CN206160268U - Multi -functional high temperature heat accumulation tank container - Google Patents

Abstract

The utility model provides a multi -functional high temperature heat accumulation tank container, be assembled between/be connected between heat storage heating jar in the container frame, it has heat storage medium to fill in the heat storage heating jar, the heat storage heating jar is provided with heat exchange line, heat - supply pipeline and safe pipeline, the heat source is connected through heat exchange line to the heat storage heating jar, last being provided with of heat exchange line can automatically controlled or manual two accuse imported valve, supply heat terminal is connected through heat - supply pipeline to the heat storage heating jar, last being provided with of heat - supply pipeline can automatically controlled or manual two accuse outlet valve, the heat storage heating jar is connected externally through safe pipeline, the bursting tube is provided with the safety -valve on the road, be provided with temperature sensor and pressure sensor in the heat storage heating jar, a weighing sensor and a temperature sensor, pressure sensor, two accuse imported valves and two accuse outlet valve difference signal connection the control unit. The beneficial effects of the utility model are that: the product suitability is high, has automation and manual control mode, can absorb multiple heat source, has multiple heat transfer, heat supply form.

Description

Multifunctional high-temperature heat-storage tank container

Technical Field

The utility model relates to a remove heat supply technical field, especially relate to a multi-functional high temperature heat accumulation jar formula container.

Background

The industrial waste heat resources in China are rich and mainly comprise high-temperature waste gas waste heat, cooling medium waste heat, waste steam waste water waste heat, high-temperature products, furnace slag waste heat, chemical reaction waste heat and the like, the waste heat resources account for 17% -67% of the total fuel consumption, the recovery rate can reach 60%, the waste heat utilization rate is large in lifting space, and the energy-saving potential is huge. The current waste heat resource is characterized in that the waste heat quantity is unstable due to periodicity, discontinuity or production fluctuation in the process production process. The waste heat medium nature is abominable, if the dust content is big or contain corrosive substance in the flue gas, waste heat utilization equipment receives the place, inherent condition restriction such as production situation, consequently industry waste heat resource utilization system or equipment operational environment are relatively abominable, require that equipment has the characteristic that the adaptability is strong and the steady operation, can adapt to changeable production technology requirement, equipment part reliability is high, initial investment cost is high, from economic nature, need combine technology production to carry out the holistic design of system and arrange, the comprehensive utilization energy, in order to improve the efficiency of waste heat utilization system equipment. At present, some industrial enterprises are not in the pipe network coverage range of heating power enterprises, coal-fired boilers, oil-fired boilers and gas-fired boilers are usually built by themselves, the boilers are low in operation efficiency and high in emission pollutant, the influence on the environment is large, and some enterprises adopt clean electric boilers for heat supply, but the heat supply cost is high. Therefore, the method for recovering the waste heat by adopting a heat supply mode of mobile heat storage and then providing the waste heat for industrial users is one of effective ways for solving the heat utilization dilemma of the industrial users. The ubiquitous heat transfer heat supply operation of the mobile heat storage heating device that appears at present is complicated, and the heat storage effect is relatively poor, heat exchange efficiency low grade problem.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a multi-functional high temperature heat storage tank container solves the problem that removes heat storage heating device heat transfer heat supply operation complicacy, the heat accumulation effect is relatively poor, heat exchange efficiency hangs down.

The utility model provides a multi-functional high temperature heat storage tank container, including the container frame, heat accumulation and supply jar and the control unit, assembly connection heat accumulation and supply jar in the container frame, it has the heat accumulation medium to fill in the heat accumulation and supply jar, the top of heat accumulation and supply jar is provided with the manhole, the surface parcel of heat accumulation and supply jar has the heat preservation, heat accumulation and supply jar is provided with heat transfer pipeline, heat supply pipeline and safety line, heat accumulation and supply jar connects the heat source through heat transfer pipeline, be provided with automatically controlled or manual two accuse inlet valves on the heat transfer pipeline, heat accumulation and supply jar connects the heat supply terminal through heat supply pipeline, be provided with automatically controlled or manual two accuse outlet valves on the heat supply pipeline, the heat supply jar is connected the external world through safety line, be provided with safety valve on the safety line, be provided with temperature sensor and pressure sensor in the heat accumulation and supply jar, The double-control inlet valve and the double-control outlet valve are respectively in signal connection with the control unit.

Furthermore, the heat source is clean hot fluid, the heat storage medium is clean fluid with the same chemical property as the clean hot fluid, the heat exchange pipeline comprises a main clean fluid heat exchange pipeline and a sub clean fluid heat exchange pipeline connected with the main clean fluid heat exchange pipeline, the main clean fluid heat exchange pipeline is connected with the clean hot fluid, a double-control inlet valve is arranged on the main clean fluid heat exchange pipeline, the sub clean fluid heat exchange pipeline is arranged in the heat storage and supply tank, and heat exchange holes are formed in the sub clean fluid heat exchange pipeline; the heat supply pipeline is a first heat supply pipeline, the first heat supply pipeline comprises a steam pipeline and a hot fluid pipeline, the steam pipeline and the hot fluid pipeline are respectively connected with a heat supply terminal, and double-control outlet valves are respectively arranged on the steam pipeline and the hot fluid pipeline.

Furthermore, the heat source also comprises an unclean hot fluid, the heat exchange pipeline also comprises a first unclean fluid heat exchange pipeline, the first unclean fluid heat exchange pipeline penetrates through the heat storage and supply tank, and the first unclean fluid heat exchange pipeline is provided with a double-control inlet valve.

Furthermore, the part of the first unclean fluid heat exchange pipeline in the heat storage and supply tank is distributed in a snake shape.

Furthermore, the heat source is clean hot fluid, the heat exchange pipeline and the heat supply pipeline share the same heat exchange and heat supply time-sharing multiplexing pipeline, a double-control inlet valve is arranged on the heat exchange and heat supply time-sharing multiplexing pipeline, the heat exchange and heat supply time-sharing multiplexing pipeline penetrates through the heat storage and heat supply tank, one end of the heat exchange and heat supply time-sharing multiplexing pipeline is connected with the clean hot fluid during heat exchange, one end of the heat exchange and heat supply time-sharing multiplexing pipeline is connected with the clean fluid during heat supply, and the other end of the heat exchange and heat supply time-sharing multiplexing pipeline is connected.

Furthermore, the parts of the heat exchange and heat supply time-sharing multiplexing pipelines in the heat storage and heat supply tank are distributed in a snake shape.

Furthermore, the heat source is an unclean hot fluid, the heat exchange pipeline is a second unclean fluid heat exchange pipeline, the second unclean fluid heat exchange pipeline penetrates through the heat storage and supply tank, a double-control inlet valve is arranged on the second unclean fluid heat exchange pipeline, and one end of the second unclean fluid heat exchange pipeline is connected with the unclean hot fluid; the heat supply pipeline is a second heat supply pipeline, the second heat supply pipeline penetrates through the heat storage and supply tank, a double-control inlet valve is arranged on the second heat supply pipeline, one end of the second heat supply pipeline is connected with the clean fluid, and the other end of the second heat supply pipeline is connected with the heat supply terminal.

Furthermore, the part of the second unclean fluid heat exchange pipeline in the heat storage and supply tank is distributed in a snake shape, and the part of the second heat supply pipeline in the heat storage and supply tank is distributed in a snake shape.

Further, the flow direction of the unclean hot fluid in the second unclean fluid heat exchange pipeline is opposite to the flow direction of the clean fluid in the second heat supply pipeline.

Further, the heat source is clean fluid or non-clean hot fluid, the heat storage medium is clean fluid, the heat exchange pipeline is a clean or non-clean fluid heat exchange pipeline, the clean or non-clean fluid heat exchange pipeline penetrates through the heat storage and supply tank, the clean or non-clean fluid heat exchange pipeline is connected with the clean fluid or the non-clean hot fluid, and a double-control inlet valve is arranged on the clean or non-clean fluid heat exchange pipeline; the heat supply pipeline is a first heat supply pipeline, the first heat supply pipeline comprises a steam pipeline and a hot fluid pipeline, the steam pipeline and the hot fluid pipeline are respectively connected with a heat supply terminal, and double-control outlet valves are respectively arranged on the steam pipeline and the hot fluid pipeline.

Compared with the prior art, the utility model discloses a multi-functional high temperature heat storage tank container has following characteristics and advantage:

1. the multifunctional high-temperature heat storage tank type container adopts the standardized container design, can be widely applied to various transportation modes conforming to the container, such as shipping, road transportation and the like, and improves the applicability of products;

2. the utility model discloses a multi-functional high temperature heat accumulation jar formula container has automatic and manual two kinds of control mode, and the automatic control mode is through pressure, temperature isoparametric preparation and release heat accumulation medium of different temperatures and pressure to simplify the operation of heat transfer heat supply, realizes the automatic control of heat transfer heat supply, and the manual control mode is that the manual control is controlled after the automatic control mode became invalid, in order to improve the factor of safety of heat transfer heat supply operation;

3. the utility model discloses a multi-functional high temperature heat accumulation tank formula container can adopt direct heat transfer in a flexible way, indirect heat transfer and the structural style who mixes the heat transfer, can absorb the heat source and be the waste heat of different kinds of high temperature fluids such as the waste heat of clean hot-fluid and non-clean hot-fluid for multi-functional high temperature heat accumulation tank formula container has stronger adaptability, and the heat storage capacity is big, and the cost of transportation is low, and the practicality is strong, provides high temperature high pressure heat accumulation medium or high temperature heat accumulation medium or normal atmospheric temperature medium or high temperature high pressure steam for heat supply terminal.

After reading the detailed description of the present invention in conjunction with the drawings, the features and advantages of the present invention will become more apparent.

Drawings

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

Fig. 1 is a schematic view of the overall structure of a multifunctional high-temperature heat storage tank container according to an embodiment of the present invention;

FIG. 2 is a schematic cross-sectional view of FIG. 1;

fig. 3 is a schematic structural view of a container frame of the multifunctional high-temperature heat storage tank type container in the embodiment of the present invention;

FIG. 4 is a schematic diagram of a direct heat exchange structure of a clean fluid in a heat storage and supply tank in a multifunctional high-temperature heat storage tank type container according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of a mixed heat exchange structure of a clean fluid and an unclean fluid of a heat storage and supply tank in a multifunctional high-temperature heat storage tank container according to an embodiment of the present invention;

FIG. 6 is a schematic diagram of an indirect heat exchange structure of a clean fluid of a heat storage and supply tank in a multifunctional high-temperature heat storage tank type container according to an embodiment of the present invention;

FIG. 7 is a schematic diagram of an indirect heat exchange structure of a non-clean fluid in a heat storage and supply tank in a multifunctional high-temperature heat storage tank type container according to an embodiment of the present invention;

fig. 8 is a schematic diagram of a clean or unclean fluid indirect heat exchange structure of a heat storage and supply tank in the multifunctional high-temperature heat storage tank type container in the embodiment of the utility model;

wherein,

1. the system comprises a container frame, 2, a heat storage and supply tank, 3, a control box, 4, a manhole, 5, a clean or unclean fluid heat exchange pipeline, 61, a clean fluid heat exchange main pipeline, 62, a clean fluid heat exchange branch pipeline, 71, a steam pipeline, 72, a hot fluid pipeline, 8, a safety valve, 9, a double-control inlet valve, 10, a double-control outlet valve, 11, a first unclean fluid heat exchange pipeline, 12, a heat exchange and heat supply time-sharing multiplexing pipeline, 13, a second unclean fluid heat exchange pipeline, 14, a second heat supply pipeline, 15 and a liquid baffle plate.

Detailed Description

Example 1

As shown in fig. 1 to 4, the present embodiment provides a multifunctional high-temperature heat storage tank container, wherein a heat storage and supply tank 2 is assembled and connected in a container frame 1, the heat storage and supply tank 2 is made of high-quality Q235B carbon steel/Q245R, 345R manganese steel/S30408, S31608 stainless steel and other materials, and the heat storage and supply tank 2 is filled with a heat storage medium, which includes water, saturated water, steam or phase change energy storage materials, for example. The top of the heat storage and supply tank 2 is provided with a manhole 4, and maintenance personnel can enter the heat storage and supply tank 2 through the manhole 4 to perform maintenance work. The outer surface of the heat storage and supply tank 2 is wrapped with a heat preservation layer for preserving heat of the heat storage and supply tank 2. The upper part of the inner wall of the heat storage and supply tank 2 is fixedly connected with a liquid baffle plate 15 in the vertical direction, so that the impact of a heat storage medium in the heat storage and supply tank 2 is reduced in the transportation process, and the transportation safety is improved. The heat source in this embodiment is clean hot fluid, such as clean waste hot water, the heat storage medium is clean water, the heat exchange pipeline includes a main clean fluid heat exchange pipeline 61 and a sub clean fluid heat exchange pipeline 62 connected to the main clean fluid heat exchange pipeline 61, the main clean fluid heat exchange pipeline 61 is connected to the clean hot fluid of the heat source, the main clean fluid heat exchange pipeline 61 is provided with an electrically or manually controllable double-control inlet valve 9, the sub clean fluid heat exchange pipeline 62 is disposed in the heat storage and supply tank 2, and the sub clean fluid heat exchange pipeline 62 is provided with heat exchange holes. The heat supply pipeline is a first heat supply pipeline, the first heat supply pipeline comprises a steam pipeline 71 and a hot fluid pipeline 72, the steam pipeline 71 and the hot fluid pipeline 72 are respectively connected with a heat supply terminal, and the steam pipeline 71 and the hot fluid pipeline 72 are respectively provided with an electrically-controlled or manually-controlled double-control outlet valve 10. The heat storage and supply tank 2 is connected with the outside through a safety pipeline, and a safety valve 8 is arranged on the safety pipeline. A temperature sensor and a pressure sensor are arranged in the heat storage and supply tank 2, the temperature sensor, the pressure sensor, the double-control inlet valve 9 and the double-control outlet valve 10 are respectively in signal connection with a control unit formed by a single chip microcomputer and the like, the control unit is arranged in a control box 3, and the control box 3 is assembled and installed at the rear part of the heat storage and supply tank 2.

The heat exchange and supply processes of the multifunctional high-temperature heat storage tank container in the embodiment are as follows: during heat exchange, after the main clean fluid heat exchange pipeline 61 is connected with the clean waste hot water, an operator controls the double-control inlet valve 9 to be opened through the control unit in the operation control box 3, the clean waste hot water enters the clean fluid heat exchange branch pipeline 62 through the main clean fluid heat exchange pipeline 61, and the clean waste hot water enters the heat storage and supply tank 2 through the heat exchange holes, so that a heat storage medium (water) in the heat storage and supply tank 2 is heated. The control unit controls whether the double-control inlet valve 9 is closed or not through monitoring of the temperature sensor and the pressure sensor, so that the heat storage medium (water) is heated into a high-temperature high-pressure heat storage medium (the temperature can reach 500 ℃ and the pressure can reach 10MPa) or a high-temperature heat storage medium or normal-temperature hot water; during heat supply, an operator controls the double-control outlet valve 10 on the hot fluid pipeline 72 to be opened by operating the control unit in the control box 3 and provides hot water with different temperatures for the heat supply terminal according to monitoring of the temperature sensor, and controls the double-control outlet valve 10 on the steam pipeline 71 to be opened by operating the control unit in the control box 3 and provides high-temperature and high-pressure steam (the high temperature can reach 260 ℃ and the high pressure can reach 5MPa) for the heat supply terminal according to monitoring of the temperature sensor. The multifunctional high-temperature heat storage tank container in the embodiment has two control modes of automatic control and manual control, in the automatic control mode, the control unit in the operation control box 3 controls the on or off of the double-control inlet valve 9 and the double-control outlet valve 10 according to temperature and pressure parameters monitored by the temperature sensor and the pressure sensor so as to prepare and release heat storage media with different temperatures and pressures, so that the traditional heat exchange and heat supply operations are simplified, and the automatic control of heat exchange and heat supply is realized; and in the manual control mode, the double-control inlet valve 9 and the double-control outlet valve 10 are manually opened or closed after the automatic control mode fails, so that the safety coefficient of heat exchange and heat supply operation is improved.

Example 2

As shown in fig. 5, the present embodiment is different from embodiment 1 in that the heat source may further include an unclean thermal fluid, the unclean thermal fluid may be hot air, hot flue gas, hot water with impurities, or hot steam, the heat exchange pipeline further includes a first unclean fluid heat exchange pipeline 11, the first unclean fluid heat exchange pipeline 11 passes through the thermal storage and heat supply tank 2, an electrically or manually controllable dual-control inlet valve 9 is disposed on the first unclean fluid heat exchange pipeline 11, the dual-control inlet valve 9 on the first unclean fluid heat exchange pipeline 11 is controlled by operating a control unit in the control box 3 according to temperature and pressure parameters monitored by a temperature sensor and a pressure sensor, the unclean thermal fluid enters the first unclean fluid heat exchange pipeline 11 to heat the thermal storage medium in the thermal storage and heat supply tank 2 to a high-temperature high-pressure thermal storage medium or a high-temperature thermal storage medium or a normal-temperature thermal storage medium, and controls the double-control inlet valve 9 to provide a high-temperature high-pressure heat storage medium or a high-temperature heat storage medium or a normal-temperature heat storage medium, controls the double-control outlet valve 10 to be opened, and provides high-temperature high-pressure steam for the heat supply terminal according to the monitoring of the temperature sensor. The first unclean fluid heat exchange pipeline 11 is distributed in a serpentine shape in the heat storage and supply tank 2 to enhance the heat exchange between the unclean hot fluid and the heat storage medium in the heat storage and supply tank 2.

Example 3

As shown in fig. 6, the present embodiment is different from embodiment 1 in that the heat source is only clean hot fluid, the heat exchange pipeline and the heat supply pipeline share the same heat exchange and heat supply time-sharing multiplexing pipeline 12, the double-control inlet valve 9 is disposed on the heat exchange and heat supply time-sharing multiplexing pipeline 12, and the heat exchange and heat supply time-sharing multiplexing pipeline 12 passes through the heat storage and heat supply tank 2. According to the temperature and pressure parameters in the heat storage and supply tank 2 monitored by the temperature sensor and the pressure sensor, the control unit in the control box 3 is operated to control the on-off of the double-control inlet valve 9 on the heat exchange and supply time-sharing multiplexing pipeline 12 so as to prepare and release a high-temperature high-pressure heat storage medium or a high-temperature heat storage medium or a normal-temperature heat storage medium. The heat exchange and heat supply time-sharing multiplexing pipeline is distributed in a serpentine shape in the heat storage and supply tank to enhance the heat exchange between the clean hot fluid and the heat storage medium in the heat storage and supply tank 2. During heat exchange, one end of the heat exchange and supply time-sharing multiplexing pipeline 12 is connected with a clean hot fluid, and the clean hot fluid enables a heat storage medium in the heat storage and supply tank 2 to absorb heat and store heat. When supplying heat, one end of the heat exchange and supply time-sharing multiplexing pipeline 12 is connected with a clean fluid, the clean fluid flows through the heat supply tank 3 and is heated by a heat storage medium, the other end of the heat exchange and supply time-sharing multiplexing pipeline 12 is connected with a heat supply terminal, and the heated clean fluid flows out from the other end of the heat exchange and supply time-sharing multiplexing pipeline 12 for users to use. At this time, the heat storage medium in the heat storage and supply tank 2 includes, for example, water, saturated water, steam, or a phase change energy storage material, and does not have to be the same as the chemical property of the clean hot fluid.

Example 4

As shown in fig. 7, the present embodiment is different from embodiment 1 in that the heat source is an unclean thermal fluid, the unclean thermal fluid may be hot air, hot flue gas, hot water with impurities, or hot steam, the heat exchange pipeline is a second unclean fluid heat exchange pipeline 13, the second unclean fluid heat exchange pipeline 13 passes through the thermal storage and supply tank 2, the second unclean fluid heat exchange pipeline 13 is provided with a dual-control inlet valve 9, and one end of the second unclean fluid heat exchange pipeline 13 is connected to the unclean thermal fluid; the heat supply pipeline is a second heat supply pipeline 14, the second heat supply pipeline 14 penetrates through the heat storage and supply tank 2, a double-control inlet valve 9 is arranged on the second heat supply pipeline 14, one end of the second heat supply pipeline 14 is connected with the clean fluid, and the other end of the second heat supply pipeline 14 is connected with the heat supply terminal. The control unit in the control box 3 is operated to control the on-off of the double-control inlet valves 9 on the second unclean fluid heat exchange pipeline 13 and the second heat supply pipeline 14 so as to prepare and release a high-temperature high-pressure heat storage medium or a high-temperature heat storage medium or a normal-temperature heat storage medium. During heat exchange, the second unclean fluid heat exchange pipeline 13 of the unclean hot fluid enters the heat storage and supply tank 2, the heat storage medium in the heat storage and supply tank 2 is heated, the clean fluid enters the heat storage and supply tank 2 through the second heat supply pipeline 14, the clean fluid is heated, and the heated clean fluid is supplied to a heat supply terminal of a user from the other end of the second heat supply pipeline 14. The unclean hot fluid in the second unclean fluid heat exchange pipeline 13 may be exchanged with the heat storage medium in the heat storage and supply tank 2, or the clean fluid may enter the heat storage and supply tank 2 to absorb heat in the second heat supply pipeline 14 during the above two heat exchange processes. The parts of the second unclean fluid heat exchange pipeline 13 in the heat storage and supply tank 2 are distributed in a serpentine shape, the parts of the second heat supply pipeline 14 in the heat storage and supply tank 2 are distributed in a serpentine shape, and the flowing direction of the unclean hot fluid in the second unclean fluid heat exchange pipeline 13 is opposite to the flowing direction of the clean fluid in the second heat supply pipeline 14, so as to enhance the heat exchange between the unclean hot fluid and the heat storage medium in the heat storage and supply tank 2 and the clean fluid in the second heat supply pipeline 14.

Example 5

As shown in fig. 8, the present embodiment is different from embodiment 1 in that the heat source may be a clean fluid or a non-clean thermal fluid, the clean thermal fluid may be clean waste hot water, the non-clean thermal fluid may be hot air, hot flue gas, hot water with impurities, or hot steam, and the heat storage medium may be a clean fluid and may be domestic water. The heat exchange pipeline is a clean or non-clean fluid heat exchange pipeline 5, the clean or non-clean fluid heat exchange pipeline 5 penetrates through the heat storage and supply tank 2, the clean or non-clean fluid heat exchange pipeline 5 is connected with clean fluid or non-clean hot fluid, and a double-control inlet valve 9 is arranged on the clean or non-clean fluid heat exchange pipeline 5; the heat supply pipeline is a first heat supply pipeline, the first heat supply pipeline comprises a steam pipeline 71 and a hot fluid pipeline 72, the steam pipeline 71 and the hot fluid pipeline 72 are respectively connected with a heat supply terminal, and the steam pipeline 71 and the hot fluid pipeline 72 are respectively provided with a double-control outlet valve 10. According to the temperature and pressure parameters monitored by the temperature sensor and the pressure sensor, the double-control inlet valve 9 on the clean or non-clean fluid heat exchange pipeline 5 is controlled by operating the control unit in the control box 3, the clean or non-clean hot fluid enters the clean or non-clean fluid heat exchange pipeline 5, the heat storage medium in the heat storage and supply tank 2 is heated to the high-temperature high-pressure heat storage medium or the high-temperature heat storage medium or the normal-temperature heat storage medium, the double-control outlet valve 10 is controlled to be opened, and the high-temperature high-pressure steam is supplied to the heat supply terminal according to the monitoring of the temperature. The part of the clean or unclean fluid heat exchange pipeline 5 in the heat storage and supply tank 2 is distributed in a serpentine shape to enhance the heat exchange between the unclean hot fluid and the heat storage medium in the heat storage and supply tank 2.

Of course, the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and the changes, modifications, additions or substitutions made by those skilled in the art within the scope of the present invention should also belong to the protection scope of the present invention.

Claims (10)

1. The utility model provides a multi-functional high temperature heat accumulation jar formula container which characterized in that: comprises a container frame, a heat storage and supply tank and a control unit, wherein the container frame is internally assembled and connected with the heat storage and supply tank, the heat storage and supply tank is filled with a heat storage medium, the top of the heat storage and supply tank is provided with a manhole, the outer surface of the heat storage and supply tank is wrapped with a heat insulation layer, the heat storage and supply tank is provided with a heat exchange pipeline, a heat supply pipeline and a safety pipeline, the heat storage and supply tank is connected with a heat source through the heat exchange pipeline, the heat exchange pipeline is provided with an electrically or manually controlled double-control inlet valve, the heat storage and supply tank is connected with a heat supply terminal through the heat supply pipeline, the heat supply pipeline is provided with an electrically or manually controlled double-control outlet valve, the heat storage and supply tank is connected with the outside through the safety, the pressure sensor, the double-control inlet valve and the double-control outlet valve are respectively in signal connection with the control unit.

2. The multi-functional high-temperature heat storage tank container of claim 1, wherein: the heat source is clean hot fluid, the heat storage medium is clean fluid with the same chemical property as the clean hot fluid, the heat exchange pipeline comprises a main clean fluid heat exchange pipeline and a sub clean fluid heat exchange pipeline connected with the main clean fluid heat exchange pipeline, the main clean fluid heat exchange pipeline is connected with the clean hot fluid, a double-control inlet valve is arranged on the main clean fluid heat exchange pipeline, the sub clean fluid heat exchange pipeline is arranged in the heat storage and supply tank, and heat exchange holes are formed in the sub clean fluid heat exchange pipeline; the heat supply pipeline is a first heat supply pipeline, the first heat supply pipeline comprises a steam pipeline and a hot fluid pipeline, the steam pipeline and the hot fluid pipeline are respectively connected with a heat supply terminal, and double-control outlet valves are respectively arranged on the steam pipeline and the hot fluid pipeline.

3. The multi-functional high-temperature heat storage tank container of claim 2, wherein: the heat source further comprises an unclean hot fluid, the heat exchange pipeline further comprises a first unclean fluid heat exchange pipeline, the first unclean fluid heat exchange pipeline penetrates through the heat storage and supply tank, and a double-control inlet valve is arranged on the first unclean fluid heat exchange pipeline.

4. The multifunctional high-temperature thermal storage tank container according to claim 3, characterized in that: the first unclean fluid heat exchange pipeline is distributed in a serpentine shape in the heat storage and supply tank.

5. The multi-functional high-temperature heat storage tank container of claim 1, wherein: the heat source is clean hot fluid, the heat exchange pipeline and the heat supply pipeline share the same heat exchange and heat supply time-sharing multiplexing pipeline, a double-control inlet valve is arranged on the heat exchange and heat supply time-sharing multiplexing pipeline, the heat exchange and heat supply time-sharing multiplexing pipeline penetrates through the heat storage and heat supply tank, one end of the heat exchange and heat supply time-sharing multiplexing pipeline is connected with the clean hot fluid during heat exchange, one end of the heat exchange and heat supply time-sharing multiplexing pipeline is connected with the clean fluid during heat supply, and the other end of the heat exchange and heat supply time-sharing multiplexing pipeline.

6. The multi-functional high-temperature heat storage tank container of claim 5, wherein: the heat exchange and supply time-sharing multiplexing pipeline is distributed in a snake shape in the heat storage and supply tank.

7. The multi-functional high-temperature heat storage tank container of claim 1, wherein: the heat source is an unclean hot fluid, the heat exchange pipeline is a second unclean fluid heat exchange pipeline, the second unclean fluid heat exchange pipeline penetrates through the heat storage and supply tank, a double-control inlet valve is arranged on the second unclean fluid heat exchange pipeline, and one end of the second unclean fluid heat exchange pipeline is connected with the unclean hot fluid; the heat supply pipeline is a second heat supply pipeline, the second heat supply pipeline penetrates through the heat storage and supply tank, a double-control inlet valve is arranged on the second heat supply pipeline, one end of the second heat supply pipeline is connected with the clean fluid, and the other end of the second heat supply pipeline is connected with the heat supply terminal.

8. The multi-functional high-temperature heat storage tank container of claim 7, wherein: the part of the second unclean fluid heat exchange pipeline in the heat storage and supply tank is distributed in a snake shape, and the part of the second heat supply pipeline in the heat storage and supply tank is distributed in a snake shape.

9. The multi-functional high-temperature heat storage tank container of claim 7, wherein: the flow direction of the unclean hot fluid in the second unclean fluid heat exchange pipeline is opposite to the flow direction of the clean fluid in the second heat supply pipeline.

10. The multi-functional high-temperature heat storage tank container of claim 1, wherein: the heat source is clean fluid or non-clean hot fluid, the heat storage medium is clean fluid, the heat exchange pipeline is a clean or non-clean fluid heat exchange pipeline, the clean or non-clean fluid heat exchange pipeline penetrates through the heat storage and supply tank and is connected with the clean fluid or the non-clean hot fluid, and a double-control inlet valve is arranged on the clean or non-clean fluid heat exchange pipeline; the heat supply pipeline is a first heat supply pipeline, the first heat supply pipeline comprises a steam pipeline and a hot fluid pipeline, the steam pipeline and the hot fluid pipeline are respectively connected with a heat supply terminal, and double-control outlet valves are respectively arranged on the steam pipeline and the hot fluid pipeline.