CN219551286U - Energy storage container provided with temperature gradiometer - Google Patents

Abstract

The utility model discloses an energy storage container provided with a temperature gradiometer, which comprises a container and a container cover arranged at the upper part of the container, wherein a sinking type temperature gradiometer is fixedly arranged at the inner bottom of the container, an upward floating type temperature gradiometer floats on the water surface in the container, the sinking type temperature gradiometer comprises a first vibrating arm communicated with a low-temperature medium inlet pipe and a first decompression cavity communicated with the first vibrating arm, the upward floating type temperature gradiometer comprises a second vibrating arm communicated with a high-temperature medium inlet pipe, a second decompression cavity communicated with the second vibrating arm and a buoyancy bag arranged at the upper side outside the second decompression cavity, both sides of the first decompression cavity and the second decompression cavity are steady flow openings, and a buffer net is arranged at the steady flow openings. The utility model has the advantages of simple structure, simple and convenient installation and easy operation, reduces disturbance of the exchange medium in the storage container, and improves the heat exchange efficiency of the equipment and the heat utilization efficiency.

Description

Energy storage container provided with temperature gradiometer

Technical Field

The utility model relates to the field of energy storage containers, in particular to an energy storage container provided with a temperature gradiometer.

Background

In the current energy storage container, a flow guide pipe is generally adopted to enable a low-temperature medium entering the container to enter the bottom of the container and a high-temperature medium to enter the top of the volume. However, the prior honeycomb duct technology has the following disadvantages: 1) The medium enters the container through the guide pipe, and the medium can generate different degrees of disturbance on surrounding medium due to gravity impact, so that the stability of temperature layering of the medium is forced to be damaged; 2) Once the layers are disturbed, the water temperature for taking changes, and the heating efficiency or the heating effect is affected.

Disclosure of Invention

The utility model aims to solve the technical problem of providing the energy storage container with the temperature gradiometer, solving the problem of mixing different temperature layers caused by gravity impact of media in the energy storage container, reducing disturbance of exchange media in the storage container, improving heat exchange efficiency of equipment and improving heat utilization efficiency.

In order to solve the technical problems, the utility model adopts the following technical scheme: the utility model provides an energy storage container with temperature gradiometer, includes the container and sets up in the container lid on container upper portion, the fixed formula temperature gradiometer that is provided with in container inner bottom, the floating formula temperature gradiometer that floats on the surface of water in the container, the formula temperature gradiometer that floats includes with advance the first vibrating arm of low temperature medium pipe intercommunication and with the first decompression chamber of first vibrating arm intercommunication, the formula temperature gradiometer that floats includes with advance the second vibrating arm of high temperature medium pipe intercommunication, with the second decompression chamber of second vibrating arm intercommunication and set up in the buoyancy bag of the outside upside of second decompression chamber, the both sides in first decompression chamber and second decompression chamber are the stationary flow mouth, the buffering net is installed to stationary flow mouth department.

The technical scheme of the utility model is further improved as follows: the rear side surfaces of the first decompression cavity and the second decompression cavity are welded with interfaces respectively communicated with the first decompression cavity and the second decompression cavity, the interfaces are of external thread structures, and the first vibrating arms and the second vibrating arms are in threaded connection with the interfaces and are sealed at the joints.

The technical scheme of the utility model is further improved as follows: the buoyancy bag is connected with the second decompression cavity by adopting a clamp.

The technical scheme of the utility model is further improved as follows: the bottom of the first decompression cavity is fixedly provided with a support, and the support is fixedly connected with the bottom of the container.

The technical scheme of the utility model is further improved as follows: the first decompression cavity, the second decompression cavity and the interface are all made of stainless steel.

The technical scheme of the utility model is further improved as follows: the first vibrating arm, the second vibrating arm, the low-temperature medium inlet pipe and the high-temperature medium inlet pipe are all high-temperature resistant hoses.

By adopting the technical scheme, the utility model has the following technical progress:

the utility model has simple structure, simple installation and easy operation, solves the problem of mixing of different temperature layering caused by gravity impact of the medium in the energy storage container, sets the sinking type temperature gradiometer and the floating type temperature gradiometer according to different water inlet temperatures, ensures that the temperature gradiometer and the floating type temperature gradiometer are positioned at different heights in the energy storage container, and low-temperature medium enters the bottom of the energy storage container and high-temperature medium enters the top of the energy storage container, when the medium flows in, enters the decompression cavity through the interface through the swinging arm, after the medium is decompressed in the decompression cavity, the medium transversely and stably flows out through the steady flow ports at the two sides of the decompression cavity, the medium transversely and stably flows out, the water layer disturbance of the medium in the container is not caused, and the gravity impact of the medium is reduced, so that the temperature layering in the container is relatively stable, the disturbance of the circulating water outlet flow speed in the container is reduced by 0.1-0. 0.2 m/s is realized, the disturbance of the exchange medium in the storage container is reduced, the heat exchange efficiency of the equipment is improved, and the heat utilization efficiency is improved.

Drawings

FIG. 1 is a schematic view of the overall structure of the present utility model;

FIG. 2 is a front view of the structure of the submerged temperature gradiometer of the present utility model;

FIG. 3 is a front view of the structure of the floating temperature gradiometer of the present utility model;

FIG. 4 is a side view of the floating temperature gradiometer of the present utility model;

the device comprises a container, a sinking type temperature gradiometer, a floating type temperature gradiometer, a low-temperature medium inlet pipe, a first vibrating arm, a first decompression cavity, a high-temperature medium inlet pipe, a second vibrating arm, a second decompression cavity, a buoyancy bag, a buffer net, a connector, a support, a container cover and a container cover, wherein the container is 1, the container is 2, the sinking type temperature gradiometer, the floating type temperature gradiometer is 3, the floating type temperature gradiometer is 4, the low-temperature medium inlet pipe is 5, the first vibrating arm is 6, the first decompression cavity is 7, the high-temperature medium inlet pipe is 8, the second vibrating arm is 9, the second decompression cavity is 10, the buoyancy bag is 11, the buffer net is 12, the connector is 13, the support is 14, and the container cover.

Detailed Description

The utility model is further illustrated by the following examples:

as shown in fig. 1, the energy storage container with the temperature gradiometer comprises a container 1 and a container cover 14 arranged at the upper part of the container 1, wherein according to different water inlet temperatures, a sinking type temperature gradiometer 2 is fixedly arranged at the bottom of the container 1, an upward floating type temperature gradiometer 3 floats on the water surface in the container 1, as shown in fig. 2, the sinking type temperature gradiometer 2 comprises a first vibrating arm 5 communicated with a low-temperature medium inlet pipe 4 and a first decompression cavity 6 communicated with the first vibrating arm 5, a bracket 13 is fixedly arranged at the bottom of the first decompression cavity 6, and the bracket 13 is fixedly connected with the bottom of the container 1. As shown in fig. 3-4, the floating temperature gradiometer 3 comprises a second vibrating arm 8 communicated with a high-temperature medium inlet pipe 7, a second decompression cavity 9 communicated with the second vibrating arm 8, and a buoyancy bag 10 arranged on the upper outer side of the second decompression cavity 9, wherein the buoyancy bag 10 is connected with the second decompression cavity 9 through a clamp. The floating temperature gradiometer 3 floats on the water surface through the buoyancy bladder 10.

The both sides of first decompression chamber 6 and second decompression chamber 9 are the stationary flow mouth, and the stationary flow mouth department installs buffer network 11, and the medium of being convenient for entering can transversely steadily flow out. The rear side surfaces of the first decompression cavity 6 and the second decompression cavity 9 are welded with interfaces 12 which are respectively communicated with the first decompression cavity 6 and the second decompression cavity 9, the first decompression cavity 6, the second decompression cavity 9 and the interfaces 12 are made of stainless steel, the stainless steel is not easy to rust, and the water quality is kept clean. The interface 12 is of an external thread structure, the first vibrating arm 5 and the second vibrating arm 8 are in threaded connection with the interface 12, and the joint is sealed, so that water leakage at the joint is avoided, and medium in the energy storage container is disturbed. The first vibrating arm 5, the second vibrating arm 8, the low-temperature medium inlet pipe 4 and the high-temperature medium inlet pipe 7 are all high-temperature resistant hoses, so that the service life is prolonged.

The low-temperature medium enters the bottom of the energy storage container through the sinking type temperature gradiometer 2, the high-temperature medium enters the upper layer of the water surface of the energy storage container through the floating type temperature gradiometer 3, no matter the low-temperature medium or the high-temperature medium flows in, the medium enters the decompression cavity through the interface through the swinging arm, after being decompressed in the decompression cavity, the medium flows out transversely and stably through the steady flow ports at the two sides of the decompression cavity, the flowing-out medium flows out transversely and stably, the medium in the container 1 is not disturbed, the gravity impact of the medium is reduced, the relative stability of the temperature layering in the container is kept, the circulation water flow rate is reduced to 0.1-0.2 m/s stably, the disturbance of the exchange medium in the container is reduced to the greatest extent, and the effects of improving the heat exchange efficiency and the heat utilization efficiency of the equipment are improved.

Claims (6)

1. The utility model provides an energy storage container with temperature gradiometer, includes container (1) and sets up in container lid (14) on container (1) upper portion, its characterized in that: the utility model provides a thermal gradient appearance (2) of floating in fixed being provided with in container (1), the surface of water come-up in container (1) has floating temperature gradient appearance (3), floating temperature gradient appearance (2) include with advance first vibrating arm (5) of low temperature medium pipe (4) intercommunication and with first decompression chamber (6) of first vibrating arm (5) intercommunication, floating temperature gradient appearance (3) include with advance second vibrating arm (8) of high temperature medium pipe (7) intercommunication, with second decompression chamber (9) of second vibrating arm (8) intercommunication and buoyancy bag (10) of setting in second decompression chamber (9) outside upside, the both sides in first decompression chamber (6) and second decompression chamber (9) are the stationary flow mouth, buffering net (11) are installed to stationary flow mouth department.

2. An energy storage container provided with a temperature gradiometer according to claim 1, wherein: the novel vibrating device is characterized in that interfaces (12) which are respectively communicated with the first decompression cavity (6) and the second decompression cavity (9) are welded on the rear side surfaces of the first decompression cavity (6) and the second decompression cavity (9), the interfaces (12) are of external thread structures, and the first vibrating arms (5) and the second vibrating arms (8) are in threaded connection with the interfaces (12) and are subjected to sealing treatment at joints.

3. An energy storage container provided with a temperature gradiometer according to claim 1, wherein: the buoyancy bag (10) is connected with the second decompression cavity (9) through a clamp.

4. An energy storage container provided with a temperature gradiometer according to claim 1, wherein: the bottom of the first decompression cavity (6) is fixedly provided with a bracket (13), and the bracket (13) is fixedly connected with the bottom of the container (1).

5. An energy storage container provided with a temperature gradiometer according to claim 2, wherein: the first decompression cavity (6), the second decompression cavity (9) and the interface (12) are made of stainless steel.

6. An energy storage container provided with a temperature gradiometer according to claim 1, wherein: the first vibrating arm (5), the second vibrating arm (8), the low-temperature medium inlet pipe (4) and the high-temperature medium inlet pipe (7) are all high-temperature resistant hoses.