CN219048080U - Intelligent integrated packaging beverage refrigerating instant heating swinging mixing direct-drinking integrated machine based on Internet of things - Google Patents

Abstract

The utility model relates to the technical field of water dispensers, in particular to an intelligent integrated packaging beverage refrigerating instant-heating swinging mixed direct-drinking integrated machine of the Internet of things, which comprises a refrigerating cabin, wherein a cavity is arranged in the refrigerating cabin and is used for directly placing packaged beverages; the hollow needle is arranged at the bottom of the refrigerating cabin and driven by the motor to move up and down, and the hollow needle is connected with the liquid outlet pipeline and the refrigerating cabin steam flushing pipeline through the multi-way connector; the steam flushing sewage discharge pipeline is arranged at the bottom of the refrigerating cabin cavity, forms a passage with the refrigerating cabin cavity, the hollow needle and the steam flushing pipeline, punctures the whole packaging beverage sealing film through the controlled telescopic action of the hollow needle with the pipeline, and therefore the self-sucking pump in the system pipeline can suck beverage.

Description

Intelligent integrated packaging beverage refrigerating instant heating swinging mixing direct-drinking integrated machine based on Internet of things

Technical Field

The utility model relates to the technical field of water dispensers, in particular to an intelligent integrated packaging beverage refrigerating, instant heating and swinging mixed direct-drinking integrated machine of the Internet of things.

Background

The water dispenser is a common household appliance in life. The existing water dispenser consists of a water storage tank and a water outlet pipeline, the beverage on the market is unpacked and poured into the water storage tank, and then the beverage is poured into a cup through the water outlet pipeline. However, such a water dispenser has several disadvantages: 1. after the beverage is unpacked, the quality guarantee period is short, and the beverage needs to be drunk as soon as possible; 2. the water storage tank is filled with different beverages, so that the taste of the beverages can be changed; 3. the beverage enters the water storage tank from the package, and secondary pollution is caused.

While for some beverages containing sediment, a conventional water dispenser may be equipped with a stirring device. But due to gravity the precipitate eventually settles to the bottom after stirring.

Disclosure of Invention

The utility model aims to solve the defects of the prior art and provides an intelligent integrated refrigerating, instant heating and swinging mixed direct-drinking machine for integrally packaging beverages by using the Internet of things.

In order to achieve the above purpose, the intelligent integrated packaging beverage refrigerating, instant heating and swinging mixed direct-drinking integrated machine of the Internet of things is designed, and comprises a refrigerating cabin, wherein a cavity is arranged in the refrigerating cabin and is used for directly placing packaged beverages; the hollow needle is arranged at the bottom of the refrigerating cabin and driven by the motor to move up and down, and the hollow needle is connected with the liquid outlet pipeline and the refrigerating cabin steam flushing pipeline through the multi-way connector; the steam flushing sewage discharge pipeline is arranged at the bottom of the refrigerating cabin cavity and forms a passage with the refrigerating cabin cavity, the hollow needle and the steam flushing pipeline.

The utility model also has the following preferable technical scheme:

1. the liquid outlet pipeline comprises the following components: the hollow needle is connected with a refrigerating outlet electromagnetic valve, the refrigerating outlet electromagnetic valve is connected to the inlet of the heating plate through an outlet pipe, a flowmeter and a temperature sensor, and the outlet of the heating plate is connected with a liquid outlet pipe.

2. The liquid outlet pipe is provided with a self-priming pump, so that liquid flows from the hollow needle to the liquid outlet pipe.

3. The steam flushing pipeline of the refrigerating cabin comprises the following components: the water tank is connected with the water pump, the water pump is connected with the steam generator, the steam generator is connected with the steam two-position three-way electromagnetic valve, the steam two-position three-way electromagnetic valve is connected with the hollow needle through the flushing pipe of the refrigerating cabin, and the steam two-position three-way electromagnetic valve enters the inner cavity of the refrigerating cabin from the hollow needle.

4. The steam flushing sewage discharge pipeline comprises the following components: the low position of the inner cavity of the refrigerating cabin is provided with a sewage draining interface which is connected with a steam flushing sewage discharging pipe, the steam flushing sewage discharging pipe is connected with a self-priming sewage draining pump, and the self-priming sewage draining pump is connected with a detachable water collecting disc.

5. Comprises a liquid outlet pipeline and a steam flushing pipeline, and comprises the following components: the water tank is connected with the water pump, the water pump is connected with the steam generator, the steam generator is connected with the steam two-position three-way electromagnetic valve, the steam two-position three-way electromagnetic valve is connected with the outlet pipe through the liquid outlet pipeline steam flushing pipe, the outlet pipe is connected to the heating plate through the flowmeter and the temperature sensor, the heating plate is connected with the self-priming pump, and the self-priming pump is connected with the detachable water collecting tray.

6. Comprises an outlet management steam flushing check valve and a refrigerating cabin inner cavity steam flushing check valve, so that beverage can not enter the refrigerating cabin steam flushing pipeline through the liquid outlet pipeline.

7. The swing mechanism comprises a swing motor, a sliding block and a rocker arm, wherein a shaft is arranged on the refrigerating cabin and fixedly connected with one end of the rocker arm through a bearing seat, a sliding groove is formed in the other end of the rocker arm, a limiting block capable of moving in the sliding groove is arranged on the sliding block, and the sliding block is connected with a screw rod of the swing motor.

8. Limit switches are arranged on the left side and the right side of the rocker arm.

Compared with the prior art, the utility model has the advantages that:

1. the utility model solves the problem that the refrigerated fresh-keeping beverage needs instant heating and accurate heating for eating. Many beverages can be continuously eaten for a plurality of times within the shelf life only by refrigerating after opening the packaging sealing film. Such as milk, oat milk, soy milk, and the like. However, these beverages are often heated at an accurate temperature before being eaten, and at present, the common practice is to take out the beverages from a refrigerating chamber of a refrigerator, pour the beverages into a container, and then put the beverages into a microwave oven, a natural gas stove, an electromagnetic oven and the like for heating for eating. It is difficult to achieve accurate temperature control to reach the desired beverage temperatures for various drinking scenarios. For example, milk heated to 45 degrees celsius is a good drinking temperature for taste and nutrient preservation.

2. The utility model only needs to manually open the whole packaged beverage cover without removing the whole packaged beverage sealing film, and the whole packaged beverage is placed in the refrigerating cabin in an inverted mode. The semiconductor refrigeration ensures that the whole packaged beverage is in a refrigerating and fresh-keeping state.

3. The utility model punctures the sealing film of the whole packaged beverage through the controlled telescopic action of the hollow needle with the pipeline, thereby enabling the self-sucking pump in the system pipeline to suck the beverage.

4. The beverage self-priming pump of the system of the utility model has a controlled solenoid valve for the beverage outlet after the hollow needle with the pipeline at the end of the output outlet of the system. The beverage outlet electromagnetic valve is closed first and then the beverage self-priming pump at the tail end of the output outlet of the system is stopped when the required volume is reached by comparing the volume of the beverage required by the consumer input each time with the flow meter data feedback in the pipeline, so that the residual volume of the beverage in the pipeline is reduced as much as possible.

5. The utility model has 2 sets of controlled steam flushing pipelines, and can flush all daily pipelines from the electromagnetic valve at the beverage outlet to the electromagnetic valve at the tail end of the system output under the controlled condition, and the flushed steam and/or hot water can be selectively discharged from the output port at the tail end of the system through the electromagnetic valve at the tail end of the system output and then fall into the detachable water collecting disc or be directly discharged into the detachable water collecting disc. Under the condition that the refrigerating cabin is empty and is not provided with the whole packaged beverage, the hollow needle and the inner cavity of the refrigerating cabin can be independently subjected to steam flushing, and the flushed sewage is discharged into the detachable water collecting tray through the sewage draining outlet in the inner cavity of the refrigerating cabin by the sewage draining self-sucking pump. So that the whole system pipeline reached by the beverage can be washed and disinfected by steam.

6. After each daily pipeline use, the daily pipeline can be subjected to steam flushing by manual key operation. The system can also be set with time intervals, the daily pipeline is not used again in the time intervals, and the system automatically carries out steam flushing on the daily pipeline.

7. The inner cavity of the refrigerating cabin is fixed with the refrigerating cabin body through the weight sensor, so that the system can sense the weight change of the whole packaged beverage. So that the user can be informed in advance of the immediate replacement of the whole packaged beverage.

8. A hollow shaft on a refrigerating cabin of the utility model passes through a bearing seat on the side wall of a main machine, a swing arm is fixed by a sleeve screw, a sliding groove on the swing arm is sleeved with a trunnion on a sliding block with an internal thread through hole, and the sliding block with the internal thread through hole is in threaded fit with a screw shaft outlet motor. Therefore, the sliding block with the internal thread through hole reciprocates on the screw rod output shaft motor under the control of the left-right stroke electromagnetic valve, so that the refrigerating cabin swings through the rocker arm. And simultaneously, the whole packaged beverage stored in the inner cavity of the refrigerating cabin is rocked in the package to be mixed.

Drawings

FIG. 1 is a schematic front view of the overall structure of the present utility model;

FIG. 2 is a schematic rear view of the overall structure of the present utility model;

FIG. 3 is a schematic view of the overall structure of the present utility model;

FIG. 4 is a schematic view of the structure of the refrigerating compartment of the present utility model;

FIG. 5 is a partially disassembled schematic view of the refrigerated compartment of the present utility model;

FIG. 6 is a schematic view of the back of the refrigerated compartment of the present utility model;

FIG. 7 is a schematic view of the front of the refrigerated compartment of the present utility model;

FIG. 8 is a schematic view of the hollow needle structure of the present utility model;

FIG. 9 is a view showing the state of movement of the hollow needle according to the present utility model;

FIG. 10 is a schematic view of the rocking mechanism of the present utility model;

FIG. 11 is a front view of the rocking mechanism of the present utility model;

FIG. 12 is a schematic view showing a tilting state of the refrigerating compartment of the present utility model;

FIG. 13 is a front view of the utility model in an inclined position with respect to the refrigerated compartment;

FIG. 14 is a schematic view of the internal piping structure of the present utility model;

FIG. 15 is a schematic view of another angled internal piping of the present utility model;

FIG. 16 is a schematic view of the internal piping structure of the present utility model with the housing removed;

FIG. 17 is a schematic diagram of a liquid outlet pipeline structure according to the present utility model;

FIG. 18 is a schematic view of another angle structure of the liquid outlet pipeline of the present utility model;

FIG. 19 is a schematic diagram of the operation of the liquid outlet pipeline of the present utility model;

FIG. 20 is a schematic view of the steam flushing line of the liquid outlet line of the present utility model;

FIG. 21 is a schematic view of another angular configuration of the vapor flush line of the liquid discharge line of the present utility model;

FIG. 22 is a schematic diagram of the operation of the steam flush line of the liquid outlet line of the present utility model;

FIG. 23 is a schematic view of a vapor flush circuit of a refrigerated compartment in accordance with the present utility model;

FIG. 24 is a schematic view of another angular configuration of the vapor flush line of the refrigerated compartment of the present utility model;

FIG. 25 is a schematic diagram of the vapor flush circuit of the refrigerated compartment of the present utility model;

in the figure: the device comprises a main body 1, a rear cover of the main body 1.1, a switch power supply plug, a motor for a screw rod outlet of a swinging motion of a refrigerating compartment 1.2, a slider with a through hole with internal threads of a trunnion 1.3, a rocker arm 1.4, a rocker arm 1.4.1 and a hollow journal fixing screw, a left travel limit switch of swinging motion of the refrigerating compartment 1.5, a right travel limit switch of swinging motion of the refrigerating compartment 1.6, a bearing seat 1.7, a flowmeter 1.8, a temperature sensor 1.9, a heating plate inlet 1.10, a heating plate outlet 1.11, a self-priming pump 1.12, a two-position three-way electromagnetic valve (daily interface) of a terminal output port of a system 1.13, a two-position three-way electromagnetic valve (blowdown interface) of a terminal output port of a system 1.13.1, a water supplementing receiving interface of a water tank 1.14, a water pump 1.15, a steam generator 1.16, a two-position three-way electromagnetic valve (daily pipeline steam flushing) of a steam 1.17, and a port of a detachable water collecting disc interface for blowdown 1.18;

2 cold storage cabin body, 2.1 cold storage cabin cover, 2.2 cold storage cabin cover spring sliding lock catch, 2.3 cold storage cabin cover rotating shaft, 2.4 cold storage cabin cover closing touch induction switch, 2.5 cold storage cabin cover locking lock catch position, 2.6 cold storage cabin inner cavity, 2.7 heat insulation layer, 2.8 semiconductor refrigerating sheet, 2.9 radiating fin, 2.10 radiating fan, 2.11 weight sensor, 2.12 weight sensor upper fixed gasket, 2.13 weight sensor lower fixed gasket, 2.14 side shell with hollow shaft neck, 2.15 cold storage cabin body radiating ventilation groove, 2.16 hollow needle telescopic action limit switch installation fixed position, 2.17 hollow needle telescopic action upper limit switch, 2.18 hollow needle telescopic action lower limit switch, 2.19 hollow needle, 2.20 hollow needle telescopic action D output shaft motor 2.21 hollow needle telescopic action D output shaft motor swing arm, 2.22 refrigeration outlet electromagnetic valve, 2.23 daily outlet pipeline, 2.24 daily outlet pipeline steam flushing check valve, 2.24.1 daily outlet pipeline steam flushing pipe, 2.25 outlet pipeline steam flushing pipeline, 2.26 hollow needle and refrigeration cabin inner cavity steam flushing check valve, 2.27 hollow needle and refrigeration cabin inner cavity steam flushing pipeline, 2.28 hollow needle and refrigeration cabin inner cavity steam flushing sewage discharge pipeline, 2.28.1 hollow needle and refrigeration cabin inner cavity sewage discharge interface, 2.29 beverage packing box, 2.30 beverage packing box sealing film, 2.31 refrigeration cabin inner cavity silica gel sealing ring, 2.32 refrigeration cabin inner cavity hollow needle pipeline silica gel sealing ring;

3. the touch screen module, 4 can dismantle the water tank, 5 infrared sensor, 6 can dismantle the water collector, 7 system terminal delivery outlet.

Detailed Description

The construction and principles of the present utility model will be readily apparent to those skilled in the art from the following description taken in conjunction with the accompanying drawings. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

The utility model relates to an intelligent integrated packaging beverage refrigerating instant heating swinging mixing direct-drinking integrated machine of the Internet of things, which comprises a refrigerating cabin, wherein a cavity is arranged in the refrigerating cabin and is used for directly placing packaged beverages; the hollow needle is arranged at the bottom of the refrigerating cabin and driven by the motor to move up and down, and the hollow needle is connected with the liquid outlet pipeline and the refrigerating cabin steam flushing pipeline through the multi-way connector; the steam flushing sewage discharge pipeline is arranged at the bottom of the refrigerating cabin cavity and forms a passage with the refrigerating cabin cavity, the hollow needle and the steam flushing pipeline.

Referring to fig. 17-19, the liquid outlet line is composed as follows: the hollow needle is connected with a refrigerating outlet electromagnetic valve, the refrigerating outlet electromagnetic valve is connected to the inlet of the heating plate through an outlet pipe, a flowmeter and a temperature sensor, and the outlet of the heating plate is connected with a liquid outlet pipe. The liquid outlet pipeline is provided with a self-priming pump, so that liquid flows from the hollow needle to the liquid outlet pipeline.

The working principle of the liquid outlet pipeline is as follows: the hollow needle is controlled to stretch and puncture a sealing film of the beverage packaging box on the beverage packaging box stored in the inner cavity of the refrigerating cabin, and the electromagnetic valve of the refrigerating outlet is opened, and the self-priming pump is started. Beverage in the beverage packaging box flows through the hollow needle, the refrigerating outlet electromagnetic valve, the flowmeter and the temperature sensor to the inlet of the instant heating plate, enters the heating plate, and exits from the outlet of the instant heating plate to the two-position three-way electromagnetic valve (daily interface) of the terminal output port of the system and then to the terminal output port of the system to leave the equipment system. The steam flushing check valve of the outlet pipeline, the hollow needle and the steam flushing check valve of the inner cavity of the refrigerating cabin are arranged in the pipeline, so that beverage cannot enter the steam pipeline.

Referring to fig. 20-22, the liquid outlet line steam flush line is composed as follows: the water tank is connected with the water pump, the water pump is connected with the steam generator, the steam generator is connected with the steam two-position three-way electromagnetic valve, the steam two-position three-way electromagnetic valve is connected with the outlet pipe through the liquid outlet pipeline steam flushing pipe, the outlet pipe is connected to the heating plate through the flowmeter and the temperature sensor, the heating plate is connected with the self-priming pump, and the self-priming pump is connected with the detachable water collecting tray.

The working principle of the liquid outlet pipeline steam flushing pipeline is as follows: the electromagnetic valve of the refrigeration outlet is in a closed state, water in the detachable water tank is pumped and injected into the steam generator through the water tank water supplementing receiving interface, after steam is generated, the steam enters the daily outlet pipeline through the steam flushing check valve of the daily outlet pipeline from the steam two-position three-way electromagnetic valve (daily pipeline steam flushing interface), flows through the flowmeter, the temperature sensor, the instant heating plate inlet, the instant heating plate outlet and the self-sucking pump, and finally flows to the detachable water collecting disc from the two-position three-way electromagnetic valve (blowdown interface) of the tail end output port of the system to the blowdown to the detachable water collecting disc interface. The water can also be splashed to the detachable water collecting tray by a two-position three-way electromagnetic valve (daily interface) at the tail end output port of the system and then leave the equipment system at the tail end output port of the system.

Referring to fig. 23-25, the refrigerated compartment vapor flush line is composed as follows: the water tank is connected with the water pump, the water pump is connected with the steam generator, the steam generator is connected with the steam two-position three-way electromagnetic valve, the steam two-position three-way electromagnetic valve is connected with the hollow needle through the flushing pipe of the refrigerating cabin, and the steam two-position three-way electromagnetic valve enters the inner cavity of the refrigerating cabin from the hollow needle.

The steam flushing sewage discharge pipeline comprises the following components: the low position of the inner cavity of the refrigerating cabin is provided with a sewage draining interface which is connected with a steam flushing sewage discharging pipe, the steam flushing sewage discharging pipe is connected with a self-priming sewage draining pump, and the self-priming sewage draining pump is connected with a detachable water collecting disc.

The working principle of the steam flushing pipeline and the steam flushing sewage discharge pipeline of the refrigerating cabin is as follows: when the inner cavity of the refrigerating cabin is empty, the electromagnetic valve of the refrigerating outlet is in a closed state, water in the detachable water tank is pumped and injected into the steam generator through the water tank water supplementing receiving interface, steam is generated and then is injected into the inner cavity of the refrigerating cabin through the hollow needle and the steam flushing pipeline of the inner cavity of the refrigerating cabin through the steam two-position three-way electromagnetic valve (the hollow needle and the steam flushing interface of the inner cavity of the refrigerating cabin), the hollow needle and the steam flushing one-way valve of the inner cavity of the refrigerating cabin are used for cleaning, and sewage after cleaning flows through the hollow needle and the steam flushing sewage discharging pipeline of the inner cavity of the refrigerating cabin to the self-priming sewage discharging pump through the hollow needle arranged at the lower position of the inner cavity of the refrigerating cabin and the sewage discharging interface of the inner cavity of the refrigerating cabin, and is discharged to the detachable water collecting disc through sewage to the detachable water collecting disc interface.

Referring to fig. 10-13, the utility model comprises a swinging mechanism, wherein the swinging mechanism comprises a swinging motor, a sliding block and a rocker arm, a shaft is arranged on the refrigerating cabin and is fixedly connected with one end of the rocker arm through a bearing seat, a sliding groove is arranged at the other end of the rocker arm, a limiting block capable of moving in the sliding groove is arranged on the sliding block, and the sliding block is connected with a screw rod of the swinging motor.

The working principle is as follows: the swing motion motor works to drive the screw to rotate, the screw drives the sliding block connected with the screw to move on the screw, so that the limiting block of the sliding block moves in the sliding groove of the rocker arm to drive the rocker arm to move, and the rocker arm drives the refrigerating cabin to swing.

Claims (9)

1. Internet of things intelligent integrated packaging beverage refrigerating instant heating and swinging mixed direct-drinking integrated machine is characterized by comprising

The refrigerating cabin is internally provided with a cavity for directly placing the beverage with the package;

the hollow needle is arranged at the bottom of the refrigerating cabin and driven by the motor to move up and down, and the hollow needle is connected with the liquid outlet pipeline and the refrigerating cabin steam flushing pipeline through the multi-way connector;

the steam flushing sewage discharge pipeline is arranged at the bottom of the refrigerating cabin cavity and forms a passage with the refrigerating cabin cavity, the hollow needle and the steam flushing pipeline.

2. The intelligent integrated packaging beverage refrigerating, instant heating and swinging mixed direct-drinking integrated machine of the internet of things according to claim 1, wherein the liquid outlet pipeline comprises the following components: the hollow needle is connected with a refrigerating outlet electromagnetic valve, the refrigerating outlet electromagnetic valve is connected to the inlet of the heating plate through an outlet pipe, a flowmeter and a temperature sensor, and the outlet of the heating plate is connected with a liquid outlet pipe.

3. The intelligent internet of things integrated package beverage cold storage instant heating and swinging mixed direct-drinking integrated machine as claimed in claim 2, wherein: the liquid outlet pipeline is provided with a self-priming pump, so that liquid flows from the hollow needle to the liquid outlet pipeline.

4. The intelligent integrated package beverage refrigerating instant-heating swinging mixed instant-drinking integrated machine of the internet of things according to claim 1, wherein the refrigerating cabin steam flushing pipeline comprises the following components: the water tank is connected with the water pump, the water pump is connected with the steam generator, the steam generator is connected with the steam two-position three-way electromagnetic valve, the steam two-position three-way electromagnetic valve is connected with the hollow needle through the flushing pipe of the refrigerating cabin, and the steam two-position three-way electromagnetic valve enters the inner cavity of the refrigerating cabin from the hollow needle.

5. The intelligent integrated packaging beverage refrigerating, instant heating and swinging mixed direct-drinking integrated machine based on the Internet of things as claimed in claim 4, wherein the steam flushing sewage discharge pipeline comprises the following components: the low position of the inner cavity of the refrigerating cabin is provided with a sewage draining interface which is connected with a steam flushing sewage discharging pipe, the steam flushing sewage discharging pipe is connected with a self-priming sewage draining pump, and the self-priming sewage draining pump is connected with a detachable water collecting disc.

6. The intelligent integrated internet of things packaged beverage refrigerating instant heating and swinging mixed instant drinking integrated machine as claimed in claim 1, further comprising a liquid outlet pipeline and a steam flushing pipeline, wherein the intelligent integrated internet of things packaged beverage refrigerating instant heating and swinging mixed instant drinking integrated machine comprises the following components: the water tank is connected with the water pump, the water pump is connected with the steam generator, the steam generator is connected with the steam two-position three-way electromagnetic valve, the steam two-position three-way electromagnetic valve is connected with the outlet pipe through the liquid outlet pipeline steam flushing pipe, the outlet pipe is connected to the heating plate through the flowmeter and the temperature sensor, the heating plate is connected with the self-priming pump, and the self-priming pump is connected with the detachable water collecting tray.

7. The intelligent integrated internet of things packaged beverage cold storage and instant heating and swinging mixed direct-drinking integrated machine is characterized by further comprising an outlet pipe steam flushing one-way valve and a cold storage cabin inner cavity steam flushing one-way valve, so that beverage cannot enter the cold storage cabin steam flushing pipeline through a liquid outlet pipeline.

8. The intelligent integrated instant-heating and swinging integrated beverage packaging machine based on the internet of things, disclosed in claim 1, further comprising a swinging mechanism, wherein the swinging mechanism comprises a swinging motor, a sliding block and a rocker arm, the refrigerating chamber is provided with a shaft, the shaft is fixedly connected with one end of the rocker arm through a bearing seat, the other end of the rocker arm is provided with a sliding groove, the sliding block is provided with a limiting block capable of moving in the sliding groove, and the sliding block is connected with a screw rod of the swinging motor.

9. The intelligent internet of things integrated package beverage cold storage instant heating and swinging mixed direct-drinking integrated machine as claimed in claim 8, wherein: limit switches are arranged on the left side and the right side of the rocker arm.

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