CN218404077U - Filter tank integrated device that circles round - Google Patents

Abstract

The utility model provides a rotary integrated device of a filter tank, which is used for receiving mash of a saccharification device and is communicated with a boiling device, and comprises a shell, a filter bottom plate, a ploughing knife, a circulation pipeline and a wort collection pipeline; the shell is hollow to form a working space; the filtering bottom plate is arranged in the shell to divide the working space into a filtering tank and a rotary tank in sequence; a feeding port and a discharging port are formed in the peripheral side wall of the filter tank; the plowing knife is rotatably arranged in the filter tank; one end of the circulating pipeline is communicated with the bottom of the filtering tank, and the other end of the circulating pipeline is communicated with the upper part of the filtering tank for circulating the wort; the wort collecting pipe is used for conveying wort in the filter tank to the boiling pot and then whirling and precipitating residues in the whirling tank. The filter tank and the rotary tank are integrally arranged, so that the structure is simplified, the installation and the disassembly are convenient, the manufacturing cost is reduced, and the occupied area of the filter tank and the rotary tank is reduced.

Description

Filter tank integrated device that circles round

Technical Field

The utility model relates to a making wine equipment technical field, in particular to filter-tank integrated device that circles round.

Background

Wine is used as a special culture carrier, and a great number of literary scholars write down a good vintage of appreciation and beauty wine.

At present, large-scale wine production plants commonly adopt three-pot two-tank, namely a pasting pot, a saccharifying pot, a boiling pot, a filtering tank and a rotary tank, but the three-pot two-tank are separated from each other. The floor area of the production equipment is large, and the manufacturing cost is high.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a filter tank integration device that circles round that reduces area and manufacturing cost.

In order to solve the technical problem, the following technical scheme is adopted in the application:

according to one aspect of the application, the application provides a filter tank convolution integrated device which is used for receiving mash of a saccharification device and communicated with a boiling device, and comprises a shell, a filter bottom plate, a plowing knife, a circulation pipeline and a wort collecting pipe; the interior of the shell is hollow so as to form a working space; the filtering bottom plate is arranged in the middle of the shell, and the peripheral side of the filtering bottom plate is abutted against the inner peripheral wall of the shell so as to divide the working space; the filtering bottom plate comprises a sieve plate and a sandwich plate, the sieve plate filters the mash to separate wort, the sandwich plate is positioned at the lower side of the sieve plate, and the working space at the upper side of the sandwich plate is divided into filtering tanks; a feeding port and a discharging port are formed in the shell on the upper side of the sieve plate; the sandwich plate divides the working space on the lower side of the shell into convolution grooves; the tilling knife is rotatably arranged in the filter tank; one end of the circulating pipeline is communicated with the working space between the sieve plate and the sandwich plate to absorb wort; the other end of the circulating pipeline is communicated with the upper part of the filtering tank, and a circulating pump is arranged on the circulating pipeline to circulate the wort in the filtering tank; the wort collecting pipe is used for conveying wort in the filter tank to the rotary tank.

In some embodiments, the bottom wall of the casing is conical and protrudes upwards, the wort collecting pipe is communicated with the casing on the peripheral side of the whirling groove, and the wort flowing direction of one end of the wort collecting pipe communicated with the whirling groove is tangential to the inner peripheral wall of the whirling groove, so that residues in the wort are whirled and settled to the middle of the bottom wall of the casing.

In some embodiments, the liquid transfer pipeline penetrates through the bottom wall of the housing to communicate with the rotary groove, and a port of the liquid transfer pipeline, which is communicated with the rotary groove, is close to the peripheral side of the housing.

In some embodiments, the circulation pump is communicated with the liquid transfer pipeline to pump out the wort in the rotary tank.

In some embodiments, the circulation pump is a variable frequency pump.

In some embodiments, the top of the filter tank and the top of the cyclone tank are provided with constant pressure ventilation ports.

In some embodiments, the wort collection tube comprises a first wort section and a second wort section; one end of the first wort section is positioned in the rotary tank and communicated with the bottom of the filter tank, and the other end of the first wort section penetrates through the peripheral side wall of the rotary tank to be communicated with the outside boiling device; one end of the second wort section is communicated with the outside boiling device, and the other end of the second wort section is communicated with the rotary groove.

In some embodiments, a liquid level meter is disposed within the swirl tank.

In some embodiments, a cleaning pipeline is arranged in each of the filter tank and the rotary tank; the feed inlet, the discharge gate, circulation pipeline, wheat juice collecting pipe and the scavenge pipeline all are provided with the valve.

In some embodiments, the outlet is located on a peripheral sidewall of the filter bowl bottom.

According to the technical scheme, the method has at least the following advantages and positive effects:

in the application, after mash for wine making enters the filter tank through the feeding port, the ploughing knife starts to rotate at first so as to fully stir the mash. After stirring, realizing repeated circulating reflux of the wort through a circulating pipeline, and standing to enable the wort to enter a wort collecting pipe after being clear. And conveying the wort in the wort collection pipe to a boiling pot, and then feeding the wort into the rotary tank to precipitate residues in the rotary tank again, so that the filtered wort is clear and is convenient for a subsequent fermentation link. The filter tank is positioned at the upper part of the rotary tank, and the filter tank and the rotary tank are integrally arranged in the shell, thereby reducing the floor area of the filter tank and the rotary tank and reducing the manufacturing cost of the filter tank and the rotary tank.

Drawings

Fig. 1 is a schematic structural view of an embodiment of the filter tank convolution integrated device of the present invention.

The reference numerals are illustrated below:

100. a housing; 110. a filter base plate; 111. a sieve plate; 112. a sandwich panel; 121. a feeding port; 122. A discharge port; 200. a workspace; 210. a filter tank; 220. a convolution tank; 310. ploughing; 311. a bearing seat; 312. a connecting member; 313. a steel knife; 314. a drive motor; 320. a circulation line; 330. a wort collecting pipe; 331. a first wort section; 332. a second wort section; 350. a liquid transfer pipeline; 360. a constant pressure ventilation port; 370. a liquid level meter; 380. cleaning a pipeline; 40. a boiling device.

Detailed Description

Exemplary embodiments that embody the features and advantages of the present application will be described in detail in the following description. It is to be understood that the present application is capable of various modifications in various embodiments without departing from the scope of the application, and that the description and drawings are to be taken as illustrative and not restrictive in character.

In the description of the present application, it is to be understood that the terms "center," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the present application and for simplicity in description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed in a particular orientation, and be operated in a particular manner, and are not to be construed as limiting the present application. Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or to implicitly indicate the number of technical features indicated. Thus, features defined as "first", "second", may explicitly or implicitly include one or more of the described features. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

In the related art, the wine making process of large-scale wineries includes incoming material crushing, saccharification, filtration, boiling, rotary sedimentation, cooling, fermentation, beer canning, and the like. Most of the method is realized by three-pot two-tank (namely a pasting pot, a saccharifying pot, a boiling pot, a filtering tank and a rotary tank).

The gelatinization pot and the saccharification pot enable starch in the incoming material to be liquefied and gelatinized into mash, and the mash is conveyed into the filter tank; the filter tank is used for filtering mash, extracting wort and inputting the wort into the boiling pot; the boiling pot is used for boiling the wort and adding hops; and after the treatment of the boiling pot is finished, conveying the wort to a rotary tank, rotating the rotary tank to precipitate residues and reduce the temperature of the wort, and finally conveying the wort to a fermentation tank for fermentation to brew wine. The materials include wheat and barley.

Fig. 1 is a schematic structural view of an embodiment of the filter tank convolution integrated device of the present invention.

Referring to fig. 1, for convenience of understanding and description, a state in which the filter tank convolution integrated device is installed on a work floor is referred to, and an up-down direction of the filter tank convolution integrated device is referred to as an up-down direction below.

The application provides a filter tank convolution integrated device, which comprises a shell 100, a filter bottom plate 110, a tilling knife 310, a circulating pipeline 320, a wort collecting pipe 330 and a liquid transferring pipeline 350. The housing 100 is hollow to form a work space 200. The filtering bottom plate 110 is received in the casing 100 to divide the working space 200 into a filtering tank 210 and a swirling tank 220, which facilitates filtering and swirling operations. The tilling blades 310 are received in the filter tank 210 of the working space 200. The circulation line 320 is used for circulating wort in the filtration tank 210. The wort collecting pipe 330 is used for inputting the wort in the filtering tank 210 to the boiling device 40, and conveying the wort treated by the boiling device 40 to the whirling tank 220 through the wort collecting pipe 330 for whirling precipitation. The liquid transferring pipeline 350 is disposed at the bottom of the spiral tank 220 for transferring the wort in the spiral tank 220 to a subsequent brewing process. The filtering tank 210 is located above the rotary tank 220 to reduce the floor area of the brewing equipment and improve the space utilization rate of the working floor. And the filter tank 210 and the convolution tank 220 are both disposed in the housing 100, so that the structures of the filter tank 210 and the convolution tank 220 are simplified, the structures of the filter tank 210 and the convolution tank 220 are compact, and the production costs of the filter tank 210 and the convolution tank 220 are reduced.

Referring to fig. 1, in the present embodiment, the housing 100 extends in the up-down direction and is closed. The outer circumference of the casing 100 is circular in a cross section perpendicular to the up-down direction so that the whirling means whirls the wort. In some embodiments, the top of the casing 100 is a conical structure protruding upwards to improve the load-bearing capacity and structural strength of the top of the casing 100.

The working space 200 in the housing 100 comprises a filter tank 210 and a rotary tank 220, the filter tank 210 is provided with a material inlet 121 and a material outlet 122 on the housing 100 on the upper side of the filter base plate 110, the material inlet 121 is communicated with the saccharifying pot of the brewing process for receiving mash in the saccharifying pot. The discharge port 122 is used to discharge the used mash to facilitate cleaning of the filter tank 210. In some embodiments, the inlet 121 and the outlet 122 are disposed on opposite sides of the filter tank 210. The material inlet 121 and the material outlet 122 are provided with valves to open the material inlet 121 and the material outlet 122 in an electric or manual manner. In some embodiments, the outlet 122 is near the bottom of the filter cell 210.

The casing 100 is provided with constant pressure ventilation ports 360 at the top of the filter tank 210 and the top of the whirling tank 220 for balancing the air pressure in the filter tank 210 and the whirling tank 220 and ensuring the stable flow of wort. And the constant pressure ventilation port 360 can protect the structure of the casing 100, so that the filter tank convolution integrated device is stably and safely communicated with other equipment. In some embodiments, the two constant pressure ventilation ports 360 are connected to the outside through pipes to facilitate the centralized processing of the gas.

In some embodiments, a manhole is provided in the top of the housing 100 to facilitate access of maintenance personnel to the housing 100 for service and maintenance. In this embodiment, the bottom wall of the casing 100 is formed in a conical shape protruding upward to facilitate whirling and settling of wort in the whirling tank 220.

Referring to fig. 1, in the present embodiment, the filtering bottom plate 110 is disposed in the middle of the casing 100 and abuts against the inner peripheral wall of the casing 100 to partition the working space 200, thereby ensuring the sealing performance of the filtering tank 210 and the swirling tank 220. The filtering bottom plate 110 includes a sieve plate 111 and a sandwich plate 112, the sandwich plate 112 is located at the lower side of the sieve plate 111, and the peripheral side walls of the sieve plate 111 and the sandwich plate 112 are abutted to the inner peripheral wall of the housing 100. The work space 200 on the upper side of the sandwich panel 112 is divided into filter tanks 210 for filtering. The sandwich panel 112 divides the lower space inside the casing 100 into the whirling slot 220 for whirling precipitation. The working space 200 between the interlayer plate 112 and the sieve plate 111 is used for accommodating wort after mash filtration, so as to communicate the circulation pipeline 320 and the wort collecting pipe 330. The sandwich plate 112 can separate the filter tank 210 and the swirl tank 220 such that the filter tank 210 and the swirl tank 220 are spaced apart from each other. In some embodiments, the inlet 121 and outlet 122 are located on the upper side of the screen 111.

Referring to fig. 1, in the present embodiment, a tilling blade 310 is rotatably disposed in the filtering tank 210 for turning over mash in the filtering tank 210 so that the mash produces more wort. The tilling blade 310 includes a bearing seat 311, a connecting member 312, and a plurality of steel blades 313. The bearing seat 311 is located in the middle of the filter tank 210 and extends in the up-down direction. The lower end of the bearing seat 311 penetrates through the sieve plate 111 to be limited on the sandwich plate 112. The connecting member 312 extends in the left-right direction, and the middle portion of the connecting member 312 is rotatably connected to the upper end of the bearing seat 311, so that the two ends of the connecting member 312 can rotate circumferentially around the axis of the bearing seat 311. The plurality of steel knives 313 extend in the vertical direction, the upper ends of the plurality of steel knives 313 are fixedly connected to the connecting piece 312, the lower ends of the plurality of steel knives 313 are close to the screen plate 111, and the plurality of steel knives 313 are arranged at intervals in the extending direction of the connecting piece 312. When mash enters the filter tank 210 to produce wort, the connecting piece 312 drives the steel knives 313 to rotate so as to fully turn over the mash, improve the production efficiency of the wort and increase the concentration of the wort.

The outer side of the upper end of the casing 100 is further provided with a driving motor 314, and the driving motor 314 is in transmission connection with the connecting member 312 so as to drive the connecting member 312 to rotate around the axis of the bearing seat 311.

Referring to fig. 1, in the present embodiment, the circulation line 320 is used for circulating the wort in the filtering tank 210, so that the mash is sufficiently separated from the wort. One end of the circulating pipeline 320 is communicated with the working space 200 between the sieve plate 111 and the sandwich plate 112 for absorbing wort. The other end of the circulation pipeline 320 is located at the upper part of the filtering tank 210 to convey the wort at the bottom of the filtering tank 210 to the upper part of the filtering tank 210, so as to realize the circulation of the wort and improve the separation efficiency of mash.

In some embodiments, one end of the circulation line 310 communicates with the working space 200 between the screen panel 111 and the sandwich panel 120. The other end of the circulation pipe 320 penetrates the housing 100 and extends to the upper portion of the housing 100 to penetrate the upper housing 100 to communicate with the upper portion of the filter tank 210. The wort at the bottom of the filtering tank 210 enters the circulating pipeline 320 through one end of the circulating pipeline 320, and flows back to the top of the filtering tank 210 through the other end of the circulating pipeline 320 after flowing through the circulating pipeline 320, so that the wort in the filtering tank 210 can be circulated for multiple times, and the wort in the mash can be fully extracted.

In some embodiments, one end of the circulation pipeline is located between the sieve plate 111 and the sandwich plate 112, and the other end of the circulation pipeline is communicated with the feed inlet 121 to complete the circulation extraction of wort. In other embodiments, the inlet of the circulation pipeline 320 is multiple, and the inlets of the circulation pipeline 320 are respectively arranged through the sandwich plate 112 and connected through the filter cells 210, so as to disperse and slowly absorb wort through the multiple ports. So that the flow rate of the wort in the filter tank 210 is slow, and the wort can be conveniently and fully extracted. In other embodiments, the circulation pipeline is in the social self-healing working space and extends along the inner circumferential wall of the shell 100 in the up-down direction.

The circulation pipe 320 is provided with a circulation pump (not shown) to provide power for the circulation of wort in the circulation pipe 320. The circulating pump is a variable frequency pump, and the liquid pumping speed can be adjusted according to the total wort amount in the filter tank 210, so that repeated high-efficiency circulation of wort is realized. The circulation line 320 is provided with a valve to control the start and stop of the circulation line 320. In some embodiments, a valve is disposed in the recirculation line 320.

In this embodiment, the filter tank convolution integrated apparatus further includes a cleaning pipeline 380, an inlet of the cleaning pipeline 380 is communicated with the outside to input an external water source into the filter tank 210 and the convolution tank 220, so as to clean the filter tank 210 and the convolution tank 220 after the filter tank 210 and the convolution tank 220 are used. Two valves are disposed on the cleaning pipeline 380 to control the start and stop of cleaning the filter tank 210 and the convolution tank 220 respectively. In still other embodiments, the outlet of the cleaning pipe 380 communicating with the filter tank 210 and the swirl tank 220 is located at the upper part of the filter tank 210 and the swirl tank 220, respectively, so as to clean the filter tank 210 and the swirl tank 220 sufficiently.

In some embodiments, the outlet of the cleaning pipeline 380 communicated with the filter tank 210 is multiple, and the multiple outlets of the cleaning pipeline 380 are annularly spaced on the casing 100 at the upper part of the filter tank 210, so that the water in the cleaning pipeline 380 is uniformly sprayed into the filter tank 210.

In some embodiments, the filter tank convolution integrated device further includes a water inlet pipe, an inlet of the water inlet pipe is communicated with the outside for inputting an outside water source into the filter tank 210 through the water inlet pipe. The outlet of the water inlet pipe is communicated with a cleaning pipeline 380 so as to convey the water source into the filter tank 210 through the cleaning pipeline 380 to supply water for mash to extract wort. The connection between the outlet of the inlet pipe and the cleaning pipeline 380 is located between two valves of the cleaning pipeline 380, and the inlet pipe is provided with a valve, so that the cleaning pipeline 380 and the inlet pipe can open and close the valves according to requirements, and cleaning or water supply for the filter tank 210 is realized.

Referring to fig. 1, in the present embodiment, the wort collecting pipe 330 is used for conveying the wort in the filtering tank 210 to the whirling tank 220 after passing through the boiling device 40. The wort collecting pipe 330 is communicated with the external boiling device 40. The wort collecting pipe 330 includes a first wort section 331 and a second wort section 332. One end of the first wort section 331 is located between the sieve plate 111 and the sandwich plate 112 for absorbing wort, and the other end of the first wort section 331 penetrates the peripheral side casing 100 to communicate with the external boiling device 40. One end of the second wort section 332 is connected to the external boiling device 40, and the other end of the second wort section 332 is connected to the spiral groove 220.

In some embodiments, the first wort section 331 is located at the top of the spiral tank 220, one end of the first wort section 331 is connected to the filtering tank 210 after passing through the sandwich panel 112, and the other end of the first wort section 331 is connected to the boiling device 40 by passing through the shell around the spiral tank 220. In other embodiments, the circulation line 320 is in communication with the first wort section 331 for receiving wort from the bottom of the lauter tun 210 for circulation.

The wort in the filter tank 210 is circulated for many times, so that the wort is fully separated from the mash. After the wort is introduced into the boiling device 40 through the first wort section 331, the boiling process is performed in the boiling device 40. After the wort treatment in the boiling device 40 is completed, the wort is transported to the whirling tank 220 through the second wort section 332 for whirling precipitation. In some embodiments, the first wort section 331 and the second wort section 332 are provided with valves for controlling the opening and closing of the first wort section 331 and the second wort section 332.

Referring to fig. 1, in the present embodiment, the second juice pipe section 332 is communicated with the peripheral casing of the whirling tank 220, and the flowing direction of the wort at the end of the second juice pipe section 332 communicated with the whirling tank 220 is tangent to the inner peripheral wall of the whirling tank 220, so that the wort enters the whirling tank 220 and is whirled and precipitated to further filter impurities in the wort, thereby facilitating the subsequent fermentation process.

Referring to fig. 1, in the present embodiment, the liquid transfer pipeline 350 is disposed at the bottom of the casing 100, and penetrates the bottom wall of the casing 100 to communicate with the rotation tank 220, so that the wort in the rotation tank 220 is delivered to the external fermentation device through the liquid transfer pipeline 350. In some embodiments, the port of the liquid transfer pipeline 350 communicating with the whirling tank 220 is close to the peripheral sidewall of the casing 100 for conveying the wort after removing the residue in the whirling tank 220 to improve the quality of the subsequent fermentation.

In other embodiments, the liquid transfer pipeline 350 has a plurality of ports communicating with the whirling tank 220, and the plurality of ports communicating with the liquid transfer pipeline 350 and the whirling tank 220 are annularly disposed on the bottom wall of the whirling tank 220 for sucking the wort in the whirling tank 220. In other embodiments, a port of the transfer line 350 communicating with the swirl groove 220 is located at the center of the bottom wall of the swirl groove 220.

The outlet of the liquid transferring pipeline 350 is communicated with the second wort section 332, and a valve is arranged on the liquid transferring pipeline 350 for controlling the on-off of the liquid transferring pipeline 350. In some embodiments, the liquid transfer pipeline 350 is communicated with a circulation pump to pump out wort in the whirling tank 220 through the circulation pump, so as to realize multi-stage utilization of the circulation pump and reduce the production cost of the filter tank whirling integrated device.

In this embodiment, a refrigeration pump is disposed outside the casing around the whirling tank 220 to provide cold for the wort after whirling and precipitation in the whirling tank 220, and the wort is cooled to facilitate the subsequent fermentation process. In some embodiments, a thermometer is disposed within the swirl tank 220 to enable real-time monitoring of the temperature of the swirl tank 220.

In this embodiment, a liquid level meter 370 is disposed on the casing 100 around the whirling tank 220 for real-time monitoring of the total amount of wort in the whirling tank 220 for the convenience of operation of the operator.

Referring to fig. 1, in the present invention, the integrated device of the filtration tank for convolution is used for the filtration process and the convolution process of the wine brewing process. The filter tank 210 is arranged above the rotary tank 220, so that the working floor area occupied by the brewing equipment is reduced, the structure of the rotary integrated filter tank device is simplified, and the production cost of the rotary integrated filter tank device is reduced.

When the materials in the gelatinizing pot and the saccharifying pot are processed to form mash, the mash enters the filter tank 210 through the feed inlet 121, and after the mash enters the filter tank 210, the valve of the feed inlet 121 is closed to seal the filter tank 210. The water inlet pipe supplies water to the filtering tank 210 for mash separation of wort. The wort in the filtration tank 210 flows from the bottom of the filtration tank 210 to the upper part of the filtration tank 210 through the circulation line 320, and the wort is circulated and extracted. In the circulation process, the tilling blades 310 rotate to turn over the mash, so that repeated circulation separation of the mash is realized, and the concentration of the wort is increased.

After standing for clarification of wort, the wort is fed into the external boiling device 40 through the first wort pipe 331, and the wort treated by the boiling device 40 is fed into the rotary tank 220 through the second wort pipe 332. The operator can observe the total amount of wort in the cyclone tank 220 by the level gauge 370, and close the valve on the second wort section 332 to disconnect the second wort section 332 after the total amount reaches the standard. After the wort in the second wort pipe section 332 is input into the whirling tank 220, the wort circulates along the circumferential direction of the inner circumferential wall of the whirling tank 220 under the action of the kinetic energy of the wort, so that the wort in the whirling tank 220 rotates to precipitate the residue in the wort. After the residues of the wort in the whirling tank 220 are precipitated, the wort is kept stand and then is conveyed to the subsequent fermentation process through a liquid transfer pipeline 350.

In this application, after the mash for wine making enters the filtering tank 210 through the inlet 121, the tilling blade 310 starts to rotate to fully stir the mash. After stirring, the wort is circulated and refluxed for many times through the circulation pipeline 320, and then is kept stand to clear the wort and then enters the wort collection pipe 330. The wort in the wort collecting pipe 330 enters the whirling tank 220 to precipitate the residue in the whirling tank 220, so that the filtered wort is clear for the subsequent fermentation process. The filter tank 210 is located at the upper portion of the spiral tank 220, and the filter tank 210 and the spiral tank 220 are integrally disposed in the casing 100, so as to reduce the floor space of the filter tank 210 and the spiral tank 220 and reduce the manufacturing cost thereof.

While the present application has been described with reference to several exemplary embodiments, it is understood that the terminology used is intended to be in the nature of words of description and illustration, rather than of limitation. As the present application may be embodied in several forms without departing from the spirit or essential characteristics thereof, it should also be understood that the above-described embodiments are not limited by any of the details of the foregoing description, but rather should be construed broadly within its spirit and scope as defined in the appended claims, and therefore all changes and modifications that fall within the meets and bounds of the claims, or equivalences of such meets and bounds are therefore intended to be embraced by the appended claims.

Claims (10)

1. A filter tank convolution integrated device for receiving mash of a saccharification device and communicating with a boiling device, comprising:

a housing having a hollow interior to form a working space;

the filtering bottom plate is arranged in the middle of the shell, and the peripheral side of the filtering bottom plate is abutted against the inner peripheral wall of the shell so as to divide the working space; the filter bottom plate comprises a sieve plate and a sandwich plate, the sieve plate filters the mash to separate wort, the sandwich plate is positioned at the lower side of the sieve plate, and the working space at the upper side of the sandwich plate is divided into filter tanks; a feeding port and a discharging port are formed in the shell on the upper side of the sieve plate; the sandwich plate divides the working space on the lower side of the shell into convolution grooves;

a tilling blade rotatably disposed in the filtering tank;

one end of the circulating pipeline is communicated with the working space between the sieve plate and the sandwich plate so as to absorb wort; the other end of the circulating pipeline is communicated with the upper part of the filtering tank, and a circulating pump is arranged on the circulating pipeline to circulate the wort in the filtering tank;

and the wort collecting pipe is used for conveying the wort in the filter tank to the rotary tank.

2. The integrated lauter tun gyrating apparatus as claimed in claim 1, wherein the bottom wall of the casing is conical and protrudes upward, the wort collecting pipe is connected to the casing around the gyrating tub, and the wort flowing direction at one end of the wort collecting pipe connected to the gyrating tub is tangential to the inner peripheral wall of the gyrating tub, so that the residue in the wort is swirled and settled to the middle of the bottom wall of the casing.

3. The integrated filter tank convolution device according to claim 2, further comprising a liquid transfer pipeline, wherein the liquid transfer pipeline penetrates through the bottom wall of the housing to communicate with the convolution tank, and a port of the liquid transfer pipeline communicating with the convolution tank is close to the peripheral side of the housing.

4. The integrated filter tank cyclone device of claim 3, wherein the circulation pump is connected to the liquid transfer line to pump out the wort in the cyclone tank.

5. The integrated filter tank cyclone device according to claim 1, wherein the circulation pump is a variable frequency pump.

6. The integrated filter tank cyclone device according to claim 1, wherein the top of the filter tank and the top of the cyclone tank are provided with constant pressure ventilation ports.

7. The integrated lauter tun rotor apparatus of claim 1, wherein the wort collection pipe comprises a first wort section and a second wort section; one end of the first wort section is positioned in the rotary tank and communicated with the bottom of the filter tank, and the other end of the first wort section penetrates through the peripheral side wall of the rotary tank to be communicated with the outside boiling device; one end of the second wort section is communicated with the outside boiling device, and the other end of the second wort section is communicated with the rotary groove.

8. The integrated filter tank cyclone device of claim 1, wherein a liquid level gauge is disposed in the cyclone tank.

9. The filter tank convolution integrated device of claim 1 wherein a cleaning pipeline is disposed in each of the filter tank and the convolution tank; the feed inlet, the discharge gate, circulation pipeline, wheat juice collecting pipe and the scavenge pipeline all are provided with the valve.

10. The filter tank convolution integrated device of claim 1 wherein the spout is located on a peripheral sidewall of the filter tank bottom.

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