CN217764313U - Combustion apparatus and sintering equipment - Google Patents

Abstract

The utility model discloses a burner and sintering equipment relates to solar cell thermal treatment technical field. A combustion apparatus specifically includes: the combustion box body with the combustion chamber, the heat exchange box body with the air inlet communicated with the air outlet of the combustion box body and used for cooling hot air flow exhausted from the combustion box body, and the cooling assembly arranged on one side of the air outlet of the combustion box body and used for cooling hot air flow in the heat exchange box body when the heat exchange box body stops working. The aim is to continuously cool the high-temperature gas generated by the combustion chamber after the water cooling equipment stops working, so that the water cooling equipment is prevented from being damaged.

Description

Combustion apparatus and sintering equipment

Technical Field

The utility model relates to a solar cell heat treatment technical field, in particular to burner and sintering equipment.

Background

When the solar photovoltaic cell is prepared, the surface of the silicon wafer is required to be dried and cured after the conductive paste is printed on the surface of the silicon wafer. In the process of drying and solidifying the conductive paste, organic matters are volatilized, and a large amount of harmful pollutants are accompanied, so that the working environment is polluted.

At present, in order to avoid the pollution problem caused by the volatilization of organic matters, the organic matters are often fused into a combustion chamber to be combusted, the external pipeline is easily damaged by hot air flow exhausted by combustion, and meanwhile, the heat generated after the combustion cannot be recovered, so that the waste of resources is caused.

In order to solve the technical problem, the water cooling equipment is usually installed at the exhaust port of the combustion chamber to cool the high-temperature gas exhausted from the combustion chamber, so that heat recovery is realized. Therefore, how to continue to cool the hot air flow exhausted from the combustion chamber after the water cooling equipment stops working avoids the damage of the water cooling equipment, and the guarantee of the normal operation of the equipment becomes a technical problem to be solved urgently.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a burner and sintering equipment, aim at when the water-cooling equipment stop work back, continue to cool down the high-temperature gas that the combustion chamber produced, avoid the damage of water-cooling equipment.

In order to achieve the above object, the utility model provides a combustion apparatus, be used for carrying out the heat transfer box of cooling down and locating burning box exhaust hot gas flow including the gas outlet intercommunication that has burning box, air inlet and the burning box in burning chamber one side of burning box gas outlet carries out the cooling subassembly of cooling down to the hot gas flow in the heat transfer box when heat transfer box stop work.

In an embodiment of the application, the cooling assembly includes an air pump capable of blowing cold air, and a first blowing pipe body capable of guiding the cold air blown by the air pump into the heat exchange box to exchange heat with hot air in the heat exchange box.

In an embodiment of this application, still be connected with on the air pump and can be with the cold air part that the air pump blew off guide to the gas outlet department of heat transfer box with carry out at least one second body of blowing that cools down to heat transfer box exhaust hot-air current.

In an embodiment of the application, be equipped with on the burning box and be used for monitoring the temperature detection spare of burning chamber temperature.

In an embodiment of this application, be provided with along the horizontal direction interval in the combustion chamber with the combustion chamber separates into the heat insulating board in at least three combustion space that is listed as side by side, the air inlet of burning box is located the bottom of burning box and communicates with outside combustion space, the gas outlet of burning box is located the top of burning box and communicates with outside combustion space, wherein, the air inlet of burning box and the gas outlet of burning box switch on with the combustion space of difference respectively, be equipped with the ventilation zone who communicates two adjacent combustion spaces on the heat insulating board, the ventilation zone of two arbitrary adjacent heat insulating boards of intercommunication sets up along vertical direction stagger, and the quantity in combustion chamber is the odd number.

In an embodiment of the present application, the inner wall of the combustion chamber is provided with a heat insulation cotton plate.

In an embodiment of the application, the combustion box body is provided with a disassembly handle.

In an embodiment of this application, be equipped with water inlet and delivery port on the heat transfer box, be equipped with the condenser pipe that is the curve extension with water inlet and delivery port intercommunication in the heat transfer box, the condenser pipe has a plurality of straight tube parts that are array distribution and connects the elbow portion of adjacent straight tube part.

In an embodiment of the present application, any two adjacent rows or two columns of straight tubes in the straight tubes arranged in an array are arranged in a staggered manner.

The application also discloses sintering equipment, including treat the heating chamber that the machined part carries out the heating, locate treat in the heating chamber that the machined part carries out the conveying subassembly that conveys and with the heating chamber switch on be used for treating the organic gas that the machined part heating chamber produced as above arbitrary one burner that burns.

By adopting the technical scheme, the cooling assembly is arranged when the hot air flow in the heat exchange box body is continuously cooled when the heat exchange box body stops working, and the heat exchange box body damage caused by the continuous rise of the temperature in the heat exchange box body after the heat exchange box body stops working is avoided. Meanwhile, the temperature of hot air flow discharged by the combustion box body is reduced to a preset temperature and then discharged, and the working safety of equipment is improved.

Drawings

The invention will be described in detail with reference to the following embodiments and drawings, in which:

fig. 1 is a schematic structural diagram of a first embodiment of the present invention.

Fig. 2 isbase:Sub>A cross-sectional view taken atbase:Sub>A-base:Sub>A in fig. 1.

Fig. 3 is an enlarged schematic view of a portion a in fig. 2.

Figure 4 is a front view of the heat shield.

Figure 5 is a side view of the heat shield.

Fig. 6 is an exploded view of the combustion case of fig. 1.

Fig. 7 is a schematic view of the internal structure of the heat exchange box in fig. 1.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the present invention is described in detail with reference to the accompanying drawings and embodiments. It should be understood that the following specific examples are only for illustrating the present invention and are not to be construed as limiting the present invention.

As shown in fig. 1 to 7, in order to achieve the above object, the present invention provides a combustion apparatus, which comprises a combustion box 30 with a combustion chamber, a heat exchange box 40 having an air inlet and a combustion box, and a cooling component disposed on one side of the air outlet of the combustion box 30 for cooling the hot air flow in the heat exchange box 40 when the heat exchange box 40 stops working.

Specifically, the combustion apparatus includes a combustion case 30, a heat exchange case 40, and a cooling assembly.

The combustion box 30 is made of a metal material, such as an aluminum alloy material or an alloy steel material, and the combustion box 30 made of the metal material has the advantages of strong supporting capability, wear resistance, good heat conductivity and the like. When the combustion box 30 is made of other inorganic materials according to the design requirement, the combustion box 30 made of inorganic materials has the advantages of low cost and the like. A combustion chamber is arranged in the combustion box body 30 and is used for burning organic matters generated in the solar cell panel production process. The combustion box 30 has an air inlet and an air outlet, wherein the air inlet is located at the bottom of the combustion box 30 and is used for introducing gas with organic matters into a combustion cavity in the combustion box 30, and the air outlet is located at the top of the combustion box 30 and is used for discharging the gas after combustion. A heat source is arranged in the combustion box body 30, and the heat source can be generated after resistance wires are electrified or can be generated by combustion of combustible gas. In the application, the resistance wire is preferably generated after being electrified.

The heat exchange box body 40 is provided with an air inlet and an air outlet, the air inlet of the heat exchange box body 40 is communicated with the air outlet 33 of the combustion box body, and the air outlet of the heat exchange box body 40 can be communicated with the atmosphere or other equipment through the flow guide pipe body. The heat exchange box 40 is provided with a cold source capable of exchanging heat with the hot air flow discharged from the combustion box 30, and the cold source may be a condenser 43, or externally introduced cold air, or the like. The heat exchange box 40 is also made of metal materials, such as aluminum alloy materials, alloy steel materials and the like, and the heat exchange box 40 made of the metal materials has the advantages of good heat conductivity, wear resistance and the like. Of course, other inorganic materials may be adopted according to the design requirement, and the effect of the inorganic material is consistent with the above content, which is not described herein.

A cooling assembly is arranged at the joint of the air outlet 33 of the combustion box and the air inlet of the heat exchange box 40, and cools the high-temperature air flow in the heat exchange box 40 when the heat exchange box 40 stops working, namely the condenser pipe 43 or the cold air stops working. So as to ensure that the hot air flow discharged from the combustion box 30 reaches the preset discharge condition, protect the heat exchange box 40, and avoid the damage of the heat exchange box 40.

By adopting the technical scheme, the cooling assembly is arranged when the heat exchange box body 40 stops working and the hot air flow in the heat exchange box body 40 continues to be cooled, so that the heat exchange box body 40 is prevented from being damaged due to continuous rise of the temperature in the heat exchange box body 40 after the heat exchange box body 40 stops working. Meanwhile, the temperature of the hot air flow discharged from the combustion box body 30 is reduced to the preset temperature and then discharged, and the working safety of the equipment is improved.

In an embodiment of the present application, the cooling assembly includes an air pump (not shown) for blowing out cool air, and a first blowing pipe 10 for guiding the cool air blown out by the air pump (not shown) to the heat exchange box for exchanging heat with the hot air in the heat exchange box.

Specifically, the cooling assembly includes an air pump (not shown in the drawings) and the first blowing pipe 10.

The air pump (not shown) is a pneumatic vacuum pump commonly used in the prior art, and the pneumatic vacuum pump has the advantages of small volume, light weight, low noise and the like.

The first blowpipe 10 is made of a metal material, for example, an aluminum alloy material, and the first blowpipe 10 made of the aluminum alloy material has the advantages of strong supporting capability, wear resistance, stable operation and the like.

One end of the first air blowing pipe 10 is connected to an air outlet of an air pump (not shown in the figure), and the other end is connected to an air inlet of the heat exchange box 40 and used for guiding cold air blown out by the air pump (not shown in the figure) to the inside of the heat exchange box 40.

Heat transfer box 40 in this application adopts water-cooled heat transfer box 40, be equipped with solenoid valve in the water-cooled heat transfer box 40, this solenoid valve can be used to open or close the circulating line in the water-cooled heat transfer box 40, also can monitor the velocity of water in the water-cooled heat transfer box 40 circulating line simultaneously, when the solenoid valve detects the circulating line velocity of water in the water-cooled heat transfer box 40 and is less than predetermineeing the threshold value, show water-cooled heat transfer box 40 stop work promptly, solenoid valve sends this signal for air pump (not shown in the figure) through industrial computer (not shown in the figure) this moment, air pump (not shown in the figure) begins to work this moment, go into cold air to heat transfer box 40 internal pump, the hot gas flow to in the heat transfer box 40 is cooled down and is handled.

By adopting the technical scheme, the structure is simple, and the implementation is convenient.

In an embodiment of the present application, the air pump (not shown) is further connected to at least one second blowing pipe 20, which can guide a portion of cold air blown out by the air pump (not shown) to the air outlet of the heat exchange box 40 to cool down the hot air flow discharged from the heat exchange box 40.

Specifically, the air pump (not shown in the figure) is further connected with at least one second air blowing pipe 20 capable of guiding part of cold air blown out by the air pump (not shown in the figure) to the air outlet of the heat exchange box 40, the second air blowing pipe 20 is made of a metal material, and the material of the second air blowing pipe 20 is the same as that of the first air blowing pipe 10, so that the same technical effects are achieved, and the details are not repeated. The number of the second air blowing pipes 20 is two, and the air outlets of the two air blowing pipes are uniformly distributed at the edge of the air outlet of the heat exchange box 40. The mode setting that adopts evenly distributed can make even heat transfer of cold air and the hot-blast of heat transfer box 40 exhaust, and the heat transfer effect is better.

It is of course conceivable that the second blowing pipe 20 may be connected to a separate air pump (not shown), and a separate air pump (not shown) may be used to blow cold air into the second blowing pipe 20, so that the control is simple and the amount of cold air can be adjusted conveniently.

By adopting the technical scheme, the hot air flow exhausted from the heat exchange box body 40 is cooled again through the second air blowing pipe 20, so that the cooling pressure of the first air blowing pipe 10 is reduced, and the stability of the whole combustion device in working is improved.

In an embodiment of the present application, a temperature detector 50 for monitoring the temperature of the combustion chamber is disposed on the combustion box 30.

Specifically, still be equipped with the temperature detection piece 50 that is used for monitoring the inside burning chamber temperature of burning box 30 on burning box 30, through the temperature in the real-time monitoring burning chamber of temperature detection piece 50, be convenient for to the control of burning chamber temperature, conveniently to the temperature regulation in the burning chamber, because there is the highest limit in the temperature in the burning chamber, when the temperature in burning chamber is higher than the highest limit, can cause the damage to the constitution part in burning chamber, consequently need guarantee that the temperature in burning chamber is less than the highest limit. Through the temperature monitoring to burning box 30, can effectively avoid the temperature in burning box 30 to reach the highest limit, guaranteed the security of burning box 30.

In an embodiment of this application, be provided with along the horizontal direction interval in the combustion chamber with the heat insulating board 31 of the combustion space that the combustion chamber is separated into at least three parallels, the air inlet of combustion box 30 is located the bottom of combustion box 30 and communicates with outside combustion space, the gas outlet 33 of combustion box is located the top of combustion box 30 and communicates with outside combustion space, wherein, the gas outlet 33 of combustion box 30 and the combustion box switches on with different combustion space respectively, be equipped with the ventilation zone of two adjacent combustion spaces of intercommunication on the heat insulating board 31, the ventilation zone of two arbitrary adjacent heat insulating boards 31 staggers along vertical direction and sets up, and the quantity in combustion chamber is the odd number.

Specifically, at least two heat insulation plates 31 are arranged in the combustion chamber along the horizontal direction of the combustion chamber, and when the number of the heat insulation plates 31 is two, the combustion chamber is divided into three corresponding parallel combustion spaces by the two heat insulation plates 31. When the number of the heat insulation plates 31 is four, the four heat insulation plates 31 divide the combustion chamber into five corresponding parallel combustion spaces. Wherein the number of the heat insulation plates 31 is an even number, and the heat insulation plates 31 having the even number may partition the combustion chamber into the combustion spaces having the odd number, so that the inlet and the outlet of the combustion case 30 may be located on the opposite two surfaces.

The heat insulation plate 31 is made of calcium aluminum silicate plate, and the calcium aluminum silicate plate has a catalytic effect, can catalyze the combustion of organic matters, and can improve the combustion efficiency of the combustion matters. The surface of the calcium aluminum silicate plate, which can be contacted with organic matters, is provided with a plurality of blind holes 311 which are distributed in a matrix manner, so that the contact area between the calcium aluminum silicate plate and gas containing the organic matters is increased, and the catalytic effect of the calcium aluminum silicate plate is improved. Meanwhile, the aluminum calcium silicate board can also play a role in heat preservation and reduce heat loss.

The air inlet of the combustion casing 30 is located at the bottom of the combustion casing 30, and the air inlet of the combustion casing 30 is communicated with the combustion space located at the outermost side for introducing the gas containing the organic matter into the combustion space. In order to achieve the maximum intake setting for combustion case 30, the cross-sectional area of the intake port of combustion case 30 is equal to the cross-sectional area of the combustion space communicating therewith.

The gas outlet 33 of the combustion box body is positioned at the top of the combustion box body 30, and the gas outlet 33 of the combustion box body is communicated with the combustion space positioned at the outermost side and used for guiding out the combusted gas to the outside of the combustion space. In order to achieve a maximum exhaust setting for the combustion casing 30, the cross-sectional area of the outlet 33 of the combustion casing is equal to the cross-sectional area of the combustion space in communication therewith.

The gas outlet 33 of the combustion box body and the gas inlet of the combustion box body 30 are respectively communicated with different combustion spaces, and by adopting the arrangement, the passing path of the gas with organic matters can be prolonged, so that the gas with organic matters can be fully combusted in the combustion spaces.

The heat insulation plate 31 is provided with the ventilation areas communicated with the two adjacent combustion spaces, and the ventilation areas on the two adjacent heat insulation plates 31 are arranged in a staggered manner, so that the passing path of the gas with organic matters can be prolonged, and the sufficient combustion of the organic matters in the combustion spaces is realized. Preferably, the ventilation area is provided at the end of the heat insulation plate 31, so that the gas with organic matters can completely pass through all the combustion spaces, and the sufficient combustion of the gas with organic matters can be realized.

By adopting the technical scheme, the combustion chamber is divided into odd number of combustion spaces by the heat insulation plate 31, then two staggered openings are respectively arranged at the top and the bottom of the combustion box body 30, the two openings are respectively communicated with the combustion space at the outermost side, the passing path of gas with organic matters is prolonged, and the organic matters are fully combusted. Simple structure and convenient implementation.

In one embodiment of the present application, the inner wall of the combustion chamber is provided with an insulating cotton sheet 32.

Specifically, be provided with thermal-insulated cotton board 32 on the inner wall in burning chamber, reduce the heat transfer effect of the heat source in the burning chamber and the shell body of burning box 30 through setting up thermal-insulated cotton board 32, reduced thermal loss. While also avoiding damage to the outer shell of the combustion case 30 in a high temperature environment.

Adopt above-mentioned technical scheme, reduce the heat transfer effect of the heat source in the combustion chamber and the shell of burning box 30 through setting up thermal-insulated cotton board 32, reduce the calorific loss in the combustion chamber, avoid burning box 30's shell to be damaged under the environment of high temperature simultaneously.

In an embodiment of the present application, the combustion casing 30 is provided with a detachable handle 35.

Specifically, be equipped with on the burning box 30 and dismantle handle 35, be convenient for the equipment and the dismantlement of burning box 30, the maintenance in the later stage of being convenient for through dismantling handle 35.

In an embodiment of the present application, a water inlet 41 and a water outlet 42 are arranged on the heat exchange box body 40, a condensation pipe 43 extending in a curved manner and communicated with the water inlet 41 and the water outlet 42 is arranged in the heat exchange box body 40, and the condensation pipe 43 has a plurality of straight pipe portions distributed in an array manner and bent pipe portions connecting adjacent straight pipe portions.

Specifically, be equipped with water inlet 41 and delivery port 42 on the heat transfer box 40, be equipped with the condenser pipe 43 of both ends respectively with water inlet 41 and delivery port 42 intercommunication in the heat transfer box 40, condenser pipe 43 becomes the curve form and extends in heat transfer box 40, can prolong the length of condenser pipe 43 in heat transfer box 40 through curved mode extension to increase the heat transfer area between the hot air in condenser pipe 43 and the heat transfer box 40.

The condensation pipe 43 is made of metal material, such as metal aluminum, copper, etc., and the condensation pipe 43 made of metal material has the advantages of light weight, good heat conduction effect, etc. The condenser pipe 43 is provided with a plurality of straight pipe parts distributed in an array manner and bent pipe parts connecting adjacent straight pipe parts, so that the length of the condenser pipe 43 in the heat exchange box body 40 is further prolonged, and the condenser pipe is simple in structure and convenient to implement.

In an embodiment of the present application, any two adjacent rows or two columns of straight tubes in the straight tubes arranged in an array are arranged in a staggered manner.

Specifically, two arbitrary adjacent rows or two rows of straight tubes in the straight tubes arranged in the array are staggered and arranged, so that the air flow can exchange heat with at least one layer of straight tube, and the heat exchange effect of the condensation pipe 43 is further improved.

The application also discloses sintering equipment including treat the heating chamber that the machined part carries out the heating, locate treat in the heating chamber that the machined part carries out the conveying subassembly that conveys, and with the heating chamber switch on be used for treating the organic gas that the machined part heating chamber produced as above arbitrary burner that burns.

The heating chamber is used for heating the workpiece to be processed, so that the coated material on the workpiece to be processed is solidified, the conveying assembly is further arranged in the heating chamber and used for conveying the workpiece to be processed, the workpiece to be processed is moved in the heating chamber, the combustion device is communicated with the heating chamber, when the workpiece to be processed is heated, part of the coated material can be volatilized into gas in the heating chamber, and the combustion device combusts the gas mixed with the coated material, so that the coated material is prevented from being discharged out of the atmosphere.

The above only be the preferred embodiment of the utility model discloses a not consequently restriction the patent scope of the utility model, all be in the utility model discloses a under the design, utilize the equivalent structure transform of what the content of the description and the attached drawing was done, or direct/indirect application all includes in other relevant technical field the utility model discloses a patent protection is within range.

Claims (10)

1. The utility model provides a combustion apparatus, its characterized in that, is used for carrying out the heat transfer box of cooling down to burning box exhaust hot gas flow including the gas outlet intercommunication of the burning box that has the burning chamber, air inlet and burning box and locates one side of burning box gas outlet carries out the cooling assembly of cooling down to hot gas flow in the heat transfer box when the heat transfer box stop work.

2. The combustion apparatus as claimed in claim 1, wherein the cooling unit includes an air pump for blowing cool air, and a first blowing duct for guiding the cool air from the air pump into the heat exchange box to exchange heat with the hot air in the heat exchange box.

3. The combustion device as claimed in claim 2, wherein the air pump is further connected to at least one second blowing tube for guiding a portion of cold air blown from the air pump to the air outlet of the heat exchange housing for cooling the hot air flow discharged from the heat exchange housing.

4. The combustion apparatus as claimed in claim 1, wherein said combustion case is provided with a temperature detecting member for monitoring a temperature of said combustion chamber.

5. The combustion device as claimed in claim 1, wherein heat insulating plates are arranged in the combustion chamber at intervals along the horizontal direction to divide the combustion chamber into at least three combustion spaces arranged in parallel, the air inlet of the combustion box is positioned at the bottom of the combustion box and communicated with the outermost combustion space, the air outlet of the combustion box is positioned at the top of the combustion box and communicated with the outermost combustion space, wherein the air inlet of the combustion box and the air outlet of the combustion box are respectively communicated with different combustion spaces, the heat insulating plates are provided with ventilation zones communicated with two adjacent combustion spaces, the ventilation zones of any two adjacent heat insulating plates are staggered along the vertical direction, and the number of the combustion chambers is odd.

6. The combustion apparatus as claimed in claim 1, wherein the combustion chamber is provided with heat insulating cotton sheets on the inner wall thereof.

7. The combustion unit of claim 1, wherein said combustion casing is provided with a detachable handle.

8. The combustion apparatus as claimed in claim 1, wherein the heat exchange housing has a water inlet and a water outlet, and a curvilinearly extending condensation tube communicating with the water inlet and the water outlet is provided in the heat exchange housing, and the condensation tube has a plurality of straight tube portions arranged in an array and a bent tube portion connecting the adjacent straight tube portions.

9. The combustion apparatus as claimed in claim 8, wherein any two adjacent rows or two columns of the arrayed straight tubes are arranged in a staggered manner.

10. A sintering apparatus comprising a combustion device as claimed in any one of claims 1 to 9.

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