CN213067129U - Roasting flue gas waste heat utilization equipment - Google Patents

Abstract

The utility model provides a calcination flue gas waste heat utilization equipment relates to an energy-saving equipment technical field. The utility model discloses an including the first heat transfer case and the second heat transfer case that set up side by side, first heat transfer case is provided with light oxidation UV pipe including last box and the lower box that is linked together on the box down, upward be provided with first feed liquor pipe and heat transfer pipeline in the box, and the heat transfer pipeline includes right heat transfer pipeline, goes up heat transfer pipeline and left heat transfer pipeline, is provided with second feed liquor pipe on the second heat transfer case. The utility model discloses simple structure retrieves the cycle and recycles the unnecessary gas of production, has not only avoided polluting, can also very big reduction to the waste of raw and other materials to reach energy-concerving and environment-protective purpose.

Description

Roasting flue gas waste heat utilization equipment

Technical Field

The utility model relates to an energy-saving equipment technical field especially relates to a calcination flue gas waste heat utilization equipment.

Background

Currently, along with the development of social economy, the national economy develops and simultaneously inevitably brings about a plurality of development problems, such as environmental problems, the increasingly worsening of the environment brings about serious influence on the life of people, and the country also attaches more importance to the protection of the environment. The production type enterprises are used as a main source of environmental pollution, the improvement technology of high-energy-consumption equipment is particularly important, at present, relevant additional energy generated by the high-energy-consumption equipment is not utilized, so that energy waste is caused, the waste of heat energy is particularly remarkable, a large amount of heat generated in the production process of the equipment is mostly directly discharged to the air, the reasonable utilization is not realized, the energy waste is caused, the environmental pollution is increased, and the requirement on environmental protection is not met.

SUMMERY OF THE UTILITY MODEL

To the weak point that exists in the above-mentioned problem, the utility model provides a calcination flue gas waste heat utilization equipment makes its simple structure, retrieves the cycle recycle to the unnecessary gas that produces, has not only avoided the pollution, reduction that can also be very big to the waste of raw and other materials to reach energy-concerving and environment-protective purpose.

In order to solve the above problems, the utility model provides a roasting flue gas waste heat utilization equipment, wherein, including the first heat exchange case and the second heat exchange case that set up side by side, the first heat exchange case includes upper box and lower box that are linked together, be provided with the photooxidation UV pipe on the box down, the photooxidation UV pipe includes the first photooxidation UV pipe and the second photooxidation UV pipe that set up side by side, first photooxidation UV pipe and the second photooxidation UV pipe all set up in the bottom of box down, be provided with first feed liquor pipe and heat transfer pipeline in the upper box, the heat transfer pipeline includes right heat transfer pipeline, last heat transfer pipeline and left heat transfer pipeline, the bottom of right heat transfer pipeline with the lower box intercommunication, the upper portion of right heat transfer pipeline with go up the heat transfer pipeline intercommunication, the other end of going up the heat transfer pipeline with left heat transfer pipeline intercommunication, the other end of the left heat exchange pipeline is communicated with the air inlet pipe, the first liquid inlet pipe is arranged above the right end of the upper heat exchange pipeline, the second heat exchange box is provided with a second liquid inlet pipe, the left heat exchange pipeline is arranged in the second heat exchange box, and the second liquid inlet pipe is arranged above the left heat exchange pipeline.

Preferably, the right heat exchange pipeline comprises a first right heat exchange pipeline, a second right heat exchange pipeline, a third right heat exchange pipeline, a fourth right heat exchange pipeline, a fifth right heat exchange pipeline, a sixth right heat exchange pipeline and a seventh right heat exchange pipeline, and the first right heat exchange pipeline, the second right heat exchange pipeline, the third right heat exchange pipeline, the fourth right heat exchange pipeline, the fifth right heat exchange pipeline, the sixth right heat exchange pipeline and the seventh right heat exchange pipeline are arranged in parallel and are all communicated with the lower box body.

Preferably, the upper heat exchange pipeline includes a first upper heat exchange pipeline, a second upper heat exchange pipeline, a third upper heat exchange pipeline, a fourth upper heat exchange pipeline, a fifth upper heat exchange pipeline, a sixth upper heat exchange pipeline and a seventh upper heat exchange pipeline, which are arranged in parallel, and the first upper heat exchange pipeline, the second upper heat exchange pipeline, the third upper heat exchange pipeline, the fourth upper heat exchange pipeline, the fifth upper heat exchange pipeline, the sixth upper heat exchange pipeline and the seventh upper heat exchange pipeline are respectively and correspondingly communicated with the first right heat exchange pipeline, the second right heat exchange pipeline, the third right heat exchange pipeline, the fourth right heat exchange pipeline, the fifth right heat exchange pipeline, the sixth right heat exchange pipeline and the seventh right heat exchange pipeline.

Preferably, the left heat exchange pipeline includes a first left heat exchange pipeline, a second left heat exchange pipeline, a third left heat exchange pipeline, a fourth left heat exchange pipeline, a fifth left heat exchange pipeline, a sixth left heat exchange pipeline and a seventh left heat exchange pipeline, which are arranged in parallel, and the first left heat exchange pipeline, the second left heat exchange pipeline, the third left heat exchange pipeline, the fourth left heat exchange pipeline, the fifth left heat exchange pipeline, the sixth left heat exchange pipeline and the seventh left heat exchange pipeline are respectively communicated with the first upper heat exchange pipeline, the second upper heat exchange pipeline, the third upper heat exchange pipeline, the fourth upper heat exchange pipeline, the fifth upper heat exchange pipeline, the sixth upper heat exchange pipeline and the seventh upper heat exchange pipeline correspondingly.

Preferably, a fan and an air pipe are arranged in the upper box body, and the fan is connected with the air pipe.

Preferably, a fan is arranged at the joint of the upper box body and the lower box body, the fan is communicated with the inside of the first heat exchange box through an air duct, and the fan is connected with the air pipe.

Preferably, the first photo-oxidation UV tube and the second photo-oxidation UV tube are both connected to the air duct.

Preferably, the right end of the lower box body is provided with an air outlet pipeline which is communicated with an external refining tower.

Preferably, the air inlet pipe is communicated with a circulation pipeline, and the circulation pipeline is communicated with a refining tower arranged outside.

Preferably, the air inlet pipe is provided with a control valve.

Compared with the prior art, the utility model has the advantages of it is following:

the utility model discloses simple structure retrieves the cycle and recycles the unnecessary gas of production, has not only avoided polluting, can also very big reduction to the waste of raw and other materials to reach energy-concerving and environment-protective purpose.

Drawings

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

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention will be further described in detail with reference to the accompanying drawings and examples, which are not intended to limit the present invention.

As shown in figure 1, the embodiment of the utility model comprises a first heat exchange box 1 and a second heat exchange box 2 which are arranged in parallel, wherein the first heat exchange box 1 comprises an upper box body 3 and a lower box body 4 which are communicated, a photooxidation UV tube 5 is arranged on the lower box body 4, the photooxidation UV tube 5 comprises a first photooxidation UV tube and a second photooxidation UV tube which are arranged in parallel, the first photooxidation UV tube and the second photooxidation UV tube are both arranged at the bottom of the lower box body 4, a first liquid inlet tube 6 and a heat exchange pipeline are arranged in the upper box body 3, the heat exchange pipeline comprises a right heat exchange pipeline 7, an upper heat exchange pipeline 8 and a left heat exchange pipeline 9, the bottom of the right heat exchange pipeline 7 is communicated with the lower box body 4, the upper part of the right heat exchange pipeline 7 is communicated with the upper heat exchange pipeline 8, the other end of the upper heat exchange pipeline 8 is communicated with the left heat exchange pipeline 9, the other end of the left heat exchange pipeline 9 is communicated with the air inlet pipe 10, the first liquid inlet pipe 6 is arranged above the right end of the upper heat exchange pipeline 8, the second heat exchange box 2 is provided with a second liquid inlet pipe 11, the left heat exchange pipeline 9 is arranged in the second heat exchange box 2, and the second liquid inlet pipe 11 is arranged above the left heat exchange pipeline 9.

The right heat exchange pipeline 7 comprises a first right heat exchange pipeline, a second right heat exchange pipeline, a third right heat exchange pipeline, a fourth right heat exchange pipeline, a fifth right heat exchange pipeline, a sixth right heat exchange pipeline and a seventh right heat exchange pipeline, and the first right heat exchange pipeline, the second right heat exchange pipeline, the third right heat exchange pipeline, the fourth right heat exchange pipeline, the fifth right heat exchange pipeline, the sixth right heat exchange pipeline and the seventh right heat exchange pipeline are arranged in parallel and are communicated with the lower box body.

The upper heat exchange pipeline 8 comprises a first upper heat exchange pipeline, a second upper heat exchange pipeline, a third upper heat exchange pipeline, a fourth upper heat exchange pipeline, a fifth upper heat exchange pipeline, a sixth upper heat exchange pipeline and a seventh upper heat exchange pipeline which are arranged in parallel, and the first upper heat exchange pipeline, the second upper heat exchange pipeline, the third upper heat exchange pipeline, the fourth upper heat exchange pipeline, the fifth upper heat exchange pipeline, the sixth upper heat exchange pipeline and the seventh upper heat exchange pipeline are respectively communicated with the first right heat exchange pipeline, the second right heat exchange pipeline, the third right heat exchange pipeline, the fourth right heat exchange pipeline, the fifth right heat exchange pipeline, the sixth right heat exchange pipeline and the seventh right heat exchange pipeline correspondingly.

The left heat exchange pipeline 9 comprises a first left heat exchange pipeline, a second left heat exchange pipeline, a third left heat exchange pipeline, a fourth left heat exchange pipeline, a fifth left heat exchange pipeline, a sixth left heat exchange pipeline and a seventh left heat exchange pipeline which are arranged in parallel, and the first left heat exchange pipeline, the second left heat exchange pipeline, the third left heat exchange pipeline, the fourth left heat exchange pipeline, the fifth left heat exchange pipeline, the sixth left heat exchange pipeline and the seventh left heat exchange pipeline are respectively communicated with the first upper heat exchange pipeline, the second upper heat exchange pipeline, the third upper heat exchange pipeline, the fourth upper heat exchange pipeline, the fifth upper heat exchange pipeline, the sixth upper heat exchange pipeline and the seventh upper heat exchange pipeline correspondingly.

A fan 12 and an air pipe 13 are arranged in the upper box body 3, the fan 12 is communicated with the air pipe 13, and the fan 12 is communicated with the interior of the lower box body through the air pipe 13.

A fan 14 is arranged at the joint of the upper box body 3 and the lower box body 4, the fan 14 is communicated with the inside of the first heat exchange box 1 through an air duct, and the fan 14 is connected with the air duct 13.

The first photo-oxidation UV pipe and the second photo-oxidation UV pipe are both connected with the air pipe 13.

And the right end of the lower box body 4 is provided with an air outlet pipeline 15, and the air outlet pipeline 15 is communicated with an external refining tower.

The air inlet pipe 10 is communicated with a circulation pipeline which is communicated with a refining tower arranged outside.

The intake pipe 10 is provided with a control valve 16.

And a filter layer is arranged between the upper box body 3 and the lower box body 4, and the filter layer is a graphite carbon adsorption layer.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. The roasting flue gas waste heat utilization equipment is characterized by comprising a first heat exchange box and a second heat exchange box which are arranged in parallel, wherein the first heat exchange box comprises an upper box body and a lower box body which are communicated, a photooxidation UV pipe is arranged on the lower box body, the photooxidation UV pipe comprises a first photooxidation UV pipe and a second photooxidation UV pipe which are arranged in parallel, the first photooxidation UV pipe and the second photooxidation UV pipe are both arranged at the bottom of the lower box body, a first liquid inlet pipe and a heat exchange pipeline are arranged in the upper box body, the heat exchange pipeline comprises a right heat exchange pipeline, an upper heat exchange pipeline and a left heat exchange pipeline, the bottom of the right heat exchange pipeline is communicated with the lower box body, the upper part of the right heat exchange pipeline is communicated with the upper heat exchange pipeline, the other end of the upper heat exchange pipeline is communicated with the left heat exchange pipeline, the other end of the left heat exchange pipeline is communicated with an air inlet pipe, the first liquid inlet pipe is arranged above the right end of the upper heat exchange pipeline, the second heat exchange box is provided with a second liquid inlet pipe, the left heat exchange pipeline is arranged in the second heat exchange box, and the second liquid inlet pipe is arranged above the left heat exchange pipeline.

2. The roasting flue gas waste heat utilization device according to claim 1, wherein the right heat exchange pipelines include a first right heat exchange pipeline, a second right heat exchange pipeline, a third right heat exchange pipeline, a fourth right heat exchange pipeline, a fifth right heat exchange pipeline, a sixth right heat exchange pipeline and a seventh right heat exchange pipeline, and the first right heat exchange pipeline, the second right heat exchange pipeline, the third right heat exchange pipeline, the fourth right heat exchange pipeline, the fifth right heat exchange pipeline, the sixth right heat exchange pipeline and the seventh right heat exchange pipeline are arranged in parallel and are all communicated with the lower box body.

3. The roasting flue gas waste heat utilization device according to claim 2, wherein the upper heat exchange pipelines include a first upper heat exchange pipeline, a second upper heat exchange pipeline, a third upper heat exchange pipeline, a fourth upper heat exchange pipeline, a fifth upper heat exchange pipeline, a sixth upper heat exchange pipeline and a seventh upper heat exchange pipeline which are arranged in parallel, and the first upper heat exchange pipeline, the second upper heat exchange pipeline, the third upper heat exchange pipeline, the fourth upper heat exchange pipeline, the fifth upper heat exchange pipeline, the sixth upper heat exchange pipeline and the seventh upper heat exchange pipeline are respectively and correspondingly communicated with the first right heat exchange pipeline, the second right heat exchange pipeline, the third right heat exchange pipeline, the fourth right heat exchange pipeline, the fifth right heat exchange pipeline, the sixth right heat exchange pipeline and the seventh right heat exchange pipeline.

4. The roasting flue gas waste heat utilization device according to claim 3, wherein the left heat exchange pipelines include a first left heat exchange pipeline, a second left heat exchange pipeline, a third left heat exchange pipeline, a fourth left heat exchange pipeline, a fifth left heat exchange pipeline, a sixth left heat exchange pipeline and a seventh left heat exchange pipeline which are arranged in parallel, and the first left heat exchange pipeline, the second left heat exchange pipeline, the third left heat exchange pipeline, the fourth left heat exchange pipeline, the fifth left heat exchange pipeline, the sixth left heat exchange pipeline and the seventh left heat exchange pipeline are respectively in corresponding communication with the first upper heat exchange pipeline, the second upper heat exchange pipeline, the third upper heat exchange pipeline, the fourth upper heat exchange pipeline, the fifth upper heat exchange pipeline, the sixth upper heat exchange pipeline and the seventh upper heat exchange pipeline.

5. The roasting flue gas waste heat utilization device according to claim 4, wherein a fan and an air pipe are arranged in the upper box body, and the fan is connected with the air pipe.

6. The roasting flue gas waste heat utilization device according to claim 5, wherein a fan is arranged at the joint of the upper box body and the lower box body, the fan is communicated with the inside of the first heat exchange box through an air duct, and the fan is connected with the air duct.

7. The roasting flue gas waste heat utilization device according to claim 6, wherein the first photo-oxidation UV pipe and the second photo-oxidation UV pipe are both connected with the air pipe.

8. The roasting flue gas waste heat utilization device according to claim 7, wherein an air outlet pipeline is arranged at the right end of the lower box body and communicated with an external refining tower.

9. The roasting flue gas waste heat utilization device according to claim 8, wherein a circulation pipeline is communicated with the gas inlet pipe, and the circulation pipeline is communicated with a refining tower arranged outside.

10. The roasting flue gas waste heat utilization device according to claim 9, wherein a control valve is arranged on the gas inlet pipe.

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