CN209877654U - Graphite bipolar plate solidification cooling furnace for fuel cell - Google Patents

Abstract

The utility model discloses a fuel cell graphite bipolar plate solidification cooling furnace, including the feeding conveyor who connects gradually, solidification cooling conveyer, the discharge conveyor, be provided with the feed gate between above-mentioned feeding conveyor and the above-mentioned solidification cooling conveyer, above-mentioned solidification cooling conveyer middle zone is provided with the dodge gate, be provided with the discharge gate between above-mentioned solidification cooling conveyer and the discharge conveyor, the top that above-mentioned solidification cooling conveyer is located between above-mentioned feed gate and the above-mentioned dodge gate is provided with the heater, it is provided with a plurality of circulating fan to be located above-mentioned heater top between above-mentioned feed gate and the above-mentioned dodge gate, the top that above-mentioned solidification cooling conveyer is located between above-mentioned dodge gate and the above-mentioned discharge gate is provided with a plurality of cooling blower. The beneficial effects of the utility model reside in that, improved solidification cooling effect, improved the quality of product.

Description

Graphite bipolar plate solidification cooling furnace for fuel cell

Technical Field

The utility model relates to a solidification cooling furnace, in particular to a graphite bipolar plate solidification cooling furnace for a fuel cell.

Background

A fuel cell is a chemical device that directly converts chemical energy of fuel into electrical energy, and is also called an electrochemical generator. It is a fourth power generation technology following hydroelectric power generation, thermal power generation and atomic power generation. The fuel cell converts the Gibbs free energy in the chemical energy of the fuel into electric energy through electrochemical reaction, and is not limited by the Carnot cycle effect, so the efficiency is high; in addition, fuel cells use fuel and oxygen as raw materials; meanwhile, no mechanical transmission part is arranged, so that no noise pollution is caused, and the discharged harmful gas is less. It can be seen that from the viewpoint of energy saving and ecological environment protection, fuel cells are the most promising power generation technology, and currently, in the field of fuel cell production, solidification and cooling of graphite bipolar plates of fuel cells are important links in the field of fuel cell production, and a solidification and cooling furnace for performing such operation needs to provide higher-quality solidification and cooling performance.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to provide a fuel cell graphite bipolar plate solidification cooling furnace, improved solidification cooling effect, improved the quality of product.

The utility model discloses a realize through following technical scheme.

The utility model provides a fuel cell graphite bipolar plate solidification cooling furnace, including the feeding conveyer, solidification cooling conveyer, the ejection of compact conveyer that connect gradually, be provided with the feed door between above-mentioned feeding conveyer and the above-mentioned solidification cooling conveyer, above-mentioned solidification cooling conveyer middle zone is provided with the isolation door, be provided with the discharge door between above-mentioned solidification cooling conveyer and the ejection of compact conveyer, the top that above-mentioned solidification cooling conveyer is located between above-mentioned feed door and the above-mentioned isolation door is provided with the heater, it is provided with a plurality of circulating fans to be located above-mentioned heater between above-mentioned feed door and the above-mentioned isolation door, the top that above-mentioned solidification cooling conveyer is located between above-mentioned isolation door and the above-mentioned discharge door is provided with a plurality of cooling fans.

Further, a feeding detection switch is arranged at the position, located at the isolating door, of the feeding conveyor.

Furthermore, the solidification cold conveyor is provided with a solidification detection switch at the position of the isolation door.

Furthermore, a discharge detection switch is arranged at the discharge door of the solidification cooling conveyor.

Further, above-mentioned material conveyer is located the end and is provided with the material detection switch of getting.

Furthermore, an air inlet pipe externally connected with a clean low-temperature air source is arranged above the solidification and cooling conveyor between the feeding door and the isolation door, and an air outlet port of the air inlet pipe is positioned close to the feeding door.

Furthermore, an exhaust duct is provided, an air inlet port of the exhaust duct is located between the isolation door and the discharge door of the solidification cooling conveyor and is close to the discharge door, the exhaust duct is provided with an air blower, and an air outlet port of the exhaust duct is located outside the solidification cooling conveyor.

Furthermore, the air outlet port of the exhaust pipe is arranged above the feeding conveyor at the feeding door, and the air outlet of the exhaust pipe is fixedly provided with an exhaust hood.

The utility model has the advantages that:

the stable solidification cooling of the fuel cell graphite bipolar plate is realized, better air flow is realized in the solidification overshoot to assist the solidification effect, the product can be rapidly cooled under the action of the cooling fan and the exhaust circulation in the cooling process, and the whole automatic operation is realized by matching with each detection switch, so that the production efficiency of the product is improved.

Drawings

FIG. 1 is an illustration of a fuel cell graphite bipolar plate solidification cooling furnace;

fig. 2 is a structural schematic diagram of a graphite bipolar plate solidification cooling furnace of a fuel cell.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples.

Fig. 1 is an illustration of a curing and cooling furnace for a graphite bipolar plate of a fuel cell, fig. 2 is a schematic structural diagram of the curing and cooling furnace for the graphite bipolar plate of the fuel cell, fig. 1 and fig. 2, the curing and cooling furnace for the graphite bipolar plate of the fuel cell of the present invention comprises a feeding conveyor 1, a curing and cooling conveyor 2 and a discharging conveyor 3 which are connected in sequence, a feeding gate 4 is arranged between the feeding conveyor 1 and the curing and cooling conveyor 2, an isolation gate 5 is arranged in the middle region of the curing and cooling conveyor 2, a discharging gate 6 is arranged between the curing and cooling conveyor 2 and the discharging conveyor 3, a heater 7 is arranged above the curing and cooling conveyor 2 between the feeding gate 4 and the isolation gate 5, a plurality of circulating fans 8 are arranged above the heater 7 between the feeding gate 4 and the isolation gate 5, a plurality of cooling fans 9 are provided above the solidification cooling conveyor 2 between the isolation door 5 and the discharge door 6.

The utility model discloses, its region is feeding section 100, solidification section 200, cooling zone 300, ejection of compact section 400 according to the functional partitioning in proper order.

Further, the feeding conveyor 1 is provided with a feeding detection switch 10 at the isolation door 5.

Further, the solidification cold conveyor 2 is provided with a solidification detection switch 11 at the isolation door 5.

Further, the solidification cooling conveyor 2 is provided with a discharge detection switch 12 at the discharge door 6.

Further, the material discharging conveyor 2 is provided with a material taking detection switch 13 at the tail end.

Further, an air inlet pipe 14 externally connected with a clean low-temperature air source is arranged above the solidification cooling conveyor 2 between the feeding door 4 and the isolation door 5, and an air outlet port of the air inlet pipe 14 is located near the feeding door 4.

Further, an exhaust duct 15 is provided, an air inlet port of the exhaust duct 15 is located between the isolation door 5 and the discharge door 6 of the solidification cooling conveyor 2 and is close to the discharge door 6, the exhaust duct 15 is equipped with an air blower, and an air outlet port of the exhaust duct 15 is located outside the solidification cooling conveyor 2.

Further, the air outlet of the exhaust duct 15 is disposed above the feeding conveyor 2 at the feeding gate 4, and an exhaust hood 16 is fixedly disposed at the air outlet of the exhaust duct 15.

The utility model discloses a use:

the product is placed on a feed inlet of a feeding section, a feeding conveyor conveys the product, the product is stopped after being conveyed in place, a feeding detection switch detects a product signal, a feeding door of a curing section is opened, the feeding conveyor and a curing cooling conveyor synchronously convey the product, an exhaust hood of the curing section exhausts hot air, the product stops being conveyed after being conveyed in place, and the feeding door is closed.

The heater of the curing section heats air, the circulating fan accelerates air flow and promotes temperature balance, hot air heats products and cures adhesive glue, the curing cooling conveyor conveys the products after curing is finished, conveying is stopped after the products are conveyed in place, the curing detection switch detects a product signal, the isolation door is opened, the curing cooling conveyor conveys the products, conveying is stopped after the products are conveyed in place, and the isolation door is closed.

The cooling fan of the cooling section cools air, accelerates air flow and promotes temperature balance, and after cooling is completed, the solidification cooling conveyor conveys products, stops conveying after conveying in place, detects a product signal by the discharge detection switch, starts the discharge door, synchronously conveys the products by the solidification cooling conveyor and the discharge conveyor, stops conveying after conveying in place, and closes the discharge door.

And conveying the product, stopping conveying after the product is conveyed in place, detecting a product signal by a material taking detection switch, and sending a product offline signal.

The exhaust pipe and the air inlet pipe, the exhaust pipe removes smoke dust high-temperature air, and the air inlet pipe sucks clean low-temperature air.

The utility model discloses, fuel cell graphite bipolar plate solidification cooling furnace has realized fuel cell graphite bipolar plate's stable solidification cooling, has better air current in the solidification overshoots with the auxiliary curing effect, and the cooling process makes the product can cool off fast through cooling blower and exhaust cycle's effect, cooperates each detection switch, realizes whole automatic operation, has improved the production efficiency of product.

The above embodiments are only for illustrating the technical conception and the features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, which cannot limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered by the protection scope of the present invention.

Claims (8)

1. The utility model provides a fuel cell graphite bipolar plate solidification cooling furnace, its characterized in that, including the feeding conveyer, solidification cooling conveyer, the ejection of compact conveyer that connect gradually, feeding door is provided with between feeding conveyer and the solidification cooling conveyer, solidification cooling conveyer middle zone is provided with the insulated door, be provided with the ejection of compact door between solidification cooling conveyer and the ejection of compact conveyer, solidification cooling conveyer is located the top between feeding door and the insulated door is provided with the heater, be located between feeding door and the insulated door the heater top is provided with a plurality of circulating fan, solidification cooling conveyer is located the top between insulated door and the ejection of compact door is provided with a plurality of cooling fan.

2. The fuel cell graphite bipolar plate solidification cooling furnace of claim 1, wherein the feed conveyor is provided with a feed detection switch at an isolation door.

3. The furnace of claim 1, wherein the solidification cold conveyor is provided with a solidification detection switch at the isolation door.

4. The fuel cell graphite bipolar plate solidification cooling furnace of claim 1, wherein the solidification cooling conveyor is provided with an outfeed detection switch at the outfeed door.

5. The fuel cell graphite bipolar plate solidification cooling furnace of claim 1, wherein the discharge conveyor is provided with a take-out detection switch at an end thereof.

6. The curing cooling furnace of claim 1, wherein an air inlet pipe externally connected with a clean low-temperature air source is arranged above the curing cooling conveyor between the feeding door and the isolation door, and an air outlet port of the air inlet pipe is positioned near the feeding door.

7. The fuel cell graphite bipolar plate solidification cooling furnace as claimed in claim 1, wherein an exhaust duct is provided, an air inlet port of the exhaust duct is located between the isolation door and the discharge door of the solidification cooling conveyor and close to the discharge door, the exhaust duct is equipped with an air blower, and an air outlet port of the exhaust duct is located outside the solidification cooling conveyor.

8. The curing and cooling furnace for the graphite bipolar plate of the fuel cell as claimed in claim 7, wherein the air outlet port of the exhaust duct is arranged above the feeding conveyor at the feeding gate, and the air outlet of the exhaust duct is fixedly provided with an exhaust hood.