CN215373683U - Hexagonal water distributor convenient to install - Google Patents

Abstract

The utility model relates to the technical field of energy storage equipment, and particularly discloses a hexagonal water distributor convenient to install. In this install convenient hexagonal water-locator locates the energy storage tank, including hexagonal water-locator body, hexagonal water-locator body includes central turbulent flow chamber, one-level distributor, second grade distributor and with the one-level distributor respectively with central turbulent flow chamber and the installation component that second grade distributor is connected, wherein: the first-stage distributor comprises six first-stage distribution pipes, the six first-stage distribution pipes are distributed outside the central turbulent flow cavity in an annular array mode, and cavity grooves are formed between every two adjacent first-stage distribution pipes. The water distributor provided by the utility model can effectively reduce the height of the thermocline, thereby greatly improving the utilization rate of the energy storage tank, further improving the energy storage efficiency of the energy storage tank and being beneficial to increasing the practicability of the energy storage tank.

Description

Hexagonal water distributor convenient to install

Technical Field

The utility model belongs to the technical field of energy storage equipment, and particularly relates to a hexagonal water distributor convenient to install.

Background

The water energy storage is suitable for areas with peak-valley electricity prices, the unit generally utilizes the low-valley electricity prices at night for refrigeration/heat, then the energy is stored in the energy storage water tank through the energy storage device, and the host can be turned on or turned on less at the time of high electricity prices in the daytime, so that the purposes of saving the operating cost and reducing the power grid pressure at the time of the daytime are achieved.

The common water energy storage method is a natural layering method, which is a water distributor frequently adopted by people, low-temperature water and high-temperature water are uniformly distributed on the same plane through an upper water distributor and a lower water distributor, and the low-temperature water in a water tank can be ensured to be in the lower layer according to the densities of different water warm water. The thermocline is a temperature transition layer between cold water and hot water, and the clear and stable thermocline can prevent the cold water and the hot water from being mixed, but the existence of the thermocline reduces the energy storage efficiency, so that when the water temperature at the bottom of the energy storage tank is constant, the height of the thermocline can be reduced through slow flow of the upper water distributor and the lower water distributor, and the energy storage efficiency is improved. However, the energy storage tank belongs to a closed limited space, and when the conventional energy storage tank water distributor is installed, welding or bonding needs to be carried out in the energy storage tank, so that the construction operation time is long, the requirement on constructors is high, and professional constructors are needed. Therefore, a water distributor which can effectively reduce the height of the thermocline, can be conveniently installed and can reduce the construction period is urgently needed.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a hexagonal water distributor convenient to install, and aims to solve the problems that the construction period of the water distributor of an energy storage pool provided by the background technology is long, and the energy storage efficiency of the energy storage pool cannot be effectively improved.

In order to achieve the purpose, the utility model provides the following technical scheme: the utility model provides a hexagonal water-locator that installation is convenient locates in the energy storage jar, includes hexagonal water-locator body, and hexagonal water-locator body includes central turbulent flow chamber, one-level distributor, second grade distributor and with the one-level distributor respectively with the central turbulent flow chamber with the installation component that second grade distributor is connected, wherein:

the primary distributor comprises six primary distribution pipes, the six primary distribution pipes are distributed outside the central turbulent flow cavity in an annular array, and cavity grooves are formed between every two adjacent primary distribution pipes;

the second grade distributor is equipped with six groups altogether and every group second grade distributor all includes a plurality of second grade distributing pipes, and a plurality of second grade distributing pipes distribute in the chamber groove from inside to outside layer by layer, and the second grade distributing pipe in every chamber groove surrounds formation hexagon.

Preferably, the central turbulence cavity is provided with six distributor interfaces which are distributed in an annular array, and the six distributor interfaces correspond to the six primary distribution pipes one by one.

Preferably, a plurality of obliquely arranged connecting pipes are mounted on two sides of the six primary distribution pipes.

Preferably, the hexagonal water distributor body further comprises a quick connection assembly, the quick connection assembly comprises two second connection flanges used for connecting the central turbulent flow cavity with the water inlet and outlet pipes of the energy storage tank, and the two second connection flanges are respectively arranged at two ends of the central turbulent flow cavity.

Preferably, a plurality of secondary distribution pipes are provided with dense water-permeable holes of the water distributor.

Preferably, the installation component includes first flange, and first flange is equipped with a plurality ofly, and the tip of connecting pipe, distributor interface and secondary distribution pipe is located respectively to a plurality of first flange that connect.

Compared with the prior art, the utility model has the following beneficial effects:

(1) the height of the thermocline can be effectively reduced, so that the utilization rate of the energy storage tank is greatly improved, the energy storage efficiency of the energy storage tank is further improved, and the practicability of the energy storage tank is increased, so that the energy storage tank can be conveniently used.

(2) The water distributor has small unit volume and is connected through the flange, the installation is convenient, the construction is rapid, and the installation efficiency of the water distributor can be improved, so that the construction period is effectively shortened, and the rapid use of the water distributor is realized.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural view of a hexagonal water distributor body according to the present invention;

FIG. 3 is a schematic structural view of a central turbulence chamber in the present invention;

FIG. 4 is a schematic diagram of a primary distributor according to the present invention;

FIG. 5 is a schematic diagram of a two-stage distributor according to the present invention;

FIG. 6 is an enlarged structural view at A in FIG. 5;

in the figure: 1. a central turbulence chamber; 11. a distributor interface; 2. a first-stage distributor; 21. a primary distribution pipe; 3. a secondary distributor; 31. a secondary distribution pipe; 4. water permeable holes of the water distributor; 5. a hexagonal water distributor body; 6. an energy storage tank; 7. a first connecting flange; 8. a second attachment flange.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1-6, the present invention provides the following technical solutions: the utility model provides a hexagonal water-locator that installation is convenient, locates in energy storage tank 6, including hexagonal water-locator body 5, hexagonal water-locator body 5 includes central turbulent flow chamber 1, one-level distributor 2, second grade distributor 3 and with one-level distributor 2 respectively with the central turbulent flow chamber 1 with the installation component that second grade distributor 3 is connected, wherein: the primary distributor 2 comprises six primary distribution pipes 21, the six primary distribution pipes 21 are distributed outside the central turbulent flow cavity 1 in an annular array, and cavity grooves are formed between every two adjacent primary distribution pipes 21; the second grade distributor 3 is equipped with six groups altogether and every group second grade distributor 3 all includes a plurality of second grade distributing pipes 31, and a plurality of second grade distributing pipes 31 distribute in the chamber groove from inside to outside layer by layer, and the second grade distributing pipe 31 in every chamber groove surrounds formation hexagon.

Specifically, in the present embodiment, each group of secondary distributors 3 includes 4 secondary distribution pipes 31, but in the actual application process, the secondary distribution pipes 31 included in each group of secondary distributors 3 are not limited to the number disclosed above, and may be specifically set according to actual requirements;

when the water distributor is used, workers can firstly install the six primary distribution pipes 21 outside the central turbulent flow cavity 1 respectively, then connect the 4 secondary distribution pipes 31 in the cavity groove between the two adjacent primary distribution pipes 21 layer by layer from inside to outside, so as to realize the assembly of the hexagonal water distributor body 5, then a worker installs the hexagonal water distributor body 5 into the energy storage tank 6, so that two ends of the central turbulent flow cavity 1 are respectively connected with a water inlet pipe and a water outlet pipe of the energy storage tank 6, then under the action of an energy storage circulating pump, the water body is conveyed into the hexagonal water distributor body 5 through a water inlet pipe of the energy storage tank 6, then hexagonal water distribution is formed under the coordination of six first-stage distributors 2 and six groups of second-stage distributors 3, finally the water body is discharged from a water outlet pipe of an energy storage tank 6, so as to realize energy storage, therefore, the height of the thermocline is effectively reduced, the utilization rate of the energy storage tank is greatly improved, and the energy storage efficiency of the energy storage tank is further improved;

in addition, in the practical application process, the size of the central turbulent flow cavity 1, the length of the first-stage distributor 2 and the length of each second-stage distribution pipe 31 of the second-stage distributor 3 can be adjusted by the hexagonal water distributor body 5 according to the diameter of the energy storage tank 6.

As shown in fig. 1-3: six distributor interfaces 11 are arranged on the central turbulent flow cavity 1, the six distributor interfaces 11 are distributed in an annular array, and the six distributor interfaces 11 correspond to the six primary distribution pipes 21 one by one. Specifically, when the primary distributor 2 is connected with the central turbulent flow cavity 1, a worker can connect one ends of six primary distribution pipes 21 with six distributor interfaces 11 respectively, so as to realize the quick installation of the primary distributor 2 and the central turbulent flow cavity 1.

As shown in fig. 1, 2 and 4: a plurality of connecting pipes are all installed to six one-level distributing pipe 21's both sides, and a plurality of connecting pipes all incline to set up. Specifically, when the water distributor is used, workers can connect two ends of the secondary distributor 3 with connecting pipes on two sides of the primary distributor 21 respectively, so that the connection between the secondary distributor 3 and the primary distributor 2 is realized; in addition, in this embodiment, both sides of the primary distribution pipe 21 are provided with 4 connecting pipes, but in the actual process, the number of the connecting pipes on both sides of the primary distribution pipe 21 can be specifically designed according to the actual requirement.

As shown in fig. 3: the hexagonal water distributor body 5 further comprises a quick connection assembly, the quick connection assembly comprises two second connection flanges 8 used for connecting the central turbulent flow cavity 1 with water inlet and outlet pipes of the energy storage tank 6, and the two second connection flanges 8 are respectively arranged at two ends of the central turbulent flow cavity 1. Specifically, when the hexagonal water distributor body 5 is installed in the energy storage tank 6, workers can connect two ends of the central turbulent flow cavity 1 with the water inlet and outlet pipes of the energy storage tank 6 through the second connecting flange 8, so that the hexagonal water distributor body 5 and the energy storage tank 6 can be installed quickly, the installation speed of the hexagonal water distributor body 5 is increased, and the hexagonal water distributor body 5 can be used conveniently.

As shown in fig. 5 and 6: the plurality of secondary distribution pipes 31 are all provided with dense water-permeable holes 4 of the water distributor. Specifically, when the water is conveyed into the secondary distribution pipe 31, the water is discharged through the dense water distributor permeable holes 4, so that the water is uniformly distributed, and the energy storage of the energy storage tank 6 is facilitated; in addition, in the practical application process, the aperture size and the distance of the water permeable holes 4 of the water distributor can be set according to the diameter of the energy storage tank 6 and the flow speed of the energy storage circulating pump.

As shown in fig. 1-4: the mounting assembly for connecting the primary distributor 2 with the central turbulent flow cavity 1 and the secondary distributor 3 respectively comprises a plurality of first connecting flanges 7, wherein the first connecting flanges 7 are arranged at the end parts of the connecting pipe, the distributor interface 11 and the secondary distribution pipe 31 respectively. Specifically, when the first-stage distributor 2 is respectively connected with the central turbulent flow cavity 1 and the second-stage distributor 3, workers can firstly connect the first-stage distributor 2 with the central turbulent flow cavity 1 through the first connecting flange 7 and then connect the second-stage distributor 3 with the first-stage distributor 2 through the first connecting flange 7, so that the hexagonal water distributor body 5 can be quickly assembled, the assembling efficiency of the hexagonal water distributor body 5 is effectively improved, and the hexagonal water distributor body 5 can be quickly used conveniently.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a hexagonal type water-locator that installation is convenient, locates in energy storage tank (6), its characterized in that: including hexagonal water-locator body (5), hexagonal water-locator body (5) include central turbulent flow chamber (1), one-level distributor (2), second grade distributor (3) and with one-level distributor (2) respectively with central turbulent flow chamber (1) and the installation component that second grade distributor (3) are connected, wherein: the primary distributor (2) comprises six primary distribution pipes (21), the six primary distribution pipes (21) are distributed outside the central turbulent flow cavity (1) in an annular array, and cavity grooves are formed between every two adjacent primary distribution pipes (21); secondary distributor (3) are equipped with six groups altogether, and every group secondary distributor (3) all include a plurality of secondary distribution pipe (31), and a plurality of secondary distribution pipe (31) distribute in by interior and outer successive layer in the chamber groove, every form the hexagon after secondary distribution pipe (31) in the chamber groove surround.

2. The hexagonal water distributor convenient and fast to install according to claim 1, is characterized in that: six distributor interfaces (11) are arranged on the central turbulent flow cavity (1), the six distributor interfaces (11) are distributed in an annular array, and the six distributor interfaces (11) correspond to the six primary distribution pipes (21) one by one.

3. The hexagonal water distributor convenient and fast to install according to claim 2, is characterized in that: and a plurality of obliquely arranged connecting pipes are arranged on two sides of the six primary distribution pipes (21).

4. The hexagonal water distributor convenient and fast to install according to claim 1, is characterized in that: the hexagonal water distributor body (5) further comprises a quick connection assembly, the quick connection assembly comprises two second connection flanges (8) used for connecting the central turbulent flow cavity (1) with water inlet and outlet pipes of the energy storage tank (6), and the two second connection flanges (8) are respectively arranged at two ends of the central turbulent flow cavity (1).

5. The hexagonal water distributor convenient and fast to install according to claim 1, is characterized in that: the plurality of secondary distribution pipes (31) are all provided with dense water-permeable holes (4) of the water distributor.

6. The hexagonal water distributor convenient and fast to install according to claim 3, is characterized in that: the mounting assembly comprises a first connecting flange (7), wherein the first connecting flange (7) is provided with a plurality of first connecting flanges (7) which are arranged at the ends of the connecting pipe, the distributor interface (11) and the secondary distribution pipe (31) respectively.

Images