CN211794140U - Blending tank for mixing carbonated beverage raw materials - Google Patents

Abstract

The utility model discloses a blending tank for carbonated beverage raw materials mixes, include: the upper part of the blending tank is provided with a plurality of feed inlets for inputting carbonated beverage raw materials, and the lower part of the blending tank is provided with a discharge outlet; a plurality of feed tanks; further comprising: the concentrator is provided with a plurality of input interfaces and an output interface, the input interfaces are connected with the raw material tanks, and the output interface is connected with the feed inlet of the blending tank through a second pipeline; the gas source mechanism is used for providing carbon dioxide gas; one end of the gas pipe is connected with the output end of the gas source mechanism, and the other end of the gas pipe extends to the upper part of the blending tank, penetrates into the blending tank and is used for guiding the carbon dioxide gas output by the gas source mechanism into the blending tank; the pulse electromagnetic valve is arranged at one end of the gas transmission pipe close to the gas source mechanism, and the carbon dioxide output by the gas source mechanism is input into the blending tank through the gas transmission pipe in a pulse mode; the exhaust mechanism is arranged at the top of the blending tank and penetrates into the top of the blending tank, and is used for adjusting the air pressure in the blending tank.

Description

Blending tank for mixing carbonated beverage raw materials

Technical Field

The utility model belongs to the technical field of carbonated beverage processingequipment and specifically relates to a blending tank for carbonated beverage raw materials mixes.

Background

The existing carbonated beverage is prepared by directly mixing all components and then filling carbon dioxide for further treatment, the carbon dioxide is filled under pressure to improve the dissolving capacity of the carbon dioxide, and the carbon dioxide is dissolved and then filled into bottled beverages or filled beverages.

Disclosure of Invention

To the situation of the prior art, the utility model aims to provide a blending tank for carbonated beverage raw materials that allotment is efficient and gas injection is reliable and stable.

In order to realize the technical purpose, the utility model adopts the technical scheme that:

a blending tank for carbonated beverage ingredient mixing, comprising:

the blending tank is internally provided with a containing cavity for containing each component of carbonated beverage, the upper part of the blending tank is provided with a plurality of feed inlets for inputting the carbonated beverage raw materials, and the lower part of the blending tank is provided with a discharge outlet;

a plurality of material tanks for providing liquid materials of each component of the carbonated beverage;

it still includes:

the concentrator is provided with a plurality of input interfaces and an output interface, wherein the input interfaces correspond to the raw material tanks one by one and are respectively connected with the discharge ports of the raw material tanks through first pipelines, the first pipelines are provided with first pumps, and the output interfaces are connected with the feed ports of the blending tanks through second pipelines;

the gas source mechanism is used for providing carbon dioxide gas;

one end of the gas pipe is connected with the output end of the gas source mechanism, and the other end of the gas pipe extends to the upper part of the blending tank, penetrates into the blending tank and is used for guiding the carbon dioxide gas output by the gas source mechanism into the blending tank;

the pulse electromagnetic valve is arranged at one end of the gas transmission pipe close to the gas source mechanism, and the carbon dioxide output by the gas source mechanism is input into the blending tank through the gas transmission pipe in a pulse mode;

and the exhaust mechanism is arranged at the top of the blending tank, penetrates into the blending tank and is used for adjusting the air pressure in the blending tank.

As a possible implementation mode, the concentrator is in an annular shell structure, a plurality of input interfaces and a plurality of output interfaces of the concentrator are all in tangent communication with the outer side of the concentrator body and are communicated with the outer side of the concentrator, and the input direction of the input interfaces and the output direction of the output interfaces are both in the flow direction of media in the coextensive concentrator.

As a preferred option, it is preferred that the input port and the output port are both provided with a first valve.

As a possible implementation, further, the exhaust mechanism includes:

the connecting sleeve is of a tubular structure, one end of the connecting sleeve is used for penetrating into the blending tank, and the other end of the connecting sleeve is provided with an external thread;

one of the two end interfaces of the T-shaped pipe fitting, which are positioned in the same axial direction, is provided with internal threads and is in threaded connection with the other end of the connecting sleeve, the other interface is connected with the pressing part, one interface except the two interfaces is used for exhausting gas in the blending tank, and the interface is arranged as an exhaust port;

the adjusting part is movably arranged in the T-shaped pipe and located between the two end connectors of the T-shaped pipe in the same axial direction, the adjusting part comprises a pair of sliding plates, the sliding plates are connected through springs, one sliding plate abuts against the abutting part, the other sliding plate abuts against the other end of the connecting sleeve and is used for separating the connecting sleeve from the exhaust port, and the sliding plates slide along the direction close to the abutting part to remove the separation.

Preferably, the abutting portion is a pressure gauge, the pressure gauge has a thimble and is used for abutting against one of the sliding plates of the adjusting member, and the pressure gauge is fixed on the other joint of the T-shaped pipe member through a connecting member.

As a possible implementation manner, further, the gas source mechanism is a carbon dioxide gas tank, and a second valve is arranged on an output end of the carbon dioxide gas tank, and the second valve is an electromagnetic valve.

As a possible implementation manner, further, a third valve is arranged on the feeding hole of the blending tank, and the third valve is an electromagnetic valve.

As a possible implementation manner, further, a fourth valve is arranged on the discharge hole arranged at the lower part of the blending tank, and the fourth valve is an electromagnetic valve.

As a possible implementation mode, furthermore, a plurality of through holes are arranged on the periphery of the part of the gas pipe penetrating into the pipe of the blending tank.

Adopt foretell technical scheme, compared with the prior art, the utility model, its beneficial effect who has is: the proposal ingeniously utilizes the concentrator to gather the raw materials of a plurality of raw material tanks into one strand, and then inputs the strand into the blending tank for blending, and the pulse electromagnetic valve is matched with the gas transmission pipe and the gas source mechanism, so that when the components of carbonated beverage are blended, the carbon dioxide output by the gas source mechanism can be intermittently input into the blending tank in a pulse form through the control of the pulse electromagnetic valve, and the input carbon dioxide can form bubbles to blend the components of the carbonated beverage, namely, the gas pulse blending effect is formed among the gas source mechanism, the pulse electromagnetic valve and the gas transmission pipe, after the blending is finished, the carbon dioxide can be injected in a form of directly inputting the carbon dioxide, so that the carbon dioxide is dissolved in the carbonated beverage, the beverage aeration effect is realized, and the exhaust mechanism can realize the dynamic balance of the tank pressure in the blending tank through the matching of the T-shaped pipe fitting, the adjusting piece, the connecting sleeve and the pressing part, namely, when the air pressure in the blending tank is greater than the spring pressure of the adjusting piece, the sliding plate which is pressed against the connecting sleeve can be pushed to slide, so that the connecting sleeve is communicated with the exhaust port, and when the pressure in the blending tank is reduced, the sliding plate can be pushed by the spring to reset, so that the connecting sleeve is separated from the exhaust port, and the scheme is reliable in implementation, good in adjusting effect and high in efficiency.

Drawings

The scheme of the invention is further explained by combining the attached drawings and the detailed embodiment:

FIG. 1 is a schematic diagram of the embodiment of the present invention;

fig. 2 is a schematic diagram of an exhaust mechanism according to the present invention;

fig. 3 is a schematic diagram of a circuit concentrator according to the present invention.

Detailed Description

As shown in one of fig. 1 to 3, the present invention provides a blending tank for mixing carbonated beverage ingredients, comprising:

the mixing tank 1 is internally provided with a containing cavity 11 for containing components of carbonated beverage, the upper part of the mixing tank is provided with a plurality of feed inlets 12 for inputting the carbonated beverage raw materials, and the lower part of the mixing tank is provided with a discharge outlet 13;

a plurality of material tanks 2 for providing liquid materials of each component of the carbonated beverage;

it still includes:

the concentrator 3 is provided with a plurality of input interfaces 31 and an output interface 32, wherein the input interfaces 31 correspond to the raw material tanks 2 one by one and are respectively connected with the discharge holes of the raw material tanks 2 through first pipelines 22, the first pipelines 22 are respectively provided with a first pump 21, and the output interface 32 is connected with the feed hole 12 of the blending tank 1 through a second pipeline 33;

a gas source mechanism 5 for supplying carbon dioxide gas;

one end of the gas pipe 51 is connected with the output end of the gas source mechanism 5, and the other end of the gas pipe extends to the upper part of the blending tank 1 and penetrates into the blending tank 1 and is used for guiding the carbon dioxide gas output by the gas source mechanism 5 into the blending tank 1;

the pulse electromagnetic valve 53 is arranged at one end of the gas transmission pipe 51 close to the gas source mechanism 5, and the carbon dioxide output by the gas source mechanism 5 is input into the blending tank 1 through the gas transmission pipe 51 in a pulse mode.

And the exhaust mechanism 4 is arranged at the top of the preparation tank 1, penetrates into the preparation tank 1 and is used for adjusting the air pressure in the preparation tank 1.

As a possible implementation manner, the concentrator 3 is in an annular shell structure, and a plurality of input interfaces 31 and output interfaces 32 of the concentrator 3 are respectively in tangential communication with the outer side of the main body of the concentrator 3 and are connected to the outer peripheral side of the concentrator 3, wherein the input direction of the input interface 31 and the output direction of the output interface 32 are both the medium flow direction in the antegrade concentrator 3; as a preferred option, the input interface 31 and the output interface 32 are provided with first valves 311 and 321, and the first valves 311 and 321 may be selected as electromagnetic valves.

In addition, as a possible embodiment, the exhaust mechanism 4 further includes:

the connecting sleeve 43 is of a tubular structure, one end of the connecting sleeve is used for penetrating into the blending tank 1, and the other end of the connecting sleeve is provided with an external thread;

a T-shaped pipe 41, one of the two end interfaces of which located in the same axial direction is provided with an internal thread and is in threaded connection with the other end of the connecting sleeve 41, the other interface is connected with a pressing part 42, one of the interfaces except the two interfaces is used for discharging the gas in the blending tank 1 and is provided as an exhaust port 411;

the adjusting part is movably arranged in the T-shaped pipe 41 and positioned between two end interfaces of the T-shaped pipe 41 in the same axial direction, and comprises a pair of sliding plates 44 and 46, the pair of sliding plates 44 and 46 are connected through a spring 45, one sliding plate 44 abuts against the abutting part 42, the other sliding plate 46 abuts against the other end of the connecting sleeve 43, the connecting sleeve 43 and the exhaust port 411 are separated through the sliding plate 46, and the sliding plate 46 slides in the direction approaching the abutting part 42 to release the separation; preferably, the abutting portion 42 is a pressure gauge having a thimble 422 and adapted to abut against one of the sliding plates 44 of the adjusting member, and the pressure gauge is fixed to the other port of the T-shaped tube 41 by a connecting member 421.

Moreover, as a possible embodiment, further, the gas source mechanism 5 is a carbon dioxide gas tank, and a second valve 52 is arranged on an output end of the carbon dioxide gas tank, and the second valve 52 is an electromagnetic valve; a third valve 121 is arranged on the feeding hole of the blending tank 1, and the third valve 121 is an electromagnetic valve; as a possible implementation manner, further, a fourth valve 131 is arranged on the discharge port 13 arranged at the lower part of the blending tank 1, and the fourth valve 131 is an electromagnetic valve; the circumferential side of the part of the air pipe 51 penetrating into the blending tank 1 is provided with a plurality of through holes 511.

The technical scheme ingeniously utilizes the concentrator 3 to gather raw materials of a plurality of raw material tanks 2 into one strand, then the raw materials are input into the blending tank 1 to be blended, the pulse electromagnetic valve 53 is matched with the gas conveying pipe 51 and the gas source mechanism 5, so that when components of carbonated beverages are blended, carbon dioxide output by the gas source mechanism 5 can be intermittently input into the blending tank 1 in a pulse mode through the control of the pulse electromagnetic valve 53, the input carbon dioxide can form bubbles to blend the components of the carbonated beverages, namely, a gas pulse blending effect is formed among the gas source mechanism 5, the pulse electromagnetic valve 53 and the gas conveying pipe 51, after the blending is finished, carbon dioxide can be injected in a mode of directly inputting carbon dioxide, the carbon dioxide is dissolved in the carbonated beverages, the beverage inflation effect is realized, and the exhaust mechanism 4 can realize the beverage inflation effect through the T-shaped pipe fitting 41, The cooperation of regulating part, adapter sleeve 43 and withstand voltage portion 42 has realized the jar pressure dynamic balance in the allotment jar 1, namely, when atmospheric pressure in the allotment jar 1 is greater than the spring 45 pressure of regulating part, can promote the sliding plate 46 that supports the pressure with adapter sleeve 43 and slide for adapter sleeve 43 and gas vent 411 intercommunication, and when the pressure in the allotment jar 1 reduced, sliding plate 46 again can be promoted by spring 45 and reset, make adapter sleeve and gas vent 411 cut off, the implementation of this scheme is reliable, adjust effectual and efficient.

The above is the embodiment of the present invention, and to the ordinary skilled in the art, according to the teaching of the present invention, the equal changes, modifications, replacements and variations of the claims should all belong to the scope of the present invention without departing from the principle and spirit of the present invention.

Claims (9)

1. A blending tank for carbonated beverage ingredient mixing, comprising:

the blending tank is internally provided with a containing cavity for containing each component of carbonated beverage, the upper part of the blending tank is provided with a plurality of feed inlets for inputting the carbonated beverage raw materials, and the lower part of the blending tank is provided with a discharge outlet;

a plurality of material tanks for providing liquid materials of each component of the carbonated beverage;

the method is characterized in that: it still includes:

the concentrator is provided with a plurality of input interfaces and an output interface, wherein the input interfaces correspond to the raw material tanks one by one and are respectively connected with the discharge ports of the raw material tanks through first pipelines, the first pipelines are provided with first pumps, and the output interfaces are connected with the feed ports of the blending tanks through second pipelines;

the gas source mechanism is used for providing carbon dioxide gas;

one end of the gas pipe is connected with the output end of the gas source mechanism, and the other end of the gas pipe extends to the upper part of the blending tank, penetrates into the blending tank and is used for guiding the carbon dioxide gas output by the gas source mechanism into the blending tank;

the pulse electromagnetic valve is arranged at one end of the gas transmission pipe close to the gas source mechanism, and the carbon dioxide output by the gas source mechanism is input into the blending tank through the gas transmission pipe in a pulse mode;

and the exhaust mechanism is arranged at the top of the blending tank, penetrates into the blending tank and is used for adjusting the air pressure in the blending tank.

2. A blending tank for carbonated beverage ingredient mixing according to claim 1, wherein: the concentrator is of an annular shell structure, a plurality of input interfaces and a plurality of output interfaces of the concentrator are all communicated with the outer side of the main body of the concentrator in a tangent mode and are arranged on the outer side of the concentrator, and the input direction of the input interfaces and the output direction of the output interfaces are all the medium flow direction in the antegrade concentrator.

3. A blending tank for carbonated beverage ingredient mixing according to claim 2, wherein: and the input interface and the output interface are respectively provided with a first valve.

4. A blending tank for carbonated beverage ingredient mixing according to claim 1, wherein: the exhaust mechanism includes:

the connecting sleeve is of a tubular structure, one end of the connecting sleeve is used for penetrating into the blending tank, and the other end of the connecting sleeve is provided with an external thread;

one of the two end interfaces of the T-shaped pipe fitting, which are positioned in the same axial direction, is provided with internal threads and is in threaded connection with the other end of the connecting sleeve, the other interface is connected with the pressing part, one interface except the two interfaces is used for exhausting gas in the blending tank, and the interface is arranged as an exhaust port;

the adjusting part is movably arranged in the T-shaped pipe and located between the two end connectors of the T-shaped pipe in the same axial direction, the adjusting part comprises a pair of sliding plates, the sliding plates are connected through springs, one sliding plate abuts against the abutting part, the other sliding plate abuts against the other end of the connecting sleeve and is used for separating the connecting sleeve from the exhaust port, and the sliding plates slide along the direction close to the abutting part to remove the separation.

5. A blending tank for carbonated beverage ingredient mixing according to claim 4, wherein: the butt joint portion be the manometer, this manometer has the thimble and is used for with one of them sliding plate butt of regulating part, the manometer fix on another interface of T shape pipe fitting through a connecting piece.

6. A blending tank for carbonated beverage ingredient mixing according to claim 1, wherein: the gas source mechanism is a carbon dioxide gas tank, the output end of the carbon dioxide gas tank is provided with a second valve, and the second valve is an electromagnetic valve.

7. A blending tank for carbonated beverage ingredient mixing according to claim 1, wherein: and a third valve is arranged on the feed inlet of the blending tank and is an electromagnetic valve.

8. A blending tank for carbonated beverage ingredient mixing according to claim 1, wherein: and a discharge port arranged at the lower part of the blending tank is provided with a fourth valve which is an electromagnetic valve.

9. A blending tank for carbonated beverage ingredient mixing according to claim 1, wherein: the circumferential side of the pipeline part of the gas pipe penetrating into the blending tank is provided with a plurality of through holes.

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