CN111623400A - Hydraulic module - Google Patents

Abstract

The invention belongs to the field of building heating equipment, and discloses a hydraulic module, which comprises a shell; an equipment assembly disposed within the housing; the pipeline assembly is arranged in the shell, is connected with the equipment assembly through a pipeline, is used for supplying water to the equipment assembly, and is used for supplying the water output by the equipment assembly to the tail end; both ends of the pipeline assembly extend out of the shell; any end of the pipeline assembly is used for being connected with an external water pipe; the other end of the pipeline component is connected with a plugging piece. The two ends of the pipeline assembly extend out of the shell, so that the two ends of the water pipe in the pipeline assembly can be used for being externally connected with the water pipe, when one end of the water pipe is blocked and can not be connected with the water pipe, the water pipe can be connected through the other end of the water pipe, project application of various construction and installation conditions is flexibly adapted, the installation of a hydraulic module is facilitated, the labor cost and the equipment design/production cost of project construction are saved, and the flexibility of installation and use of the hydraulic module is ensured.

Description

Hydraulic module

Technical Field

The invention relates to the field of building heating equipment, in particular to a hydraulic module.

Background

The hydraulic module is used for circularly conveying refrigerant water, cooling water and sanitary hot water of a central air-conditioning water system such as a ground source heat pump, an air source heat pump and an air cooling module, and is provided with a pump set, a valve set, an automatic water supplementing and safety component, a bypass component, a control component and the like.

The existing hydraulic modules are all installed in a single fixed connecting pipe mode, and are suitable for projects and buildings with single and fixed installation conditions. However, with the development of existing residential and commercial residential heating and ventilation systems, the dwelling size of the same project usually includes a plurality of different installation conditions, so that the installation of the hydraulic module with the fixed connection pipe installation manner is difficult, and additional cost is generated by designing and manufacturing a new hydraulic module structure, which increases the manufacturing cost of the whole project.

Disclosure of Invention

The invention aims to provide a hydraulic module, which can be flexibly adapted to various construction and installation conditions without changing the production mold/process conditions of the hydraulic module.

The technical scheme provided by the invention is as follows:

a hydro module, comprising:

a housing;

an equipment assembly disposed within the housing;

the pipeline assembly is arranged in the shell, is connected with the equipment assembly through a pipeline, is used for supplying water to the equipment assembly, and is used for supplying the water output by the equipment assembly to the tail end;

both ends of the pipeline assembly extend out of the shell; any end of the pipeline assembly is used for being connected with an external water pipe; the other end of the pipeline component is connected with a plugging piece.

In this scheme, the both ends of pipeline subassembly all can be connected water pipe connector, and water pipe connector stretches out outside the casing for with outside water piping connection, under the production mould that does not change hydraulic module and technological condition, through the two side takeovers of pipeline, realize the project application of the multiple construction installation condition of nimble adaptation, guarantee hydraulic module's installation, flexibility of use.

Further preferably, the housing comprises an equipment cavity and a pipeline cavity;

the device assembly is disposed within the device cavity;

the pipeline assembly is arranged in the pipeline cavity.

In the scheme, the shell is provided with the independent equipment cavity and the pipeline cavity, so that the equipment and the pipeline can be independently installed respectively, the equipment is independently installed, the installation is simple and convenient, no pipeline is excessive, and the equipment cavity can be provided with the independent access hole, so that the equipment is easy to be pertinently overhauled and maintained; the pipeline is independently installed, and the installation is simple and does not influence the equipment installation and the later-stage maintenance.

Further preferably, the piping assembly includes a plurality of water supply pipes and a plurality of water return pipes;

valves are arranged at two ends of the water supply pipes and the water return pipes;

the valve is located outside the housing.

In this scheme, set up the valve on delivery pipe and wet return, the shutoff function of pipeline can be realized to the valve.

Further preferably, the pipe diameters of the plurality of water supply pipes and the plurality of water return pipes satisfy a pipe flow velocity of less than 0.3 m/s.

In the scheme, the pipe diameter is set to meet the condition that the flow velocity in the pipe is less than 0.3m/s, and the pressure loss in the pipe can be reduced.

Further preferably, the equipment assembly comprises a heat exchanger, and the heat exchanger is provided with a cold and heat source water inlet, a cold and heat source water outlet, a radiation water inlet and a radiation water outlet;

the pipeline assembly comprises a main water supply pipe, a main water return pipe, a radiation water supply pipe and a radiation water return pipe;

the cold and heat source water inlet is connected with the main water supply pipe pipeline, and the cold and heat source water outlet is connected with the main water return pipe pipeline;

the radiation water inlet is connected with the radiation water return pipe through a pipeline, and the radiation water outlet is connected with the radiation water supply pipe through a pipeline.

In this scheme, the pipeline subassembly includes two delivery pipes and two wet return, can be applicable to the water conservancy module for radiation end service.

Further preferably, the equipment assembly further comprises a water pump;

the water pump is arranged on a pipeline between the radiation water return pipe and the radiation water inlet of the heat exchanger.

Further preferably, the pipeline assembly further comprises a fresh air supply pipe and a fresh air return pipe;

the fresh air water supply pipe is connected with the main water supply pipe through a pipeline;

the fresh air water return pipe is connected with the main water return pipe through a pipeline.

In the scheme, the pipeline assembly comprises three water supply pipes and three water return pipes, and is suitable for hydraulic modules serving fresh air and radiation tail ends simultaneously; when the device is actually used, the number of the tail ends can be reduced or increased according to the actual use requirement.

Further preferably, the equipment assembly further comprises an expansion tank and a drain pipe connected with the expansion tank;

one end of the drain pipe is provided with a drain valve;

the other end of the water drain pipe is connected with the radiation water return pipe and the fresh air water return pipe respectively and used for maintaining the water quantity in the pipeline to be stable.

In the scheme, the expansion tank and the water release valve can be used for maintaining the system circulation pressure and the water quantity to be stable, and the normal operation of the hydraulic module is ensured.

Further preferably, the equipment assembly further comprises an electric cabinet;

the electric cabinet comprises a power distribution module and a tail end control module;

the power distribution module is used for carrying out power distribution control on electric equipment in the hydraulic module;

the end control module is used for controlling the opening and closing of a valve in the hydraulic module or controlling the opening degree of the valve.

In this scheme, set up the electric cabinet in the equipment subassembly, can realize hydraulic module's intelligent control.

Further preferably, a plurality of reserved interfaces are also included;

the reserved interfaces penetrate through the equipment cavity, one end of each reserved interface is positioned in the equipment cavity, and the other end of each reserved interface is positioned in the pipeline cavity;

the equipment assembly is connected with one end of the reserved interface through a pipeline;

the pipeline assembly is connected with the other end of the reserved connector through a pipeline.

The invention has the technical effects that: the both ends of pipeline subassembly all stretch out outside the casing for the both ends of the water pipe in the pipeline subassembly all can be used to external water pipe, and when the one end of water pipe was blocked unable takeover, the accessible other end was taken over, and with the project application of the multiple construction installation condition of nimble adaptation, make things convenient for the installation of water conservancy module, practice thrift the human cost and the equipment design/manufacturing cost of project construction, guarantee the flexibility of installation, the use of water conservancy module.

Drawings

The invention is described in further detail below with reference to the following figures and detailed description:

FIG. 1 is a schematic structural view of one embodiment of a hydro module of the present invention;

FIG. 2 is a schematic structural view of another embodiment of a hydro module of the present disclosure;

FIG. 3 is a schematic view of a positional relationship of the equipment and piping cavities of a hydro module of the present invention;

fig. 4 is a schematic diagram of another positional relationship of the equipment cavity and the piping cavity of a hydro module of the present invention.

The reference numbers illustrate:

1. a housing; 11. a partition plate; 111. reserving an interface; 12. an equipment cavity; 13. a pipeline cavity; 2. an equipment component; 21. a heat exchanger; 211. a cold and heat source water inlet; 212. a cold and heat source water outlet; 213. a radiation water inlet; 214. a radiation water outlet; 22. a water pump; 23. an expansion tank; 24. a drain pipe; 25. a water drain valve; 26. an electric cabinet; 3. a tubing assembly; 31. a water supply pipe; 311. a main water supply pipe; 312. a radiant water supply pipe; 313. a fresh air supply pipe; 32. a water return pipe; 321. a main water return pipe; 322. a radiation water return pipe; 323. a fresh air return pipe; 4. a blocking member; 5. and (4) a valve.

Detailed Description

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

For the sake of simplicity, the drawings only schematically show the parts relevant to the present invention, and they do not represent the actual structure as a product. In addition, in order to make the drawings concise and understandable, components having the same structure or function in some of the drawings are only schematically illustrated or only labeled. In this document, "one" means not only "only one" but also a case of "more than one".

It should be further understood that the term "and/or" as used in this specification and the appended claims refers to and includes any and all possible combinations of one or more of the associated listed items.

In this context, it is to be understood that, unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In addition, in the description of the present application, the terms "first", "second", and the like are used only for distinguishing the description, and are not intended to indicate or imply relative importance.

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the following description will be made with reference to the accompanying drawings. It is obvious that the drawings in the following description are only some examples of the invention, and that for a person skilled in the art, other drawings and embodiments can be derived from them without inventive effort.

As shown in fig. 1, the present invention provides one embodiment of a hydro module comprising a housing 1, an equipment assembly 2, and a piping assembly 3; the equipment assembly 2 and the pipeline assembly 3 are both arranged in the shell 1; the pipeline component 3 is connected with the equipment component 2 through a pipeline and used for supplying water to the equipment component 2 and supplying the water output by the equipment component 2 to the tail end; both ends of the pipeline component 3 extend out of the shell 1; any end of the pipeline component 3 can be used for being connected with an external water pipe; the other end of the pipeline assembly 3 is connected with a plugging piece 4.

The equipment assembly 2 may include components for performing various functions of the hydro module, such as, but not limited to, heat exchangers, water pumps, valves, filters, expansion tanks, electrical cabinets, and the like. The piping module 3 includes a plurality of water pipes for supplying water to the equipment module 2 and for supplying water outputted from the equipment module 2 to the tip. When one end of the water pipe is connected with an external water pipe, the other end of the water pipe can be connected with a plugging piece 4 for plugging, and the plugging piece 4 can be a pipe plug or a valve and the like so as to prevent the other end of the water pipe from leaking water.

In this embodiment, both ends of the water pipe all stretch out of the housing for the both ends of water pipe all can be used to external water pipe, and when the one end of water pipe was blocked unable takeover, the accessible other end was taken over, realizes not changing under the production mould/technological condition of water conservancy module, and the project that the multiple construction installation condition of nimble adaptation was used makes things convenient for the installation of water conservancy module, practices thrift the human cost and the equipment design/manufacturing cost of project construction, guarantees the flexibility of installation, the use of water conservancy module.

In one embodiment, the equipment assembly 2 and the pipeline assembly 3 may be disposed in a cavity formed by the housing 1, and the equipment assembly 2 and the pipeline assembly 3 are arranged in a relatively random manner, which may cause a certain difficulty in connecting the equipment assembly 2 and the pipeline assembly 3. In another embodiment, the housing 1 comprises an equipment cavity 12 and a tubing cavity 13; the equipment component 2 is arranged in the equipment cavity 12; the pipeline component 3 is arranged in the pipeline cavity 13, and two ends of the pipeline component 3 respectively extend out of the pipeline cavity 13. The equipment assembly 2 and the pipeline assembly 3 are arranged in a cavity, one cavity is mainly used for installing the equipment assembly 2, the other cavity is mainly used for installing the pipeline assembly 3, the connecting pipe positions are concentrated, and the pipeline is convenient to install and maintain in a later period. In addition, the equipment assembly 2 is independently installed in the equipment cavity 12, so that multiple pipelines do not exist in the equipment cavity 12, equipment is convenient to install, and an independent access hole can be formed in the equipment cavity 12, so that the equipment is easy to overhaul and maintain in a targeted mode.

The equipment chamber 12 and the line chamber 13 may be two separate chambers separated by a partition 11 in the housing 1. There may be a plurality of regions divided in the housing 1, and the plurality of regions are not partitioned by the partition plate 11, one of the regions is the equipment chamber 12, and the other region is the piping chamber 13. Or the pipeline cavity 13 and the equipment cavity 12 are produced in sections and then assembled together to realize multiple connecting pipe installation modes, namely the connecting pipe installation of the equipment assembly 2 in the equipment cavity 12 and the pipeline assembly 3 in the pipeline cavity 13, and the connecting pipe installation of the pipeline cavity 13 and the cold and hot source side, so that the multiple construction installation conditions can be flexibly adapted.

The number of the pipeline cavities 13 can be one or more, and each pipeline cavity 13 is internally provided with a pipeline. The arrangement of the pipe cavities 13 and the equipment cavities 12 is as shown in fig. 3 and 4, one pipe cavity 13 is arranged above the equipment cavity 12, and one pipe cavity 13 is arranged below the equipment cavity 12; or one line chamber 13 is disposed on the left side of the equipment chamber 12 and the other line chamber 13 is disposed on the right side of the equipment chamber 12. The arrangement mode of the two cavities can ensure that the pipeline cavity 13 and the equipment cavity 12 are convenient to take over, and can also ensure that the pipeline cavity 13 takes over from two sides.

In one embodiment, as shown in fig. 1 and 2, the pipe assembly 3 includes a plurality of water supply pipes 31 and a plurality of water return pipes 32; valves 5 are installed at both ends of the plurality of water supply pipes 31 and the plurality of water return pipes 32; the valve 5 is located outside the housing 1. The valve 5 realizes the shut-off function of the pipeline and is used for controlling the work of the pipeline. Preferably, the pipe diameters of the plurality of water supply pipes 31 and the plurality of water return pipes 32 satisfy a pipe flow velocity of less than 0.3 m/s. The water supply pipe 31 and the water return pipe 32 are provided with interfaces on the pipeline in the housing 1, and the connection between the water supply pipe 31 and the water return pipe 32 in the housing 1 and the water inlet and the water outlet on the equipment assembly 2 is realized through a metal corrugated hose. Both ends of the water supply pipe 31 and the water return pipe 32 can be used for externally connecting water pipes, when one end of each water pipe is blocked and can not be connected, the other ends of the water pipes can be connected, connection pipes on two sides are achieved, and the installation and use flexibility of the hydraulic module is guaranteed.

In one embodiment, as shown in FIG. 1, FIG. 1 illustrates a hydro-module configuration that serves a radiant tip. The equipment assembly 2 comprises a heat exchanger 21, and the heat exchanger 21 can be a plate heat exchanger, a fixed tube plate heat exchanger, a U-shaped tube plate heat exchanger, or the like. The heat exchanger 21 is provided with a cold and heat source water inlet 211, a cold and heat source water outlet 212, a radiation water inlet 213 and a radiation water outlet 214.

The piping component 3 includes a main water supply pipe 311, a main water return pipe 321, a radiation water supply pipe 312, and a radiation water return pipe 322; the cold and heat source water inlet 211 is connected with the main water supply pipe 311 through a pipeline, and the cold and heat source water outlet 212 is connected with the main water return pipe 321 through a pipeline; the radiation water inlet 213 is connected with the radiation water return pipe 322 by a pipeline, and the radiation water outlet 214 is connected with the radiation water supply pipe 312 by a pipeline.

The heat exchanger 21 can realize heat exchange between a primary side (main unit) and a secondary side (tail end), primary side water enters a cold and heat source water inlet 211 of the heat exchanger 21 from a main water supply pipe 311 and then is discharged to a main water return pipe 321 from a cold and heat source water outlet 212 of the heat exchanger 21; the secondary side water enters the radiation water inlet 213 of the heat exchanger 21 from the radiation water return pipe 322, then enters the radiation water supply pipe 312 from the radiation water outlet 214 of the heat exchanger 21, and the heat-exchanged water is conveyed to the radiation end through the radiation water supply pipe 312. In practical applications, the radiant water supply pipe 312 cannot be connected to the total water supply pipe 311 because the radiant water supply requires high water quality, and the radiant water supply pipe 312 and the radiant water return pipe 322 need to be separately installed and heat exchange is performed by the heat exchanger 21.

If be equipped with baffle 11 in the casing 1, can set up a plurality of reservation interfaces 111 on baffle 11, and the one end of reserving interface 111 is located equipment cavity 12, the other end of reserving interface 111 is located pipeline cavity 13, when jointing equipment and pipeline, be connected each water inlet and the delivery port on equipment unit 2 with the one end of reserving interface 111 that corresponds through metal collapsible tube respectively, the other end that will reserve interface 111 is connected with corresponding delivery pipe 31 and wet return 32 through metal collapsible tube, accomplish equipment unit 2 and pipeline unit 3's being connected.

Preferably, the equipment assembly 2 further comprises a water pump 22; the water pump 22 is disposed on a pipeline between the radiation water returning pipe 322 and the radiation water inlet 213 of the heat exchanger 21, for improving the water circulation power.

In another embodiment, as shown in FIG. 2, FIG. 2 shows a hydraulic modular structure that serves both fresh air and radiant ends simultaneously. Wherein the equipment set 2 comprises a heat exchanger 21. The heat exchanger 21 is provided with a cold and heat source water inlet 211, a cold and heat source water outlet 212, a radiation water inlet 213 and a radiation water outlet 214.

The pipeline component 3 comprises a main water supply pipe 311, a main water return pipe 321, a radiation water supply pipe 312, a radiation water return pipe 322, a fresh air water supply pipe 313 and a fresh air water return pipe 323; the cold and heat source water inlet 211 is connected with the main water supply pipe 311 through a pipeline, and the cold and heat source water outlet 212 is connected with the main water return pipe 321 through a pipeline; the radiation water inlet 213 is connected with the radiation water return pipe 322 by a pipeline, and the radiation water outlet 214 is connected with the radiation water supply pipe 312 by a pipeline. The fresh air water supply pipe 313 is connected with the total water supply pipe 311 by a pipeline; the fresh air return pipe 323 is connected with the main return pipe 321 through a pipeline.

Because the requirement of fresh air water supply on water quality is lower, in practical application, the fresh air water supply pipe 313 can be directly communicated with the total water supply pipe 311, and the fresh air water return pipe 323 is communicated with the total water return pipe 321 to supply fresh air water through the total water supply pipe 311. In practical applications, it is also within the scope of the present invention to simply reduce and increase the number of the ends according to the usage requirements, for example, when the number of the ends needs to be increased, the number of the end water supply pipes and the end water return pipes corresponding to the ends can be increased in the piping assembly 3, and according to the water quality and temperature requirements, the number is selectively communicated with the main water supply pipe 311 and the main water return pipe 321, or communicated with the radiant water supply pipe 312 and the radiant water return pipe 322, or directly communicated with the secondary side of the heat exchanger 21, and heat exchange is performed through the heat exchanger 21. When the number of the ends needs to be reduced, the end water supply pipe and the end water return pipe corresponding to the ends can be directly reduced in the pipeline assembly 3. When the hydraulic module of this embodiment is produced, a certain number of reserved water supply pipes and reserved water return pipes can be reserved in the pipeline cavity 13, and when the number of the tail ends needs to be increased, the reserved water supply pipes and the reserved water return pipes are connected with corresponding equipment and water pipes, so that the installation of the tail end-added pipelines is facilitated, and the application range of the hydraulic module is widened. A plurality of delivery pipes 31 and a plurality of wet return 32 can be in proper order from the top down in pipeline cavity 13 for the pipeline is neat orderly, not only makes pipeline cavity 13 internal layout clear, neat, pleasing to the eye, conveniently overhauls moreover.

Preferably, as shown in fig. 2, the equipment assembly 2 further comprises an expansion tank 23 and a drain pipe 24 connected to the expansion tank 23; one end of the drain pipe 24 is provided with a drain valve 25; the other end of the water drain pipe 24 is connected to the radiation water return pipe 322 and the fresh air water return pipe 323 respectively, and is used for maintaining the water quantity in the pipeline to be stable. The expansion tank 23 and the drain valve 25 are used for maintaining the system circulation pressure and water amount stable.

Preferably, as shown in fig. 2, the equipment assembly 2 further comprises an electric cabinet 26; the electric cabinet 26 comprises a power distribution module and a tail end control module; the power distribution module is used for performing power distribution control on electric equipment in the hydraulic module, such as power distribution control on electric equipment such as the water pump 22. The end control module is used for opening and closing control or opening control of a valve element in the hydraulic module, such as opening control of an electric two-way valve (the electric two-way valve can be arranged on a pipeline connected with the cold and heat source water inlet 211 of the heat exchanger 21). The intelligent control of the whole hydraulic module can be realized by arranging the electric control box 26.

In the equipment cavity 12, the heat exchanger 21 is connected with four water pipes, and the four water pipes are connected with reserved interfaces 111 on the partition plate 11; the water pump 22 is positioned on the right side of the heat exchanger 21 and is connected with the radiation water return pipe 322; the expansion tank 23 is positioned at the right lower side in the equipment cavity 12 and is connected with the drain pipe 24, the lower side of the drain pipe 24 is provided with a drain valve 25, and the upper side is connected with two water pipes; the electric cabinet 26 is arranged at the left lower side vacant position in the equipment cavity 12. Through rationally setting up above-mentioned part in equipment cavity 12, not only can optimize the part setting in equipment cavity 12, reduce occupation space, be convenient for moreover pertinence overhaul and maintain equipment. The equipment set 2 in the equipment chamber 12 may include other connections and ancillary functional equipment and valves, etc. as required in the hydro module, in addition to the equipment listed in this embodiment. The pipe cavity 13 may include other connectors, auxiliary devices, valves, etc. in addition to the above-mentioned pipes and components.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims (10)

1. A hydro module, comprising:

a housing;

an equipment assembly disposed within the housing;

the pipeline assembly is arranged in the shell, is connected with the equipment assembly through a pipeline, is used for supplying water to the equipment assembly, and is used for supplying the water output by the equipment assembly to the tail end;

both ends of the pipeline assembly extend out of the shell; any end of the pipeline assembly is used for being connected with an external water pipe; the other end of the pipeline component is connected with a plugging piece.

2. The hydro-module of claim 1,

the shell comprises an equipment cavity and a pipeline cavity;

the device assembly is disposed within the device cavity;

the pipeline assembly is arranged in the pipeline cavity.

3. The hydro-module of claim 1,

the pipeline assembly comprises a plurality of water supply pipes and a plurality of water return pipes;

valves are arranged at two ends of the water supply pipes and the water return pipes;

the valve is located outside the housing.

4. The hydro-module of claim 3,

the pipe diameters of the water supply pipes and the water return pipes meet the condition that the flow velocity in the pipes is less than 0.3 m/s.

5. A hydro module according to any of claims 1-4,

the equipment assembly comprises a heat exchanger, wherein a cold and heat source water inlet, a cold and heat source water outlet, a radiation water inlet and a radiation water outlet are formed in the heat exchanger;

the pipeline assembly comprises a main water supply pipe, a main water return pipe, a radiation water supply pipe and a radiation water return pipe;

the cold and heat source water inlet is connected with the main water supply pipe pipeline, and the cold and heat source water outlet is connected with the main water return pipe pipeline;

the radiation water inlet is connected with the radiation water return pipe through a pipeline, and the radiation water outlet is connected with the radiation water supply pipe through a pipeline.

6. The hydro-module of claim 5,

the equipment assembly further comprises a water pump;

the water pump is arranged on a pipeline between the radiation water return pipe and the radiation water inlet of the heat exchanger.

7. The hydro-module of claim 5,

the pipeline assembly also comprises a fresh air supply pipe and a fresh air return pipe;

the fresh air water supply pipe is connected with the main water supply pipe through a pipeline;

the fresh air water return pipe is connected with the main water return pipe through a pipeline.

8. The hydro-module of claim 7,

the equipment assembly also comprises an expansion tank and a water drain pipe connected with the expansion tank;

one end of the drain pipe is provided with a drain valve;

the other end of the water drain pipe is connected with the radiation water return pipe and the fresh air water return pipe respectively and used for maintaining the water quantity in the pipeline to be stable.

9. The hydro-module of claim 8,

the equipment assembly further comprises an electric cabinet;

the electric cabinet comprises a power distribution module and a tail end control module;

the power distribution module is used for carrying out power distribution control on electric equipment in the hydraulic module;

the end control module is used for controlling the opening and closing of a valve in the hydraulic module or controlling the opening degree of the valve.

10. The hydro-module of claim 2,

the system also comprises a plurality of reserved interfaces;

the reserved interfaces penetrate through the equipment cavity, one end of each reserved interface is positioned in the equipment cavity, and the other end of each reserved interface is positioned in the pipeline cavity;

the equipment assembly is connected with one end of the reserved interface through a pipeline;

the pipeline assembly is connected with the other end of the reserved connector through a pipeline.

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