CN207967177U - Efficient magnesium air fuel cell energy storage experimental rig - Google Patents

Abstract

The utility model discloses efficient magnesium air fuel cell energy storage experimental rigs, including hot test area and low-temperature test area, it is equipped with oxidant heat exchanger tube, fuel heat exchanger tube and high-temperature heat exchange tube in the hot test area, low-temperature heat exchange pipe is equipped in the low-temperature test area.The utility model compared with prior art the advantages of be：It is simple in structure, easy to operation, safe and reliable, realize the speeding-up simulation to thermal force and mechanical load in fuel battery performance deterioration process, thermal force and mechanical load alternation curve can be flexibly set according to experimental condition, the energy storage experiment of efficient magnesium air fuel cell can be completed in a short time, conventional efficient is greatly improved, experimental cost is reduced.

Description

Efficient magnesium air fuel cell energy storage experimental rig

Technical field

The utility model is related to battery energy storage experimental rig, in particular to efficient magnesium air fuel cell energy storage experiment dresses It sets.

Background technology

Fuel cell is a kind of power generator directly converting the chemical energy being stored in fuel and oxidant to electric energy, Have many advantages, such as high specific energy compared with conventional power source, high efficiency, easily use, low stain, has wide answer in fields such as mobile powers Use foreground.Fuel cell is in periodical start and stop, with progress and stopping that its internal chemical reacts, fuel battery inside temperature Cyclically-varying alternation thermal force can be caused to its encapsulating structure；Simultaneously as anode fuel-reaction production gas and cathode Oxidant pressure drop in raceway groove caused by when conversion zone flows, can to fuel cell apply low frequency mechanical load research with Fatigue degradation rule of the estimating fuel battery under thermal force and mechanical load function improves cell performance to improving battery design Energy and its reliability are of great significance.

Utility model content

The purpose of this utility model is to provide a kind of efficient magnesium air fuel cell energy storage experimental rig.

In order to solve the above technical problems, technical solution provided by the utility model is：Efficient magnesium air fuel cell energy storage Experimental rig, including chamber, the chamber is interior to be equipped with high-temperature cabinet and cryogenic box, between the high-temperature cabinet and cryogenic box Equipped with thermal insulative board, it is equipped with hot test area in the high-temperature cabinet, oxidant heat exchanger tube, combustion are equipped in the hot test area Material heat exchanger tube and high-temperature heat exchange tube, the oxidant heat exchanger tube are connected with oxidant storage tank, institute by oxidant feed pipe The oxidant feed pipe stated is equipped with oxidant pump, and the fuel heat exchanger tube is connected with fuel storing by fuel-feed pipe Tank, the fuel-feed pipe are equipped with petrolift, and the oxidant heat exchanger tube is connected with oxygen by oxidant recovery tube Agent recycling can, the fuel heat exchanger tube are connected with fuel recovery tank by recovery pipe, are set in the cryogenic box There is low-temperature test area, is equipped with low-temperature heat exchange pipe in the low-temperature test area, the low-temperature heat exchange pipe passes through law temperature joining pipe It is connected with solenoid valve, the high-temperature heat exchange tube is connected by high temperature conjunction pipe with the solenoid valve, the electromagnetism Valve is equipped with environment pipeline storage tank by environment piping connection, and the environment pipeline is equipped with environment pipeline liquid pump, the height Warm heat exchanger tube and low-temperature heat exchange pipe are connected by environment pipeline recovery tube with the environment pipeline storage tank.

As an improvement, the high-temperature cabinet is equipped with the high temperature case lid being used cooperatively.

As an improvement, the cryogenic box is equipped with the low temperature case lid being used cooperatively.

As an improvement, high-temperature medium built in the hot test area, cryogenic media built in the low-temperature test area.

As an improvement, the oxidant storage tank, oxidant pump, fuel reservoir, petrolift, oxidant recycling can and fuel Recycling can is located at outside the high-temperature cabinet.

As an improvement, the solenoid valve, environment pipeline liquid pump, environment pipeline storage tank are located at the high-temperature cabinet and cryogenic box It is external.

The utility model compared with prior art the advantages of be：The utility model is simple in structure, easy to operation, safe can It leans on, realizes the speeding-up simulation to thermal force and mechanical load in fuel battery performance deterioration process, it can be according to experimental condition spirit Setting thermal force living and mechanical load alternation curve can be completed in a short time the energy storage examination of efficient magnesium air fuel cell It tests, greatly improves conventional efficient, reduce experimental cost.

Description of the drawings

Fig. 1 is the structural schematic diagram of the efficient magnesium air fuel cell energy storage experimental rig of the utility model.

As shown in the figure：1, chamber, 2, high-temperature cabinet, 3, cryogenic box, 4, thermal insulative board, 5, hot test area, 6, oxidant changes Heat pipe, 7, fuel heat exchanger tube, 8, high-temperature heat exchange tube, 9, oxidant feed pipe, 10, oxidant storage tank, 11, oxidant pump, 12, combustion Expect feed pipe, 13, fuel reservoir, 14, petrolift, 15, oxidant recovery tube, 16, oxidant recycling can, 17, recovery pipe, 18, fuel recovery tank, 19, low-temperature test area, 20, low-temperature heat exchange pipe, 21, law temperature joining pipe, 22, solenoid valve, 23, high temperature conjunction Pipe, 24, environment pipeline, 25, environment pipeline storage tank, 26, environment pipeline liquid pump, 27, environment pipeline recovery tube.

Specific implementation mode

The following describes the utility model in further detail with reference to the accompanying drawings.

In conjunction with attached drawing, efficient magnesium air fuel cell energy storage experimental rig, including chamber 1 is set in the chamber 1 There are high-temperature cabinet 2 and cryogenic box 3, thermal insulative board 4 is equipped between the high-temperature cabinet 2 and cryogenic box 3, is equipped in the high-temperature cabinet 2 Hot test area 5, the hot test area 5 is interior to be equipped with oxidant heat exchanger tube 6, fuel heat exchanger tube 7 and high-temperature heat exchange tube 8, institute The oxidant heat exchanger tube 6 stated is connected with oxidant storage tank 10 by oxidant feed pipe 9, on the oxidant feed pipe 9 Equipped with oxidant pump 11, the fuel heat exchanger tube 7 is connected with fuel reservoir 13, the fuel by fuel-feed pipe 12 Feed pipe 12 is equipped with petrolift 14, and the oxidant heat exchanger tube 6 is connected with oxidant by oxidant recovery tube 15 and returns Closed cans 16, the fuel heat exchanger tube 7 are connected with fuel recovery tank 18 by recovery pipe 17, in the cryogenic box 3 Equipped with low-temperature test area 19, low-temperature heat exchange pipe 20 is equipped in the low-temperature test area 19, the low-temperature heat exchange pipe 20 passes through Law temperature joining pipe 21 is connected with solenoid valve 22, and the high-temperature heat exchange tube 8 passes through high temperature conjunction pipe 23 and the solenoid valve 22 are connected, and the solenoid valve 22 is connected with environment pipeline storage tank 25, the environment pipeline 24 by environment pipeline 24 It is equipped with environment pipeline liquid pump 26, the high-temperature heat exchange tube 8 and low-temperature heat exchange pipe 20 pass through environment pipeline recovery tube 27 and institute The environment pipeline storage tank 25 stated is connected.

The high-temperature cabinet 2 is equipped with the high temperature case lid being used cooperatively.

The cryogenic box 3 is equipped with the low temperature case lid being used cooperatively.

High-temperature medium built in the hot test area 5, cryogenic media built in the low-temperature test area 19.

Oxidant storage tank 10, oxidant pump 11, fuel reservoir 13, petrolift 14, oxidant recycling can 16 and the combustion Material recycling can 18 is located at outside the high-temperature cabinet 2.

The solenoid valve 22, environment pipeline liquid pump 26, environment pipeline storage tank 25 are located at the high-temperature cabinet 2 and cryogenic box 3 It is external.

The utility model and embodiments thereof are described above, this description is no restricted, shown in attached drawing Also be the utility model one of embodiment, actual structure is not limited to this.All in all if this field Those of ordinary skill is enlightened by it, without deviating from the purpose of the present invention, not inventively design with The similar frame mode of the technical solution and embodiment, all should belong to the protection range of the utility model.

Claims (6)

1. efficient magnesium air fuel cell energy storage experimental rig, including chamber（1）, it is characterised in that：The chamber（1） It is interior to be equipped with high-temperature cabinet（2）And cryogenic box（3）, the high-temperature cabinet（2）And cryogenic box（3）Between be equipped with thermal insulative board（4）, described High-temperature cabinet（2）It is interior to be equipped with hot test area（5）, the hot test area（5）It is interior to be equipped with oxidant heat exchanger tube（6）, fuel changes Heat pipe（7）And high-temperature heat exchange tube（8）, the oxidant heat exchanger tube（6）Pass through oxidant feed pipe（9）It is connected with oxidant Storage tank（10）, the oxidant feed pipe（9）It is equipped with oxidant pump（11）, the fuel heat exchanger tube（7）Pass through fuel Feed pipe（12）It is connected with fuel reservoir（13）, the fuel-feed pipe（12）It is equipped with petrolift（14）, the oxygen Agent heat exchanger tube（6）Pass through oxidant recovery tube（15）It is connected with oxidant recycling can（16）, the fuel heat exchanger tube（7） Pass through recovery pipe（17）It is connected with fuel recovery tank（18）, the cryogenic box（3）It is interior to be equipped with low-temperature test area（19）, The low-temperature test area（19）It is interior to be equipped with low-temperature heat exchange pipe（20）, the low-temperature heat exchange pipe（20）Pass through law temperature joining pipe （21）It is connected with solenoid valve（22）, the high-temperature heat exchange tube（8）Pass through high temperature conjunction pipe（23）With the solenoid valve （22）It is connected, the solenoid valve（22）Pass through environment pipeline（24）It is connected with environment pipeline storage tank（25）, the ring Border pipeline（24）It is equipped with environment pipeline liquid pump（26）, the high-temperature heat exchange tube（8）With low-temperature heat exchange pipe（20）Pass through environment Pipeline recovery tube（27）With the environment pipeline storage tank（25）It is connected.

2. efficient magnesium air fuel cell energy storage experimental rig according to claim 1, it is characterised in that：The high temperature Case（2）It is equipped with the high temperature case lid being used cooperatively.

3. efficient magnesium air fuel cell energy storage experimental rig according to claim 1, it is characterised in that：The low temperature Case（3）It is equipped with the low temperature case lid being used cooperatively.

4. efficient magnesium air fuel cell energy storage experimental rig according to claim 1, it is characterised in that：The high temperature Trial zone（5）Built-in high-temperature medium, the low-temperature test area（19）Built-in cryogenic media.

5. efficient magnesium air fuel cell energy storage experimental rig according to claim 1, it is characterised in that：The oxidation Agent storage tank（10）, oxidant pump（11）, fuel reservoir（13）, petrolift（14）, oxidant recycling can（16）With fuel recovery tank （18）Positioned at the high-temperature cabinet（2）It is external.

6. efficient magnesium air fuel cell energy storage experimental rig according to claim 1, it is characterised in that：The electromagnetism Valve（22）, environment pipeline liquid pump（26）, environment pipeline storage tank（25）Positioned at the high-temperature cabinet（2）And cryogenic box（3）It is external.