CN211695989U

CN211695989U - Boiler heating energy-saving system

Info

Publication number: CN211695989U
Application number: CN201922386996.5U
Authority: CN
Inventors: �金钟
Original assignee: Changzhou Lyuzi Environmental Protection Equipment Co ltd
Current assignee: Changzhou Lyuzi Environmental Protection Equipment Co ltd
Priority date: 2019-12-27
Filing date: 2019-12-27
Publication date: 2020-10-16
Anticipated expiration: 2029-12-27

Abstract

The utility model discloses a boiler heating economizer system, including waste heat recovery host computer, surplus vapour pipeline, low temperature jar, high temperature jar, ion exchanger, boiler energy-saving appliance, surplus vapour pipeline connects the waste heat recovery host computer, ion exchanger connects the low temperature jar, the low temperature jar passes through the defeated host computer pipe network connection of low temperature jar the waste heat recovery host computer, the waste heat recovery host computer passes through the defeated high temperature jar pipe network connection of host computer the high temperature jar, the high temperature jar is connected the boiler energy-saving appliance, the boiler energy-saving appliance connects the defeated boiler pipe network of high temperature softened water. This application rational utilization boiler economizer obtains high temperature softened water by normal atmospheric temperature water, has both participated in boiler work, saves or has reduced again and add extra heating resource loss man-hour, improves the utilization ratio maximize of production line to heat energy.

Description

Boiler heating energy-saving system

Technical Field

The utility model relates to an energy-conserving technical field, concretely relates to boiler heating economizer system.

Background

At present, with the continuous consumption of limited energy resources on the earth, the development and utilization of the energy resources are more and more concerned by people, and how to efficiently utilize the energy resources, reduce the consumption, realize energy conservation and emission reduction is one of the most concerned problems of the whole mankind. As a heat energy transfer conversion device, a boiler is generally used for water heating or steam is used in other fields. The existing boiler generally uses coal as main energy source for heating.

The boiler of prior art produces steam through fuel burning heating water tank, and the boiler is in the use, and flue gas channel's waste heat utilization is not high, causes the waste in a large number of energy. Meanwhile, most of the existing boilers directly heat cold water, so that the heat efficiency is low, the energy consumption is high, the use requirement can be met only by needing a long time, and the energy consumption is further increased.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects, the utility model provides a following technical scheme: the utility model provides a boiler heating economizer system, includes waste heat recovery host computer, surplus vapour pipeline, low temperature jar, high temperature jar, ion exchanger, boiler energy-saving appliance, surplus vapour pipeline connects the waste heat recovery host computer, ion exchanger connects the low temperature jar, the low temperature jar passes through the defeated host computer pipe network connection of low temperature jar the waste heat recovery host computer, the waste heat recovery host computer passes through the defeated high temperature jar pipe network connection of host computer the high temperature jar, the high temperature jar is connected the boiler energy-saving appliance, the boiler energy-saving appliance is connected the defeated boiler pipe network of high temperature softened water.

Furthermore, the waste steam recovery system also comprises a waste steam condensation port water outlet pipe, and the waste steam condensation port water outlet pipe is connected with the waste heat recovery host machine.

Further, an exhaust steam regulating valve is installed on the exhaust steam conveying pipeline.

Further, an electric valve is installed on a pipe network of the main machine high-temperature conveying tank.

Furthermore, a stop valve, a stainless steel multistage pump and a regulating valve are arranged on the pipe network of the low-temperature tank transportation host machine.

Furthermore, a stainless steel multistage pump and a regulating valve are arranged on the high-temperature softened water boiler delivery pipe network.

Furthermore, an energy storage medium inlet, a waste heat steam inlet, an energy storage medium outlet and a condensate outlet are arranged on the waste heat recovery host, the energy storage medium inlet and the waste heat steam inlet are arranged at the top of the waste heat recovery host, the energy storage medium outlet and the condensate outlet are arranged at the bottom of the waste heat recovery host, and the condensate outlet and the waste heat steam inlet are connected through a heat transfer pipeline.

Further, the waste heat recovery host machine still includes vertical pipeline and a plurality of cooling tube, vertical pipeline and heat transfer pipeline symmetry set up, a plurality of the cooling tube is arranged in between vertical pipeline and the heat transfer pipeline and is intercommunicated.

This application rational utilization boiler economizer obtains high temperature softened water by normal atmospheric temperature water, has both participated in boiler work, saves or has reduced again and add extra heating resource loss man-hour, improves the utilization ratio maximize of production line to heat energy.

Drawings

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

fig. 2 is a schematic structural diagram of the waste heat recovery machine.

In the figure: 1-a waste heat recovery machine, 2-a low-temperature tank, 3-a high-temperature tank, 4-an ion exchanger, 5-a boiler economizer, 6-a waste steam conveying pipeline, 7-a low-temperature tank main machine conveying pipe network, 8-a main machine high-temperature tank pipe network, 9-a high-temperature softened water conveying boiler pipe network, 10-a waste steam condensation port water outlet pipe, 11-a waste steam adjusting valve, 12-an energy storage medium inlet, 13-a radiating pipe, 14-a vertical pipeline, 15-a waste steam inlet, 16-a heat transfer pipeline, 17-a condensed water outlet and 18-an energy storage medium outlet.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Referring to fig. 1 and 2, a boiler heating energy-saving system includes a waste heat recovery host 1, a waste steam delivery pipe 6, a low-temperature tank 2, a high-temperature tank 3, an ion exchanger 4, and a boiler economizer 5, wherein the waste steam delivery pipe 6 is connected to the waste heat recovery host 1, the ion exchanger 4 is connected to the low-temperature tank 2, the low-temperature tank 2 is connected to the waste heat recovery host 1 through a low-temperature tank delivery host pipe network 7, the waste heat recovery host 1 is connected to the high-temperature tank 3 through a host high-temperature tank pipe network 8, the high-temperature tank 3 is connected to the boiler economizer 5, and the boiler economizer 5 is connected to a high-temperature softened water delivery boiler pipe network 9. The waste heat recovery system further comprises a waste steam condensation port water outlet pipe 10, and the waste steam condensation port water outlet pipe 10 is connected with the waste heat recovery host machine 1. And a residual steam regulating valve 11 is arranged on the residual steam conveying pipeline 6. And an electric valve is arranged on the high-temperature tank pipe network 8 of the main machine. And a stop valve, a stainless steel multistage pump and a regulating valve are arranged on the low-temperature tank transportation host pipe network 7. And a stainless steel multistage pump and a regulating valve are arranged on the high-temperature softened water delivery boiler pipe network 9. The waste heat recovery device is characterized in that an energy storage medium inlet 12, a waste heat steam inlet 15, an energy storage medium outlet 18 and a condensed water outlet 17 are arranged on the waste heat recovery host 1, the energy storage medium inlet 12 and the waste heat steam inlet 15 are arranged at the top of the waste heat recovery host 1, the energy storage medium outlet 18 and the condensed water outlet 17 are arranged at the bottom of the waste heat recovery host 1, and the condensed water outlet 17 is connected with the waste heat steam inlet 15 through a heat transfer pipeline 16. The waste heat recovery main unit 1 further comprises a vertical pipe 14 and a plurality of radiating pipes 13, wherein the vertical pipe 14 and the heat transfer pipe 16 are symmetrically arranged, and the plurality of radiating pipes 13 are arranged between the vertical pipe 14 and the heat transfer pipe 16 and are communicated with each other.

The utility model discloses an ion exchanger and low temperature tank obtain normal atmospheric temperature demineralized water, and normal atmospheric temperature demineralized water flows into the high temperature tank behind the waste heat recovery host computer and obtains high temperature demineralized water, and high temperature demineralized water gets into the boiler and participates in work, and the back flows out through the defeated boiler pipe network of high temperature demineralized water. This application rational utilization boiler economizer obtains high temperature softened water by normal atmospheric temperature water, has both participated in boiler work, saves or has reduced again and add extra heating resource loss man-hour, improves the utilization ratio maximize of production line to heat energy.

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 invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a boiler heating economizer system, its characterized in that, includes waste heat recovery host computer (1), surplus vapour pipeline (6), low temperature jar (2), high temperature jar (3), ion exchanger (4), boiler economizer (5), surplus vapour pipeline (6) are connected waste heat recovery host computer (1), ion exchanger (4) are connected low temperature jar (2), low temperature jar (2) are connected through defeated host computer pipe network (7) of low temperature jar waste heat recovery host computer (1), waste heat recovery host computer (1) is connected through defeated high temperature jar pipe network (8) of host computer high temperature jar (3), high temperature jar (3) are connected boiler economizer (5), boiler economizer (5) are connected high temperature softened water and are defeated boiler pipe network (9).

2. The boiler heating energy-saving system according to claim 1, further comprising a residual steam condensation outlet water outlet pipe (10), wherein the residual steam condensation outlet water outlet pipe (10) is connected with the waste heat recovery main machine (1).

3. The boiler heating energy-saving system according to claim 1, wherein the residual steam delivery pipe (6) is provided with a residual steam regulating valve (11).

4. The boiler heating energy-saving system according to claim 1, wherein an electric valve is installed on the main high-temperature tank pipe network (8).

5. The boiler heating energy-saving system according to claim 1, wherein a stop valve, a stainless steel multistage pump and a regulating valve are arranged on the low-temperature tank and main delivery machine pipe network (7).

6. The boiler heating energy-saving system according to claim 1, wherein a stainless steel multistage pump and a regulating valve are mounted on the high-temperature softened water delivery boiler pipe network (9).

7. The boiler heating energy-saving system according to claim 1, wherein an energy storage medium inlet (12), an energy storage steam inlet (15), an energy storage medium outlet (18) and a condensate outlet (17) are arranged on the waste heat recovery main unit (1), the energy storage medium inlet (12) and the waste heat steam inlet (15) are arranged at the top of the waste heat recovery main unit (1), the energy storage medium outlet (18) and the condensate outlet (17) are arranged at the bottom of the waste heat recovery main unit (1), and the condensate outlet (17) and the waste heat steam inlet (15) are connected through a heat transfer pipeline (16).

8. The boiler heating energy-saving system according to claim 7, wherein the waste heat recovery main unit (1) further comprises a vertical pipe (14) and a plurality of heat dissipation pipes (13), the vertical pipe (14) and the heat transfer pipe (16) are symmetrically arranged, and the plurality of heat dissipation pipes (13) are disposed between the vertical pipe (14) and the heat transfer pipe (16) and are communicated with each other.