CN217139313U - Full-automatic vacuum degasser - Google Patents

Abstract

The utility model discloses a full-automatic vacuum degassing machine relates to vacuum degassing machine technical field. The utility model discloses a structure includes box, vacuum tank, vacuum pump, discharge valve, circulation jar, No. two pumps, nitrogen gas jar, vacuum tank, circulation jar and nitrogen gas jar have been placed in the box in the casing, vacuum tank top lateral wall intercommunication has the pan feeding pipe, the vacuum pump passes through exhaust tube and vacuum tank lateral wall intercommunication, discharge valve sets up in the top lateral wall through-hole of vacuum tank, be provided with a pump on the top lateral wall of circulation jar, the delivery port and the circulation jar intercommunication of a pump, the water inlet is through a pipe and vacuum tank intercommunication, No. two pumps set up the right side wall at the vacuum tank, the delivery port and the vacuum tank intercommunication of No. two pumps, the water inlet is through No. two pipes and circulation jar intercommunication, the nitrogen gas jar is through No. three pipes and circulation jar intercommunication. The utility model discloses but the manifold cycles degasification, and prevent that oxygen from melting into the feed liquid again.

Description

Full-automatic vacuum degasser

Technical Field

The utility model relates to a vacuum degasser technical field especially relates to a full-automatic vacuum degasser.

Background

Deaerators, also known as deaerators, are commonly used to vacuum deaerate fruit juices to inhibit oxidation and browning of the juice. The gas attached to the suspended particles can be removed simultaneously through degassing, so that the particles are prevented from floating upwards, and the appearance of the product is improved; reduce foaming during high-temperature sterilization and filling, improve the sterilization effect and reduce the corrosion in the container. The production of liquid milk or milk-containing beverages is also often degassed. Vacuum degassing is generally carried out after homogenization and sometimes also before filling. In the prior art, the degasser utilizes a circulating pump to enable feed liquid to circularly flow in a vacuum tank for degassing for multiple times, and gas particles are easily re-melted into the feed liquid in the flowing process of the feed liquid.

Accordingly, one skilled in the art provides a subject to solve the problems set forth in the background above.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that, overcome prior art feed liquid and circulate in a vacuum tank and flow, carry out degasification many times, feed liquid flows in-process gas particle and fuses into the feed liquid again easily.

In order to solve the technical problems, the utility model provides a full-automatic vacuum degassing machine, which comprises,

the box body is of a cuboid shell structure, a vacuum tank, a circulating tank and a nitrogen tank are arranged in the shell in the box body, and the box body plays a role in supporting and protecting an internal structure;

the degassing device structurally comprises a vacuum tank, wherein the vacuum tank is of a cylindrical shell structure, four L-shaped supporting legs are uniformly fixed at the bottom end of the vacuum tank, the vacuum tank is arranged on the left side of a cavity in the tank body, a right L-shaped feeding pipe is arranged on the upper side of the vacuum tank, the bottom end of the feeding pipe is fixed in a through hole in the top side wall of the vacuum tank, and external feed liquid is guided into the vacuum tank by the feeding pipe; the vacuum pump is arranged at the left lower corner of the cavity of the box body and is communicated with the side wall of the top of the vacuum tank through an exhaust pipe, the vacuum pump exhausts air in the vacuum tank to form negative pressure in the vacuum tank, and gas particles in feed liquid in the vacuum tank float upwards and are separated from the feed liquid; the exhaust valve is arranged in the through hole on the top side wall of the vacuum tank, gas in the feed liquid is exhausted, so that the pressure in the vacuum tank is increased to positive pressure, and the gas is exhausted from the exhaust valve;

the circulating device structurally comprises a circulating tank, wherein the circulating tank is of a cylindrical shell structure, four L-shaped supporting legs are uniformly fixed at the bottom end of the circulating tank, the circulating tank is arranged in the middle of a cavity in a box body, a first pump is arranged on the top side wall of the circulating tank, the water outlet of the first pump is fixed in a through hole in the top side wall of the circulating tank, a first pipe is fixed at the water inlet end of the first pump, the bottom end of the first pipe is fixed in a through hole in the bottom wall of the vacuum tank, and the first pump pumps feed liquid subjected to primary degassing in the vacuum tank into the circulating tank through the first pipe; the second pump is arranged at the top of the right side wall of the vacuum tank, a water outlet of the second pump is fixed in a through hole in the right wall of the vacuum tank, a second pipe is fixed at a water inlet end of the second pump, the bottom end of the second pipe is fixed in a through hole in the bottom side wall of the circulating tank, and the second pump pumps the feed liquid in the circulating tank into the vacuum tank again for degassing; nitrogen gas jar, nitrogen gas jar are cylinder shell structure, and the bottom is evenly fixed with four L type landing legs, the nitrogen gas jar sets up the right side at the box inner chamber, nitrogen gas has been stored in the nitrogen gas jar, the roof of nitrogen gas jar is through the top lateral wall intercommunication of No. three pipes with the circulating tank, nitrogen gas passes through No. three pipe input circulating tanks in the nitrogen gas jar, when preventing to lead to the feed liquid circulation not smooth because of atmospheric pressure, guarantees not to make new oxygen melt into the feed liquid.

As a further aspect of the present invention: the feeding pipe is provided with a first electromagnetic valve, and the first electromagnetic valve can electrically brake to control whether the feeding pipe is conducted or not.

As a further aspect of the present invention: and a third electromagnetic valve is arranged at the connecting part of the third pipe and the nitrogen tank, and the third electromagnetic valve can electrically brake the third pipe to be conducted or not.

As a further aspect of the present invention: the bottom of the second pipe is communicated with a discharge pipe, and the discharge pipe is convenient for discharging the feed liquid degassed for multiple times in the circulating tank.

As a further aspect of the present invention: the discharging pipe is provided with a second electromagnetic valve, and the second electromagnetic valve can electrically brake whether the discharging pipe is conducted or not.

As a further aspect of the present invention: the refrigerator is characterized in that a double-leaf refrigerator door is arranged on the front side wall of the refrigerator body, the refrigerator door is convenient to open the refrigerator body, and a vacuum tank, a circulating tank and a nitrogen tank are installed on the refrigerator door.

As a further aspect of the present invention: an observation window is arranged in a through hole in the top of the box door, and the observation window is convenient for observing the internal structure of the box body.

As a further aspect of the present invention: four corners of the bottom side wall of the box body are respectively provided with a universal self-locking wheel, and the box body is convenient to move through the universal self-locking wheels.

As a further aspect of the present invention: a U-shaped pushing handle is fixed on the right side wall of the box body, and the pushing handle is convenient for pushing the box body to move.

As a further aspect of the present invention: the control panel is arranged on the box door and electrically connected with the electromagnetic valve, the pump and the vacuum pump, and the control panel is convenient for controlling the operation of equipment.

As a further aspect of the present invention: the model of the electromagnetic valve is HU 5404.

The utility model has the advantages that:

(1) the utility model is provided with a circulating device, when in use, a first electromagnetic valve is opened, an external feed liquid is guided into a vacuum tank by a feeding pipe, a vacuum pump pumps air out of the vacuum tank, so that negative pressure is formed in the vacuum tank, gas particles in the feed liquid in the vacuum tank float upwards and are separated from the feed liquid, gas in the feed liquid is discharged, the air pressure in the vacuum tank is increased to positive pressure, and the gas is discharged from a vent valve; the first pump pumps the material liquid subjected to primary degassing in the vacuum tank into the circulating tank through the first pipe, and the nitrogen in the circulating tank forms bubbles and enters the vacuum tank from the first pipe; the second pump pumps the feed liquid in the circulation tank into the vacuum tank again for degassing, the third electromagnetic valve is opened, nitrogen in the nitrogen tank is input into the circulation tank through the third pipe, positive pressure is formed in the vacuum tank along with the feed liquid filled in the vacuum tank, and residual gas and nitrogen are mixed and discharged from the exhaust valve. The utility model discloses but manifold cycles degasification.

(2) The utility model discloses set up the nitrogen gas jar, No. two pumps go into vacuum tank degasification again with the feed liquid in the circulating tank, and No. three solenoid valves are opened simultaneously, and nitrogen gas is in the nitrogen gas jar through No. three pipe input circulating tanks, along with sufficient feed liquid in the vacuum tank, forms the malleation in the vacuum tank, and residual gas and nitrogen gas mix, discharge from discharge valve. The utility model discloses prevent that oxygen from melting into in the feed liquid again.

Drawings

Fig. 1 is a front view of the present invention;

fig. 2 is a sectional view of the case.

Wherein: the device comprises a box body 10, a box door 11, an observation window 12, a control panel 13, universal self-locking wheels 14, a push handle 15, a vacuum tank 20, supporting legs 21, a feeding pipe 22, a first electromagnetic valve 23, a vacuum pump 24, an air suction pipe 25, an exhaust valve 26, a circulating tank 30, a first pipe 31, a first pump 32, a second pipe 33, a second pump 34, an exhaust pipe 35, a second electromagnetic valve 36, a nitrogen tank 37, a third pipe 38 and a third electromagnetic valve 39.

Detailed Description

The structure of the fully automatic vacuum degasser provided by the embodiment is shown in fig. 1-2, and comprises,

the box body 10 is of a cuboid shell structure, a vacuum tank 20, a circulating tank 30 and a nitrogen tank 37 are placed in an inner shell of the box body 10, and the box body 10 plays a role in supporting and protecting an internal structure;

the degassing device structurally comprises a vacuum tank 20, wherein the vacuum tank 20 is of a cylindrical shell structure, four L-shaped supporting legs 21 are uniformly fixed at the bottom end of the vacuum tank 20, the vacuum tank 20 is arranged on the left side of a cavity in a box body 10, a right L-shaped feeding pipe 22 is arranged on the upper side of the vacuum tank 20, the bottom end of the feeding pipe 22 is fixed in a through hole in the top side wall of the vacuum tank 20, and external feed liquid is guided into the vacuum tank 20 through the feeding pipe 22; the vacuum pump 24 is arranged at the left lower corner of the cavity of the box body 10, the vacuum pump 24 is communicated with the side wall of the top of the vacuum tank 20 through an air exhaust pipe 25, the vacuum pump 24 exhausts air in the vacuum tank 20 to form negative pressure in the vacuum tank 20, and gas particles in feed liquid in the vacuum tank 20 float upwards and are separated from the feed liquid; an exhaust valve 26, the exhaust valve 26 is arranged in the through hole of the top side wall of the vacuum tank 20, the gas in the feed liquid is exhausted, so that the pressure in the vacuum tank 20 is increased to positive pressure, and the gas is exhausted from the exhaust valve 26;

the circulating device structurally comprises a circulating tank 30, wherein the circulating tank 30 is of a cylindrical shell structure, four L-shaped supporting legs 21 are uniformly fixed at the bottom end of the circulating tank 30, the circulating tank 30 is arranged in the middle of a cavity in a box body 10, a first pump 32 is arranged on the top side wall of the circulating tank 30, a water outlet of the first pump 32 is fixed in a through hole in the top side wall of the circulating tank 30, a first pipe 31 is fixed at a water inlet end of the first pump 32, the bottom end of the first pipe 31 is fixed in a through hole in the bottom wall of a vacuum tank 20, and the first pump 32 pumps feed liquid subjected to primary degassing in the vacuum tank 20 into the circulating tank 30 through the first pipe 31; a second pump 34, the second pump 34 is arranged at the top of the right side wall of the vacuum tank 20, the water outlet of the second pump 34 is fixed in the through hole of the right side wall of the vacuum tank 20, a second pipe 33 is fixed at the water inlet of the second pump 34, the bottom end of the second pipe 33 is fixed in the through hole of the bottom side wall of the circulation tank 30, and the second pump 34 pumps the feed liquid in the circulation tank 30 into the vacuum tank 20 again for degassing; nitrogen gas jar 37, nitrogen gas jar 37 are cylinder shell structure, and the bottom is evenly fixed with four L type landing legs 21, nitrogen gas jar 37 sets up the right side at box 10 inner chamber, nitrogen gas has been stored in nitrogen gas jar 37, nitrogen gas jar 37's roof is through the top lateral wall intercommunication of No. three pipe 38 with circulation tank 30, nitrogen gas is in the nitrogen gas jar 37 through No. three pipe 38 input circulation tank 30, when preventing to lead to the feed liquid circulation not smooth because of atmospheric pressure, guarantees not to make new oxygen melt into the feed liquid.

The feeding pipe 22 is provided with a first electromagnetic valve 23, and the first electromagnetic valve 23 can electrically brake to control whether the feeding pipe 22 is conducted or not.

And a third electromagnetic valve 39 is arranged at the connecting part of the third pipe 38 and the nitrogen tank 37, and the third electromagnetic valve 39 can electrically brake whether the third pipe 38 is conducted or not.

The bottom of the second pipe 33 is communicated with a discharge pipe 35, and the discharge pipe 35 is convenient for discharging the feed liquid which is degassed for multiple times in the circulation tank 30.

The discharge pipe 35 is provided with a second electromagnetic valve 36, and the second electromagnetic valve 36 can electrically brake whether the discharge pipe 35 is conducted or not.

The front side wall of the box body 10 is provided with a double-blade box door 11, the box door 11 is convenient for opening the box body 10, and a vacuum tank 20, a circulating tank 30 and a nitrogen tank 37 are installed.

An observation window 12 is arranged in a through hole at the top of the box door 11, and the observation window 12 is convenient for observing the internal structure of the box body 10.

Four corners of the bottom side wall of the box body 10 are respectively provided with a universal self-locking wheel 14, and the box body 10 is convenient to move through the universal self-locking wheels 14.

A U-shaped push handle 15 is fixed on the right side wall of the box body 10, and the push handle 15 is convenient for pushing the box body 10 to move.

The refrigerator door 10 is provided with a control panel 13, the control panel 13 is electrically connected with the electromagnetic valve, the pump and the vacuum pump 24, and the control panel 13 is convenient for controlling the operation of the device.

The model of the electromagnetic valve is HU 5404.

The utility model discloses a theory of operation: when the device is used, the first electromagnetic valve 23 is opened, the feeding pipe 22 guides external feed liquid into the vacuum tank 20, the vacuum pump 24 pumps air out of the vacuum tank 20, so that negative pressure is formed in the vacuum tank 20, gas particles in the feed liquid in the vacuum tank 20 float upwards and are separated from the feed liquid, gas in the feed liquid is discharged, so that the gas pressure in the vacuum tank 20 is increased to positive pressure, and the gas is discharged from the exhaust valve 26; the first pump 32 pumps the feed liquid which is degassed once in the vacuum tank 20 into the circulating tank 30 through the first pipe 31, and the nitrogen in the circulating tank 30 forms bubbles and enters the vacuum tank 20 from the first pipe 31; the second pump 34 pumps the feed liquid in the circulation tank 30 into the vacuum tank 20 again for degassing, meanwhile, the third electromagnetic valve is opened, nitrogen in the nitrogen tank 37 is input into the circulation tank 30 through the third pipe 38, positive pressure is formed in the vacuum tank 20 along with the feed liquid filled in the vacuum tank 20, and residual gas and nitrogen are mixed and discharged from the exhaust valve 26. The utility model discloses but the manifold cycles degasification, and prevent that oxygen from melting into the feed liquid again.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (5)

1. A full-automatic vacuum degasser is characterized by comprising,

the box body (10) is of a cuboid shell structure, a vacuum tank (20), a circulating tank (30) and a nitrogen tank (37) are placed in an inner shell of the box body (10), and the box body (10) plays a role in supporting and protecting an internal structure;

the degassing device structurally comprises a vacuum tank (20), wherein the vacuum tank (20) is of a cylindrical shell structure, four L-shaped supporting legs (21) are uniformly fixed at the bottom end of the vacuum tank (20), the vacuum tank (20) is arranged on the left side of a cavity in a box body (10), a right L-shaped feeding pipe (22) is arranged on the upper side of the vacuum tank (20), the bottom end of the feeding pipe (22) is fixed in a through hole in the top side wall of the vacuum tank (20), and external feed liquid is introduced into the vacuum tank (20) through the feeding pipe (22); the vacuum pump (24) is arranged at the left lower corner of the cavity of the box body (10), the vacuum pump (24) is communicated with the side wall of the top of the vacuum tank (20) through an air exhaust pipe (25), the vacuum pump (24) exhausts air in the vacuum tank (20) to enable negative pressure to be formed in the vacuum tank (20), and gas particles in feed liquid in the vacuum tank (20) float upwards and are separated from the feed liquid; the exhaust valve (26), the exhaust valve (26) is arranged in the through hole of the top side wall of the vacuum tank (20), the gas in the feed liquid is exhausted, so that the pressure in the vacuum tank (20) is increased to positive pressure, and the gas is exhausted from the exhaust valve (26);

the circulating device structurally comprises a circulating tank (30), wherein the circulating tank (30) is of a cylindrical shell structure, four L-shaped supporting legs (21) are uniformly fixed at the bottom end of the circulating tank (30), the circulating tank (30) is arranged in the middle of a cavity in a box body (10), a first pump (32) is arranged on the top side wall of the circulating tank (30), a water outlet of the first pump (32) is fixed in a through hole in the top side wall of the circulating tank (30), a first pipe (31) is fixed at the water inlet end of the first pump (32), the bottom end of the first pipe (31) is fixed in a through hole in the bottom wall of the vacuum tank (20), and the first pump (32) pumps feed liquid which is degassed once in the vacuum tank (20) into the circulating tank (30) through the first pipe (31); the second pump (34), the second pump (34) is arranged at the top of the right side wall of the vacuum tank (20), the water outlet of the second pump (34) is fixed in a through hole in the right wall of the vacuum tank (20), a second pipe (33) is fixed at the water inlet of the second pump (34), the bottom end of the second pipe (33) is fixed in a through hole in the bottom side wall of the circulation tank (30), and the second pump (34) pumps the feed liquid in the circulation tank (30) into the vacuum tank (20) again for degassing; nitrogen gas jar (37), nitrogen gas jar (37) are cylinder shell structure, and the bottom is evenly fixed with four L type landing legs (21), nitrogen gas jar (37) set up the right side at box (10) inner chamber, nitrogen gas has been stored in nitrogen gas jar (37), the roof of nitrogen gas jar (37) is through the top lateral wall intercommunication of No. three pipe (38) with circulation tank (30), nitrogen gas is in nitrogen gas jar (37) through No. three pipe (38) input circulation tank (30), when preventing to lead to the feed liquid circulation not smooth because of atmospheric pressure, guarantees not to make new oxygen melt into the feed liquid.

2. A fully automatic vacuum degasser as claimed in claim 1 wherein: the feeding pipe (22) is provided with a first electromagnetic valve (23), and the first electromagnetic valve (23) can electrically brake to control whether the feeding pipe (22) is conducted or not.

3. A fully automatic vacuum degasser as claimed in claim 1 wherein: and a third electromagnetic valve (39) is arranged at the connecting part of the third pipe (38) and the nitrogen tank (37), and the third electromagnetic valve (39) can electrically brake the third pipe (38) to be conducted or not.

4. A fully automatic vacuum degasser as claimed in claim 1 wherein: the bottom of the second pipe (33) is communicated with a discharge pipe (35), and the discharge pipe (35) is convenient for discharging the feed liquid which is degassed for multiple times in the circulating tank (30).

5. The fully automatic vacuum degasser of claim 4, further comprising: a second electromagnetic valve (36) is arranged on the discharge pipe (35), and the second electromagnetic valve (36) can electrically brake whether the discharge pipe (35) is conducted or not.

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