CN217403697U - Double-station pile reciprocating stacking device - Google Patents

Abstract

The utility model relates to the technical field of fuel cells, in particular to a double-station electric pile reciprocating stacking device, which comprises a base, a rotating mechanism arranged on the base, a first stacking test mechanism and a second stacking test mechanism arranged on the rotating mechanism, and an air tightness test component arranged at the bottom of the front side of a fixed frame; the first stacking testing mechanism and the second stacking testing mechanism comprise a fixing frame arranged on the rotating mechanism, a rear positioning assembly arranged on the front side of the fixing frame, a first front guide positive assembly arranged on the left side of the fixing frame, a second front guide positive assembly arranged on the right side of the fixing frame, a first side positioning assembly arranged on the left side of the fixing frame and a second side positioning assembly arranged on the right side of the fixing frame. The utility model discloses when one of them piles up accredited testing organization and carry out piling up of galvanic pile, another piles up accredited testing organization and can carry out the gas tightness test, and the piling up of galvanic pile has realized seamless connection with the testing process, has improved the efficiency of piling up and testing, has reduced manufacturing cost.

Description

Double-station pile reciprocating stacking device

Technical Field

The utility model relates to a fuel cell technical field, concretely relates to reciprocal device that piles up of duplex position galvanic pile.

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 without the limitation of Carnot cycle effect, so that the fuel cell has high efficiency, uses the fuel and oxygen as raw materials, has no mechanical transmission part, has no noise pollution and emits few harmful gases. Because the traditional fossil fuels are developed and utilized on a large scale by human beings, in recent years, the development and utilization of environmental protection energy sources such as hydrogen energy sources are receiving more and more attention, and the hydrogen-oxygen fuel cell is more and more taken by people as an important direction of the application of the hydrogen energy sources, so that research and development are continuously carried out, new products emerge endlessly, and with the development of the fuel cell, the fuel cell engine also starts to walk into the field of vision of the public. In the production process of fuel cells and fuel cell engines, the galvanic pile needs to be stacked, and the air tightness test is carried out after the stacking is finished, at present, the stacking of the galvanic pile is generally finished on a jig, and then the air tightness test equipment is connected with the galvanic pile to carry out the air tightness test, but the stacking and the air tightness test of the galvanic pile can consume long time, the stacking position is occupied when the air tightness test is carried out on the galvanic pile, the continuous stacking can not be carried out, the waiting time is long, and the efficiency is low.

SUMMERY OF THE UTILITY MODEL

In order to solve the problem, the utility model provides a reciprocal device that piles up of duplex position galvanic pile.

The utility model discloses a following scheme realizes:

a double-station electric pile reciprocating stacking device comprises a base, a rotating mechanism arranged on the base, a first stacking testing mechanism arranged on the rotating mechanism, and a second stacking testing mechanism arranged on the rotating mechanism; the first stacking testing mechanism and the second stacking testing mechanism respectively comprise a fixed frame arranged on the rotating mechanism, a rear positioning component arranged on the front side of the fixed frame, a first front guide positive component arranged on the left side of the fixed frame, a second front guide positive component arranged on the right side of the fixed frame, a first side positioning component arranged on the left side of the fixed frame and a second side positioning component arranged on the right side of the fixed frame; and the bottom of the front side of the fixing frame is provided with an air tightness testing assembly.

Furthermore, positive subassembly of first preceding and second preceding all including set up in the first driving piece of leading of mount rear side, with the first positive support of leading that leads that just the driving piece output is connected, set up in lead the second on the positive support and lead the driving piece, with the second lead that just the driving piece output is connected lead the positive board, set up in lead the positive board orientation of leading of positive mount one side is just the pole.

Furthermore, the guide plate is provided with a guide seat for connecting the guide rod.

Furthermore, the first side positioning assembly and the second side positioning assembly respectively comprise a positioning frame connected with the fixing frame, a plurality of connecting rods movably connected with the positioning frame, positioning seats connected to one ends of the connecting rods, and first positioning guide rods connected with the positioning seats.

Furthermore, the other end of the connecting rod is also provided with a fixing plate.

Furthermore, the rear positioning assembly comprises a rear positioning base arranged on the front side of the fixing frame and a second positioning guide rod arranged on the rear positioning base.

Furthermore, the fixing frame of the first stacking test mechanism and the fixing frame of the second stacking test mechanism are fixedly connected through a plurality of connecting pieces.

Further, the first stacking test mechanism and the second stacking test mechanism further comprise two product detection assemblies arranged on the left side and the right side of the air tightness detection assembly, and each product detection assembly comprises a detection support and a sensor arranged on the detection support.

Furthermore, the air tightness testing assembly comprises a supporting frame connected with the fixing frame and an air tightness testing jig arranged on the supporting frame.

Further, the rotating mechanism comprises a motor arranged on the base, a divider connected with an output end of the motor, and a turntable connected with an output end of the divider, and the first stacking test mechanism and the second stacking test mechanism are arranged on the turntable.

Contrast prior art, the utility model discloses following beneficial effect has:

the utility model discloses in set up first pile testing mechanism and second on rotary mechanism and pile up accredited testing organization, when one of them piles up accredited testing organization and carries out piling up of pile, another pile up accredited testing organization and can carry out the gas tightness test, pile up of pile up and the testing process has realized seamless connection, has saved the time of waiting for, has improved the efficiency of piling up and testing, has reduced manufacturing cost. On the other hand, the first stacking testing mechanism and the second stacking testing mechanism can be used for conducting accurate correction and positioning on the electric pile, and stacking accuracy of the electric pile is guaranteed.

Drawings

Fig. 1 is the utility model provides a pair of reciprocal constructional schematic of piling up device of duplex position galvanic pile.

Fig. 2 is an enlarged view of a portion a in fig. 1.

Fig. 3 is a schematic diagram of a first front guiding assembly according to the present invention.

Fig. 4 is a top view of the present invention.

The figure includes:

the testing device comprises a base 1, a rotating mechanism 2, a motor 21, a divider 22, a turntable 23, a first stacking testing mechanism 3, a fixed frame 31, a rear positioning component 32, a rear positioning base 321, a second positioning guide rod 322, a first front guiding component 33, a first guiding driving component 331, a guiding bracket 332, a second guiding driving component 333, a guiding plate 334, a guiding rod 335, a guiding base 336, a second guiding component 34, a first side positioning component 35, a positioning frame 351, a connecting rod 352, a positioning seat 353, a first positioning guide rod 354, a second side positioning component 36, a product detecting component 37, a detecting bracket 371, a sensor 372, a second stacking testing mechanism 4, an air tightness testing component 5, a supporting frame 51, an air tightness testing jig 52 and a connecting piece 6.

Detailed Description

To facilitate understanding of the present invention for those skilled in the art, the present invention will be described in further detail with reference to the following detailed description and accompanying drawings.

Referring to fig. 1 to 4, the utility model provides a pair of reciprocal device that piles up of duplex position galvanic pile, including base 1, set up in rotary mechanism 2 on the base 1, set up in first pile accredited testing organization 3 on rotary mechanism 2, set up in accredited testing organization 4 is piled up to the second on rotary mechanism 2. The first stack testing mechanism 3 and the second stack testing mechanism 4 are respectively disposed on opposite sides of the rotating mechanism 2. In the present embodiment, the front, rear, left, and right directions are described with reference to the view angle of fig. 1.

The rotating mechanism 2 comprises a motor 21 arranged on the base 1, a divider 22 connected with the output end of the motor 21, and a turntable 23 connected with the output end of the divider 22, wherein the first stacking test mechanism 3 and the second stacking test mechanism 4 are arranged on the turntable 23. In addition, a box body is further arranged on the rotary table 23, an electric control module can be arranged in the box body, and the electric control module is connected with a power supply through an air-electric slip ring arranged on the box body. When the turntable 23 rotates one hundred and eighty degrees (the outermost turn in fig. 1 is the rotation trajectory), the positions of the first stack testing mechanism 3 and the second stack testing mechanism 4 are interchanged.

First stacking test mechanism 3 and second stacking test mechanism 4 all including set up in rotary mechanism 2 is last mount 31, set up in the back locating component 32 of mount 31 front side, set up in the positive subassembly 33 of the left first preceding of mount 31, set up in the positive subassembly 34 of the second preceding on mount 31 right side, set up in the left first side locating component 35 of mount 31, set up in the second side locating component 36 on mount 31 right side. The bottom of the front side of the fixing frame 31 is also provided with an air tightness testing component 5. The rear positioning component 32 is used for rear side positioning of the galvanic pile, the first front guiding positive component 33 and the second front guiding positive component 34 can guide the galvanic pile from two sides of the front of the galvanic pile, and the first side positioning component 35 and the second side positioning component 36 can position the galvanic pile from the left side and the right side of the galvanic pile.

The first leading positive component 33 and the second leading positive component 34 both include a first leading driving part 331 arranged at the rear side of the fixed frame 31, a leading support 332 connected with the output end of the first leading driving part, a second leading driving part 333 arranged on the leading support 332, a leading plate 334 connected with the output end of the second leading driving part 333, and a leading rod 335 arranged at one side of the fixed frame 31 and facing the leading plate 334. The pilot plate 334 is provided with a pilot seat 336 for connecting the pilot rod 335. In this embodiment, the first guiding driving member 331 and the second guiding driving member 333 both use air cylinders, the first guiding driving member 331 can drive the guiding support 332 to move in the left-right direction, and the second guiding driving member 333 can drive the guiding plate 334 to move in the front-back direction. In a working state, the first guiding driving piece 331 of the first guiding positive assembly 33 is driven to the left side, the second guiding driving piece 333 of the first guiding positive assembly 33 is driven to the front side, the first guiding driving piece 331 of the second guiding positive assembly 34 is driven to the right side, and the second guiding driving piece 333 of the second guiding positive assembly 34 is driven to the front side, namely the whole space for stacking the galvanic pile is opened, after the galvanic pile stacking is finished, each driving piece is reset, and the galvanic pile is guided, positioned and compressed, so that the airtightness test is performed.

The first side positioning assembly 35 and the second side positioning assembly 36 each include a positioning frame 351 connected to the fixing frame 31, a plurality of connecting rods 352 movably connected to the positioning frame 351, a positioning seat 353 connected to one end of the connecting rods 352, and a first positioning guide 354 connected to the positioning seat 353. The first positioning guide rod 354 of the first side positioning assembly 35 and the first positioning guide rod 354 of the second side positioning assembly 36 can guide and position the stack from the left side and the right side. The other end of the connecting rod 352 is further provided with a fixing plate, so that the overall movement of the first side positioning component 35 or the second side positioning component 36 is more stable.

The rear positioning assembly 32 includes a rear positioning base 321 disposed on the front side of the fixing frame 31, and a second positioning guide rod 322 disposed on the rear positioning base 321. In this embodiment, the number of the rear positioning assemblies 32 is two, so that accurate positioning of the galvanic pile is ensured.

The fixing frame 31 of the first stacking test mechanism 3 and the fixing frame 31 of the second stacking test mechanism 4 are fixedly connected through a plurality of connecting pieces 6. Because the weight of the galvanic pile is large, the two stacking test mechanisms are fixedly connected by the connecting pieces 6, so that the integral stability during rotation can be ensured.

The first stacking test mechanism 3 and the second stacking test mechanism 4 further comprise two product detection assemblies 37 arranged on the left side and the right side of the air tightness detection assembly, each product detection assembly 37 comprises a detection support 371, and a sensor 372 arranged on the detection support 371. The sensors 372 of the two product inspection assemblies 37 may be paired sensors 372 (such as opposed optical fibers or gratings) positioned on the left and right sides of the stack for detecting whether the stack is stacked on the airtightness testing assembly 5. To avoid interfering with the stacking and testing process, the product detection assembly 37 is disposed on an additional support mechanism (not shown).

The air tightness testing assembly 5 comprises a supporting frame 51 connected with the fixing frame 31, and an air tightness testing jig 52 arranged on the supporting frame 51. The galvanic pile is stacked on the air tightness detection jig, and the air tightness detection equipment can test the air tightness of the galvanic pile through the air tightness detection jig after the stacking is finished.

In specific operation, the initial positions of the first stacking test mechanism 3 and the second stacking test mechanism 4 are used as two working stations, wherein one is used for stacking the electric pile, and the other is used for carrying out the air tightness test. Firstly, pile up at first pile accredited testing organization 3 and carry out the pile, pile up after the pile up, rotary mechanism 2's carousel 23 rotates one hundred eighty degrees, first pile accredited testing organization 3 and second pile accredited testing organization 4 interchange the position, the gas tightness check out test set carries out the gas tightness test to the pile on first pile accredited testing organization 3, meanwhile, second pile accredited testing organization 4 carries out the pile up operation of pile, after the gas tightness of the pile on first pile accredited testing organization 3 detects, the pile of second pile accredited testing organization 4 piles up, carousel 23 continues to rotate one hundred eighty degrees, first pile accredited testing organization 3 and second pile accredited testing organization 4 interchange the position once more, so reciprocal operation.

The utility model discloses in set up first pile up accredited testing organization 3 and second on rotary mechanism 2 and piled up accredited testing organization 4, when one of them piles up accredited testing organization and carries out piling up of pile, another pile up accredited testing organization and can carry out the gas tightness test, pile up of pile up and the testing process has realized seamless joint, has saved the time of waiting for, has improved the efficiency of piling up and testing, has reduced manufacturing cost. On the other hand, first stacking test mechanism 3 and second stacking test mechanism 4 can be used for accurately guiding and positioning the galvanic pile, so that the stacking accuracy of the galvanic pile is ensured.

In the description of the present invention, it should be understood that the indicated orientation or positional relationship is based on the orientation or positional relationship shown in the drawings, and is only for convenience of description and simplification of description, and does not indicate or imply that the indicated device or element must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present invention.

Furthermore, the terms "first", "second", etc. are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "connected" and "fixed" are to be construed broadly, e.g., as meaning either a fixed connection or a removable connection, or as an integral part; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

While the invention has been described in conjunction with the specific embodiments set forth above, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the foregoing description. Accordingly, it is intended to embrace all such alternatives, modifications, and variations that fall within the scope of the included claims.

Claims (10)

1. The double-station pile reciprocating stacking device is characterized by comprising a base, a rotating mechanism arranged on the base, a first stacking test mechanism arranged on the rotating mechanism, and a second stacking test mechanism arranged on the rotating mechanism; the first stacking testing mechanism and the second stacking testing mechanism respectively comprise a fixed frame arranged on the rotating mechanism, a rear positioning component arranged on the front side of the fixed frame, a first front guide positive component arranged on the left side of the fixed frame, a second front guide positive component arranged on the right side of the fixed frame, a first side positioning component arranged on the left side of the fixed frame and a second side positioning component arranged on the right side of the fixed frame; and the bottom of the front side of the fixing frame is provided with an air tightness testing assembly.

2. The double-station pile reciprocating stacking device of claim 1, wherein the first front guide and positive assembly and the second front guide and positive assembly each comprise a first guide and positive driving member arranged at the rear side of the fixed frame, a guide and positive support connected with the output end of the first guide and positive driving member, a second guide and positive driving member arranged on the guide and positive support, a guide and positive plate connected with the output end of the second guide and positive driving member, and a guide and positive rod arranged at one side of the guide and positive plate, which faces the fixed frame.

3. The double-station pile reciprocating stacking device as claimed in claim 2, wherein the guide plate is provided with a guide seat for connecting the guide rod.

4. The double-station pile reciprocating stacking device of claim 2, wherein the first side positioning assembly and the second side positioning assembly each comprise a positioning frame connected with the fixing frame, a plurality of connecting rods movably connected with the positioning frame, positioning seats connected with one ends of the connecting rods, and first positioning guide rods connected with the positioning seats.

5. The double-station pile reciprocating stacking device of claim 4, wherein the other end of the connecting rod is further provided with a fixing plate.

6. The double-station pile reciprocating stacking device according to claim 2, wherein the rear positioning assembly comprises a rear positioning base arranged on the front side of the fixing frame and a second positioning guide rod arranged on the rear positioning base.

7. The double-station electric pile reciprocating stacking device as claimed in claim 2, wherein the fixing frame of the first stacking test mechanism and the fixing frame of the second stacking test mechanism are fixedly connected through a plurality of connecting pieces.

8. The double-station electric pile reciprocating stacking device according to claim 2, wherein the first stacking test mechanism and the second stacking test mechanism further comprise two product detection assemblies arranged on the left side and the right side of the air tightness test assembly, and each product detection assembly comprises a detection support and a sensor arranged on the detection support.

9. The double-station electric pile reciprocating stacking device according to claim 1, wherein the air tightness testing assembly comprises a supporting frame connected with the fixing frame and an air tightness testing jig arranged on the supporting frame.

10. The double-station electric pile reciprocating stacking device according to claim 1, wherein the rotating mechanism comprises a motor arranged on the base, a divider connected with an output end of the motor, and a turntable connected with an output end of the divider, and the first stacking test mechanism and the second stacking test mechanism are arranged on the turntable.

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