100 is disclosed and described in the following description, wherein the pedestal upper frame 511 is provided with reference to the stage shown in fig. 6, wherein the pedestal upper frame 511 has one of the upper frame perforations 511.

In the stage shown in fig. 7 to 9, the cover film 513 is formed on the base upper surface 5112 of the base upper frame 511 by a molding die 300. Specifically, the molding die 300 includes a first die 301 and a second die 302, wherein at least one of the first die 301 and the second die 302 is capable of being clamped and unclamped, such that the molding die 300 is capable of being clamped and unclamped. The first mold 301 further has at least one molding protrusion 3011, wherein after the second mold 302 and the first mold 301 are closed, the molding protrusion 3011 of the first mold 301 faces the second mold 302, and a molding gap 303 is formed between the molding protrusion 3011 of the first mold 301 and an inner wall of the second mold 302.

Specifically, in the stage shown in fig. 7, the molding protrusion 3011 of the first mold 301 is provided to the first mold 301 so as to be held by the upper frame hole 511 of the first mold 301, the molding mold 300 is subjected to a mold clamping operation in such a manner that the second mold 302 is operated to move toward the first mold 301, and after the first mold 301 and the second mold 302 are clamped, a molding space 304 is formed between the inner wall of the second mold 302 and the base upper surface 5112 and the base peripheral wall 5113 of the base upper frame 511, and the molding space 304 communicates with the molding space 303. It is worth mentioning that the outer wall of the molding protrusion 3011 of the first mold 301 is identical in size to the upper frame penetration 5111 of the upper frame base 511, so that after the molding protrusion 3011 of the first mold 301 is held at the upper frame penetration 5111 of the upper frame base 511, it is possible to avoid the generation of a gap between the outer wall of the molding protrusion 3011 of the first mold 301 and the inner wall of the upper frame base 511 for forming the upper frame penetration 5111.

In the stage shown in fig. 8, a fluid molding material is added to the molding gap 303 and the molding space 304, and after the molding material fills the molding gap 303 and the molding space 304, the molding material is cured. In the stage shown in fig. 9, after the molding material is solidified in the molding gap 303 and the molding space 304 to form the cover film 513, a drawing operation is performed on the first mold 301 and the second mold 302 of the molding die 300 to obtain a base upper frame with a cover film. Preferably, the cover film 513 is formed of the molding material having better elasticity, in such a way that the accuracy and reliability of the smart container 100 can be increased.

In the stage shown in fig. 10, the heat insulating material is applied to the portion of the cover film 513 facing the upper frame perforation 5111 of the base upper frame 511 so that the heat insulating material forms the heat insulating portion 53. Alternatively, the surface of the pedestal upper frame 511 may be coated with the heat insulating material to form the heat insulating part 53.

In the stage shown in fig. 11, the lower chassis 512 to which the sensor 52 is mounted to the upper chassis 511 in such a manner that the sensor body 522 of the sensor 52 is held at the upper chassis penetration 5111 of the upper chassis 511, wherein the mounting space 510 is formed between the upper chassis 511 and the lower chassis 512, and the outer wall of the sensor body 522 of the sensor 52 is not in contact with the inner wall of the upper chassis 511 for forming the upper chassis penetration 5111, and the sensor upper surface 5221 of the sensor body 522 is adhered to the cover film 513. It is understood that the base body 51 is formed after the base upper frame 511 and the base upper frame 512 are mounted together.

In the stage shown in fig. 12, the base unit 50 is formed by attaching the base body 51 to the housing 54. At the stage shown in fig. 13, the lower end 42 of the bottle body 40 is mounted to the housing 54 to close the lower end opening 420 of the bottle body 40 by the base unit 50, thereby forming the receiving chamber 110 between the base unit 50 and the bottle body 40, thereby manufacturing the smart container 100. It will be appreciated that at the stage shown in fig. 11, the processor 56, the circuit board 58, the memory 59 and the communication mechanism 60 are mounted to the mounting space 510 of the base body 51, respectively.

Fig. 14 shows an application of the smart container 100, wherein the smart container 100 is embodied as the milk bottle in real time, wherein the smart container 100 embodied as the milk bottle is detachably mounted to a breast pump body 2 to form a breast pump by the smart container 100 and the breast pump body 2. That is, according to another aspect of the present invention, referring to fig. 14, the breast pump further comprises one of the breast pump bodies 2 and the smart container 100 detachably provided to the breast pump body 2. It should be noted that the installation manner between the breast pump body 2 and the intelligent container 100 is not limited. When a user draws milk using the breast pump, based on the same principle, the intelligent container 100 can obtain the amount of milk drawn and digitally display it on the display screen 57 of the intelligent container 100 for viewing by the user. In addition, the amount of breast milk sucked by the user using the breast pump can be transmitted to the electronic device through the communication mechanism 60 of the base unit 50 of the smart container 100 to analyze the health degree of the user through the amount of breast milk by the application program of the electronic device and can give the related guidance. Alternatively, the amount of breast milk absorbed by the user using the breast pump may be sent to an expert or a nutrition manager through the communication means 60 of the base unit 50 of the smart container 100, which can analyze the health of the user according to expert knowledge and experience and can give related guidance.

Fig. 15 shows a modified embodiment of the smart container 100, unlike the smart container 100 shown in fig. 2 and 3, in this specific example of the smart container 100 shown in fig. 15, the base upper frame 511 of the base body 51 further has at least one groove 5114, wherein an opening of the groove 5114 is formed in the base upper surface 5112 of the base upper frame 511, and a portion of the cover film 513 is formed in the groove 5114 of the base upper frame 511, in such a manner that the bonding strength of the cover film 513 and the base upper frame 511 can be increased, so that the cover film 513 can be prevented from falling off from the base upper frame 511 during use of the smart container 100 and cleaning of the smart container 100. It should be noted that the shape of the groove 5114 of the base upper frame 511 is not limited, and the groove 5114 may be an annular groove or a shape groove. In addition, although in this particular example of the smart container 100 shown in fig. 15, the groove 5114 is a blind hole, in other possible examples of the smart container 100 of the present invention, the smart container 100 may be a perforated hole. Or a portion of the grooves 5114 are blind holes and another portion of the grooves 5114 are perforated.

Preferably, the groove 5114 of the upper chassis 511 is formed at an edge of the upper chassis 511. In yet another modified embodiment of the smart container 100 shown in fig. 16 of the present invention, the groove 5114 of the upper base frame 511 is formed at the middle of the upper base frame 511.

Fig. 17 shows another variant embodiment of the smart container 100, which differs from the smart container 100 shown in fig. 2 and 3 in that in this particular example of the smart container 100 shown in fig. 17, the base upper frame 511 and the base lower frame 512 of the base body 51 may also be of unitary construction.

Fig. 18 shows another variant embodiment of the smart container 100, unlike the smart container 100 shown in fig. 2 and 3, in this particular example of the smart container 100 shown in fig. 18, the base lower frame 512 of the base body 51 and the housing 54 may also be of unitary construction.

Fig. 19 shows another variant embodiment of the smart container 100, unlike the smart container 100 shown in fig. 2 and 3, in this particular example of the smart container 100 shown in fig. 19, the base upper frame 511 and the cover film 513 of the base body 51 may also be of an integral structure, for example, the base upper frame 511 and the cover film 513 of the base body 51 may be integrally formed by a molding process by the molding die 300.

Fig. 20 shows another variant embodiment of the smart container 100, unlike the smart container 100 shown in fig. 2 and 3, in this particular example of the smart container 100 shown in fig. 20, the base unit 50 includes one base body 51 and one sensor 52 provided to the base body 51, wherein the sensor 52 is held in the receiving chamber 110 when the bottle 40 is mounted to the base unit 50 while the receiving chamber 110 is formed between the bottle 40 and the base unit 50. It will be appreciated that, unlike the smart container 100 shown in fig. 2 and 3, in this particular example of the smart container 100 shown in fig. 20, after water is added to the receiving cavity 110 of the smart container 100, the water can directly contact the sensor 52 to obtain the amount of water added to the receiving cavity 110 of the smart container 100 by sensing pressure or weighing by the sensor 52.

With further reference to fig. 1A and 1B, the smart device 20 includes a monitoring device 21, and when the monitoring device 21 is connected to the container body 10, the monitoring device 21 can monitor physical information of the substance contained in the container body 10 in real time, such as: temperature information and characterization information (e.g., mass, volume, etc.), and the monitoring device 20 forms at least one physical signal corresponding to the physical information. In the embodiment of the smart container 100 of the present invention such as fig. 1A and 1B, the detecting device 21 can be connected to the container body 10 in such a manner that the container body 10 is mounted to the smart device 20. For example, in this particular example of the smart container 100 shown in fig. 1C, the monitoring device 21 may obtain the physical information, which may be, for example, the amount of water, added to the receiving cavity 110 of the smart container 100 in real time via the sensor 52. That is, the content of the physical information of the monitoring device 21 may be the amount of water added to the receiving chamber 110 of the smart container 100.

It should be noted that the monitoring device 21 can also record the relevant situation of each time the user uses the smart container 100, for example: when a user uses the intelligent container 100 to dispense milk powder, the monitoring device 21 can record the number of uses of the intelligent container 100 and the ratio of the amount of dispensed milk powder to the water and milk powder in the milk powder per use.

As shown in fig. 21, the monitoring device 21 further comprises a characterization monitoring component 211, wherein the characterization monitoring component 211 is configured to monitor and record in real time the physical information, such as the mass, volume, concentration, etc., of the substance contained in the container body 10 to form a corresponding physical signal, for example, the characterization monitoring component 211 may obtain in real time the physical information added to the containing cavity 110 of the smart container 100 via the sensor 52.

In a further embodiment, the characterization monitoring assembly 211 of the smart container 100 of the present invention is implemented as a gravity sensor, or a load cell, or a touch sensor, or a barometric sensor, wherein the characterization monitoring assembly 211 is capable of monitoring and recording the weight of a substance located in the receiving cavity 110 of the container body 10 to form a physical signal of the substance when the smart device 20 is mounted to the container body 10. In this particular example of the smart container 100 shown in fig. 1C, the characterization detection assembly 211 may be implemented as the sensor 52 such that the characterization detection assembly 211 is able to obtain the weight of water and the weight of milk powder added to the receiving cavity 110 and subsequently the ratio of water and milk powder infused with the smart container 100.

It will be appreciated by those skilled in the art that the characterization monitoring assembly 211 in the present invention may convert the weight of the substance in the accommodating cavity 110 of the container body 10 monitored and recorded by the gravity sensor into the volume of the substance, etc. to form a corresponding physical signal, which is merely for example capable of enabling those skilled in the art to implement the present invention, and those skilled in the art will recognize other embodiments consistent with the spirit of the present invention, and the present invention is not limited thereto.

The monitoring device 21 further comprises a temperature monitoring assembly 212, wherein the temperature monitoring assembly 212 is capable of monitoring and recording temperature information of the substance located in the receiving cavity 110 of the container body 10 in real time to form a corresponding physical signal when the smart device 20 is mounted to the container body 10.

Preferably, the bottom wall 11 of the container body 10 may be made of a heat sensitive material to improve the sensitivity of the temperature monitoring assembly 212 to monitor the change in temperature of the substance located in the receiving cavity 110 of the container body 10. Those skilled in the art will appreciate that the temperature monitoring assembly 212 of the present invention may be implemented as a temperature sensor or a temperature monitoring circuit, and that other obvious variations will occur to those skilled in the art, and the present invention is not limited in this respect.

The smart device 20 further comprises a processing means 22. In one embodiment of the invention, the processing means 22 are connected to the monitoring means 21 to be able to acquire the corresponding physical signals formed by the monitoring means 21.

Specifically, the processing device 22 includes an analyzing component 221, where the analyzing component 221 is connected to the monitoring device 21, so as to obtain a physical signal formed by the monitoring device 21.

It should be noted that the analyzing component 221 can also obtain a reference signal, where the analyzing component 221 is further capable of comparing and analyzing the reference signal with the physical signal, so as to form a result signal, by which a user can accurately perform the next operation.

Preferably, the processing device 22 further comprises a storage component 222, wherein the reference signal can be stored in the storage component 222, wherein the reference signal can be implemented as a standard value of the related physical information of the substance to be configured.

Those skilled in the art will appreciate that the reference signal may be provided by the user in the analysis component 221, or the analysis component 221 may be read from other hardware or software (including web pages). For example, when a user needs to borrow the smart container to dispense a certain amount of coffee, the reference signal may be a manually set amount of coffee to be added and an amount of hot water to be added. According to an embodiment of the present invention, when the quality of the coffee corresponding to the reference signal is lower than the quality of the coffee corresponding to the physical signal, the result signal corresponds to an instruction to the user to continue adding coffee.

According to an embodiment of the present invention, the smart device 20 further includes a communication device 23, the communication device 23 is connected to the container body 10, and the communication device 23 is connected to the monitoring device 21, so as to be capable of acquiring the physical signal monitored by the monitoring device 21.

Further, the communication device 23 can transmit the acquired physical signal to a terminal (e.g., intelligent robot, electronic device, virtual cloud, etc.). That is, when the user needs to use the container body 10 to dispense the solution, the conventional scale marks on the outer wall 12 of the container can be omitted, and the physical signal of the substance measured or dispensed by the intelligent container can be directly known according to the physical signal and the reference signal transmitted by the communication device 23, so that the user can measure the substance with accurate amount or dispense the solution with accurate concentration.

Specifically, the communication device 23 includes a characterization communication component 231, wherein the characterization communication component 231 is connected to the characterization monitoring component 211, so as to obtain a physical signal related to characterization information about the substance contained in the container body 10 monitored by the characterization monitoring component 211.

More specifically, the communication device 23 further comprises a temperature communication component 232, wherein the temperature communication component 232 is connected to the temperature monitoring component 212, so as to be capable of acquiring another physical signal related to the temperature information of the substance contained in the container body 10 monitored by the temperature monitoring component 212.

Further, the characterizing communication unit 231 and the temperature communication unit 232 can respectively transmit the obtained characterizing signal and the obtained temperature signal to an electronic device of the user, so that the user can know the temperature information of the substance in the accommodating cavity of the container body through the electronic device.

According to another embodiment of the invention said communication means 23 are connected to said processing means 22. Specifically, the communication device 23 is connected to the analysis component 221 of the processing device 22, so that the result signal formed by the analysis component 221 can be acquired by the communication device 23, wherein the communication device 23 is further capable of transmitting the acquired result signal to the electronic device of the user. That is, when the user needs to dispense the solution using the container body 10, the user can know whether the substance dispensed using the smart container meets the requirement in a remote manner, and particularly when the smart container is used to dispense the milk powder solution or the aqueous breast milk solution, the user can know the concentration of the milk powder solution or the aqueous breast milk solution dispensed by the user using the smart container in real time through an electronic device even if the user cannot dispense the milk powder solution or the aqueous breast milk solution personally.

In another embodiment of the present invention, the processing device 22 is implemented as a cloud processing program, and the processing program is communicatively connected to the communication device 23. The processing program can be communicatively connected to a terminal (e.g., intelligent robot, electronic device, virtual cloud, etc.), so that a user can obtain the result signal by means of an electronic device.

It will be appreciated by those skilled in the art that the reference signal in this embodiment may be a signal manually set by the user or may be any signal obtained by the analysis module 232 from the internet and corresponding to a standard parameter, where the standard signal may be the concentration of milk powder consumed by infants of each age group.

Those skilled in the art will appreciate that in one embodiment of the present invention, the communication device 23 may be implemented as a bluetooth module.

In another embodiment of the present invention, the smart device 20 comprises an indication means 24, wherein the indication means 24 is connected to the monitoring means 21, wherein the indication means 24 comprises a characterization indication component 241 and a temperature indication component 242, wherein the characterization indication component 241 and the temperature indication component are connected to the characterization monitoring component 211 and the temperature monitoring component 212, respectively, for communicating physical signals acquired from the characterization monitoring component 211 and the temperature monitoring component 212, respectively, to a user, the physical signals specifically corresponding to mass information and temperature information of a substance according to an embodiment of the present invention.

It should be noted that the indication means 24 may be implemented as an LED display screen, the electronic screen may directly display the physical signal of the substance located in the container body 10, and preferably the indication means may be configured as a virtual display screen, and the virtual display screen may be projected on the outer wall of the container body 10. Alternatively, the indication means 24 may be embodied as a voice prompt means which is capable of informing the user of the physical signal of the substance located in the container body 10 directly by means of voice prompt.

According to another embodiment of the present invention, the indicating device 24 is connected to the analyzing component 221 of the processing device 22, so that the result signal formed by the analyzing component 221 can be transmitted to the user through the indicating device 24.

According to another embodiment of the present invention, the smart device 20 includes both the communication device 23 and the indicating device 24, wherein the indicating device 24 is connected to the communication device 23, and further, when the processing device 22 is implemented as a cloud processing program, the indicating device 24 is also capable of acquiring the result signal from the communication device 23. It should be noted that the communication device 23 is also communicatively connected to a terminal (e.g., intelligent robot, electronic device, virtual cloud, etc.).

That is, the user can not only know the physical signal of the substance in the receiving cavity 110 of the container body 10 in real time through the indicating device 24, but also know the physical signal of the substance in the receiving cavity 110 of the container body 10 remotely through an electronic device connected to the communication device 23.

The smart device 20 further comprises a heating means 25. According to an embodiment of the present invention, the heating device 25 is connected to the indicating device 24, so that the working state of the heating device 24 is transmitted to the user through the indicating device 24.

According to an embodiment of the present invention, the heating device 25 is connected to the analysis module 221 of the processing device 22, so that the heating device 25 is selectively activated or deactivated after obtaining a temperature-related result signal generated by the analysis module 221, wherein the substance in the accommodating cavity of the container body 10 is heated when the smart device 20 is mounted to the container body 10 and the heating device 25 is driven to operate.

Specifically, the reference signal provided by the storage unit 222 in the processing unit 22 may be a reference signal corresponding to a temperature, and when the temperature in the physical signal received by the analysis unit 221 is lower than the temperature in the reference signal, the heating unit 25 is driven to heat the container body by the result signal formed by the analysis unit 221; the heating device 25 does not operate when the temperature in the physical signal received by the analysis component 221 is not lower than the temperature in the reference signal.

According to another embodiment of the present invention, wherein the heating means 25 is connected to the temperature communication assembly 232 of the communication means 23, the substance located in the receiving chamber 110 of the container body 10 is heated when the smart device 20 is mounted to the container body 10 and the heating means 25 is driven to operate.

Specifically, the reference signal provided by the storage component 222 in the processing device 22 may be a reference signal corresponding to a temperature, and when the temperature in the physical signal acquired by the analysis component 221 is lower than the temperature in the reference signal acquired from the storage component 222, the temperature-related result signal formed by the analysis component 221 is transmitted to the heating device 22 through the temperature communication component 232 so that the heating device 25 is driven; when the temperature in the physical signal received by the analysis component 221 is not lower than the temperature in the reference signal, the resulting signal transmitted by the temperature communication component 232 will not drive the heating device 25 to operate. That is, the heating means 25 is automatically controlled to be turned on and off in the present invention, thereby enabling the substance located in the container body 10 to be maintained above a critical temperature.

Specifically, the heating device 25 includes a control component 251 and a heating component 252, wherein the heating component 252 can heat the container body 10 by the heating component 252 when the smart device 20 is mounted on the container body 10.

Wherein the control assembly 251 is coupled to the analysis assembly 221 and the heating assembly 251 in accordance with one embodiment of the present invention. According to another embodiment of the present invention, wherein said control assembly 251 is connected to said communication means 23 and said heating assembly 252.

When the control module 251 is turned on, the result signal generated by the analysis module 221 is transmitted to the heating module 252, so that the heating module is automatically controlled to be turned on and off; when the control unit 251 is turned off, the temperature-related result signal generated by the analysis unit 221 cannot be transmitted to the heating unit 252, and at this time, the temperature-related result signal generated by the analysis unit 22 may be implemented to prompt the user to turn on the control unit 251 of the heating device 25. That is, the user can selectively operate the heating assembly 252 of the heating device 25 as desired.

Referring to fig. 24A, 24B and 24C, when the container body 10 is implemented as a feeding bottle, wherein graduation marks provided on a conventional feeding bottle can be selectively provided on the container body 10, wherein the monitoring device 21 can monitor physical signals of the powdered milk solution in the receiving chamber 110 of the container body 10 when the smart device 20 is provided to the container body 10, according to an embodiment of the present invention. When a user needs to dispense milk powder of a desired concentration, an appropriate amount of water may be first added to the receiving chamber 110 of the container body 10.

It should be noted that, during the process of adding water to the container body 10, the characterization monitoring component 211 of the monitoring device 21 can monitor and record, in real time, characterization information of the water added to the containing cavity 110 of the container body 10, such as: the quality of the added water, the rate of the added water, the volume of the added water, etc., and in particular, according to the embodiment of the present invention, the characterization monitoring component 211 of the monitoring device can monitor and record the physical information of the quality of the water added to the receiving cavity 110 of the container body 10 in real time to form a first physical signal,

According to an embodiment of the invention, the communication means 23 connected to the monitoring means 21 are able to transmit a first physical signal received by the quality of the water in the containing cavity 110 of the container body 10 to the electronic device of the user, so that the user can know the quality of the water in the containing cavity 110 of the container body 10 by means of the electronic device.

According to another embodiment of the present invention, the user can also know the quality of the water in the receiving chamber 110 of the container body 10 by means of the indicating device 24.

Preferably, according to an embodiment of the invention, said first physical signal of the quality of the water is transmitted to said analysis component 221 of said processing means 22 by means of said characterizing communication component 231 of said communication means 23.

Further, the processing device 22 can compare and analyze the first physical signal with the first reference signal stored in the storage component 222 in advance to form a first result signal, wherein the first result signal is transmitted to the electronic device of the user through the communication device 23, so that the user can refer to the feedback information for further operation.

It should be noted that the result signals are stored in the storage component 222 at the same time, so that the user can retrieve and review the result signals at any time and set the result signals as the first reference signals, and further, the user can prepare the milk powder solution with the same concentration for multiple times.

It will be appreciated by those skilled in the art that in this example, when a user cannot dispense milk powder or concentration of breast milk by himself, the user can further know the quality of water added into the receiving chamber 110 of the container body 10 by means of an electronic device, so that the user can instruct the person using the smart container to dispense milk powder solution by remote manner to add accurate quality water into the receiving chamber 110 of the container body 10.

According to another embodiment of the present invention, the temperature communication means 232 is capable of communicating not only the received first physical signal, i.e. the quality of the water in the receiving cavity 110 of the container body 10, to the user, but also the received first result signal to the user via the indicating means 24.

In the above embodiment, the first reference signal preset in the storage component 222 may be selected from the mass of water to be added corresponding to the concentration of milk powder to be prepared set by a user through a terminal (e.g. intelligent robot, electronic device, virtual cloud, etc.), and the first reference signal may also be the international standard mass of practical milk powder to be added for infants of the age group corresponding to the infants of the user stored in the storage component 222 in advance.

Subsequently, the user can add milk powder to the receiving chamber 110 of the container body 10, and likewise, during the process of adding milk powder to the receiving chamber 110 of the container body 10, the characterization monitoring component 211 of the monitoring device 21 can also monitor and record the quality of the added milk powder in real time to form a second physical signal, and likewise, the second physical signal is transmitted to the analyzing component 221 of the processing device 22 by the characterization communication component 231 of the communication device 23, and the analyzing component 221 further compares the second physical signal with a second reference signal preset in the storing component 222 to form a second result signal, wherein the second result signal can be transmitted to the user.

Wherein the second reference signal may be implemented as selected from: the concentration of the milk powder to be prepared set by the user through a terminal (for example, intelligent robot, electronic device, virtual cloud end, etc.) may be one or more of the mass of milk powder to be added or the mass of milk powder required by the international standard of practical milk powder of infants of the age group corresponding to the infants of the user stored in the storage unit 222 in advance.

In the above embodiment, the second result signal formed by the analysis component 221 of the processing device 22 during the process of adding milk powder to the receiving chamber 110 of the container body 10 by the user may be further implemented as: instruct the user to continue adding milk powder or instruct the user to stop adding milk powder.

In an embodiment of the invention, wherein the result signal is implemented as a voice prompt, such as "continue adding" or "stop adding", etc., the result signal can be directly implemented by the information analyzer to an application on the user electronic device.

In another embodiment of the present invention, the result signal may be transmitted to the user's electronic device in the form of a graphic (including a graphic or text, etc.) that is edited.

According to another embodiment of the present invention, the analyzing component 221 of the processing device 22 may also receive a third physical signal, which is a temperature of the milk powder solution in the receiving chamber 110 of the container body 10, monitored and recorded by the temperature monitoring component 212 of the monitoring device 21, so as to transmit the temperature information to the analyzing component 221 of the processing device 22 through the temperature communication component 212, wherein the analyzing component 221 further performs a comparative analysis on the received temperature information with a third reference signal preset in the storing component 222 to form a third result signal, and according to an embodiment of the present invention, the third result signal can be further transmitted to a user through the temperature communication component 232 of the communication device 23.

According to another embodiment of the invention, a third result signal is communicated to the user by means of the indicating means 24.

According to an embodiment of the present invention, when the control component 251 of the heating device 25 is in an off state and the temperature in the third physical signal monitored and recorded by the temperature monitoring component 212 is lower than the temperature in the third reference signal, the third result signal may be set to prompt the user to turn on the temperature initialization element, for example, a voice prompt ("please turn on the control component").

Wherein the third reference signal may be implemented as any temperature above the minimum temperature required for an international dispensing milk powder, wherein the heating means 22 is not activated when the temperature recorded by the temperature information is higher than the third reference signal; when the temperature of the temperature information record is lower than the temperature set by the third reference signal, the processing device 22 will drive the heating device 22 to operate to heat the outer wall 12 of the container body 10.

As can be appreciated from the above description, when the user cannot personally prepare the milk powder due to various situations, the user can further know the usage of the smart device 20 in real time by using a terminal (e.g. smart robot, electronic device, virtual cloud, etc.) and the first transceiver of the processing device 22.

From the above description, it will be appreciated by those skilled in the art that the use of the smart container of the present invention enables accurate metering of a substance desired by a user, such as a milk powder container, and that the user can remotely understand the use of the smart container. Especially, when the intelligent container is used for dispensing milk powder, a user can accurately dispense the milk powder with required concentration, and when the user cannot dispense the milk powder personally due to reasons, other caregivers can monitor the situation that the intelligent container is used for dispensing the milk powder in a remote mode, and in addition, the user can set the concentration of the milk powder to be dispensed in the remote mode.

According to another embodiment of the present invention, when the main body is used to dispense chemical agents, the user may install the smart device 20 in the container main body 10, and then may first add a solute or a solvent into the accommodating cavity 110 of the container main body 10, and similarly, when the user adds a solute or a solvent into the accommodating cavity 110 of the container main body 10, the monitoring device 21 of the smart device 20 may also monitor the quality of the solute or the solvent added into the accommodating cavity 110 of the container main body 10 in real time, and the processing device 22 may also receive the information about the solute or the solvent located in the container main body 10 acquired by the communication device 23 from the monitoring device 21, and then may analyze and compare the information with the information stored in the storing component 222 of the information communication component, and then transmit the result of the analysis and comparison to the user, so that the user determines the following operation according to the communication device 23 or the indication device 24.

Referring to fig. 25, in accordance with another aspect of the present invention, a milk ejection device 300 with a smart container is provided, wherein the milk ejection device 300 is capable of ejecting breast milk from a lactating female.

The milk discharging device 300 comprises a milk discharging device 31, which may be a conventional liquid suction device such as a commercially available breast pump, when the milk discharging device 31 is used by a user. The milk discharger 31 includes a milk discharger body 311, the milk discharger body 311 having an inflow portion 3111 and an outflow portion 3112, a fluid passage 3110 being formed between the inflow portion 3111 and the outflow portion 3112 of the milk discharger body 311, wherein the outflow portion 3112 of the milk discharger body 311 may be installed at the opening 120 of the outer wall 12 of the container body 10 of the smart container such that the fluid passage 3110 is communicated with the receiving chamber 110 of the container body 10, and thus the breast milk discharged by the milk discharger 31 is further guided to the receiving chamber 110 of the container body 10.

It is worth mentioning that the monitoring means 21 of the smart device 20 is capable of monitoring and recording in real time the physical signal of the milk flowing into the receiving chamber 110 of the container body 10 when the milk drawn by the milk discharging means is directed into the receiving chamber 110 of the container body 10: such as one or more selected from the group consisting of temperature, volume or mass of breast milk, rate of removal, and the like. According to an embodiment of the invention, the monitoring device 21 will automatically record the rate at which the milk ejector sucks off milk. That is, the smart container of the present invention can be used to accurately monitor and record the rate at which milk is removed by the milk discharging device 300.

When the milk pump is implemented as a commercially available breast pump, the container body 10 of the smart container may be implemented as a milk bottle, and a user may use the smart device 20 in cooperation to discharge breast milk. It will be appreciated that the characterization monitoring component 211 of the monitoring component 21 of the smart device 20 can monitor and record a fourth physical signal relating to the rate of milk removal by the user when milk is expelled, wherein when the fourth physical signal is communicated to the analysis component 221 of the processing device 22 by the characterization communication component 231 of the communication device 23, the analysis component 221 can compare the received fourth physical signal relating to milk with a fourth reference signal pre-stored or pre-disposed in the storage component 222 of the information exchange component, such as: the flow rate information of normal female breast milk is analyzed and compared, and then a feedback result related to the breast milk is generated. Further, the feedback result about the breast milk is transmitted to the user's electronic equipment through the communication device 23, that is, the user can know whether the breast milk is healthy or not through the communication device 23 communicatively connected to the communication device 23.

It should be noted that, the characterization monitoring component 211 of the monitoring component is further capable of monitoring the amount of milk discharged by the milk discharging device 300 during the period, in other words, according to this embodiment of the method, the characterization monitoring component 211 may also monitor the amount of milk discharged by the milk discharging device during the period, and in medical science, the amount of milk produced during the period of women during the period of lactation may also be a parameter for measuring health of women during the period of lactation, and the parameter also has an international standard, and in this embodiment, the parameter is also pre-stored in the storage component 222 of the processing device 22, and further, after the characterization information (in this embodiment, the amount of milk sucked by the suction device) monitored by the characterization component is transmitted to the analysis component 221 of the processing device 22, the analysis component 221 is capable of analyzing and comparing the received information with the parameter pre-stored in the storage component 222 of the processing device 22, thereby forming a feedback information, further, the feedback information is further communicated to the user by means of the communication device 23, that is directly informed about the health of himself or herself.

Further, the milk discharging device 300 includes a flow control assembly 32, wherein the flow control assembly 32 is disposed in the fluid channel 3110 of the milk discharging device body 31, so that when fluid flows from the inlet 3111 to the outlet 3112, a user can adjust the flow rate of the fluid by adjusting the flow control assembly 32. Preferably, the flow control assembly 32 may be set to different gear positions.

The milk discharging device 300 further comprises a timer 33, wherein the timer 33 is connected to the control unit 32 and is disposed on the milk discharging device main body 311, so that the time of the flow control unit 32 operating at each flow rate is recorded by the timer 33 to form a corresponding data signal. In particular, in the present embodiment, the timer is capable of recording the time when the milk discharging device is operated in different gear positions. It will be appreciated that the timer 33 is capable of recording the total time the milk ejection device is operating.

Preferably, the temperature monitoring component 34 of the fluid channel 3110 of the milk discharging device body 311 monitors the temperature of the liquid flowing through the fluid channel 3110, so as to determine whether the milk discharging device is in an operating state.

More preferably, the milk discharging device 300 further comprises a heater 35, wherein the heater 35 is disposed in the fluid channel 3110 of the milk discharging device body 311, wherein the heater is connected to the temperature sensing assembly such that the heater can be selectively driven by the temperature sensing assembly. Specifically, when the temperature of the liquid flowing through the fluid channel 3110 is lower than the temperature preset in the temperature sensing unit 34, the heater 34 is driven to heat the liquid flowing through the fluid channel, so that the liquid can reach the critical temperature.

More preferably, the milk discharging device 300 may further include a massage device (not shown) capable of massaging the user when the user is discharging milk using the milk discharging device.

The milk discharging device 300 further comprises a communication assembly 36, wherein the communication assembly 36 is connected to the flow control assembly 32 to obtain the working state of the flow control assembly 32. In this embodiment, the passing module 32 may obtain the gear in which the flow control assembly 32 is located. Preferably, the communication module 32 is communicatively connected to a terminal (e.g., an intelligent robot, an electronic device, a virtual cloud end, etc.) used by a user, so that the user can regulate the milk discharging device by means of the terminal (e.g., the intelligent robot, the electronic device, the virtual cloud end, etc.), for example, a virtual key corresponding to each gear of the flow control module 32 may be provided on the intelligent terminal of the user, so that the gear of the flow control module 32 and the opening of the milk discharging device may be regulated. More preferably, the communication component is capable of synchronizing the recorded information to the cloud.

Further, the communication component 36 is connected to the timer 33 to be able to obtain information recorded by the timer (such as the time the milk discharging device is operated in different gear, the operation time of the milk discharging device, etc.) to further form another data signal. Preferably, the data signals acquired by the communication component 36 can be transmitted to a terminal (e.g., intelligent robot, electronic device, virtual cloud, etc.) for use by a user.

It should be noted that, according to the embodiment of the present invention, when the user uses the milk discharging device 300 and the smart container 100 together, the communication component 36 of the milk discharging device 300 is communicatively connected to the communication device 23 of the smart device 20 of the smart container 100, so that the data signal acquired by the communication component 36 of the milk discharging device 300 is transmitted to the communication device 23 of the smart device 20. The analysis component 221 of the processing device 22 in the smart device 20 combines the data signal and the physical signal monitored by the monitoring device 21 of the smart device 20, so as to calculate the rate of milk discharge of the milk discharging device in different gear positions to form a corresponding result signal, where the result signal can be synchronously transmitted to a terminal (e.g. smart robot, electronic device, virtual cloud, etc.). That is, the user may use a terminal (e.g., intelligent robot, electronic device, virtual cloud, etc.).

It should be further noted that the analysis component 221 can compare and analyze the milk discharging rate of the milk discharging device 300 in different gears with the milk discharging rate of the lactating female corresponding to the international standard, so as to form another corresponding result signal, and the result signal can be transmitted to a terminal (e.g. intelligent robot, electronic device, virtual cloud terminal, etc.) of the user, and can also be synchronized with the cloud terminal.

It will be appreciated by those skilled in the art that the above flow rates and flow rates of milk when the milk discharge device is used to draw milk may be used as a measure of general female health, and are merely illustrative of the invention and not limiting of the invention, as other obvious embodiments will occur to those of skill in the art.

It will be appreciated by those skilled in the art that the milk ejection device of the present invention may be used with other containers on the market, whereby a user may be able to monitor the physical signal of the fluid being extracted in real time during use, and the milk ejection device may be able to monitor the relevant physical health of a mother in lactation when the milk ejection device is being used to extract breast milk.

Referring to fig. 26, according to another aspect of the present invention, a smart container operating system 500 is provided, wherein the smart container operating system 500 includes a collection module 51, wherein the collection module 51 collects physical information of a substance located in a container body 10 of the smart container to form a corresponding physical signal.

The collection module 51 includes a first collection module 511, where the first collection module 511 collects the characterization information of the substance in the container body 10 of the smart container to form a physical signal corresponding thereto. The collection module 51 further comprises a second collection module 512, wherein the second collection module 512 collects the temperature of the substance in the container body 10 of the smart container to form a temperature signal corresponding thereto.

According to the invention, the acquisition module 51 is arranged with the monitoring device 51.

Those skilled in the art will appreciate that the collection module 51 may also collect other physical information of the substance in the container body 10, such as temperature, volume, concentration, etc., and the present invention is not limited thereto.

The working system 50 of the smart container further comprises a processing module 52, wherein the processing module comprises an analyzing unit 521, wherein the analyzing unit 521 is connected to the collecting module 51 so as to be capable of acquiring a physical signal collected by the collecting module 51, wherein the analyzing unit 521 is capable of acquiring a reference signal, and the analyzing unit 521 is capable of comparing the physical signal with the reference signal to form a result signal. According to the invention, the processing module 52 is arranged with the processing means 22.

Preferably, the processing module 52 further comprises a storage unit 522, wherein the reference signal is configured to be stored in the storage unit 522, and wherein the storage unit 522 is connected to the analysis unit 521, so that the analysis unit 521 can acquire the reference signal stored in the storage unit 52.

The working system 50 of the smart container further comprises a communication module 53, wherein the communication module 53 is connected to the collection module 51, the communication module 53 obtains the physical signal collected by the collection module 51, and the communication module 53 can be connected to any external electronic device in a communication manner, so as to remotely communicate the physical signal to a user.

According to an embodiment of the present invention, the processing module 52 may be implemented as a network terminal, where the processing module 52 is communicatively connected to the communication module 53, so that the processing module 52 can remotely acquire the physical signal acquired by the communication module 53 from the acquisition module 51.

Preferably, the working system 50 of the smart container further comprises a display module 54, wherein the display module 54 is connected to the collecting module 51, so as to obtain a physical signal related to the temperature collected by the collecting module 51, so that the physical signal is transmitted to a user.

In addition, the display module 54 is connected to the analysis unit 521 of the processing module 52 so as to be able to acquire a result signal formed by the analysis unit 521.

Referring to fig. 27, according to another aspect of the present invention, a management system 700 is provided, wherein the management system 700 includes a transmission module 71 and an analysis module 72, wherein the analysis module 72 is connected to the transmission module 72.

In the present invention, the transmission module 71 comprises a receiving unit 711, wherein the receiving unit 711 of the transmission module 71 is communicatively connected to the communication device 23 of the smart container 100, wherein the receiving unit 711 is capable of acquiring a physical signal and a result signal transmitted by the communication device 23, wherein the analysis module 72 is further capable of acquiring the physical signal and the result signal from the receiving unit 711, by means of which the analysis module 72 is further capable of comparing and analyzing to form a feedback signal.

When the smart container is used by a user for a long period of time to dispense milk powder, the feedback signal may be a child feeding rate related signal formed by one or more of the number of times the user dispenses milk powder with the smart container each time, the amount of milk powder dispensed with the smart container each time the user dispenses milk powder, or the total amount of milk powder dispensed with the smart container by the user each time each month/week, etc. Those skilled in the art will appreciate that the feedback signal described in the present invention may be implemented as other content, and the present invention is not so limited.

It should be noted that the user may log in to the management system 700, and further may view the feedback signal. Those skilled in the art will appreciate that the management system 700 may set a related login instruction, where the login instruction corresponds to related information (such as a user name, a mobile phone number, a password, etc.) set by the user when purchasing the smart container, and the present invention is not limited thereto.

Further, the transmission module 71 further comprises a communication unit 712, wherein the communication unit 712 is connected to the analysis module 72, wherein the communication unit 72 is connected to the analysis module 72, thereby enabling the communication unit to obtain the feedback signal formed by the analysis module 72. Further, the communication unit 712 is communicatively connected to a communication terminal (e.g., cellular data terminal, micro-communication platform, etc.) of a communication industry service provider, so that the feedback signal can be directly transmitted to the user in the form of a short message, information, etc.

It is worth mentioning that the receiving unit 711 of the communication module 71 is further connected to the communication component 36 of the milk discharging device 300, thereby enabling the receiving unit 711 to obtain the data signal from the communication component 39, wherein the receiving unit 711 transmits the received data signal to the analyzing module 72, wherein the analyzing module 72 is further capable of analyzing the data signal, thereby forming another feedback signal. Wherein the feedback signal may be a signal of the health of the breast milk of the user formed by one or more of the time the user uses the milk discharging device 300 each time, the total time the user uses the milk discharging device 300 each week/month, and the feedback signal may be communicated to the user by a communication terminal of a communication industry service provider.

According to another aspect of the present invention, there is provided a method for operating a smart container, according to an embodiment of the present invention, wherein the method for operating a smart container includes:

(a) A monitoring device 21 monitors physical information of a substance in a container body 10 of the smart container to form a corresponding physical signal; and

(b) A communication device 23 connected to the monitoring device 21 acquires the physical signal, wherein the communication device 23 is communicatively connected to any external electronic equipment.

Preferably, the working method of the smart container further comprises:

(c) An indicator device 25 connected to the monitoring device 21 communicates the physical signal to the user.

According to another embodiment of the present invention, the working method of the smart container includes:

(1) A monitoring device 21 monitors physical information of a substance in a container body 10 of the smart container to form a corresponding physical signal; and

(2) An analyzing component 221 included in a processing device 20 connected to the monitoring device 21 acquires the physical signal from the monitoring device 21, and the analyzing component 21 acquires a reference signal;

(3) The analysis component 221 analyzes the physical signal and the reference signal to form a resultant signal.

Preferably, the step (1) includes:

(1.1) the characterization monitoring component 211 of the monitoring device 21 monitors characterization information of a substance in the container body 10 to form a corresponding physical signal.

(1.2) the temperature monitoring unit 211 of the monitoring unit 21 monitors temperature information of the substance in the container body 10 to form a physical signal corresponding thereto.

More preferably, wherein said step (1.1) is implemented as:

(1.11) the characterization monitoring component 211 of the monitoring component 21 monitors the weight of a substance in the container body 10 to form a corresponding physical signal.

Preferably said step (2) further comprises:

(2.1) the analysis component 21 obtains the reference signal from a storage component 222 that is coupled to the analysis component 221 and stores the reference signal.

Further, the working method of the intelligent container further comprises the following steps of

(4) A display device 24 connected to the processing device 20 acquires the result signal.

Further, the working method of the intelligent container further comprises the following steps of

(5) A heating device connected to the processing device 20 acquires the result signal.

According to another aspect of the present invention, there is provided a method for operating a smart container operating system 500, wherein the method for operating a smart container operating system comprises:

(A) An acquisition module 51 acquires physical information of the substances in the intelligent container to form corresponding physical signals;

(B) An analysis element 521 comprised by a processing module 52 connected to the acquisition module 51 acquires the physical signal from the acquisition module 51, and the analysis element 521 acquires a reference signal; and

(C) The analysis element 521 analyzes the comparison of the physical signal and the reference signal to form a resultant signal.

Preferably, wherein the step (a) comprises:

(A1) A first acquisition module 511 of the acquisition module 51 acquires the characterization information of the substances in the smart container to form corresponding physical signals.

Wherein said step (a) further comprises:

(A2) The collection module 51-the second collection module 512 collects the temperature of the material in the smart container to form the corresponding physical signal.

More preferably, wherein said step (A1) is implemented as:

(A11) A first collection module 511 of the collection module 51 collects the weight of the contents of the smart container to form a corresponding physical signal.

Preferably, wherein step (B) comprises:

(B1) The analysis element 521 obtains the reference signal from a memory element 522 connected to the analysis element 521.

According to another embodiment of the present invention, the working method of the intelligent container working system includes:

(h) An acquisition module 51 acquires physical information of the substances in the intelligent container to form corresponding physical signals; and

(g) A communication module 53 connected to the collection module 51 obtains the physical signal collected by the collection module 51, so that the communication module 53 can transmit the obtained physical signal to any electronic device connected to the outside through communication, and further remotely transmit the physical signal to a user.

According to another aspect of the present invention, there is provided a management method of a management system, wherein the management method includes:

(K) A receiving unit 711 communicatively connected to a transmission module 71 of a smart container acquires a physical signal or a result signal from a communication means of a smart device of the smart container;

(L) the analysis module 72 connected to the receiving unit 711 acquires the physical signal and the result signal from the receiving unit 711; and

(M) the receiving unit 711 analyzing the physical signal and the result signal to form a feedback signal.

According to an embodiment of the present invention, the management method further includes:

(N) a communication unit 712 coupled to the analysis module 72 obtains the feedback signal to transmit the feedback signal to a terminal (e.g., smart robot, electronic device, virtual cloud, etc.) of the user.

According to another aspect of the present invention, the present invention further provides a method for manufacturing a smart container 100, wherein the method comprises the steps of:

(a) The cover film 513 is disposed on the base upper surface 5112 of the base upper frame 511 in such a manner that an upper frame penetrating hole 5111 of the base upper frame 511 corresponds to a cover film 513;

(b) Suspending at least a portion of a sensor body 522 of a sensor 52 from the upper frame perforation 5111 of the base upper frame 511 to obtain a base unit 50, wherein the sensor body 522 can be pressed after the cover film 513 is deformed; and

(c) The smart container 100 is manufactured by installing a bottle body 40 to the base unit 50 to form a receiving cavity 110 between the bottle body 40 and the base unit 50, wherein a portion of the cover film 513 corresponding to the upper frame penetration 5111 of the base upper frame 511 is held in the receiving cavity 110.

Those skilled in the art will appreciate that the embodiments of the invention shown in the drawings and described above are merely illustrative of the invention and not limiting.

It will thus be seen that the objects of the invention are efficiently attained. The embodiments for explaining the functional and structural principles of the present invention have been fully illustrated and described, and the present invention is not limited by the changes based on the principles of the embodiments. Accordingly, the invention includes all modifications encompassed within the scope and spirit of the following claims.

Claims (20)

1. An intelligent container, comprising:

a bottle body, wherein the bottle body is provided with a high-end opening and a low-end opening corresponding to the high-end opening; and

a base unit, wherein the base unit further comprises a sensor and a base body, wherein the base body comprises a base upper frame and a cover film provided on a base upper surface of the base upper frame, wherein the bottle body is mounted to the base body to close the lower end opening of the bottle body by the base body, thereby forming a receiving cavity between the bottle body and the base body, wherein the cover film is held between the bottle body and the base upper frame to prevent a gap from being generated between the bottle body and the base upper frame, at least a portion of the cover film is held in the receiving cavity, and at least a portion of the sensor is held in a lower portion of the cover film to press the sensor after the cover film is deformed.

2. The smart container of claim 1, wherein the base body further comprises a base upper shelf having an upper shelf perforation, wherein the cover film is disposed on the base upper shelf, and the upper shelf perforation of the base upper shelf corresponds to the cover film.

3. The smart container of claim 2, wherein the sensor includes a sensor cantilever and a sensor body disposed at a free end of the sensor cantilever, a connection end of the sensor cantilever is disposed at the base body, and at least a portion of the sensor is retained in a suspended manner at the upper shelf perforation of the base upper shelf.

4. A smart container according to claim 3, wherein a sensor upper surface of the sensor body of the sensor is flush with a base upper surface of the base upper shelf; or a sensor upper surface of the sensor body of the sensor is lower than a base upper surface of the base upper frame; or the sensor upper surface of the sensor body of the sensor is higher than the base upper surface of the base upper frame.

5. The smart container according to any one of claims 2 to 4, wherein the cover film is attached to a base upper surface of the base upper frame.

6. The smart container according to any one of claims 2 to 4, wherein the cover film is integrally formed on a base upper surface of the base upper frame.

7. The smart container of any one of claims 2-4, wherein the cover film and the base upper shelf are integrally formed.

8. The smart container of any one of claims 1-4, wherein the base unit further comprises at least one thermal shield held between the cover film and sensor.

9. The smart container of claim 5, wherein the base unit further comprises at least one insulation held between the cover film and the sensor.

10. The smart container of claim 6, wherein the base unit further comprises at least one insulation held between the cover film and sensor.

11. The smart container of claim 7, wherein the base unit further comprises at least one insulation held between the cover film and the sensor.

12. A method of manufacturing a smart container, the method comprising the steps of:

(a) Providing a cover film on the upper surface of a base upper frame, wherein an upper frame perforation of the base upper frame corresponds to the cover film;

(b) Forming a receiving cavity between the bottle and the base upper frame in such a manner that the base upper frame closes a lower end opening of the bottle, wherein at least a portion of the cover film is held in the receiving cavity, wherein the bottle is mounted to the base upper frame, and the cover film is held between the bottle and the base upper frame to prevent a gap from being generated between the bottle and the base upper frame; and

(c) The sensor is arranged at the lower part of the cover film in such a way that the cover film presses against the sensor after deformation.

13. The manufacturing method according to claim 12, wherein in the step (c), the sensor is disposed at a lower portion of the cover film in such a manner that the sensor is suspended from the upper frame perforation of the base upper frame.

14. The manufacturing method according to claim 12 or 13, wherein in the step (a), further comprising the step of:

providing the base upper shelf with the upper shelf perforations; and

and attaching the cover film to the upper surface of the base of the upper base frame so as to set the cover film on the upper surface of the base of the upper base frame.

15. The manufacturing method according to claim 12 or 13, wherein in the step (a), further comprising the step of:

providing the base upper shelf with the upper shelf perforations; and

and forming the cover film on the base upper frame through an injection molding process so as to set the cover film on the base upper frame.

16. The manufacturing method according to claim 12 or 13, wherein in the step (a), the cover film and the base upper frame are integrally formed by an injection molding process.

17. The manufacturing method according to claim 12 or 13, wherein in the above method, further comprising the step of: at least one insulating portion is held between the cover film and the sensor.

18. The manufacturing method according to claim 14, wherein in the above method, further comprising the step of: at least one insulating portion is held between the cover film and the sensor.

19. The manufacturing method according to claim 15, wherein in the above method, further comprising the step of: at least one insulating portion is held between the cover film and the sensor.

20. The manufacturing method according to claim 16, wherein in the above method, further comprising the step of: at least one insulating portion is held between the cover film and the sensor.