CN214536405U - Steam pipeline system for outer net gas supply - Google Patents

Abstract

The utility model discloses a steam piping system of outer net air feed, mainly relate to steam piping system technical field, including heat source, end user and transmission line, the transmission line sets up between heat source and heating user, still utilize the unit including the transmission, supplementary heat source unit and supplementary heat source utilize the unit, the transmission utilizes the unit, supplementary heat source unit and supplementary heat source utilize the equal interval of unit to set up on the transmission line, the transmission utilizes the unit to include cold water pipe box, heat preservation storage water tank two and hot water supply system two, supplementary heat source unit includes solar panel, solar collector and supplementary heat source pipe case one. The utility model discloses be provided with transmission utilization unit, auxiliary heat source unit and auxiliary heat source utilization unit on the transmission pipeline, steam transmission process's waste heat utilization adopts the cold water pipe absorption of winding on the pipeline in the condenser tube case and derives through the hot water pipeline and carry out follow-up hot water utilization, simple structure, auxiliary heat source waste heat utilization solar energy, environmental protection emission reduction, low carbon economy.

Description

Steam pipeline system for outer net gas supply

Technical Field

The utility model relates to a steam piping system, especially a steam piping system of outer net air feed.

Background

The steam pipeline system is a system for supplying heat in a steam form through a pipeline, particularly a system for supplying heat in a city central heating system by taking water as a heating medium, carrying heat from a heat source in the form of steam and supplying the heat to users through a heat supply network. The steam heating system is conveyed by the pressure of steam, and has the advantages and disadvantages: the heat requirement for various process production is easily met; the specific gravity of the steam is small, so that excessive static pressure cannot be generated in a high-rise building; the flow rate in the pipe is greater than that of water; the heating system is easy to start quickly; the heat transfer efficiency in the heat exchange equipment is high; however, heat energy loss of the steam is high in the conveying process, and in addition, waste heat cannot be fully utilized, so that the design of a steam pipeline system for supplying air through an external net is very necessary for matching with the energy storage requirement of compressed air.

SUMMERY OF THE UTILITY MODEL

The utility model provides a steam pipe system of outer net air feed has solved the steam that exists among the above-mentioned prior art more and the problem that the waste heat is not effectively utilized of heat loss in transportation process.

The utility model discloses a solve the technical scheme that above-mentioned technical problem adopted and be: the solar heat-source heat-preserving system comprises a heat source, an end user and a transmission pipeline, wherein the transmission pipeline is arranged between the heat source and a heating user, the solar heat-preserving system also comprises a transmission utilization unit, an auxiliary heat source unit and an auxiliary heat source utilization unit, the transmission utilization unit, the auxiliary heat source unit and the auxiliary heat source utilization unit are arranged on the transmission pipeline at intervals, the transmission utilization unit comprises a cold water pipe box, a heat-preserving water storage box II and a hot water supply system II, the cold water pipe box is communicated with the heat-preserving water storage box through a pipeline, the heat-preserving water storage box II is communicated with the hot water supply system through a pipeline, the auxiliary heat source unit comprises a solar panel, a solar heat collector and an auxiliary heat source pipe box I, the solar heat collector is arranged between the solar panel and the auxiliary heat source pipe box II, the auxiliary heat source pipe box II is communicated with the heat preservation water storage tank I through a pipeline, and the heat preservation water storage tank I is communicated with the hot water supply system through a pipeline.

In order to economically benefit the waste heat of the steam pipeline, the cold water pipeline box comprises a first shell, a first cold water pipeline, a second cold water pipeline and a second hot water pipeline, the first shell is arranged on the periphery of the first cold water pipeline, the first cold water pipeline is wound on a transmission pipeline, one end of the first cold water pipeline is communicated with the second cold water pipeline, the other end of the first cold water pipeline is communicated with the second hot water pipeline, and the second hot water pipeline is communicated with an inlet of the second heat preservation water storage tank.

In order to compensate the heat loss of the steam pipeline in the transmission process, the auxiliary heat source pipe box I comprises a second shell and a second cold water pipe, the second shell is arranged on the periphery of the second cold water pipe, the second cold water pipe is wound on the transmission pipeline, the second cold water pipe is connected with the solar heat collector, and the second cold water pipe is filled with cold water and two ends of the second cold water pipe are plugged.

In order to utilize waste heat generated by solar energy assistance, the auxiliary heat source pipe box II comprises a third shell, a third cold water pipe, a first cold water pipe and a first hot water pipe, the third shell is arranged on the periphery of the third cold water pipe, the third cold water pipe is wound on a transmission pipeline, the third cold water pipe is connected with the solar heat collector, one end of the third cold water pipe is communicated with the first cold water pipe, the other end of the third cold water pipe is communicated with the first hot water pipe, and the first hot water pipe is communicated with an inlet of the first heat preservation water storage tank.

In order to realize multi-level hot water utilization, the hot water supply system comprises a hot water system for the surrounding plant area and a heating system for the surrounding residential district, and the hot water supply system comprises a hot water system for the surrounding plant area and a heating system for the surrounding residential district.

In order to utilize the waste heat more efficiently, the first cold water pipe, the second cold water pipe and the third cold water pipe are spirally wound in the radial direction or are wound on the transmission pipeline in the axial direction in an S shape.

The utility model adopts the above structure, following advantage has: the transmission pipeline is provided with a transmission utilization unit, an auxiliary heat source unit and an auxiliary heat source utilization unit, and the transmission utilization unit is used for carrying out waste heat utilization on a large amount of heat energy generated in the steam transmission process; the auxiliary heat source unit absorbs the energy of the sun through the solar panel, collects solar radiation through the solar heat collector and converts the solar radiation into heat energy, and the heat energy is used for compensating the heat loss of the steam in the steam pipeline in the transmission process by heating the water in the water pipe wound on the pipeline; the auxiliary heat source utilization unit absorbs the energy of the sun through the solar panel, collects solar radiation through the solar heat collector and converts the solar radiation into heat energy, part of the heat energy is used for compensating the heat loss of steam in the steam pipeline in the transmission process, and part of the heat energy is led out through the hot water pipeline for waste heat utilization; the cold water pipe wound on the pipeline in the cooling water pipe box is adopted for absorbing the waste heat in the steam transmission process and the waste heat is led out through the hot water pipeline for subsequent hot water utilization, the structure is simple, the solar energy is utilized by the aid of the waste heat of the auxiliary heat source, the environment is protected, emission is reduced, and low carbon economy is realized.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

In the figure, 1, a heat source; 2. a solar panel; 3. a solar heat collector; 4. an auxiliary heat source pipe box I; 5. a cold water pipe box; 6. a heating user; 7. a hot water supply system; 8. a first heat preservation water storage tank; 9. a hot water pipeline I; 10. a first cold water pipeline; 11. an auxiliary heat source pipe box II; 12. a cold water pipeline II; 13. a second heat preservation water storage tank; 14. a second hot water supply system; 15. a second hot water pipeline; 16. a transfer line.

Detailed Description

In order to clearly illustrate the technical features of the present invention, the present invention is explained in detail by the following embodiments in combination with the accompanying drawings.

As shown in fig. 1, the solar heat-collecting system integrally comprises a heat source 1, an end user and a transmission pipeline 16, wherein the transmission pipeline 16 is erected between the heat source 1 and a heating user 6, the solar heat-collecting system also comprises a transmission utilization unit, an auxiliary heat source unit and an auxiliary heat source utilization unit, the transmission utilization unit, the auxiliary heat source unit and the auxiliary heat source utilization unit are erected on the transmission pipeline 16 at intervals, the transmission utilization unit comprises a cold water pipe box 5, a heat-preservation water storage box II 13 and a hot water supply system II 14, the cold water pipe box 5 is communicated with the heat-preservation water storage box II 13 through a pipeline, the heat-preservation water storage box II 13 is communicated with the hot water supply system II 14 through a pipeline, the auxiliary heat source 1 unit comprises a solar panel 2, a solar heat collector 3 and an auxiliary heat source pipe box I4, the solar heat collector 3 is arranged between the solar panel 2 and the auxiliary heat source pipe box I4, and the auxiliary heat source utilization unit comprises a solar panel 2, a solar heat collector 3, a transmission pipeline 16, The solar heat collector 3 is arranged between the solar panel 2 and the auxiliary heat source pipe box II 11, the auxiliary heat source pipe box II 11 is communicated with the heat preservation water storage tank I8 through a pipeline, and the heat preservation water storage tank I8 is communicated with the hot water supply system I7 through a pipeline;

in order to economically benefit the waste heat of the steam pipeline, the cold water pipe box 5 comprises a first shell, a first cold water pipe, a second cold water pipe 12 and a second hot water pipe 15, wherein the first shell is arranged on the periphery of the first cold water pipe, the first cold water pipe is wound on a transmission pipeline 16, one end of the first cold water pipe is communicated with the second cold water pipe 12, the other end of the first cold water pipe is communicated with the second hot water pipe 15, and the second hot water pipe 15 is communicated with an inlet of a second heat-preservation water storage box 13;

in order to compensate the heat loss of the steam pipeline in the transmission process, the auxiliary heat source pipe box I4 comprises a second shell and a second cold water pipe, the second shell is arranged on the periphery of the second cold water pipe, the second cold water pipe is wound on the transmission pipeline 16 and is connected with the solar heat collector 3, and the second cold water pipe is filled with cold water and two ends of the second cold water pipe are sealed;

in order to utilize waste heat generated by solar energy assistance, the auxiliary heat source pipe box II 11 comprises a third shell, a third cold water pipe, a first cold water pipe 10 and a first hot water pipe 9, the third shell is arranged on the periphery of the third cold water pipe, the third cold water pipe is wound on a transmission pipeline 16 and is connected with the solar heat collector 3, one end of the third cold water pipe is communicated with the first cold water pipe 10, the other end of the third cold water pipe is communicated with the first hot water pipe 9, and the first hot water pipe 9 is communicated with an inlet of the first heat-preservation water storage tank 8;

in order to realize multi-level hot water utilization, the hot water supply system I7 comprises a hot water system for a peripheral plant area and a heating system for a peripheral residential district, and the hot water supply system II 14 comprises a hot water system for a peripheral plant area and a heating system for a peripheral residential district;

in order to utilize the waste heat more efficiently, the first cold water pipe, the second cold water pipe and the third cold water pipe are spirally wound in the radial direction or are wound on the transmission pipeline 16 in the axial direction in an S shape. The loss of heat energy during the course of transport,

the working principle is as follows: the heat source 1 transports steam to a heating user 6 through a transmission pipeline 16 to form steam heating, a transmission utilization unit is erected on the transmission pipeline 16, part of heat energy is absorbed through a first cold water pipe and is led out through a second hot water pipe 15, heat insulation and storage are carried out through a second heat insulation water storage tank 13, and then layered utilization is carried out through a second hot water supply system 14, so that hot water for production or living can be provided for a surrounding plant area and a surrounding residential area;

the auxiliary heat source unit is erected on the transmission pipeline 16, absorbs the energy of the sun through the solar panel 2, collects solar radiation through the solar heat collector 3 and converts the solar radiation into heat energy, and heats cold water in the cold water pipe II to heat the cold water so as to compensate the heat loss of steam in the steam pipeline in the transmission process;

the auxiliary heat source utilization units are all erected on the transmission pipeline 16, the solar energy is absorbed by the solar panels 2, solar radiation is collected by the solar heat collectors 3 and converted into heat energy, cold water in the cold water pipe II is heated to be heated, part of the heat energy is used for compensating heat loss of steam in the steam pipeline in the transmission process, part of the heat energy is led out through the hot water pipeline I9 and is subjected to heat preservation and storage through the heat preservation water storage tank I8, and then the heat energy is utilized in a layered mode through the hot water supply system I7, so that hot water for production or life can be provided for surrounding plant areas and surrounding residential areas.

Wherein, above-mentioned solar panel 2, solar collector 3, heat preservation storage water tank and pipeline all belong to prior art.

The above-mentioned specific embodiments can not be regarded as the restriction to the scope of protection of the utility model, to technical personnel in this technical field, it is right the utility model discloses any replacement improvement or transform that embodiment made all fall within the scope of protection of the utility model.

The parts of the present invention not described in detail are the known techniques of those skilled in the art.

Claims (6)

1. The utility model provides a steam pipework system of outer net air feed, includes heat source, end user and transmission line, transmission line sets up between heat source and the heating user, its characterized in that: the solar heat-preservation water-heating system is characterized by further comprising a transmission utilization unit, an auxiliary heat source unit and an auxiliary heat source utilization unit, wherein the transmission utilization unit, the auxiliary heat source unit and the auxiliary heat source utilization unit are arranged on the transmission pipeline at intervals, the transmission utilization unit comprises a cold water pipe box, a heat-preservation water storage box II and a hot water supply system II, the cold water pipe box is communicated with the heat-preservation water storage box through a pipeline, the heat-preservation water storage box II is communicated with the hot water supply system through a pipeline, the auxiliary heat source unit comprises a solar panel, a solar heat collector and an auxiliary heat source pipe box I, the solar heat collector is arranged between the solar panel and the auxiliary heat source pipe box I, the auxiliary heat source utilization unit comprises a solar panel, a solar heat collector, an auxiliary heat source pipe box II, a hot water supply system I and a heat-preservation water storage box I, the solar heat collector is arranged between the solar panel and the auxiliary heat source pipe box II, the auxiliary heat source pipe box II is communicated with the heat preservation water storage tank I through a pipeline, and the heat preservation water storage tank I is communicated with the hot water supply system through a pipeline.

2. The steam duct system for air supply to an external grid of claim 1, wherein: the cold water pipeline box comprises a first shell, a first cold water pipeline, a second cold water pipeline and a second hot water pipeline, wherein the first shell is arranged on the periphery of the first cold water pipeline, the first cold water pipeline is wound on the transmission pipeline, one end of the first cold water pipeline is communicated with the second cold water pipeline, the other end of the first cold water pipeline is communicated with the second hot water pipeline, and the second hot water pipeline is communicated with an inlet of the second heat-preservation water storage tank.

3. A steam duct system for air supply to an external grid according to claim 1 or 2, characterised in that: the auxiliary heat source pipe box I comprises a shell II and a cold water pipe II, the shell II is arranged on the periphery of the cold water pipe II, the cold water pipe II is wound on the transmission pipeline, the cold water pipe II is connected with the solar heat collector, and the cold water pipe II is filled with cold water and two ends of the cold water pipe II are sealed.

4. The steam duct system for air supply to an external grid of claim 3, wherein: the auxiliary heat source pipe box II comprises a third shell, a third cold water pipe, a first cold water pipe and a first hot water pipe, the third shell is arranged on the periphery of the third cold water pipe, the third cold water pipe is wound on the transmission pipeline, the third cold water pipe is connected with the solar heat collector, one end of the third cold water pipe is communicated with the first cold water pipe, the other end of the third cold water pipe is communicated with the first hot water pipe, and the first hot water pipe is communicated with an inlet of the first heat preservation water storage tank.

5. The steam duct system for air supply to an external grid of claim 4, wherein: the hot water supply system comprises a hot water system for the plant area around and a heating system for the residential district around, and the hot water supply system comprises a hot water system for the plant area around and a heating system for the residential district around.

6. The steam duct system for air supply to an external grid of claim 5, wherein: the first cold water pipe, the second cold water pipe and the third cold water pipe are spirally wound in the radial direction or wound on the transmission pipeline in the axial direction in an S shape.

Images