CN112872793B

CN112872793B - Assembling method and assembling equipment for fuel cell air compressor

Info

Publication number: CN112872793B
Application number: CN202110050356.6A
Authority: CN
Inventors: 尹丛勃; 宋和国; 陈雷; 裴满; 许仁涛
Original assignee: Qingneng Power Technology Suzhou Co ltd
Current assignee: Qingneng Power Technology Suzhou Co ltd
Priority date: 2021-01-14
Filing date: 2021-01-14
Publication date: 2021-09-17
Anticipated expiration: 2041-01-14
Also published as: CN112872793A

Abstract

The invention discloses an assembly method and an assembly device of a fuel cell air compressor, which comprise the following steps: the device comprises a frame, a bolt conveying mechanism, a workpiece longitudinal moving mechanism, a workpiece transverse moving mechanism and a tightening mechanism; the position of a threaded hole of the workpiece is adjusted through the workpiece longitudinal moving mechanism and the workpiece transverse moving mechanism; when the position of the threaded hole corresponds to the bolt arranged on the tightening mechanism, a second lifting cylinder of the bolt conveying mechanism is started, so that the bolt descends; and then starting the tightening mechanism in due time to fix the bolt and the threaded hole or the nut of the workpiece. The invention aims to provide an assembling method and assembling equipment of a fuel cell air compressor, which can improve the mounting efficiency of the fuel cell air compressor.

Description

Assembling method and assembling equipment for fuel cell air compressor

Technical Field

The invention relates to the technical field of fuel cell air compressor installation, in particular to an assembling method and assembling equipment for a fuel cell air compressor.

Background

The air compressor machine head, the rear cover plate and the front cover plate are assembled, and the final process of the installation of the air compressor machine is realized.

In view of the above mounting apparatus, the applicant proposes a concept: and (3) one-time installation, namely assembling the air compressor head, the rear cover plate and the front cover plate by adopting 8 groups of bolt-nut assemblies, correspondingly, presetting 8 groups of corresponding pneumatic pulse assembling tools, and installing at one time. For the above concept, it is characterized in that: the speed is fast, but it can only be to one air compressor machine model, when changing another kind of air compressor machine model, and the quantity and the relative position of pneumatic pulse erecting tool need to make again (like changing the mould), therefore, its general type is poor.

Therefore, how to design a universal bolt tightening assembly mode is particularly important for improving the production efficiency.

Disclosure of Invention

The present invention is directed to a fuel cell air compressor assembly method that addresses the above-described deficiencies of the prior art.

The invention aims to provide a fuel cell air compressor assembling device aiming at the defects of the prior art.

The technical scheme of the invention is as follows:

a fuel cell air compressor assembly method adopts fuel cell air compressor assembly equipment for assembly, and can realize that: mounting a bolt-workpiece-nut, and mounting a bolt-workpiece;

when the bolt-nut needs to be fixed, the assembling steps are as follows:

firstly, mounting a bolt and a nut: placing the hexagonal flange face locking nut in the hexagonal flange face locking nut placing hole at the end part of the hexagonal flange face locking nut placing plate; inserting the hexagon head bolt into a sleeve of the tightening mechanism;

secondly, the method comprises the following steps: the bolt conveying sub-component with the bolt in the sleeve is rotated to the position to be installed: the second rotating column rotating power mechanism is started, the second rotating column rotates, and the required bolt conveying sub-component rotates to the position to be installed;

thirdly, adjusting the transverse position of the workpiece: placing the workpiece on the workpiece positioning block, and then moving the workpiece positioning block to a required position by the workpiece transverse moving mechanism: the workpiece transversely moves the telescopic cylinder to shorten, and moves the workpiece below the tightening mechanism;

fourthly, adjusting the longitudinal position of the workpiece: the longitudinal telescopic cylinder of the 2 workpiece longitudinal moving mechanism sub-components extends, and the L-shaped limiting plates on the two sides are clamped with the workpiece positioning blocks; then, adjusting the length of a longitudinal telescopic cylinder of each of the 2 workpiece longitudinal moving mechanism sub-components, and adjusting the longitudinal position of the workpiece to enable the pneumatic pulse assembling tool to correspond to the hole to be installed of the workpiece;

fifthly, the nut conveying sub-component provided with the hexagonal flange face locking nut rotates to the position to be installed: the first rotating column rotating power mechanism is started, the first rotating column rotates, and the needed nut conveying sub-component rotates to the position to be installed;

sixthly, extending the first lifting cylinder until the hexagonal flange face locking nut of the hexagonal flange face locking nut placing plate is attached to the lower surface of the workpiece;

seventhly, starting a lifting cylinder of the bolt conveying mechanism to drive the hexagon head bolt to descend; then, starting a pneumatic pulse assembly tool until the hexagon head bolt is screwed, so that the hexagon head bolt is screwed with the hexagon flange face locking nut;

eighthly, after the hexagon head bolt and the hexagon flange face locking nut are installed, starting a bolt conveying mechanism to drive the sleeve to ascend, and overcoming the magnetic force between the sleeve and the hexagon head bolt due to the fact that the hexagon head bolt and the hexagon flange face locking nut are fixed; then, starting a first rotating column rotating power mechanism, rotating the first rotating column, and separating the bolt conveying sub-component from the mounting position;

ninth, after the work is finished, namely the bolt-nut connection of the workpiece is finished, the first lifting cylinder is shortened, and the height of the hexagonal flange surface locking nut placing plate is reduced until the height of the hexagonal flange surface locking nut placing plate is lower than that of the bolt;

then, the first rotating column rotating power mechanism is started, and the first rotating column rotates to enable the nut conveying sub-component to leave the mounting position;

then, the longitudinal telescopic cylinder 5-2 of the sub-components of the 2 workpiece longitudinal moving mechanisms is shortened, and the L-shaped limiting plate 5-4 is separated from the workpiece positioning block;

tenth, then, repeating the first to ninth steps, and mounting the next bolt of the workpiece;

when the 'bolt-threaded hole in a workpiece' needs to be fixed, the assembling steps are as follows:

firstly, installing a bolt: inserting the hexagon head bolt into a sleeve of the tightening mechanism;

fifthly, extending the first lifting cylinder until the hexagonal flange face locking nut of the hexagonal flange face locking nut placing plate is attached to the lower surface of the workpiece;

sixthly, starting a lifting cylinder of the bolt conveying mechanism to drive the hexagon head bolt to descend; then, starting a pneumatic pulse assembly tool until the hexagon head bolt is screwed, so that the hexagon head bolt is screwed with the workpiece;

seventhly, after the bolt and the workpiece are installed, the bolt conveying mechanism is started to drive the sleeve to ascend, and the magnetic force between the sleeve and the hexagon head bolt can be overcome because the hexagon head bolt and the workpiece are fixed;

then, starting a first rotating column rotating power mechanism, rotating the first rotating column, and separating the bolt conveying sub-component from the mounting position;

eighthly, the longitudinal telescopic cylinder 5-2 of the sub-component of the 2 workpiece longitudinal moving mechanism is shortened, and the L-shaped limiting plate 5-4 is separated from the workpiece positioning block;

tenth, the first to eighth steps are then repeated, and the next bolt of the workpiece is installed.

Furthermore, after all the bolts on the workpiece are installed, the workpiece is moved out through the workpiece transverse moving mechanism, and then a new workpiece to be installed is replaced.

A fuel cell air compressor assembly apparatus comprising: the device comprises a frame, a bolt conveying mechanism, a workpiece longitudinal moving mechanism, a workpiece transverse moving mechanism and a tightening mechanism;

a rack substrate is arranged on the top of the frame;

wherein, work piece lateral shifting mechanism includes: the device comprises a workpiece transverse moving telescopic cylinder, a transverse guide rail group, a bearing plate, a connecting piece, a workpiece positioning block placing plate and a workpiece positioning block; the transverse guide rail group is fixedly arranged on the rack base plate, the workpiece transverse moving telescopic cylinder is arranged on the lower side of the rack base plate, a strip-shaped hole is formed in the rack base plate, and a connecting piece is fixed on the lower side of the bearing plate; the direction of the strip-shaped hole formed in the rack substrate is parallel to the direction of the transverse guide rail group; the fixed end of the workpiece transverse moving telescopic cylinder is fixedly connected with the frame, and the movable end of the workpiece transverse moving telescopic cylinder is connected with the connecting piece; the connecting piece penetrates through a strip-shaped hole formed in the base plate of the rack; the lower surface of the bearing plate is matched with the guide rail, and a workpiece positioning block placing plate is arranged above the bearing plate; the bearing plate and the workpiece positioning block placing plate are supported by support pillars; a movable workpiece positioning block is placed on the workpiece positioning block placing plate;

wherein, work piece longitudinal movement mechanism includes: 2 workpiece longitudinal moving mechanism sub-components, wherein the 2 workpiece longitudinal moving mechanism sub-components are symmetrically arranged at two sides of the transverse guide rail group; the workpiece longitudinal movement mechanism sub-member includes: the vertical supporting part, the longitudinal telescopic cylinder, the connecting plate and the L-shaped limiting plate are arranged on the vertical supporting part; the vertical supporting part is fixed on the base plate of the rack, the fixed end of the longitudinal telescopic cylinder is fixed on the vertical supporting part, the movable end of the longitudinal telescopic power mechanism is fixed with a connecting plate, and the connecting plate is connected with the L-shaped limiting plate; l type limiting plate includes: the workpiece positioning block can be clamped by the L-shaped structures of the L-shaped limiting plates of the 2 workpiece longitudinal moving mechanism sub-components;

wherein, bolt conveying mechanism includes: the plurality of bolt conveying sub-components, the second rotating disc, the second rotating column and the second rotating column rotating power mechanism; each bolt carrying sub-member includes: the second lifting cylinder, the bolt tightening mechanism placing plate, the second vertical guide rail and the horizontal cantilever plate; a screwing mechanism mounting hole is formed in the front end part of the bolt screwing mechanism placing plate; a clamping groove matched with the second vertical guide rail is formed in the rear end part of the bolt tightening mechanism placing plate; one end of the horizontal cantilever plate is fixed on the second rotating column, and the other end of the horizontal cantilever plate is cantilevered out; the fixed end of the second lifting cylinder is arranged above the movable end; the fixed end of the second lifting cylinder is fixedly arranged on the lower surface of the horizontal cantilever plate; the movable end of the second lifting cylinder is fixedly connected with the upper surface of the bolt tightening mechanism placing plate; a second rotating disc is fixedly arranged on the outer side of the second rotating column, the outer surface of the second rotating disc is in a gear shape, and the second rotating disc is driven to rotate by a second rotating column rotating power mechanism;

wherein, screw up the mechanism and include: a pneumatic pulse assembly tool, a sleeve; a sleeve is arranged at the lower end part of the pneumatic pulse assembling tool; the end part of the sleeve is provided with the permanent magnet, so that the hexagon head bolt can be placed in the sleeve to prevent the hexagon head bolt from falling under the dead weight.

Further, a second rotating column rotating power mechanism adopts a motor, and is vertically arranged on a platform; a vertical hole through which a rotating shaft of the motor passes is formed in the platform, a rotating shaft of the motor is provided with a third driving gear, the third driving gear is meshed with a fourth gear, and the fourth gear is meshed with a second rotating disc; the second rotating disc and the base plate of the rack keep a certain gap.

Further, a motor is adopted as a second rotating column rotating power mechanism, the second rotating column rotating power mechanism is transversely arranged, the end part of a rotating shaft of the second rotating column rotating power mechanism is meshed with a second steering gear through a second bevel gear, the second steering gear is coaxially arranged with a fourth gear, and the fourth gear is meshed with a second rotating disc; the second rotating disc and the base plate of the rack keep a certain gap.

Further, in the installation state, the lower side of the sleeve of the pneumatic pulse assembling tool corresponds to the hexagonal flange surface locking nut placing hole at the end part of the hexagonal flange surface locking nut placing plate, namely the central axis of the sleeve and the central axis of the hexagonal flange surface locking nut placing hole are in the same vertical line.

Further, still include: the 2 nut conveying mechanisms are respectively arranged on two sides of the transverse guide rail group;

wherein, nut transport mechanism includes: a plurality of nut conveying sub-members, a first rotary disc, a first rotary column rotation power mechanism;

each nut carrying sub-member includes: the device comprises a first lifting cylinder, a hexagonal flange surface locking nut placing plate and a first vertical guide rail;

a hexagonal flange face locking nut placing hole is formed in the front end of the hexagonal flange face locking nut placing plate, and a hexagonal flange face locking nut can be placed in the hexagonal flange face locking nut placing hole;

a clamping groove matched with the first vertical guide rail is formed in the rear end part of the hexagonal flange surface locking nut placing plate; the fixed end of the first lifting cylinder is arranged at the lower part, and the movable end of the first lifting cylinder is arranged at the upper part;

the fixed end of the first lifting cylinder is fixedly arranged on the first rotating disc; the movable end of the first lifting cylinder is fixedly connected with the lower surface of the hexagonal flange surface locking nut placing plate;

the outside of first rotation post is fixed and is provided with first rotation dish, and the surface of first rotation dish is the gear form, rotates power unit through first rotation post and drives first rotation dish and rotate.

Further, the first rotating column rotating power mechanism adopts a motor.

Furthermore, the first rotating column rotating power mechanism is vertically arranged and is arranged on a platform; a vertical hole through which a rotating shaft of the motor passes is formed in the platform, a first driving gear is arranged on the rotating shaft of the motor, the first driving gear is meshed with a second gear, and the second gear is meshed with a first rotating disc; the first rotating disc and the rack base plate keep a certain gap.

Furthermore, the first rotating column rotating power mechanism is transversely arranged, the end part of a rotating shaft of the first rotating column rotating power mechanism is meshed with the first steering gear through a first bevel gear, the second gear is coaxially arranged with the first steering gear, and the second gear is meshed with the first rotating disc; the first rotating disc and the rack base plate keep a certain gap.

Further, a longitudinal guide rail is arranged above the workpiece positioning block placing plate, and the workpiece positioning block is provided with a clamping groove matched with the longitudinal guide rail, so that the working positioning block longitudinally moves along the longitudinal guide rail.

Further, the direction of the longitudinal guide rail is parallel to that of the longitudinal telescopic power mechanism.

Further, the longitudinal guide rails are perpendicular to the direction of the transverse guide rail group.

The mounting method under the complicated distribution of bolt hole, the position of bolt installation is invariable, is called and waits to mount the position; the bolt is arranged in the sleeve; enabling the bolt hole on the workpiece to reach a position to be installed in a mode of moving the workpiece;

n bolt holes are arranged on the workpiece,

taking the projection of the central point of the sleeve on the horizontal plane when the bolt is installed as the original point, the direction of the transverse guide rail group as the X direction and the telescopic direction of the longitudinal telescopic power mechanism as the Y direction;

in the initial state, the coordinates of each bolt hole of the workpiece placed on the workpiece positioning block are as follows:

bolt hole No. 1: (x)₁，y₁)；

……

Bolt hole No. j: (x)_j，y_j)；

……

No. n-1 bolt hole: (x)_n-1，y_n-1)；

No. n bolt hole: (x)_n，y_n)；

The bolt holes are arranged in the order of A (n, n) combinations, i.e. n! A moving mode is planted;

taking the movement time T as a comparison target parameter;

for any combination thereof:

d, … … e and f … … g, wherein d, e, f and g are all less than or equal to n and all four are different; e is the mth number;

for any two adjacent steps, point e to point f, the time required is:

t_m＝|x_e-x_f|/V_x+|y_e-y_f|/V_y

time t from initial state to d₀＝|x_d|/V_x+|y_d|/V_y

t₀＝|x_g|/V_x+|y_g|/V_y

Time from the last 1 g bolt hole to final state, t_n＝|x_g|/V_x+|y_g|/V_y

T＝t₀+t₁+……t_m+……t_n。

Compare n! And selecting the bolt hole mounting sequence when T is the minimum in T of the moving modes, namely the target bolt hole mounting sequence.

n bolt holes are arranged on the workpiece,

bolt hole No. 1: (x)₁，y₁)；

……

Bolt hole No. j: (x)_j，y_j)；

……

No. n-1 bolt hole: (x)_n-1，y_n-1)；

No. n bolt hole: (x)_n，y_n)；

The bolt hole installation sequence is carried out according to the following steps:

first, determining a starting mounting hole:

calculating P_0，j

P_0，j＝|x_j|/V_x+|y_j|/V_y

Wherein j is (1, … … …, n);

P_0，jthe smallest corresponding bolt hole position is W₁And each bolt hole position is the bolt hole position of the initial installation.

Secondly, determining a second mounting hole position:

calculating P_1，j

P_1，j＝|x_j-x_W1|/V_x+|y_j-y_W1|/V_y

Wherein j is (1, … … …, n) eliminated W₁A digital set of (a);

P_1，jthe smallest corresponding bolt hole position is W₂And each bolt hole position is the bolt hole position of the second installation.

………

Step s, determining an s mounting hole position:

calculating P_s-1，j

P_s-1，j＝|x_j-x_Ws-1|/V_x+|y_j-y_Ws-1|/V_y

Wherein j is (1, … … …, n) eliminated W_1、W₂………W_S-1A digital set of (a);

P_s-1，jthe smallest corresponding bolt hole position is W_sAnd the bolt hole position is the position of the bolt hole for the s-th installation.

……

Step n, determining an nth mounting hole position:

calculating P_n-1，j

P_n-1，j＝|x_j-x_Wn-1|/V_x+|y_j-y_Wn-1|/V_y

Wherein j is (1, … … …, n) eliminated W_1、W₂………W_n-1A digital set of (a);

P_n-1，jthe smallest corresponding bolt hole position is W_nAnd the bolt hole position is the bolt hole position of the nth installation.

The bolt hole installation sequence is as follows: w_1、W₂………W_nThe workpiece is mounted in the following moving sequence: initial State-Wth₁Each bolt hole position corresponds to a bolt mounting position, W₂Each bolt hole position corresponds to a bolt mounting position, W₃The position of each bolt hole corresponds to the W-th bolt mounting position … …_nEach bolt hole position corresponds to a bolt mounting position-an initial state.

n bolt holes are arranged on the workpiece,

bolt hole No. 1: (x)₁，y₁)；

……

Bolt hole No. j: (x)_j，y_j)；

……

No. n-1 bolt hole: (x)_n-1，y_n-1)；

No. n bolt hole: (x)_n，y_n)；

The bolt hole installation sequence is carried out according to the following scheme:

firstly, calculating the distance between each bolt mounting hole and the center or centroid of a workpiece, wherein in an initial state, the coordinates of the center or centroid of the workpiece are as follows: x is the number of_L,y_L；

Calculating the distance r from any jth bolt mounting hole to the center (or centroid) of the workpiece_j

r_j＝[(x_j—x_L)²+(y_j—x_L)²]^0.5

Wherein j is (1, … … …, n);

each is comparedR is₁，……r_j，……r_nAccording to r_jThe mounting order is determined from small to large, i.e. r_jThe smaller the mounting, the further forward.

The beneficial effect of this application lies in:

first, the application is not only applicable to the bolt-nut tightening of the front cover plate-stator-rear cover plate of the motor of the air compressor, but also applicable to the bolt-nut installation of the front cover plate-stator-rear cover plate of the motor of the air compressor, namely, the application is applicable to the connection of a bolt-workpiece threaded hole as well as the installation of the bolt-nut.

Secondly, the position of the bolt-nut of the application is unchanged during installation, namely the position of the bolt is unchanged; when the device is used, the position of a workpiece is adjusted through the workpiece longitudinal moving mechanism 5 and the workpiece transverse moving mechanism 7, so that a hole through which a bolt needs to be inserted corresponds to the lower part of the sleeve 10-2.

Thirdly, the bolt conveying mechanism 2 of the present application is provided with a plurality of sets of bolt conveying sub-members, and the nut conveying mechanism 12 (the nut conveying mechanism 12 must be provided with 2 sets of nut conveying sub-members) is provided with a plurality of sets of nut conveying sub-members; after the installation is finished once, the second rotating column and the first rotating column rotate for 120 degrees (the rotation of 120 degrees is that 3 sets of bolt conveying sub-components and 3 sets of nut conveying sub-components are correspondingly arranged), and on one side of the rotating column, bolts and nuts are installed in the sleeve and the hexagonal flange face locking nut placing holes; the bolt conveying sub-component and the nut conveying sub-component which are turned to the installation position are already provided with the bolts and the nuts to be installed in advance; therefore, the flow operation is formed, and the time is saved.

Fourth, the present application installs 1 bolt at a time, which also applies when the bolt hole distribution of the workpiece changes.

Fifth, in the present application: the mounting positions of the bolt and the nut are fixed, namely, the projection of the bolt on the plane is the same point each time the bolt is mounted; this point is called: the bolt is to be installed, and the nut is to be installed.

Sixth, the present application presents a solution (alternative application) of three bolt hole installation sequences, which correspond to different purposes.

Drawings

The invention will be further described in detail with reference to examples of embodiments shown in the drawings to which, however, the invention is not restricted.

Fig. 1 is a three-dimensional view of the bolt tightening assembling apparatus of the first embodiment in an initial state.

Fig. 2a is a three-dimensional view of the bolt tightening assembling apparatus of the first embodiment in an installed state.

Fig. 2b is a plan view of the bolt tightening assembling apparatus according to the first embodiment in an installed state.

Fig. 3 is a schematic three-dimensional design diagram of the workpiece transverse moving mechanism 7 according to the first embodiment.

Fig. 4 is a schematic three-dimensional design diagram of the workpiece longitudinal movement mechanism 5 according to the first embodiment.

Fig. 5 is a schematic three-dimensional design diagram of the workpiece longitudinal moving mechanism 5 and the workpiece transverse moving mechanism 7 in the first embodiment at the time of assembly.

Fig. 6 is a side view of the workpiece longitudinal moving mechanism 5 and the workpiece lateral moving mechanism 7 in the first embodiment in assembly.

Fig. 7 is a schematic three-dimensional design diagram of the nut conveying mechanism 12 according to the first embodiment.

Fig. 8 is a plan view of the nut conveying mechanism 12 according to the first embodiment.

Fig. 9 is an elevation view of the nut conveying mechanism 12 according to the first embodiment.

Fig. 10 is a schematic design view of the transverse arrangement of the first rotary column rotary power mechanism 12-8 according to the first embodiment.

Fig. 11 is a schematic three-dimensional design diagram of a control system of the bolt conveying mechanism 2 according to the first embodiment.

Fig. 12 is an elevation view of a control system of the bolt conveying mechanism 2 according to the first embodiment.

Fig. 13 is a schematic design diagram of the tightening mechanism 10 of embodiment 1.

Fig. 14 is a schematic front elevation view of the workpiece longitudinal movement mechanism 5, the workpiece lateral movement mechanism 7, and the frame 1 of embodiment 1.

Fig. 15 is a schematic view of the workpiece mounting bolt-nut of embodiment 1.

Fig. 16 is a schematic view of the second/first rotating column pivoting power mechanism placed on the platform.

FIG. 17 is a layout of holes to be installed in a workpiece according to the present application.

Fig. 18 is a schematic view of workpiece movement according to the present application.

Fig. 19 is a plan view of the workpiece, hex flange face lock nut placement plate of the present application.

FIG. 20 is a design view of a hexagonal flange-face lock nut placement plate according to the fourth embodiment.

The reference numerals in fig. 1-20 are illustrated as follows:

the device comprises a frame 1, a bolt conveying mechanism 2, a workpiece longitudinal moving mechanism 5, a workpiece transverse moving mechanism 7, a tightening mechanism 10 and a nut conveying mechanism 12;

a stage substrate 1-1;

the device comprises a workpiece transverse moving telescopic cylinder 7-1, a transverse guide rail group 7-2, a bearing plate 7-3, a connecting piece 7-4, a workpiece positioning block placing plate 7-5 and a workpiece positioning block 7-6;

the device comprises a vertical supporting part 5-1, a longitudinal telescopic cylinder 5-2, a connecting plate 5-3 and an L-shaped limiting plate 5-4;

the device comprises a second lifting cylinder 2-1, a bolt tightening mechanism placing plate 2-2, a second rotating disc 2-3, a second vertical guide rail 2-5, a second rotating column 2-7, a second rotating column rotating power mechanism 2-8, a third driving gear 2-9-1, a fourth gear 2-9-2 and a horizontal cantilever plate 2-10;

the device comprises a first lifting cylinder 12-1, a hexagonal flange face lock nut placing plate 12-2, a first rotating disc 12-3, a first vertical guide rail 12-5, a first rotating column 12-7, a first rotating column rotating power mechanism 12-8, a first driving gear 12-9-1 and a second gear 12-9-2;

a pneumatic pulse assembly tool 10-1 and a sleeve 10-2.

Detailed Description

In one embodiment, a bolt-tightening assembling apparatus includes: the device comprises a frame 1, a bolt conveying mechanism 2, a workpiece longitudinal moving mechanism 5, a workpiece transverse moving mechanism 7, a

tightening mechanism

10 and 2 nut conveying mechanisms 12.

Wherein, the workpiece lateral movement mechanism 7 includes: the device comprises a workpiece transverse moving telescopic cylinder 7-1, a transverse guide rail group 7-2, a bearing plate 7-3, a connecting piece 7-4, a workpiece positioning block placing plate 7-5 and a workpiece positioning block 7-6; the transverse guide rail group 7-2 is fixedly arranged on the rack base plate 1-1, the workpiece transverse moving telescopic cylinder 7-1 is arranged on the lower side of the rack base plate 1-1, a strip-shaped hole is formed in the rack base plate 1-1, and a connecting piece 7-4 is fixed on the lower side of the bearing plate 7-3; the direction of the strip-shaped hole formed in the rack substrate 1-1 is parallel to the direction of the transverse guide rail group 7-2; the fixed end of the workpiece transverse moving telescopic cylinder 7-1 is fixedly connected with the frame 1, and the movable end of the workpiece transverse moving telescopic cylinder is connected with the connecting piece 7-4; the connecting piece 7-4 penetrates through a strip-shaped hole formed in the rack substrate 1-1; the lower surface of the bearing plate 7-3 is matched with the guide rail, and a workpiece positioning block placing plate 7-5 is arranged above the bearing plate 7-3; the bearing plate 7-3 and the workpiece positioning block placing plate 7-5 are supported by a support column. A movable workpiece positioning block 7-6 is placed on the workpiece positioning block placing plate 7-5, and the workpiece positioning block 7-6 is a cuboid. The upper surface of the workpiece positioning block 7-6 is matched with the surface of a workpiece so as to fix the workpiece (the head part of the air compressor is a special-shaped part).

Wherein, the workpiece longitudinal moving mechanism 5 includes: 2 workpiece longitudinal moving mechanism sub-components, wherein the 2 workpiece longitudinal moving mechanism sub-components are symmetrically arranged on two sides of the transverse guide rail group 7-2; the workpiece longitudinal movement mechanism sub-member includes: the device comprises a vertical supporting part 5-1, a longitudinal telescopic cylinder 5-2, a connecting plate 5-3 and an L-shaped limiting plate 5-4; the vertical supporting part 5-1 is fixed on the rack base plate 1-1, the fixed end of the longitudinal telescopic cylinder 5-2 is fixed on the vertical supporting part, the movable end of the longitudinal telescopic power mechanism is fixed with a connecting plate 5-3, and the connecting plate 5-3 is connected with an L-shaped limiting plate 5-4; l type limiting plate 5-4 includes: the vertical plate and the horizontal plate, and the L-shaped structure of the L-shaped limiting plate 5-4 of the sub-component of the 2 workpiece longitudinal moving mechanism can clamp the workpiece positioning block 7-6 (namely the lower surface of the horizontal plate of the L-shaped limiting plate 5-4 and the upper surface of the workpiece positioning block 7-6 are at the same height). Namely, a workpiece is fixed on a workpiece positioning block 7-6, and a workpiece transverse moving telescopic cylinder 7-1 of a workpiece transverse moving mechanism is shortened to drive a workpiece 3 to move towards a rotating column 2-7; after the workpiece 3 moves in place, the longitudinal telescopic cylinders 5-2 of the sub-components of the 2 workpiece longitudinal moving mechanisms of the workpiece longitudinal moving mechanism 5 extend, and the L-shaped limiting plates 5-4 at the two sides clamp the workpiece positioning blocks 7-6.

The 2 nut conveying mechanisms 12 are symmetrically arranged at two sides of the transverse guide rail group, more specifically, at two sides of the workpiece longitudinal moving mechanism 5 (it should be noted here that, the more general definition should be that the 2 nut conveying mechanisms 12 are arranged at two sides of the transverse guide rail group);

wherein, nut conveying mechanism 12 includes: a plurality of nut conveying sub-components, a first rotating disc 12-3, a first rotating column 12-7 and a first rotating column rotating power mechanism 12-8;

each nut carrying sub-member includes: the device comprises a first lifting cylinder 12-1, a hexagonal flange face lock nut placing plate 12-2 and a first vertical guide rail 12-5; a hexagonal flange face locking nut placing hole (in a stepped hole shape) is formed in the front end portion of the hexagonal flange face locking nut placing plate, and a hexagonal flange face locking nut can be placed in the hexagonal flange face locking nut placing hole (due to the fact that the hexagonal flange face locking nut has a flange face, the hexagonal flange face locking nut does not fall from the hexagonal flange face locking nut placing hole); a clamping groove matched with the first vertical guide rail 12-5 is formed in the rear end part of the hexagonal flange surface locking nut placing plate; in particular, the first vertical guide rail 12-5 is designed to be large outside and small inside (i.e. the side far away from the first rotating column 12-7 has a larger side length, and the side near the first rotating column 12-7 has a smaller side length) so as to limit the hexagonal flange surface locking nut placing plate to move up and down only along the first vertical guide rail 12-5. The fixed end of the first lifting cylinder 12-1 is arranged at the lower part, and the movable end thereof is arranged at the upper part; the fixed end of the first lifting cylinder 12-1 is fixedly arranged on the first rotating disc 12-3; the movable end of the first lifting cylinder 12-1 is fixedly connected with the lower surface of the hexagonal flange face locking nut placing plate 12-2. A first rotating disc is fixedly arranged on the outer side of the first rotating column 12-7, the outer surface of the first rotating disc is in a gear shape, and the first rotating disc is driven to rotate by a first rotating column rotating power mechanism 12-8; specifically, the first rotating column rotation power mechanism 12-8 adopts a motor, as shown in fig. 9, the first rotating column rotation power mechanism 12-8 is vertically arranged on a platform (a vertical hole is arranged on the platform, through which a motor rotating shaft passes), a rotating shaft of the motor is provided with a first driving gear 12-9-1, the first driving gear is meshed with a second gear 12-9-2, and the second gear is meshed with a first rotating disc; the first rotary disk is held at a certain clearance (i.e., non-contact to avoid friction between the first rotary disk and the stage base plate 1-1) from the stage base plate 1-1. It should be noted that, as shown in fig. 10, the first rotating column rotating power mechanism 12-8 may be disposed transversely, and the end of the rotating shaft of the first rotating column rotating power mechanism 12-8 passes through a first bevel gear, the first bevel gear is engaged with the first steering gear, and the second gear is disposed coaxially with the first steering gear. The lower part of the first rotating column 12-7 is rotatably connected in the rack base plate 1-1, which belongs to the mature design in the prior art and is not described again.

Wherein, bolt conveying mechanism 2 includes: a plurality of bolt conveying sub-components, a second rotating disc 2-3, a second rotating column 2-7 and a second rotating column rotating power mechanism 2-8;

each bolt carrying sub-member includes: a second lifting cylinder 2-1, a bolt tightening mechanism placing plate 2-2, a second vertical guide rail 2-5 and a horizontal cantilever plate 2-10; a screwing mechanism mounting hole is formed in the front end part of the bolt screwing mechanism placing plate 2-2; a clamping groove matched with the second vertical guide rail 2-5 is formed in the rear end part of the bolt tightening mechanism placing plate 2-2; in particular, the second vertical guide rail 2-5 is designed to be large outside and small inside (i.e. the side far away from the second rotating column 2-7 is large in side length and the side near the second rotating column 2-7 is small in side length) so as to limit the bolt tightening mechanism placing plate 2-2 to move up and down only along the second vertical guide rail 2-5.

One end of the horizontal cantilever plate 2-10 is fixed on the second rotating column 2-7, and the other end is cantilevered out; the fixed end of the second lifting cylinder 2-1 is arranged above the movable end; the fixed end of the second lifting cylinder 2-1 is fixedly arranged on the lower surface of the horizontal cantilever plate 2-10; the movable end of the second lifting cylinder 2-1 is fixedly connected with the upper surface of the bolt tightening mechanism placing plate 2-2.

A second rotating disc 2-3 is fixedly arranged on the outer side of the second rotating column 2-7, the outer surface of the second rotating disc 2-3 is in a gear shape, and the second rotating disc 2-3 is driven to rotate by a second rotating column rotating power mechanism 2-8.

Specifically, the second rotating column rotation power mechanism 2-8 adopts a motor, as shown in fig. 12, the second rotating column rotation power mechanism 2-8 is vertically placed on a platform (a vertical hole is formed in the platform, through which a motor rotating shaft passes), a rotating shaft of the motor is provided with a third driving gear 2-9-1, the third driving gear is meshed with a fourth gear 2-9-2, and the fourth gear is meshed with a second rotating disc; the second rotating disk is kept at a certain clearance (i.e. non-contact to avoid friction between the second rotating disk and the gantry base plate 1-1) from the gantry base plate 1-1.

It should be noted that the second rotating column rotation power mechanism 2-8 may also be placed transversely, the end of the rotating shaft of the second rotating column rotation power mechanism 2-8 passes through a second bevel gear, the second bevel gear is engaged with a second steering gear, and the second steering gear and a fourth gear are arranged coaxially.

The lower part of the second rotating column 2-7 is rotatably connected in the rack base plate 1-1, and the technology belongs to the mature design in the prior art, so the technology is not described again.

The tightening mechanism 10 includes: a pneumatic pulse assembly tool 10-1, a sleeve 10-2; the pneumatic pulse assembly tool 10-1 is of KWZ type straight type speed-loss type (the upper end part of the tool applies airflow and the lower end part of the tool rotates under the action of the airflow) of Kewerson industry (KEWELL industry), and is fixed on a mounting hole of a horizontal plate of the tightening mechanism mounting plate 2-2.

A sleeve 10-2 is arranged at the lower end part of the pneumatic pulse assembling tool 10-1; the end of the sleeve 10-2 is provided with a permanent magnet, and the hexagon head bolt 12 can be placed in the sleeve 10-2 to prevent the hexagon head bolt from falling under the dead weight.

The middle part of the hexagon head bolt is not provided with threads, and the end part of the hexagon head bolt is provided with threads; correspondingly, the middle part of the workpiece is not provided with threads, and the threads at the end part of the hexagon head bolt are used for being screwed with the hexagon flange face locking nut 11.

It should be noted that: the tightening mechanism of this application also can install the bolt that the bolt middle part set up the screw thread.

It should be noted that, in the installed state, the lower side of the sleeve of the pneumatic pulse assembling tool 10-1 corresponds to the hexagonal flange-faced locknut placing hole at the end of the hexagonal flange-faced locknut placing plate 12-2 (i.e., the central axis of the sleeve and the central axis of the hexagonal flange-faced locknut placing hole are on the same vertical line).

When the bolt-nut needs to be fixed, the working method of the application is as follows:

1. a fuel cell air compressor assembly method, characterized by, adopt the bolt tightening assembly equipment of the general type, it can realize: mounting a bolt-workpiece-nut, and mounting a bolt-workpiece;

when the bolt-nut needs to be fixed, the assembling steps are as follows:

tenth, the first to ninth steps are then repeated, and the next bolt of the workpiece is installed.

Further, the set of transverse rails 7-2 comprises at least 2 parallel rails.

It should be noted that a longitudinal guide rail (the direction of which is perpendicular to the direction of the transverse guide rail set and parallel to the telescopic direction of the longitudinal telescopic cylinder 5-2) may be disposed above the workpiece positioning block placing plate 7-5, and a guide groove adapted to the longitudinal guide rail is disposed below the workpiece positioning block 7-6, so that the workpiece positioning block 7-6 moves longitudinally along the longitudinal guide rail. However, this feature is not essential because the workpiece positioning block can be firmly clamped by the L-shaped position limiting plates 5-4 of the 2 workpiece longitudinal movement mechanism subcomponents, which cannot be moved laterally but can be moved longitudinally.

tenth, then, repeating the first to eighth steps, and installing the next bolt of the workpiece;

and after all the bolts on the workpiece are installed, the workpiece is moved out through the workpiece transverse moving mechanism, and then a new workpiece to be installed is replaced.

Further, the set of transverse rails 7-2 comprises at least 2 parallel rails.

It should be noted that: the depth of the hex head bolt into the socket is less than the depth of the head of the hex head bolt (i.e., defines the length of the socket).

The above-described assembling method is applicable to the case shown in fig. 17 (in the case of both bolt-workpiece-nut and bolt-workpiece threaded hole), and fig. 17 is a complicated bolt hole distribution diagram of the motor rotor-front cover plate-rear cover plate of the air compressor. Wherein, the number of the A-type holes is 8 (evenly distributed at intervals), the inner holes are not provided with threads and are connected by bolts and nuts; the number of the B-type holes is 6 (evenly distributed at intervals), threaded holes are formed in the B-type holes, and the B-type holes are connected through the threaded holes in the bolt-workpiece.

In the second embodiment, as in the case of fig. 17, the number of the holes in the category a is 8 (evenly spaced), and the inner holes are not provided with threads and are connected by bolts and nuts; the number of the B-type holes is 6 (evenly distributed at intervals), threaded holes are formed in the B-type holes, and the B-type holes are connected through the threaded holes in the bolt-workpiece.

The bolt heads of the bolts to be installed in the holes of the type A and the holes of the type B are consistent in size (namely, the bolts in the holes of the type A and the holes of the type B can be rotatably installed by adopting the same sleeve 10-2).

Faced with a design like that of fig. 17, one problem is: bolt holes No. 1-14, and how the installation order is determined.

The conventional idea is: no. 1- > No. 2- > No. 3- > No. 4- > No. 5- > No. 6- > No. 7- > No. 8- > No. 9- > No. 10- > No. 11- > No. 12- > No. 13- > No. 14;

however, observing the distribution of bolt holes in fig. 17, it is clear that the following solution is more efficient:

no. 1- > No. 2- > No. 3- > No. 4- > No. 5- > No. 6- > No. 7- > No. 8- > No. 14- > No. 13- > No. 12- > No. 11- > No. 10- > 9.

However, is the above approach the optimal solution? And, if a more complex bolt hole distribution is encountered, how to determine the bolt hole installation sequence.

Fig. 18 is a schematic diagram of moving a workpiece when the apparatus of the present application is installed, please only illustrate that No. 7 hole site is installed first, then No. 6 hole site is installed, the installation sequence of other hole sites is similar, first moving in the X direction, and then moving in the Y direction.

N bolt holes are arranged on the workpiece,

the projection of the central point of the sleeve 10-2 on the horizontal plane is taken as the origin when the sleeve is installed (the equipment of the application is characterized in that the position of the sleeve when the sleeve is installed is unchanged, namely the sleeve is unchanged, and a workpiece moves), the direction of the transverse guide rail group 7-2 is taken as the X direction, and the telescopic direction of the longitudinal telescopic power mechanism is taken as the Y direction (namely the direction of the longitudinal guide rail is the Y direction);

in the initial state (for convenience of the next final state), the coordinates of each bolt hole in which the workpiece is placed on the workpiece positioning block are:

bolt hole No. 1: (x)₁，y₁)

……

Bolt hole No. j: (x)_j，y_j)

……

No. n-1 bolt hole: (x)_n-1，y_n-1)

No. n bolt hole: (x)_n，y_n)

taking the movement time T as a comparison target parameter;

no. 1- > No. 2- > No. 3- > … … j- > j + 1- > No. n bolt hole;

time from initial state to number 1, t₀＝|x₁|/V_x+|y₁|/V_y

Time from nth bolt hole to final state, t_n＝|x_n|/V_x+|y_n|/V_y

The time required from j to j +1 is:

t_j＝|x_j-x_j-1|/V_x+|y_j-y_j-1|/V_y。

wherein, V_xIndicating the speed, V, of the telescopic cylinder 7-1 at which the workpiece is moved transversely_yIndicating the speed of the longitudinal telescopic cylinder 5-2.

T＝t₀+t₁+……t_j+……t_n；

For n bolt holes, the moving steps thereof are n +1 steps from the initial state to the final state.

For any one combination:

for any two adjacent steps, point e to point f, the time required is:

t_m＝|x_e-x_f|/V_x+|y_e-y_f|/V_y

time t from initial state to d₀＝|x_d|/V_x+|y_d|/V_y

t₀＝|x_g|/V_x+|y_g|/V_y

Time from the last 1 g bolt hole to final state, t_n＝|x_g|/V_x+|y_g|/V_y

T＝t₀+t₁+……t_m+……t_n。

And comparing the T of each sequence, and selecting the bolt hole installation sequence when the T is minimum, namely the target bolt hole installation sequence.

The technical contribution of the second embodiment is as follows: the applicant proposed an assembly plant which can correspond to three production lines (each production line producing models for one or more air compressors), each model of air compressor having a different distribution of bolts. In this case, how to optimize the bolt installation time is very significant; the efficiency of the assembly equipment of the first embodiment can be maximized.

The contribution of the second embodiment is that the above actual problem is converted into a mathematical problem (a technical solution is obtained by assigning a label to each hole site and converting the label into an arrangement and combination problem), and on the basis, a target comparison quantity, namely T; on the basis of the above, the solution can be achieved through a specific algorithm (embodiment two gives an algorithm idea, and specific codes can be realized through C language (for example: recursive algorithm)).

Example three: the scheme of the second embodiment is an optimal solution, but the calculation amount is large, and the program writing is difficult.

A simplified scheme is given below:

the projection of the central point (hereinafter referred to as a bolt mounting position) of the sleeve 10-2 on a horizontal plane during mounting is taken as an original point (the equipment of the application is characterized in that the position of the sleeve during mounting is unchanged, namely the sleeve is unchanged, and a workpiece moves), the direction of the transverse guide rail group 7-2 is taken as an X direction, and the telescopic direction of the longitudinal telescopic power mechanism is taken as a Y direction (namely the direction of the longitudinal guide rail is the Y direction);

bolt hole No. 1: (x)₁，y₁)

……

Bolt hole No. j:(x_j，y_j)

……

no. n-1 bolt hole: (x)_n-1，y_n-1)

No. n bolt hole: (x)_n，y_n)

first, determining a starting mounting hole:

calculating P_0，j

P_0，j＝|x_j|/V_x+|y_j|/V_y

Wherein j is (1, … … …, n);

Secondly, determining a second mounting hole position:

calculating P_1，j

P_1，j＝|x_j-x_W1|/V_x+|y_j-y_W1|/V_y

Wherein j is (1, … … …, n) eliminated W₁The number set of (i.e., installed hole sites do not need to be recalculated);

………

Step s, determining an s mounting hole position:

calculating P_s-1，j

P_s-1，j＝|x_j-x_Ws-1|/V_x+|y_j-y_Ws-1|/V_y

Wherein j is (1, … … …, n) eliminated W_1、W₂………W_S-1The number set of (i.e., installed hole sites do not need to be recalculated);

P_s-1，jthe smallest corresponding bolt hole position is W_sThe position of each bolt hole isThe bolt hole site of the s installation.

……

Step n, determining an nth mounting hole position:

calculating P_n-1，j

P_n-1，j＝|x_j-x_Wn-1|/V_x+|y_j-y_Wn-1|/V_y

Wherein j is (1, … … …, n) eliminated W_1、W₂………W_n-1The number set of (i.e., installed hole sites do not need to be recalculated);

P_n-1，jthe smallest corresponding bolt hole position is W_nOne bolt hole site, namely the bolt hole site for the nth installation (actually, only 1 hole site is left).

The bolt hole installation sequence is as follows: w_1、W₂………W_nThe workpiece is mounted in the following moving sequence: initial State-Wth₁Each bolt hole position corresponds to a bolt mounting position, W₂Each bolt hole position corresponds to a bolt mounting position, W₃The position of each bolt hole corresponds to the W-th bolt mounting position … …_nEach bolt hole position corresponds to a bolt mounting position-initial state (the initial state of the workpiece positioning block is ensured to be consistent every time).

The results for example two and example three are the same for most cases, but: the algorithm of the third embodiment is easier to implement in code.

However, the results of the second and third embodiments are not the same for complex irregular bolt distributions.

Example four, for the case of fig. 19, the inner layer is also bolt-nut mounted and the outer layer is also bolt-nut mounted, if: when two bolt holes-nuts are arranged on the same straight line, if an outer layer hole is drilled firstly and then an inner layer hole is drilled, the inner layer hole cannot be constructed (the hexagonal flange surface locking nut placing plate is contradictory to the outer layer hole drilled firstly); the reverse order is adopted, and the problems do not exist after the inside and the outside.

To the problem of fig. 19, the board is placed to hexagonal flange face lock nut adopts the design of L type, and the tip that the board was placed to hexagonal flange face lock nut is thickened promptly, like the design of fig. 20, the hole setting is placed to hexagonal flange face lock nut on the position of thickening. This avoids the aforementioned problems.

With the design of fig. 20, the workpiece bolt hole locations of the second and third embodiments can still be used.

Another scheme is as follows:

firstly, calculating the distance from each bolt mounting hole to the center (or centroid) of a workpiece;

in the initial state, the coordinates of the center (or centroid) of the workpiece are: x is the number of_L,y_L；

r_j＝[(x_j—x_L)²+(y_j—x_L)²]^0.5

Wherein j is (1, … … …, n);

compare each r₁，……r_j，……r_nAccording to r_jThe mounting order is determined from small to large, i.e. r_jThe smaller the mounting, the further forward.

Although the above mounting method is somewhat less efficient than the second and third embodiments, any bolt hole distribution can be mounted using the apparatus of the present application.

The above-mentioned embodiments are only for convenience of description, and are not intended to limit the present invention in any way, and those skilled in the art will understand that the technical features of the present invention can be modified or changed by other equivalent embodiments without departing from the scope of the present invention.

Claims

1. The utility model provides a fuel cell air compressor machine rigging equipment which characterized in that includes: the device comprises a frame, a bolt conveying mechanism, a workpiece longitudinal moving mechanism, a workpiece transverse moving mechanism and a tightening mechanism;

a rack substrate is arranged on the top of the frame;

wherein, screw up the mechanism and include: a pneumatic pulse assembly tool, a sleeve; a sleeve is arranged at the lower end part of the pneumatic pulse assembling tool; the permanent magnet is arranged at the end part of the sleeve, so that the hexagon head bolt can be placed in the sleeve to prevent the hexagon head bolt from falling under the dead weight;

further comprising: the 2 nut conveying mechanisms are respectively arranged on two sides of the transverse guide rail group;

2. The fuel cell air compressor assembling apparatus according to claim 1, wherein the second rotary post rotary actuating mechanism employs a motor, and the second rotary post rotary actuating mechanism is vertically disposed and disposed on a platform; a vertical hole through which a rotating shaft of the motor passes is formed in the platform, a rotating shaft of the motor is provided with a third driving gear, the third driving gear is meshed with a fourth gear, and the fourth gear is meshed with a second rotating disc; the second rotating disc and the base plate of the rack keep a certain gap.

3. The fuel cell air compressor assembling device according to claim 1, wherein the second rotary post rotary actuating mechanism employs a motor, the second rotary post rotary actuating mechanism is disposed laterally, a rotating shaft end of the second rotary post rotary actuating mechanism passes through a second bevel gear, the second bevel gear is engaged with a second steering gear, the second steering gear is disposed coaxially with a fourth gear, and the fourth gear is engaged with a second rotary disk; the second rotating disc and the base plate of the rack keep a certain gap.

4. The fuel cell air compressor assembling apparatus according to claim 1, wherein, in the mounted state, a lower portion of the sleeve of the pneumatic pulse assembling tool corresponds to the hexagonal flange face lock nut seating hole at the end portion of the hexagonal flange face lock nut seating plate, that is, a central axis of the sleeve and a central axis of the hexagonal flange face lock nut seating hole are on the same vertical line.

5. The fuel cell air compressor assembly apparatus as claimed in claim 1, wherein the first rotary post rotary actuating means employs a motor.

6. The fuel cell air compressor assembling apparatus according to claim 5, wherein the first rotary post rotary actuating unit is vertically disposed, and is disposed on a platform; a vertical hole through which a rotating shaft of the motor passes is formed in the platform, a first driving gear is arranged on the rotating shaft of the motor, the first driving gear is meshed with a second gear, and the second gear is meshed with a first rotating disc; a certain gap is kept between the first rotating disc and the base plate of the rack;

or the first rotating column rotating power mechanism is transversely arranged, the end part of a rotating shaft of the first rotating column rotating power mechanism is meshed with the first steering gear through a first bevel gear, the second gear is coaxially arranged with the first steering gear, and the second gear is meshed with the first rotating disc; the first rotating disc and the rack base plate keep a certain gap.

7. The fuel cell air compressor assembling apparatus according to claim 1, wherein a longitudinal rail is provided above the workpiece positioning block placement plate, and the workpiece positioning block is provided with a locking groove adapted to the longitudinal rail, so that the work positioning block is moved longitudinally along the longitudinal rail.

8. The fuel cell air compressor assembling apparatus according to claim 7, wherein said longitudinal guide rail is oriented in parallel with the longitudinal telescopic power mechanism; the longitudinal guide rails are perpendicular to the direction of the transverse guide rail group.

9. A fuel cell air compressor assembling method, characterized in that the fuel cell air compressor assembling apparatus according to any one of claims 1 to 8 is used for assembling, which can realize: mounting a bolt-workpiece-nut, and mounting a bolt-workpiece;

when the bolt-nut needs to be fixed, the assembling steps are as follows:

then, the longitudinal telescopic cylinders of the sub-components of the 2 workpiece longitudinal moving mechanisms are shortened, and the L-shaped limiting plates are separated from the workpiece positioning blocks;

eighthly, the longitudinal telescopic cylinder of the sub-component of the 2 workpiece longitudinal moving mechanism is shortened, and the L-shaped limiting plate is separated from the workpiece positioning block;

10. The fuel cell air compressor assembling method according to claim 9, wherein when all the bolts are mounted on the workpiece, the workpiece is removed by the workpiece transverse moving mechanism, and then a new workpiece to be mounted is replaced.