CN219714087U - Galvanized furnace heat exchanger - Google Patents

Abstract

The utility model relates to the technical field of heat exchangers and discloses a galvanized furnace heat exchanger, which comprises a device body, wherein the device body comprises a heat exchange tube main body, the heat exchange tube main body is arranged in a galvanized furnace body, an air inlet is fixedly arranged at the air inlet end of the heat exchange tube main body, an air outlet is fixedly arranged at the air outlet end of the heat exchange tube main body, a flow dividing assembly is arranged at the outer side of the end part of the air outlet end, the flow dividing assembly comprises a connecting hole, the connecting hole is formed at the outer side of the air outlet end of the heat exchange tube main body, and a flow dividing tube body is welded and arranged on the inner wall of the connecting hole. According to the utility model, the split-flow assembly is arranged, after the control valve is opened, the split-flow pipe body is communicated with the air outlet, and the temperature detector and other instruments penetrate through the split-flow pipe body and extend into the heat exchange pipe body, so that the detection and analysis of the data such as the gas temperature and the like in the heat exchange pipe body can be conveniently carried out, the detection can be conveniently carried out, and the control of the temperature in the furnace is facilitated.

Description

Galvanized furnace heat exchanger

Technical Field

The utility model relates to the technical field of heat exchangers, in particular to a galvanized furnace heat exchanger.

Background

The temperature in the galvanizing furnace is raised through the heat exchanger, the high-temperature gas enters the heat exchange tube for internal circulation, the temperature in the furnace is raised, the current heat exchanger is generally formed by an S-shaped integrated tube body, a U-shaped integrated tube body and the like, and in the use process, the temperature in the tube and the gas are inconvenient to analyze and detect, and the accurate control of the temperature in the furnace is inconvenient, so that the design of the galvanizing furnace heat exchanger is urgently needed.

Disclosure of Invention

In order to overcome the defects of the prior art, the utility model provides a galvanized furnace heat exchanger, which aims to solve the problems that in the prior art, the temperature in the galvanized furnace is raised through the heat exchanger, the temperature in the furnace is raised through high-temperature gas entering the heat exchange tube for circulation, the current heat exchanger is generally formed by an S-shaped, U-shaped and other integrated tube bodies, and the analysis and the detection of the temperature in the tube and the gas are inconvenient in the use process, so that the temperature in the furnace is not easy to accurately control.

The utility model provides the following technical scheme: the utility model provides a galvanized furnace heat exchanger, includes the device body, the device body includes the heat transfer pipe main part, the heat transfer pipe main part is installed in the galvanized furnace body, the inlet end fixed mounting of heat transfer pipe main part has the air intake, the end fixed mounting has the air outlet of giving vent to anger of heat transfer pipe main part, it is equipped with the reposition of redundant personnel subassembly to give vent to anger the end outside of end, the reposition of redundant personnel subassembly includes the connecting hole, the connecting hole is seted up in the heat transfer pipe main part outside of giving vent to anger, the inner wall welded mounting of connecting hole has the shunt tube body, the shunt tube body extends to the heat transfer pipe main part outside, the outside fixed mounting of shunt tube body has control valve, the tip fixed mounting of shunt tube body has the flange piece, the outside fixed mounting of heat transfer pipe main part has the soaking subassembly, after opening control valve for shunt tube body and air outlet are linked together, through stretching into inside the heat transfer pipe main part with instrument such as temperature detector to convenient detection such as the inside the heat transfer pipe main part of the inside gas temperature.

Further, the cross section of the heat exchange tube main body is flat, so that the contact area between the heat exchange tube main body and the furnace is increased, and the heat exchange efficiency and uniformity are improved.

Further, the soaking component comprises sleeve joint pieces, the sleeve joint pieces are sleeved and mounted on the outer side of the heat exchange tube main body, the number of the sleeve joint pieces is two, a plurality of soaking pieces are uniformly and fixedly mounted between the sleeve joint pieces, heat of the heat exchange tube main body shell can be absorbed through the sleeve joint pieces and the soaking pieces, and then the heat can be diffused through the sleeve joint pieces and the soaking pieces, so that the contact area can be increased.

Furthermore, a plurality of radiating fins are uniformly welded and mounted on two sides of the soaking piece, and the contact area between the radiating fins on two sides of the soaking piece and materials and air in the furnace is further increased, so that the heating efficiency and uniformity are improved.

Further, a plurality of heat conducting rings are uniformly sleeved on the outer side of the heat exchange tube main body, so that the contact area between the heat exchange tube main body and the material and air in the furnace is increased, and the heating efficiency of the material is improved.

Further, the inside of air intake is equipped with the filter screen, plays filterable effect at the in-process of gas circulation, avoids impurity in the gas to pile up heat exchange tube main part inner wall, influences the condition of heat circulation.

The utility model has the technical effects and advantages that:

according to the utility model, the split-flow assembly is arranged, after the control valve is opened, the split-flow pipe body is communicated with the air outlet, and the temperature detector and other instruments penetrate through the split-flow pipe body and extend into the heat exchange pipe body, so that the detection and analysis of the data such as the gas temperature and the like in the heat exchange pipe body can be conveniently carried out, the detection can be conveniently carried out, and the control of the temperature in the furnace is facilitated.

By arranging the soaking component, the utility model adopts the design, so that the contact area between the device and raw materials or air in the furnace can be increased through the sleeve joint sheet and the soaking sheet, and the heat exchange efficiency and uniformity can be increased.

Drawings

Fig. 1 is a schematic perspective view of the structure of the present utility model.

Fig. 2 is a schematic perspective view of the present utility model with its structure separated.

Fig. 3 is a schematic perspective view of a soaking component structure according to the present utility model.

Fig. 4 is a schematic perspective view of a heat conducting ring structure of the present utility model.

The reference numerals are: 100. a device body; 110. a heat exchange tube main body; 111. an air inlet; 112. an air outlet; 200. a shunt assembly; 210. a shunt; 211. a control valve; 212. a flange plate; 213. a connection hole; 300. a soaking component; 310. a sleeve joint sheet; 311. soaking slices; 312. a heat radiation fin; 313. a heat conducting ring.

Detailed Description

The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings.

Examples

Referring to fig. 1-4, the utility model provides a galvanized heat exchanger, which comprises a device body 100, wherein the device body 100 comprises a heat exchange tube main body 110, the heat exchange tube main body 110 is installed in a galvanized furnace, an air inlet 111 is fixedly installed at the air inlet end of the heat exchange tube main body 110, an air outlet 112 is fixedly installed at the air outlet end of the heat exchange tube main body 110, a flow dividing assembly 200 is arranged at the outer side of the end part of the air outlet end, the flow dividing assembly 200 comprises a connecting hole 213, the connecting hole 213 is arranged at the outer side of the air outlet end of the heat exchange tube main body 110, a flow dividing tube body 210 is welded on the inner wall of the connecting hole 213, the flow dividing tube body 210 extends to the outer side of the heat exchange tube main body 110, a control valve 211 is fixedly installed at the outer side of the flow dividing tube body 210, a flange 212 is fixedly installed at the end part of the flow dividing tube main body 210, a soaking assembly 300 is fixedly installed at the outer side of the heat exchange tube main body 110, the section of the heat exchange tube main body 110 is flat, and a filter screen is arranged inside the air inlet 111.

Working principle: during the use, through being connected air intake 111 and heating gas, high temperature gas gets into heat exchange tube main part 110 inside through air intake 111 to circulate through air outlet 112, realize the intensification to the furnace body inside through the heat exchange tube main part 110 that is located the galvanizing furnace body, the accessible is opened control valve 211 during the use, makes the inside gaseous reposition of redundant personnel of heat exchange tube main part 110 to inside shunt tubes body 210, and staff's accessible passes shunt tubes body 210 with temperature detection instrument and extends to the inside detection of temperature or velocity of flow etc. of heat exchange tube main part 110.

Examples

The second embodiment differs from the first embodiment in that: the soaking component 300 comprises a sleeving connection piece 310, the sleeving connection piece 310 is sleeved and installed on the outer side of the heat exchange tube main body 110, the number of the sleeving connection pieces 310 is two, a plurality of soaking pieces 311 are uniformly and fixedly installed between the sleeving connection pieces 310, a plurality of radiating fins 312 are uniformly welded and installed on two sides of each soaking piece 311, a plurality of heat conducting rings 313 are uniformly sleeved and installed on the outer side of the heat exchange tube main body 110, the contact area between the device and raw materials or air in a furnace can be increased through the sleeving connection piece 310 and the soaking pieces 311, and the heat exchange efficiency and uniformity can be increased.

Finally: the foregoing description of the preferred embodiments of the utility model is not intended to limit the utility model to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and principles of the utility model are intended to be included within the scope of the utility model.

Claims (6)

1. The utility model provides a zinc-plating stove heat exchanger, includes device body (100), device body (100) are including heat exchange tube main part (110), heat exchange tube main part (110) are installed in the zinc-plating stove body, the air intake (111) are fixed to the air inlet end of heat exchange tube main part (110), the air outlet (112) are fixed firmly to the air outlet end of heat exchange tube main part (110), its characterized in that: the utility model discloses a heat exchange tube, including branch pipe body (110), including branch pipe body (210), branch pipe body (210) are installed in the inner wall welding of connecting hole (213), branch pipe body (210) extend to heat exchange tube body (110) outside, the outside fixed mounting of branch pipe body (210) has control valve (211), the tip fixed mounting of branch pipe body (210) has flange piece (212), the outside fixed mounting of heat exchange tube body (110) has soaking subassembly (300).

2. A galvanising furnace heat exchanger according to claim 1, characterized by: the heat exchange tube main body (110) has a flat cross section.

3. A galvanising furnace heat exchanger according to claim 1, characterized by: the soaking component (300) comprises sleeving connection pieces (310), the sleeving connection pieces (310) are sleeved and arranged on the outer side of the heat exchange tube main body (110), the number of the sleeving connection pieces (310) is two, and a plurality of soaking pieces (311) are uniformly and fixedly arranged between the sleeving connection pieces (310).

4. A galvanising furnace heat exchanger according to claim 3, characterized in that: a plurality of radiating fins (312) are uniformly welded and mounted on two sides of the soaking piece (311).

5. A galvanising furnace heat exchanger according to claim 1, characterized by: and a plurality of heat conducting rings (313) are uniformly sleeved on the outer side of the heat exchange tube main body (110).

6. A galvanising furnace heat exchanger according to claim 1, characterized by: a filter screen is arranged in the air inlet (111).