CN214130314U

CN214130314U - Spherical concentration device of edible mushroom polysaccharide extracting solution

Info

Publication number: CN214130314U
Application number: CN202022622788.3U
Authority: CN
Inventors: 王冰怡
Original assignee: Guizhou Hongchishui Group Co ltd
Current assignee: Guizhou Hongchishui Group Co ltd
Priority date: 2020-11-13
Filing date: 2020-11-13
Publication date: 2021-09-07
Anticipated expiration: 2030-11-13

Abstract

The utility model discloses a spherical concentration device of edible fungus polysaccharide extract, which comprises a buffer tank and a concentration tank which are spherical, wherein the upper part of the buffer tank is provided with an exhaust pipe with a check valve, the top end of the buffer tank is provided with a pressure sensor, and the bottom of the buffer tank is provided with a drain pipe A with a drain valve A; the concentrating tank is surrounded by a steam jacket, the steam jacket is divided into half parts into independent jackets, the independent jackets are respectively connected with a steam input pipe and a steam output pipe, the independent jackets are communicated with each other through a heating tube array transversely penetrating through the lower half part of the concentrating tank, the top end of the concentrating tank is provided with a liquid inlet pipe with an isolation valve, and the bottom end of the concentrating tank is provided with a liquid outlet pipe with a liquid outlet valve; the top side of the concentration tank is communicated with the cache tank through a communicating pipe. The utility model discloses steam jacket half-and-half divide into the independent cover that presss from both sides, independently press from both sides the heating tubulation intercommunication through transversely running through concentrated jar lower half between the cover, and the inside and outside concurrent heating increases evaporation efficiency. And the negative pressure pump does not need to work all the time, the pumping is more efficient, and the energy-saving effect is achieved.

Description

Spherical concentration device of edible mushroom polysaccharide extracting solution

Technical Field

The utility model relates to an edible mushroom processing equipment technical field, in particular to spherical enrichment facility of edible mushroom polysaccharide extract.

Background

The subsequent process of the edible fungus polysaccharide extracting solution needs to concentrate the edible fungus polysaccharide extracting solution, the most efficient process is steam heating and negative pressure evaporation, but the current steam heating adopts an integral jacket, the inside cannot be heated, a negative pressure pump needs to be operated all the time in the negative pressure evaporation process, but the concentration of the steam generated in unit time is not high, the suction efficiency is low, and the overall energy consumption is high.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to provide a spherical enrichment facility of domestic fungus polysaccharide extract to solve the technical problem in the above-mentioned background art.

The technical scheme of the utility model is that:

a spherical concentration device for edible fungus polysaccharide extract comprises a cache tank and a concentration tank which are spherical, wherein an exhaust pipe with a check valve is arranged at the upper part of the cache tank, a pressure sensor is arranged at the top end of the cache tank, and a drain pipe A with a drain valve A is arranged at the bottom of the cache tank; the concentrating tank is surrounded by a steam jacket, the steam jacket is divided into half parts into independent jackets, the independent jackets are respectively connected with a steam input pipe and a steam output pipe, the independent jackets are communicated with each other through a heating tube array transversely penetrating through the lower half part of the concentrating tank, the top end of the concentrating tank is provided with a liquid inlet pipe with an isolation valve, and the bottom end of the concentrating tank is provided with a liquid outlet pipe with a liquid outlet valve; the top side of the concentration tank is communicated with the cache tank through a communicating pipe.

Furthermore, the bottom sides of the independent jackets are respectively provided with a drain pipe B with a drain valve B.

Furthermore, the heating tube array adopts a quartz glass tube or a ceramic tube.

Further, the pressure sensor feeds back the pressure to the controller, and the controller controls the negative pressure pump to pump the cache tank.

Furthermore, both ends of the communicating pipe are connected with the concentration tank and the cache tank through flange plates.

Furthermore, the bottoms of the concentration tank and the buffer tank are provided with support legs.

The utility model discloses an useful part lies in:

the utility model discloses a steam heating, inferior vacuum evaporation, the steam jacket is half divided into and independently presss from both sides the cover with prior art difference, independently presss from both sides the heating tubulation intercommunication through transversely running through concentrated jar lower half between the cover, so not only adopts the external heating, also can follow the internal heating, increases evaporation efficiency. And different with traditional negative pressure pump continuous work, the utility model discloses well concentrated jar is the intercommunication with the buffer memory jar, and the storage volume of its steam increases, only need take the buffer memory jar interior air out the back, all is in inferior vacuum state in a period, does not need negative pressure pump to work always, when pressure sensor monitors pressure and will be close the atmospheric pressure, negative pressure pump restarts, stops work, reciprocating cycle again until the lower limit threshold value that is close to the setting. Therefore, the negative pressure pump can be prevented from running all the time, the suction is more efficient, and the energy-saving effect is achieved.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

In the figure: 1-cache tank, 11-suction pipe, 111-check valve, 12-drain pipe A, 13-drain valve A, 2-concentration tank, 21-liquid inlet pipe, 211-isolation valve, 22-drain pipe, 221-drain valve, 3-steam jacket, 31-steam input pipe, 32-steam output pipe, 33-drain pipe B, 331-drain valve B, 34-support leg, 4-communicating pipe, 41-flange plate, 5-heating array pipe and 6-pressure sensor.

Detailed Description

The following describes the present invention with reference to the accompanying drawings. It should be noted that the description of the embodiments is provided to help understanding of the present invention, but the present invention is not limited thereto. In addition, the technical features related to the embodiments of the present invention described below may be combined with each other as long as they do not conflict with each other.

As shown in fig. 1:

a spherical concentration device for edible fungus polysaccharide extract comprises a buffer tank 1 and a concentration tank 2 which are spherical, wherein an exhaust pipe 11 with a check valve 111 is arranged at the upper part of the buffer tank 1, a pressure sensor 6 is arranged at the top end of the buffer tank, and a drain pipe A12 with a drain valve A13 is arranged at the bottom of the buffer tank; a steam jacket 3 is surrounded outside the concentration tank 2, the steam jacket 3 is divided into half parts into independent jackets, the independent jackets are respectively connected with a steam input pipe 31 and a steam output pipe 32, the independent jackets are communicated with each other through a heating tube array 5 transversely penetrating through the lower half part of the concentration tank 2, a liquid inlet pipe 21 with an isolation valve 211 is arranged at the top end of the concentration tank 2, and a liquid outlet pipe 22 with a liquid outlet valve 221 is arranged at the bottom end of the concentration tank 2; the top side of the concentration tank 2 is communicated with the buffer tank 1 through a communicating pipe 4.

Specifically, the bottom sides of the independent jackets are respectively provided with a drain pipe B33 with a drain valve B331.

Specifically, the heating tubes 5 are quartz glass tubes or ceramic tubes, and the quartz tubes and the ceramic tubes have high thermal stability and are not easy to generate biochemical reaction with the extracting solution.

Specifically, the pressure sensor 6 feeds back the pressure to the controller, and the controller controls the negative pressure pump to pump the buffer tank 1.

Specifically, both ends of the communicating pipe 4 are connected with the concentration tank 2 and the buffer tank 1 through the flange plate 41, so that the maintenance, the transportation, the installation and the like are facilitated.

Specifically, the bottoms of the concentration tank 2 and the buffer tank 1 are provided with support legs 34.

The working principle is as follows: the utility model discloses a steam heating, inferior vacuum evaporation, the difference with prior art is that steam jacket 3 is divided into half and independently presss from both sides the cover, independently presss from both sides the heating tubulation 5 intercommunication through transversely running through 2 lower halves of concentrated jar between the cover, so not only adopts the external heating, also can follow the internal heating, increases evaporation efficiency. And different with traditional negative pressure pump continuous work, the utility model discloses well concentrated jar 2 is the intercommunication with buffer memory jar 1, and the storage volume of its steam increases, only needs take the back out with buffer memory jar 1 interior air, all is in inferior vacuum state in a period, does not need negative pressure pump to work always, when pressure sensor 6 monitors pressure and will be close the atmospheric pressure, negative pressure pump restart, until the lower limit threshold value that is close to the setting stop work again, reciprocal circulation. Therefore, the negative pressure pump can be prevented from running all the time, the suction is more efficient, and the energy-saving effect is achieved.

The embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited to the described embodiments. It will be apparent to those skilled in the art that various changes, modifications, substitutions and alterations can be made in the embodiments without departing from the principles and spirit of the invention, and the scope of the invention is to be accorded the full scope of the claims.

Claims

1. The utility model provides a spherical enrichment facility of domestic fungus polysaccharide extract which characterized in that: the device comprises a buffer tank and a concentration tank which are both spherical, wherein an exhaust pipe with a check valve is arranged at the upper part of the buffer tank, a pressure sensor is arranged at the top end of the buffer tank, and a drain pipe A with a drain valve A is arranged at the bottom of the buffer tank; the concentrating tank is surrounded by a steam jacket, the steam jacket is divided into half parts into independent jackets, the independent jackets are respectively connected with a steam input pipe and a steam output pipe, the independent jackets are communicated with each other through a heating tube array transversely penetrating through the lower half part of the concentrating tank, the top end of the concentrating tank is provided with a liquid inlet pipe with an isolation valve, and the bottom end of the concentrating tank is provided with a liquid outlet pipe with a liquid outlet valve; the top side of the concentration tank is communicated with the cache tank through a communicating pipe.

2. The spherical concentrating device of edible fungus polysaccharide extracting solution as claimed in claim 1, wherein: and the bottom sides of the independent jackets are respectively provided with a drain pipe B with a drain valve B.

3. The spherical concentrating device of edible fungus polysaccharide extracting solution as claimed in claim 1, wherein: the heating tubes are quartz glass tubes or ceramic tubes.

4. The spherical concentrating device of edible fungus polysaccharide extracting solution as claimed in claim 1, wherein: the pressure sensor feeds back the pressure to the controller, and the controller controls the negative pressure pump to pump the cache tank.

5. The spherical edible fungus polysaccharide extracting solution concentrating device as claimed in any one of claims 1 to 4, wherein: and two ends of the communicating pipe are connected with the concentration tank and the cache tank through flange plates.

6. The spherical edible fungus polysaccharide extracting solution concentrating device as claimed in any one of claims 1 to 4, wherein: and supporting legs are arranged at the bottoms of the concentration tank and the buffer tank.