CN113883620B

CN113883620B - Indoor water circulating system

Info

Publication number: CN113883620B
Application number: CN202111109943.4A
Authority: CN
Inventors: 胡长弟
Original assignee: Ningbo Shuangqiao Garden Construction Co ltd
Current assignee: Ningbo Shuangqiao Garden Construction Co ltd
Priority date: 2021-09-23
Filing date: 2021-09-23
Publication date: 2023-03-31
Anticipated expiration: 2041-09-23
Also published as: CN113883620A

Abstract

The application relates to an indoor water circulation system, which belongs to the field of building temperature regulation and comprises a heat insulation layer and a heat insulation layer, wherein the heat insulation layer is arranged on the inner wall of a building, and a cavity is formed in the heat insulation layer; the pumping assembly comprises a water pump and a drain pipe connected with the water pump, the drain pipe is positioned in the cavity of the heat insulation layer, and a plurality of water outlet holes are formed in the drain pipe along the length direction; the recovery assembly comprises a recovery box and a recovery pipe arranged on the recovery box, and the recovery pipe is communicated with the cavity of the heat insulation layer; the energy storage assembly comprises an energy storage box, and the energy storage box is connected with one end, far away from the water pump, of the water discharge pipe. The application has the effect of keeping the lower temperature in the plant and not increasing the humidity in the plant.

Description

Indoor water circulating system

Technical Field

The application relates to the field of building temperature regulation, in particular to an indoor water circulation system.

Background

Large-scale industry factory building often uses the steel construction factory building in order to obtain great span and area, and the steel construction factory building includes steel skeleton and roofing, and the steel skeleton comprises stand, frame crossbeam, roof truss or roof beam, and the roofing often adopts the preparation of various steel sheet, and a large amount of steel construction and various steel sheet can absorb a large amount of heats when weather is comparatively hot, make the temperature in the factory building higher.

At present, the industrial factory building often adopts powerful air conditioning equipment to cool down the factory building, and air conditioning equipment power consumption is huge, and the energy consumption is serious on the one hand, is unfavorable for green production, and on the other hand use cost is higher.

Chinese patent publication No. CN111878942A discloses a high-temperature industrial factory building aeration cooling device, which comprises a flashing board, a roof and wall boards, wherein a first fan is installed in the middle of the roof, a first wall board is installed at the bottom end of the side edge of the roof, a second wall board is arranged at the inner side of the first wall board, a second fan is installed at the side surface of the bottom end of the second wall board, a water tank is installed at the bottom end between the first wall board and the second wall board, a water tank is installed at the outer side of the first wall board, a water inlet is arranged at the right side of the upper end of the water tank, a first water pump is installed at the left side of the upper end of the water tank, a water delivery pipe is installed at the upper end of the first water pump, the water delivery pipe is connected with a control valve, a water storage pipe is installed at the bottom end of the control valve, and a spray head is installed at the bottom end of the water storage pipe; through shower nozzle blowout water cooling air, the second fan sends into the factory building with cooling air in, effectively reduces the inboard temperature of industry factory building, forms the air convection, has solved the great problem of traditional air conditioner power consumption.

In view of the above-mentioned related technologies, the inventor believes that the air with high humidity is directly sent into the factory building, which may affect the normal operation of the electrical equipment in the factory building, and reduce the service life of the electrical equipment.

Disclosure of Invention

In order to keep the humidity in can not increasing the factory building in the lower temperature in making the factory building, this application provides an indoor water circulating system.

The application provides an indoor water circulating system adopts following technical scheme:

an indoor water circulation system comprising:

the heat insulation layer is arranged on the inner wall of the building, and a cavity is formed in the heat insulation layer;

the pumping assembly comprises a water pump and a drain pipe connected with the water pump, the drain pipe is positioned in the cavity of the heat insulation layer, and a plurality of water outlet holes are formed in the drain pipe along the length direction;

the recovery assembly comprises a recovery box and a recovery pipe arranged on the recovery box, and the recovery pipe is communicated with the cavity of the heat insulation layer;

the energy storage assembly comprises an energy storage box, and the energy storage box is connected with one end, far away from the water pump, of the water discharge pipe.

By adopting the technical scheme, the heat insulation layer can isolate the outer wall of a building from the indoor space, so that the indoor temperature is kept in a lower state, the water pump pumps water into the water drainage pipe when the temperature is higher, then the water is discharged into the heat insulation layer through the water outlet hole, the water flow flows back into the backflow box through the recovery pipe after absorbing the heat in the heat insulation layer, the water is recycled, the water flow cannot directly enter the indoor space, and the indoor humidity cannot be influenced while the indoor space can be cooled;

the one end of the water pump that keeps away from in order to guarantee the drain pipe also has sufficient water pressure, and the output pressure of water pump is often great, and unnecessary water can enter into the energy storage incasement, and after the water pump stop work, the water in the energy storage incasement can get into in the drain pipe under the action of gravity and then discharge in the outlet port, continuously cools down, can practice thrift the electric energy, comparatively environmental protection.

Optionally, the apopore is formed with two on the drain pipe, and two apopores are located the both sides of drain pipe respectively, be provided with the direction subassembly of control from the direction of apopore discharge rivers in the apopore, the direction subassembly include with drain pipe clearance fit's deflector, the deflector is not in different states at the same time of the interior rivers direction of drain pipe.

Through adopting above-mentioned technical scheme, when the water pump initiative with the water pump send to on the drain pipe and water in the drain pipe of staying under the action of gravity, rivers are different from apopore exhaust direction, make rivers can more even distribution in thermal-insulated layer, avoid appearing in the thermal-insulated layer not by the region that rivers covered.

Optionally, the guide plate is slidably connected in the drain pipe, two limiting blocks used for limiting the stroke of the guide plate are arranged in the drain pipe, the number of the water outlets between the two limiting blocks is two, one side of each water outlet, which is located outside the drain pipe, is connected with the guide pipe, the opening directions of the adjacent guide pipes are opposite, and one drain hole is sealed when the guide plate slides to the stroke limit.

Through adopting above-mentioned technical scheme, rivers can drive the deflector and slide between two stoppers, and the rivers direction is different, and the deflector contacts with the stopper of difference to confined wash port is different, makes the rivers direction different, and water can be followed different wash port and discharged.

Optionally, a rotating shaft perpendicular to the drain pipe is arranged on the guide plate, the rotating shaft is located on a symmetry line of the water outlet and is rotatably connected with the drain pipe, and limiting blocks for limiting the travel of the guide plate are respectively arranged on two sides of the water outlet on the inner wall of the drain pipe.

Through adopting above-mentioned technical scheme, rivers can drive the deflector and revolute the axis rotation of rotation, and when the direction of rivers is different, deflector wobbling angle is different, and rivers are discharged along the deflector from the delivery port and are used for the direction also different that flows out.

Optionally, a flow guide plate is arranged in the cavity of the heat insulation layer.

Through adopting above-mentioned technical scheme, the deflector can lead rivers, makes rivers can not all converge together, can carry out even heat dissipation to the insulating layer, also can increase the intensity of insulating layer simultaneously, makes the difficult emergence of insulating layer damage.

Optionally, the part of the drain pipe provided with the water outlet and the guide assembly is independently formed and is connected with the other part of the drain pipe through a flange structure.

Through adopting above-mentioned technical scheme, can carry out the dismouting alone with the part that is provided with the direction subassembly at the in-process of equipment and maintenance, it is comparatively convenient to use.

Optionally, the heat insulating layer includes a roof heat insulating layer arranged on the top of the building and a wall heat insulating layer arranged on the inner side of the outer wall of the building, the drain pipe includes a first pipe body arranged in the roof heat insulating layer and a second pipe body arranged on the top of the wall heat insulating layer, a water outlet on the first pipe body is arranged along the horizontal direction, and a water outlet on the second pipe body is arranged downwards along the vertical direction.

Through adopting above-mentioned technical scheme, the wall on roof can be cooled down to the roof insulating layer, and the wall body insulating layer can be cooled down to the outer wall, forms a water curtain on whole building, the lower temperature of messenger's that can be better indoor maintenance, and the cooling effect is better.

Optionally, the water pump is connected with a first connecting pipe, the first connecting pipe is connected with the middle of the first pipe body, the first pipe body is connected with the middle of the second pipe body, and two ends of the second pipe body are connected with the energy storage tank.

Through adopting above-mentioned technical scheme, the water pump is connected through the middle part of first connecting pipe with first body for the water pressure at first body both ends is the same, can realize load balance, promotes work efficiency, avoids appearing the condition that one end water pressure is low excessively.

In summary, the present application includes at least one of the following beneficial technical effects:

by arranging the heat insulation layer, heat exchange between indoor air and a building wall can be blocked, heat is taken away through water flow, indoor temperature reduction can be realized, indoor humidity cannot be influenced, and normal work of indoor electronic devices cannot be interfered;

through setting up the energy storage case, at the water pump during operation, can last the retaining in the energy storage case, at the water pump stop work during, the energy storage case also can last to supply water, can practice thrift the electric energy, comparatively environmental protection.

Drawings

Fig. 1 is a schematic perspective view of an indoor water circulation system according to embodiment 1 of the present application;

FIG. 2 is a schematic diagram of the structure of the pipe connection of FIG. 1;

FIG. 3 is a schematic cross-sectional view of the water outlet section shown in FIG. 2;

FIG. 4 is a schematic sectional view of the water outlet joint in example 2.

Description of reference numerals: 1. a roof insulation layer; 2. a wall heat insulation layer; 3. a baffle; 4. a pumping assembly; 41. a water pump; 42. a first connecting pipe; 431. a first pipe body; 432. a second tube body; 44. a water outlet hole; 45. water outlet is saved; 46. a second connecting pipe; 5. a flange plate; 6. an energy storage tank; 7. a guide assembly; 71. a guide plate; 72. a limiting block; 73. a guide tube; 74. a rotating shaft; 8. a recovery assembly; 81. a recovery pipe; 82. and (6) a recycling bin.

Detailed Description

The present application is described in further detail below with reference to figures 1-4.

Embodiment 1, refer to fig. 1, this embodiment discloses an indoor water circulating system, including insulating layer, pumping module 4 and recovery subassembly 8, the insulating layer is used for installing indoorly, and the insulating layer is equipped with the cavity that supplies rivers to pass through, pumps rivers in 4 to the cavity through pumping module, makes rivers take away the heat of insulating layer, and recovery subassembly 8 can retrieve water, realizes the cyclic utilization of water.

The heat insulation layer comprises a roof heat insulation layer 1 and a wall heat insulation layer 2, wherein the roof heat insulation layer 1 is fixedly arranged below the roof of the building and is tightly attached to the roof; the wall body heat insulation layer 2 is arranged in an inner side groove of an outer wall of a building and is tightly attached to the wall body, and the roof heat insulation layer 1 and the wall body heat insulation layer 2 surround the indoor space together, so that heat exchange between the indoor space and the outdoor space is reduced.

Optionally, a guide plate 3 is arranged in the cavity of the heat insulation layer, the guide plate 3 in the roof heat insulation layer 1 is arranged along the roof inclination direction, and the guide plate 3 of the wall heat insulation layer 2 is arranged along the vertical direction.

Referring to fig. 1 and 2, the pumping assembly 4 includes a water pump 41, a first connection pipe 42 and a drain pipe, the water pump 41 is located in a water source, the drain pipe is located in a heat insulation layer and is provided with a water outlet 44 for discharging water, and the first connection pipe 42 is used for connecting the water pump 41 and the drain pipe.

The drain pipe includes first body 431 and second body 432, and first body 431 is located the middle part of roof insulating layer 1, and second body 432 is provided with two sets of all installs in wall body insulating layer 2, and the middle part of two second bodies 432 is connected with the both ends of first body 431 respectively, all can dismantle on first body 431 and the second body 432 and be connected with water outlet section 45, and apopore 44 all is located water outlet section 45. A group of water outlet holes 44 are respectively arranged on two sides of the water outlet joint 45 on the first pipe body 431, and the two groups of water outlet holes 44 penetrate through the water outlet joint 45 along the horizontal direction; the water outlet hole 44 on the water outlet joint 45 on the second pipe 432 penetrates downward in the vertical direction. Part of water can flow out from two sides of the first pipe body 431 and cover the whole roof heat insulation layer 1 to two sides; another portion of the water can flow out of the second pipe 432 and cover the entire wall insulation 2 downward.

Specifically, based on the structure of the existing frame-type factory building, the first pipe 431 is arranged along the ridge of the frame-type factory building and longitudinally penetrates through the whole factory building; the second pipe body 432 is provided along the width direction of the roof girder and located below the first pipe body 431, and the first pipe body 431 and the second pipe body 432 are connected by the second connecting pipe 46.

The both ends of second body 432 all are connected with energy storage box 6, and energy storage box 6 is installed at the building top, and when water pump 41 started, unnecessary water can flow back to in first body 431 and the second body 432 through first body 431 and second body 432, after water pump 41 stop work, water in the energy storage box 6 can flow back to in first body 431 and the second body 432 under the action of gravity to discharge from apopore 44, continuously cool down.

Referring to fig. 3, two ends of the water outlet joint 45 are both provided with flanges 5, and the water outlet joint 45 is fixedly connected with a drain pipe through flange connection. A guide component 7 for controlling the direction of water flow discharged from the water outlet hole 44 is arranged in the water outlet joint 45, and when the energy storage tank 6 is in two states of water storage and water discharge, the guide component 7 enables the water flow discharged from the water outlet hole 44 to flow to different directions.

The guide assembly 7 includes a guide plate 71 and two limiting blocks 72 disposed in the water outlet section 45, the two limiting blocks 72 are disposed, the number of the water outlet holes 44 between the two limiting blocks 72 is two, one side of the water outlet hole 44 located outside the water outlet pipe is connected with a guide pipe 73, and the opening directions of the adjacent guide pipes 73 are opposite. The guide plate 71 is annular and slides between the two limit blocks 72, the limit blocks 72 limit the stroke of the guide plate 71, when water flows from the water pump 41 to the energy storage tank 6, the guide plate 71 is impacted by water flow to move towards the right side until the guide plate is contacted with the limit block 72 on the right side, so that the guide plate 71 seals the drain hole on the right side, and the water flow is discharged from the drain hole on the left side; similarly, when water flows from the water storage tank to the water discharge pipe, the guide plate 71 is impacted by the water flow and moves to the left side until the guide plate contacts with the left side limiting block 72, so that the guide plate 71 closes the left side water discharge hole, and the water flow is discharged from the right side water discharge hole.

Retrieve subassembly 8, including collection box 82 and the recovery tube 81 of setting on collection box 82, the cavity intercommunication of recovery tube 81 and insulating layer, water pump 41 is located collection box 82, can install refrigeration plant in collection box 82 simultaneously in order to accelerate the cooling of water, promotes the cooling effect.

The implementation principle of an indoor water circulation system of the embodiment of the application is as follows: when the water pump 41 is started, the water pump 41 is sent into the drainage pipe, then water is discharged through the water outlet hole 44 and enters the heat insulation layer, and water flow flows back into the return tank through the recovery pipe 81 after absorbing heat in the heat insulation layer; after the water pump 41 stops working, the water in the energy storage tank 6 can flow back into the first pipe 431 and the second pipe 432 under the action of gravity, and is discharged from the water outlet 44, and the temperature is continuously reduced.

Embodiment 2, referring to fig. 4, the difference between this embodiment and embodiment 1 is that a rotating shaft 74 perpendicular to the water outlet pipe is disposed on the guide plate 71, the rotating shaft 74 is located on the symmetry line of the water outlet and is rotatably connected with the water outlet joint 45, and the inner wall of the water outlet pipe is respectively provided with a limiting block 72 for limiting the stroke of the guide plate 71 on both sides of the water outlet.

The implementation principle of an indoor water circulation system in the embodiment of the application is as follows: when water flows from the water pump 41 to the energy storage tank 6, the guide plate 71 is impacted by water flow to rotate towards the right side until the guide plate contacts with the right limit block 72, so that the water flow flows out from the left side of the water drainage hole along the guide plate 71; similarly, when water flows from the reservoir to the drain pipe, the guide plate 71 is impacted by the water flow to rotate to the left until contacting the left stopper 72, so that the water flow flows out from the right side of the drain hole along the guide plate 71.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: equivalent changes in structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims

1. An indoor water circulation system, characterized by comprising:

the pumping assembly (4) comprises a water pump (41) and a drain pipe connected with the water pump (41), the drain pipe is positioned in the cavity of the heat insulation layer, and a plurality of water outlet holes (44) are formed in the drain pipe along the length direction;

the recycling assembly (8) comprises a recycling tank (82) and a recycling pipe (81) arranged on the recycling tank (82), and the recycling pipe (81) is communicated with the cavity of the heat insulating layer;

the energy storage assembly comprises an energy storage tank (6), and the energy storage tank (6) is connected with one end, far away from the water pump (41), of the water drainage pipe;

the water outlet holes (44) are formed in two rows on the water drain pipe, the two rows of water outlet holes (44) are respectively located on two sides of the water drain pipe, the heat insulation layer comprises a roof heat insulation layer (1) arranged on the top of a building and a wall heat insulation layer (2) arranged on the inner side of the outer wall of the building, the water drain pipe comprises a first pipe body (431) arranged in the roof heat insulation layer (1) and a second pipe body (432) arranged on the top of the wall heat insulation layer (2), the first pipe body (431) is located in the middle of the roof heat insulation layer (1), and two groups of second pipe bodies (432) are arranged; the middle parts of the two second pipe bodies (432) are respectively connected with the two ends of the first pipe body (431), the first pipe body (431) and the second pipe body (432) can be detachably connected with a water outlet joint (45), water outlet holes (44) are respectively positioned on the water outlet joints (45), a group of water outlet holes (44) are respectively arranged on the two sides of the water outlet joint (45) positioned on the first pipe body (431), and the two groups of water outlet holes (44) penetrate through the water outlet joints (45) along the horizontal direction; the water outlet hole (44) on the first pipe body (431) is formed along the horizontal direction, the water outlet hole (44) on the second pipe body (432) is formed downwards along the vertical direction, and the water outlet hole (44) on the water outlet joint (45) on the second pipe body (432) penetrates through the water outlet joint (45) downwards along the vertical direction; the water outlet joint (45) is internally provided with guide assemblies (7) for controlling the direction of water flow discharged from the water outlet hole (44), each guide assembly (7) comprises a guide plate (71) and two limiting blocks (72) which are movably matched with the water discharge pipe, the guide plates (71) are connected in the water discharge pipe in a sliding mode, the two limiting blocks (72) arranged in the water discharge pipe are used for limiting the stroke of the guide plates (71), the guide plates (71) are in different states when the directions of the water flow in the water discharge pipe are different, and the guide plates (71) close the water outlet hole (44) when sliding to the stroke limit;

the number of the water outlet holes (44) on each side of the water outlet joint (45) between the two limiting blocks (72) is two, the guide pipes (73) are respectively connected to one side of each water outlet hole (44) outside the water outlet joint (45), the opening directions of the two adjacent guide pipes (73) on the same side of the water outlet joint (45) are opposite, and the two guide pipes (73) on the same side of the same water outlet joint (45) are inclined towards the side close to each other;

when water flows from the water pump (41) to the energy storage tank (6), the guide plate (71) is impacted by water flow to move to the right side until the guide plate is contacted with the limiting block (72) on the right side, so that the guide plate (71) seals the water outlet hole (44) on the right side, and the water flow is discharged from the water outlet hole (44) on the left side; similarly, when water flows from the water storage tank to the water discharge pipe, the guide plate (71) is impacted by water flow to move to the left side until the guide plate contacts with the limiting block (72) on the left side, so that the guide plate (71) seals the water outlet hole (44) on the left side, and the water flow is discharged from the water outlet hole (44) on the right side;

the first pipe body (431) is arranged along a ridge of the frame type plant and longitudinally penetrates through the whole plant; the second pipe body (432) is arranged along the width direction of the roof girder and is positioned below the first pipe body (431), the first pipe body (431) and the second pipe body (432) are connected through a second connecting pipe (46), two ends of the second pipe body (432) are connected with the energy storage tank (6), the energy storage tank (6) is installed at the top of a building, when the water pump (41) is started, redundant water can enter the energy storage tank (6) through the first pipe body (431) and the second pipe body (432), and after the water pump (41) stops working, water in the energy storage tank (6) can flow back into the first pipe body (431) and the second pipe body (432) under the action of gravity and is discharged from the water outlet hole (44) to continuously cool; the water pump (41) is connected with a first connecting pipe (42), the first connecting pipe (42) is connected with the middle part of a first pipe body (431), and the first pipe body (431) is connected with the middle part of a second pipe body (432);

both ends of the water outlet joint (45) are provided with flange plates (5), and the water outlet joint (45) is fixedly connected with a drain pipe through the flange plates (5).

2. An indoor water circulation system according to claim 1, wherein: a guide plate (3) is arranged in the cavity of the heat insulation layer.