A brewing filtration system
By designing flexible piping components and filtration systems, the problem of yeast loss in beer filtration systems has been solved, achieving efficient filtration of wheat beer and lager, and meeting the quality requirements of different beer categories.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- CARLSBERG TIANMUHU BEER JIANGSU CO LTD
- Filing Date
- 2025-05-19
- Publication Date
- 2026-06-12
Smart Images

Figure CN224345566U_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of brewing technology, and more particularly to a brewing filtration system. Background Technology
[0002] In the brewing process of fermented products, the filtration process of the fermentation raw materials affects the product's consumption experience. Taking beer brewing as an example, different filtration processes determine the clarity and flavor stability of the beer, thereby meeting the quality requirements of different beer categories.
[0003] In related technologies, beer filtration systems employ multi-stage series filtration devices. That is, after the fermentation liquid is initially separated into solid and liquid components from the storage tank by a primary filtration device (such as a centrifuge), it passes through a secondary filter (such as a diatomaceous earth filter) and a tertiary membrane filter in sequence before finally entering the next process.
[0004] However, in some beer categories (such as wheat beer), a certain amount of yeast needs to be retained to form a unique cloudy appearance and flavor. Filtration can easily lead to yeast loss, affecting the quality of the product. Utility Model Content
[0005] This application provides a brewing filtration system to address the problems of existing silo feed inlets being located at high positions, making it inconvenient to manually deliver raw materials to the feed inlet, and the low efficiency of transferring materials by forklift or transfer cart.
[0006] To achieve the above objectives, the technical solution of this application is as follows:
[0007] This application provides a brewing filtration system, comprising: a pipeline assembly including a first pipeline, a second pipeline, and a third pipeline; a first filter assembly having a liquid outlet, with both the first and third pipelines connected to the liquid outlet, and a second filter assembly disposed on one of the first and third pipelines; a treatment assembly having a liquid inlet, with both the first and third pipelines connected to the liquid inlet; and a CIP system, with one end of the second pipeline connected to the CIP system and the other end connected to the first pipeline, the CIP system being connected to the first filter assembly, the CIP system being used to receive liquid flowing out of the second pipeline and deliver it to the first filter assembly; the first filter assembly is configured such that liquid entering and being filtered therein is delivered to the treatment assembly via the first or third pipeline, or sequentially delivered to the CIP system via the first and second pipelines.
[0008] In one possible implementation, the brewing filtration system in this application embodiment further includes a switching assembly, which includes a first switching element and a second switching element. The first switching element is disposed at the liquid outlet end and is used to control the on / off state of the first pipeline and the third pipeline; the second switching element is disposed at the liquid inlet end and is used to control the on / off state of the first pipeline and the second pipeline.
[0009] In one possible implementation, the brewing filtration system in this application embodiment further includes a switching assembly that also includes at least two anti-mixing components, one anti-mixing component being disposed at the connection between the first pipeline and the third pipeline; and the other anti-mixing component being disposed at the connection between the first pipeline and the second pipeline.
[0010] In one possible implementation, the brewing filtration system in this application embodiment has a first switching element and a second switching element that are both three-way valves or four-way valves, and an anti-mixing element that is an anti-mixing valve.
[0011] In one possible implementation, the brewing filtration system in this application embodiment further includes a flow detection element disposed on at least one of the first pipeline, the second pipeline, and the third pipeline.
[0012] In one possible implementation, the brewing filtration system in this application embodiment further includes at least two sampling elements, each of which is respectively disposed on the first pipeline and the third pipeline.
[0013] In one possible implementation, the brewing filtration system in this application embodiment further includes a second filtration component, which is connected to the first filtration component and the component to be processed via a third pipeline.
[0014] In one possible implementation, the brewing filtration system in this application embodiment includes a second filtration component comprising a pre-buffer tank, a filter, and a post-buffer tank, which are sequentially connected via a third pipeline.
[0015] In one possible implementation, the brewing filtration system in this application embodiment includes a first filtration component comprising a plate heat exchanger and a centrifuge. The centrifuge is connected to the plate heat exchanger, which is used to regulate the temperature of the incoming liquid; the centrifuge is used to centrifuge and filter the liquid.
[0016] In one possible implementation, the brewing filtration system in this application embodiment uses a high-concentration dilution device as the component to be processed.
[0017] The brewing filtration system provided in this application includes a piping assembly comprising a first pipe, a second pipe, and a third pipe; a first filter assembly having a liquid outlet, with both the first and third pipes connected to the liquid outlet, and a second filter assembly mounted on one of the first and third pipes; a treatment assembly having a liquid inlet, with both the first and third pipes connected to the liquid inlet; and a CIP system, with one end of the second pipe connected to the CIP system and the other end connected to the first pipe, the CIP system being connected to the first filter assembly, and the CIP system receiving the liquid flowing out of the second pipe and conveying it to the first filter assembly; the first filter assembly is configured such that the liquid entering it for filtration is conveyed to the treatment assembly via the first or third pipe, or sequentially conveyed to the CIP system via the first and second pipes. This application incorporates a second filter assembly on either the first or third pipeline. If the second filter assembly is installed on the third pipeline, no second filter assembly is installed on the first pipeline. The second pipeline is used to clean the first pipeline. The cleaning liquid flowing from the first filter assembly returns to the CIP system via the second pipeline, thus cleaning the first pipeline. The first pipeline directly connects the outlet of the first filter assembly to the component to be treated, reducing the number of filtrations. This is suitable for wheat beer filtration, avoiding the filtration of yeast to retain it and create a cloudy appearance and unique flavor. The third pipeline connects to other filter assemblies, such as the second filter assembly. The liquid output from the first filter assembly undergoes secondary filtration via the second filter assembly before flowing to the component to be treated. This is suitable for lager beer where high clarity is required. Attached Figure Description
[0018] The accompanying drawings, which are incorporated in and form part of this specification, illustrate embodiments consistent with this application and, together with the description, serve to explain the principles of this application.
[0019] Figure 1 Schematic diagram of the brewing filtration system provided in the embodiments of this application Figure 1 ;
[0020] Figure 2 for Figure 1 A magnified view of part A in the middle;
[0021] Figure 3 for Figure 1 A magnified view of part B in the diagram.
[0022] Explanation of reference numerals in the attached figures:
[0023] 100 - Piping assembly;
[0024] 110 - First pipeline;
[0025] 120 - Second pipeline;
[0026] 130 - Third pipeline;
[0027] 200 - First filter assembly;
[0028] 210 - Plate heat exchanger;
[0029] 220-Centrifuge;
[0030] 300 - Components to be processed;
[0031] 400-CIP system;
[0032] 500-Switch Assembly;
[0033] 510 - First switching element; 511 - Fourth valve; 512 - Fifth valve; 513 - Sixth valve;
[0034] 520 - Second switching element; 521 - First valve; 522 - Second valve; 523 - Third valve;
[0035] 530 - Anti-mixing parts;
[0036] 700 - Flow detection device;
[0037] 800 - Sample;
[0038] 900 - Second filter assembly;
[0039] 910 - Front Buffer Tank;
[0040] 920-Filter Machine;
[0041] 930 - Rear Buffer Tank.
[0042] The accompanying drawings illustrate specific embodiments of this application, which will be described in more detail below. These drawings and descriptions are not intended to limit the scope of the concept in any way, but rather to illustrate the concept of this application to those skilled in the art through reference to particular embodiments. Detailed Implementation
[0043] Exemplary embodiments will now be described in detail, examples of which are illustrated in the accompanying drawings. When the following description relates to the drawings, unless otherwise indicated, the same numbers in different drawings denote the same or similar elements. The embodiments described in the following exemplary embodiments do not represent all embodiments consistent with this application. Rather, they are merely examples of apparatuses and methods consistent with some aspects of this application as detailed in the appended claims.
[0044] It should be noted that in the description of the embodiments of this application, the terms "upper", "lower", "inner", "outer" and other terms indicating the orientation or positional relationship are based on the orientation or positional relationship shown in the drawings, and are only for the convenience of description, and are not intended to indicate or imply that the device or component must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation on the embodiments of this application.
[0045] Furthermore, it should be noted that the terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of this application, "multiple" means two or more, unless otherwise explicitly specified.
[0046] In this application, unless otherwise expressly specified and limited, the terms "installation," "connection," "fixation," etc., should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral part; they can refer to a mechanical connection, an electrical connection, or a connection that allows communication between them; they can refer to a direct connection or an indirect connection through an intermediate medium; they can refer to the internal communication between two components or the interaction between two components. Those skilled in the art can understand the specific meaning of the above terms in this application according to the specific circumstances.
[0047] The following is an explanation of the terms used in this application:
[0048] CIP system: This is an abbreviation for Clean In Place, also known as online cleaning or on-site cleaning. For example, in beer production, it is a system that uses cleaning and disinfecting agents to periodically clean and disinfect the inner surfaces of production equipment (such as fermentation tanks, heat exchangers, pumps, valves, pipes, etc.) without disassembly and reinstallation.
[0049] High concentration dilution equipment: refers to equipment used to dilute high concentrations of substances to the required concentration.
[0050] In the brewing process of fermented products, the filtration process of the fermentation raw materials affects the product's consumption experience. Taking beer brewing as an example, different filtration processes determine the clarity and flavor stability of the beer, thereby meeting the quality requirements of different beer categories.
[0051] In related technologies, traditional beer filtration systems employ multi-stage series filtration devices. The fermentation broth, after initial solid-liquid separation in a primary filtration device (such as a centrifuge), passes through a secondary filter (such as a diatomaceous earth filter) and a tertiary membrane filter before proceeding to the next stage. However, in some beer categories (such as wheat beer brewing), a certain amount of yeast needs to be retained to create a distinctive cloudy appearance and flavor. Existing systems struggle to adapt to these different filtration requirements, and over-filtration can easily lead to yeast loss, affecting product quality.
[0052] In view of this, this application provides a brewing filtration system, comprising: a pipeline assembly including a first pipeline, a second pipeline, and a third pipeline; a first filter assembly having a liquid outlet, with both the first and third pipelines connected to the liquid outlet, and a second filter assembly disposed on one of the first and third pipelines; a treatment assembly having a liquid inlet, with both the first and third pipelines connected to the liquid inlet; a CIP system, with one end of the second pipeline connected to the CIP system and the other end connected to the first pipeline, the CIP system being connected to the first filter assembly, the CIP system being used to receive liquid flowing out of the second pipeline and deliver it to the first filter assembly; the first filter assembly is configured such that liquid entering and being filtered therein is delivered to the treatment assembly via the first or third pipeline, or sequentially delivered to the CIP system via the first and second pipelines. This application incorporates a second filter assembly on either the first or third pipeline. If the second filter assembly is installed on the third pipeline, it is not installed on the first pipeline. The second pipeline is used to clean the first pipeline. The cleaning liquid flowing from the first filter assembly returns to the CIP system via the second pipeline, thus cleaning the first pipeline. The first pipeline directly connects the outlet of the first filter assembly to the component to be treated, reducing the number of filtrations. This is suitable for wheat beer filtration, avoiding the filtration of yeast to retain it and create a cloudy appearance and unique flavor. The third pipeline connects to other filter assemblies, such as the second filter assembly. The liquid output from the first filter assembly undergoes secondary filtration via the second filter assembly before flowing to the component to be treated. This is suitable for lager beer and liquids requiring high clarity.
[0053] Combination Figures 1 to 3 The content of this application will be described in detail with specific embodiments.
[0054] This application provides a brewing filtration system, comprising: a pipeline assembly 100, including a first pipeline 110, a second pipeline 120, and a third pipeline 130; a first filter assembly 200 having a liquid outlet end, with both the first pipeline 110 and the third pipeline 130 connected to the liquid outlet end, and a second filter assembly 900 disposed on one of the first pipeline 110 and the third pipeline 130; and a treatment assembly 300 having a liquid inlet end, with both the first pipeline 110 and the third pipeline 130 connected to the liquid inlet end; C The IP system 400 has a second pipeline 120 connected at one end to the CIP system 400 and at the other end to the first pipeline 110. The CIP system 400 is connected to the first filter assembly 200. The CIP system 400 is used to receive the liquid flowing out of the second pipeline 120 and deliver it to the first filter assembly 200. The first filter assembly 200 is configured such that the liquid entering it for filtration is delivered to the component to be processed 300 via the first pipeline 110 or the third pipeline 130, or sequentially delivered to the CIP system 400 via the first pipeline 110 and the second pipeline 120.
[0055] This application does not limit the liquid output from the outlet end of the first filter component 200, and the liquid output from the outlet end can be the brewing liquid of beer.
[0056] Piping assembly 100 includes a first pipe 110, a second pipe 120, and a third pipe 130; the first pipe 110 and the third pipe 130 are both used to transport brewing liquids, such as wheat beer concentrate. The second pipe 120 is used to transport CIP liquid. It should be noted that the first pipe 110, the second pipe 120, and the third pipe 130 are all sanitary grade pipes.
[0057] The first filter assembly 200 has a liquid outlet end, and both the first pipe 110 and the third pipe 130 are connected to the liquid outlet end. The first pipe 110 and the third pipe 130 are detachably connected to the liquid outlet end, which facilitates quick assembly and disassembly of the first pipe 110 and the third pipe 130, and also allows for flexible adjustment of the pipes according to actual brewing needs.
[0058] The component to be processed 300 has a liquid inlet end, and the first pipeline 110 and the third pipeline 130 are both connected to the liquid inlet end.
[0059] The CIP system 400 has a second pipeline 120 connected at one end to the CIP system 400 and at the other end to the first pipeline 110. The CIP system 400 is connected to the liquid inlet of the first filter component 200 through the pipeline.
[0060] The first filter assembly 200 is configured such that liquid flowing from the outlet end flows to the treatment assembly 300 via the first pipe 110 or the third pipe 130; or liquid flowing from the outlet end flows to the CIP system 400 via the second pipe 120.
[0061] It should be noted that both the first pipeline 110 and the third pipeline 130 are brewing liquid conveying pipelines, made of food-grade hygiene materials. Their ends are connected to the outlet 201 of the first filter assembly 200 and the inlet 301 of the component to be treated 300, respectively, forming parallel brewing liquid conveying paths. The second pipeline 120 is a dedicated CIP liquid pipeline, with one end connected to the outlet of the CIP system 400. Furthermore, the CIP system 400 can also be directly connected to the inlet 202 of the first filter assembly 200 via an independent pipeline for the circulation of the cleaning liquid.
[0062] The first filter assembly 200 can be a centrifuge 220. When filtering the brewing liquid of wheat beer, the first pipeline 110 is first cleaned through the second pipeline 120, i.e., the second switch 520 closes the first pipeline 110 and opens the second pipeline 120. The CIP system 400 is then started, and the cleaning solution is output from the CIP system 400, passing through the centrifuge, the first pipeline 110, and the second pipeline 120 in sequence, before returning to the CIP system 400. The cleaning solution flushes the first pipeline, the inside of the centrifuge, and the inlet pipe. An anti-mixing component 530 is also installed at the junction of the first pipeline 110 and the third pipeline 130 to prevent the cleaning solution from entering other pipelines. It should be noted that the cleaning process of the CIP system 400 includes multiple stages, such as a pre-rinsing stage, in which clean water or hot water is used to remove loose surface residues (such as wheat residue and yeast), and an alkaline washing stage, in which an alkaline solution is used to decompose organic matter (such as protein and hop oil) and dissolve fatty residues. In the alkaline cleaning stage, residual alkaline solution is removed with clean water to prevent reaction with subsequent acid solutions. In the acid cleaning stage, an acidic solution is used to remove inorganic scale (such as beer stone) and neutralize any remaining alkaline solution. Finally, in the disinfection and drying stage, disinfectants such as peracetic acid are used, and air blowing accelerates the drying process.
[0063] In the brewing filtration system of this embodiment, both the first pipe 110 and the third pipe 130 are connected to the liquid outlet of the first filter assembly 200. The parallel connection of the first pipe 110 and the third pipe 130 can meet different filtration requirements. The second pipe 120 is used to clean the first pipe 110. The cleaning liquid flowing out from the liquid outlet flows back from the first pipe 110 to the CIP system 400 via the second pipe 120. The first pipe 110 is used to directly connect the liquid outlet of the first filter assembly 200, such as a centrifuge, to the component to be treated 300, which is suitable for wheat beer filtration to retain yeast. The third pipe 130 can also be connected to other filter assemblies, such as the second filter assembly, to perform secondary filtration on the centrifuged liquid before it flows to the component to be treated 300, which is suitable for lager to meet different filtration requirements.
[0064] In addition, this application also includes a switch assembly 500, which includes: a first switch element 510 and a second switch element 520. The first switch element 510 is disposed at the liquid outlet end and is used to control the on / off state of the first pipeline 110 and the third pipeline 130; the second switch element 520 is disposed at the liquid inlet end and is used to control the on / off state of the first pipeline 110 and the second pipeline 120.
[0065] This application, through the first pipe 110 and the third pipe 130, can accommodate the filtration of different brewing liquid types, such as wheat beer and stout.
[0066] Furthermore, the switch assembly 500 also includes at least two anti-mixing components 530. One anti-mixing component 530 is disposed at the connection between the first pipe 110 and the third pipe 130 to prevent the liquids from different flow paths from mixing. The other anti-mixing component 530 is disposed at the connection between the first pipe 110 and the second pipe 120.
[0067] After cleaning the first pipeline 110, the external brewing liquid enters the centrifuge through the inlet, and after centrifugation, it is output from the outlet. The first switch 510 can be a three-way valve. The first switch 510 opens the first pipeline 110 and closes the third pipeline 130. The filtered liquid flows through the first pipeline 110 to the inlet of the component to be treated 300. The second switch 520 closes the second pipeline 120. The anti-mixing component 530 automatically closes the third pipeline 130 and the second pipeline 120 to prevent the residual liquid from mixing.
[0068] When filtering other types of beer brewing liquid, the external brewing liquid enters the centrifuge through the inlet, and after centrifugal separation, it is output from the outlet. The first switch 510 opens the third pipeline 130 and closes the second pipeline 120. The filtered liquid passes through the third pipeline 130, which is also equipped with other filtration devices to meet the filtration requirements of other beer brewing liquids. The liquid flowing out of the third pipeline 130 flows to the inlet of the component to be treated 300. The anti-mixing component 530 automatically closes the third pipeline 130 and the second pipeline 120 to prevent residual liquid from mixing.
[0069] In one possible implementation, the brewing filtration system provided in this application embodiment has a first switch 510 and a second switch 520, both of which are three-way valves or four-way valves, and an anti-mixing component 530, which is an anti-mixing valve.
[0070] It should be noted that the first switching element 510 and the second switching element 520 can also be a combination of a three-way valve and an anti-mixing valve, and both the first switching element 510 and the second switching element 520 can be anti-mixing double-seat valves.
[0071] For example, the first switch 510 includes a fourth valve 511, a fifth valve 512, and a sixth valve 513, and the second switch 520 includes a first valve 521, a second valve 522, and a third valve 523. When the CIP system 400 is washing, the cleaning solution of the CIP system 400 flows out of the CIP system 400, passes through the plate heat exchanger and the centrifuge in sequence, and is output from the liquid outlet. At this time, the fourth valve 511 and the fifth valve 512 of the first switch 510 are both open, and the sixth valve 513 is closed. Meanwhile, the second valve 522 and the third valve 523 of the first switch 510 are both open, and the first valve 521 is closed. The cleaning solution flows back to the CIP system 400 from the first pipe 110 and the second pipe 120. During the filtration of wheat beer, the fermented young beer passes sequentially through a plate heat exchanger and a centrifuge, and is output from the outlet. At this time, the fourth valve 511 and the fifth valve 512 of the first switching component 510 are both open, and the sixth valve 513 is closed. Meanwhile, the second valve 522 of the second switching component 520 is open, and the first valve 521 and the third valve 523 are both closed, allowing the fermented young beer to flow directly into the processing component 300, such as a clear beer tank, after filtration through the first pipe 110. During the filtration of other beers, such as draft beer, the fermented young beer passes sequentially through a plate heat exchanger and a centrifuge, and is output from the outlet. At this time, the fourth valve 511 of the first switching component 510 is open, and the sixth valve 513 and the fifth valve 512 are both closed. Meanwhile, the first valve 521 and the second valve 522 of the second switching component 520 are both open, and the third valve 523 is both closed. After multiple filtrations through the third pipe 130, the fermented young beer enters the processing component 300, such as a clear beer tank or a high-concentration dilution device.
[0072] In addition, the filtration system also includes a flow sensor 700, which is installed on at least one of the first pipe 110, the second pipe 120, and the third pipe 130. The flow sensor 700 is used to detect the flow rate of the liquid in each pipe. By monitoring the liquid flow rate in the pipes in real time, it ensures that the flow rate for CIP cleaning and different beer filtration processes meets preset standards. The flow sensor 700 can be a flow valve.
[0073] The filtration system also includes at least two sampling elements 800, each of which is respectively installed on the first pipeline 110 and the third pipeline 130. The sampling element 800 is a sterile sampling valve used to periodically detect microbial indicators and avoid contamination.
[0074] The sampling component 800 can be a sampling valve, which can be used to periodically check whether the sanitary environment of the first pipeline 110 and the third pipeline 130 meets the requirements.
[0075] In one possible implementation, the brewing filtration system provided in this application embodiment further includes a second filtration component 900, which is connected to the first filtration component 200 and the component to be processed 300 via a third pipeline 130.
[0076] A second filter assembly 900 is installed on the third pipeline 130, which can improve the filtration performance to meet the filtration requirements of different brewing liquids.
[0077] The second filter assembly 900 includes a front buffer tank 910, a filter 920, and a rear buffer tank 930, which are connected in sequence via a third pipeline 130.
[0078] The second filter assembly 900 is connected in series between the outlet end of the first filter assembly 200 and the inlet end of the component to be treated 300 via a third pipe 130. A front buffer tank 910 is located at the front end of the third pipe 130. The inlet of the front buffer tank 910 is connected to the outlet end of the first filter assembly 200 via the third pipe 130, and the outlet of the front buffer tank 910 is connected to the inlet of the filter 920. The inlet of the filter 920 is connected to the outlet of the front buffer tank 910, and the outlet of the filter 920 is connected to the inlet of the rear buffer tank 930. The rear buffer tank 930 is located at the end of the third pipe 130, and its outlet is connected to the inlet end of the component to be treated 300 via the third pipe 130. The outlet of the rear buffer tank 930 is also connected to the inlet end of the component to be treated 300 via the third pipe 130.
[0079] For example, the first filtration assembly 200 includes a plate heat exchanger 210 and a centrifuge 220 for temperature regulation of the incoming liquid; the centrifuge 220 is connected to the plate heat exchanger 210 for centrifugal filtration of the liquid.
[0080] Centrifuge 220 centrifuges filter brewing liquid, such as wheat beer stock, after the temperature has been regulated by plate heat exchanger 210. By using centrifugal force, solid impurities or suspended matter in the liquid are separated to achieve solid-liquid separation, ensuring the purity of the output brewing liquid, such as wheat beer stock, while retaining the yeast. This allows for subsequent processing, such as flowing through the first pipeline 110 or the third pipeline 130 to the processing component 300 or the second filtration component 900, providing liquid that meets the process requirements.
[0081] The outlet can be a branch-type outlet pipe at the bottom of the centrifuge, with a tee connector at the end. It connects to the inlet of the first pipe 110 and the third pipe 130 via quick-connect fittings, allowing for parallel output of the filtered liquid. Alternatively, one of the first pipe 110 or the third pipe 130 can be selected for output. The length of the outlet pipe can be adjusted according to actual needs. The inlet can be located at the top of the centrifuge housing, connected to an external inlet pipe via a flange to receive the brewing liquid to be filtered.
[0082] It should be noted that in the brewing filtration system of this application, the component 300 to be processed is a high-concentration dilution device. The high-concentration dilution device is used to mix the filtered liquid, such as wheat beer stock, with dilution water in a preset ratio to facilitate concentration adjustment. The high-concentration dilution device also has a sake tank for temporarily storing the filtered liquid flowing out from the first pipe 110 or the second pipe 130.
[0083] Other embodiments of this application will readily occur to those skilled in the art upon consideration of the specification and practice of the utility models disclosed herein. This application is intended to cover any variations, uses, or adaptations of this application that follow the general principles of this application and include common knowledge or customary techniques in the art not disclosed herein. The specification and examples are to be considered exemplary only, and the true scope and spirit of this application are indicated by the following claims.
[0084] It should be understood that this application is not limited to the precise structure described above and shown in the accompanying drawings, and various modifications and changes can be made without departing from its scope. The scope of this application is limited only by the appended claims.
Claims
1. A brewing filtration system, characterized in that, include: Piping assembly (100), the piping assembly (100) including a first pipe (110), a second pipe (120) and a third pipe (130); A first filter assembly (200) has a liquid outlet end, and the first pipeline (110) and the third pipeline (130) are both connected to the liquid outlet end. A second filter assembly (900) is provided on one of the first pipeline (110) and the third pipeline (130). The component to be processed (300) has a liquid inlet end, and the first pipeline (110) and the third pipeline (130) are both connected to the liquid inlet end; The CIP system (400) has one end of the second pipeline (120) connected to the CIP system (400) and the other end connected to the first pipeline (110). The CIP system (400) is connected to the first filter assembly (200). The CIP system (400) is used to receive the liquid flowing out of the second pipeline (120) and deliver it to the first filter assembly (200). The first filter assembly (200) is configured such that liquid entering it for filtration is delivered to the component to be treated (300) via the first conduit (110) or the third conduit (130), or sequentially delivered to the CIP system (400) via the first conduit (110) and the second conduit (120).
2. The brewing filtration system according to claim 1, characterized in that, It also includes a switch assembly (500), which includes a first switch element (510) and a second switch element (520). The first switch element (510) is disposed at the liquid outlet end and is used to control the on / off state of the first pipeline (110) and the third pipeline (130). The second switch element (520) is disposed at the liquid inlet end and is used to control the on / off state of the first pipeline (110) and the second pipeline (120).
3. The brewing filtration system according to claim 2, characterized in that, The switch assembly (500) further includes at least two anti-mixing components (530), one of which is disposed at the connection between the first conduit (110) and the third conduit (130); the other of which is disposed at the connection between the first conduit (110) and the second conduit (120).
4. The brewing filtration system according to claim 3, characterized in that, The first switching element (510) and the second switching element (520) are both three-way valves, and the anti-mixing element (530) is an anti-mixing valve.
5. The brewing filtration system according to any one of claims 1-4, characterized in that, It also includes a flow detection element (700) disposed on at least one of the first pipeline (110), the second pipeline (120) and the third pipeline (130).
6. The brewing filtration system according to any one of claims 1-4, characterized in that, It also includes at least two sampling elements (800), each of which is respectively disposed on the first pipeline (110) and the third pipeline (130).
7. The brewing filtration system according to any one of claims 1-4, characterized in that, The second filter component (900) is disposed on the third pipeline (130) and is connected to the first filter component (200) and the component to be processed (300) through the third pipeline (130).
8. The brewing filtration system according to claim 7, characterized in that, The second filtration assembly (900) includes a front buffer tank (910), a filter (920), and a rear buffer tank (930), which are connected in sequence through the third pipeline (130).
9. The brewing filtration system according to any one of claims 1-4, characterized in that, The first filtration assembly (200) includes a plate heat exchanger (210) and a centrifuge (220), the centrifuge (220) being connected to the plate heat exchanger (210), the plate heat exchanger (210) being used to regulate the temperature of the incoming liquid; and the centrifuge (220) being used to centrifuge and filter the liquid.
10. The brewing filtration system according to any one of claims 1-4, characterized in that, The component to be processed (300) is a high-concentration dilution device.