CN111687251A - Control device of multi-machine parallel numerical control hydraulic plate pipe making forming machine - Google Patents

Abstract

The invention discloses a control device of a multi-machine parallel numerical control hydraulic plate pipe-making forming machine, which comprises a support frame, wherein first control pieces distributed in an array mode are arranged on the support frame, a support piece is arranged on one side of the support frame, an adjusting piece is arranged on the support piece, second control pieces distributed in an array mode are arranged on the support frame, and the first control pieces and the second control pieces are distributed in a staggered mode. The control device of the invention enables the sliding block to slide on the first supporting table through the expansion and contraction of the air cylinder, adjusts the distance between the first forming roller and the second forming roller, rotates the rotating adjusting block to tension the chain between the double chain wheel and the adjusting chain wheel, rotates the rotating handle to adjust the distance between the sliding supporting pieces on the same bidirectional screw rod, rotates the screw rod in the third threaded hole to enable the guide block to slide on the sliding supporting pieces, realizes the adjustment of the diameter of the tube body of the plate material tube, rotates the screw rod in the third threaded hole to fix the guide block on the sliding supporting pieces, replaces the traditional manual adjustment mode, and improves the adjustment efficiency and precision.

Description

Control device of multi-machine parallel numerical control hydraulic plate pipe making forming machine

Technical Field

The invention relates to a control device of a forming machine, in particular to a control device of a multi-machine parallel numerical control hydraulic plate pipe-making forming machine.

Background

The forming machine is also called as a case unpacking machine, and is a special device for automatically completing case unpacking, forming and bending of lower bottom folding leaves, and currently completing part of tape adhesion, opening the case boards of the stacked paper boards, folding the bottom of the case according to a certain program, and conveying the case boards to the case unpacking machine after sealing with tapes. When the sheet material tubulation is fashioned, in order to improve production efficiency, mostly adopt the parallelly connected mode of multimachine to carry out the operation, in order to improve equipment's suitability, need adjust equipment according to the diameter size of making the back pipeline, the mode that the manual screw rod of screwing in among the prior art was adjusted is inefficient, and the precision is low, consumes a large amount of manpower and materials, influences production efficiency, has increased staff's intensity of labour.

Disclosure of Invention

The invention aims to provide a control device of a multi-machine parallel numerical control hydraulic plate pipe making forming machine, wherein a regulating block is rotated to loosen a chain between a double chain wheel and a regulating chain wheel, a sliding block is positioned on a first supporting platform to slide through the expansion and contraction of an air cylinder, the distance between a first forming roller and a second forming roller is regulated, the rotating regulating block is rotated to tension the chain between the double chain wheel and the regulating chain wheel, a rotating handle is rotated to regulate the distance between sliding supporting pieces on the same bidirectional screw rod, a screw rod in a third threaded hole is rotated to enable a guide block to be positioned on the sliding supporting pieces to slide, the diameter of a pipe body of a plate pipe is regulated, the guide block is fixed on the sliding supporting pieces by rotating the screw rod in the third threaded hole, the traditional manual regulation mode is replaced, the regulation efficiency and precision are improved, the investment of manpower and material resources is reduced, and the production efficiency and the, the labor intensity of workers is reduced.

The purpose of the invention can be realized by the following technical scheme:

multimachine numerical control hydraulic pressure sheet material tubulation forming machine controlling means that connects in parallel, controlling means include the support frame, be equipped with the first control piece of array distribution on the support frame, one side of support frame is equipped with support piece, is equipped with the regulating part on the support piece, is equipped with the second control piece of array distribution on the support frame, first control piece and second control piece dislocation distribution.

The support frame comprises a square support frame body, and supporting legs distributed in an array mode are arranged below the square support frame body.

The first control part comprises a first connecting plate, first supporting tables are arranged at two ends of the first connecting plate, sliding blocks are arranged on the first supporting tables in a sliding mode, first forming rollers are arranged between the first supporting tables in a rotating mode, second forming rollers are arranged between the sliding blocks in a rotating mode, air cylinders are arranged on the first connecting plate, and fixing pieces of the air cylinders are fixedly connected with first connecting pieces.

The first supporting platform comprises a first mounting seat, a first connecting block is arranged on the first mounting seat, a first rotating connecting hole is formed in the first connecting block, first guide rods which are symmetrically distributed are arranged on the first connecting block, one end of each first guide rod is fixedly connected with the first connecting block, the other end of each first guide rod is provided with a second connecting block, and a first through hole is formed in the second connecting block.

First guiding holes are symmetrically distributed in the sliding block, and second rotating connecting holes are formed in the sliding block.

The first connecting piece comprises a second connecting plate, connecting rods are arranged at two ends of the second connecting plate, and second through holes are formed in the second connecting plate.

And the first forming roller and the second forming roller at one end are both provided with double chain wheels, the rest first forming rollers and the rest second forming rollers are both provided with single chain wheels, and one end of the first forming roller at one end is provided with a motor.

The regulating part includes the braced frame body, is equipped with the standing groove in the braced frame body, and the standing groove internal rotation is equipped with the threaded rod, and the one end of threaded rod is equipped with the regulating block, and it is equipped with the sliding block to slide in the standing groove, and the both ends of sliding block all are equipped with the stopper, be equipped with on the sliding block with threaded rod complex first screw hole, rotate on the sliding block of one end and be equipped with adjusting sprocket, and the regulating part passes through the braced.

The second control piece includes the second brace table of symmetric distribution, and the second brace table includes the sliding support piece of array distribution, and two liang of cooperations of sliding support piece, the last guide block of sliding support piece rotate on the second brace table and are equipped with the lead screw, and the one end of lead screw is equipped with rotatory handle.

The second supporting table comprises symmetrically distributed second mounting seats, third connecting blocks are arranged on the second mounting seats, symmetrically distributed second guide rods are arranged between the third connecting blocks, symmetrically distributed third guide rods are arranged on the third connecting blocks, one ends of the third guide rods are fixedly connected with the third connecting blocks, the other ends of the third guide rods are provided with fourth connecting blocks, symmetrically distributed fourth guide rods are arranged between the fourth connecting blocks, fifth connecting blocks are arranged on the fourth connecting blocks, and third rotating connecting holes are formed in the fifth connecting blocks.

The sliding support piece comprises symmetrically distributed square sliding rails, a sixth connecting block is arranged at one end of each square sliding rail, a seventh connecting block is arranged at the other end of each square sliding rail, second guide holes symmetrically distributed are formed in the sixth connecting block, third guide holes symmetrically distributed are formed in the seventh connecting block, an eighth connecting block is arranged on the seventh connecting block, and a second threaded hole is formed in the eighth connecting block.

The guide block comprises a guide block main body, square sliding holes which are symmetrically distributed are formed in the guide block main body, third threaded holes which are distributed in an array mode are formed in the two sides of the guide block main body, and guide grooves are formed in the guide block main body.

The lead screw comprises a connecting column, two-way lead screws are arranged on two sides of the connecting column, one end of each two-way lead screw is fixedly connected with the connecting column, and a rotating shaft is arranged at the other end of each two-way lead screw.

Further, the output shaft of the air cylinder penetrates through the first connecting piece to be fixedly connected with the first connecting plate.

Furthermore, the first control piece is fixedly arranged on the square supporting frame body through the first mounting seat.

Furthermore, the sliding block is connected with the first guide rod in a sliding mode through the first guide hole, the first forming roller is located in the first rotating connecting hole to rotate, and the second forming roller is located in the second rotating connecting hole to rotate.

Furthermore, the output shaft of the air cylinder penetrates through the second through hole to be fixedly connected with the first connecting plate, and the first connecting piece penetrates through the first through hole to be fixedly connected with the sliding block through the connecting rod.

Furthermore, the first forming rollers are connected with the single chain wheel in a matched and rotating mode through chains and double chain wheels, the second forming rollers are connected with the single chain wheel in a matched and rotating mode through the chains and the double chain wheels, and the first forming rollers and the second forming rollers are connected with the double chain wheels and the adjusting chain wheels in a matched and rotating mode through the chains and the double chain wheels.

Furthermore, the second control piece is fixedly arranged on the square supporting frame body through a second mounting seat.

Furthermore, the sliding support piece is connected with the second guide rod in a sliding mode through a second guide hole, and the third guide hole is connected with the fourth guide rod in a sliding mode.

Furthermore, the guide block is located on the square slide rail through the square slide hole and slides, and the guide block is fixed on the sliding support piece through the matching of the screw rod and the third threaded hole.

Furthermore, the screw rod is rotatably connected with the third rotating connecting hole through a rotating shaft and is matched with the second threaded hole through the bidirectional screw rod.

The invention has the beneficial effects that:

1. according to the control device, the sliding block is positioned on the first supporting table to slide through the expansion and contraction of the air cylinder, the distance between the first forming roller and the second forming roller is adjusted, the rotating adjusting block is rotated to tension a chain between the double chain wheel and the adjusting chain wheel, the rotating handle is rotated to adjust the distance between the sliding supporting pieces on the same bidirectional screw rod, the screw rod in the third threaded hole is rotated to enable the guide block to be positioned on the sliding supporting pieces to slide, the diameter of the tube body of the plate material tube is adjusted, the screw rod in the third threaded hole is rotated to fix the guide block on the sliding supporting pieces, the traditional manual adjusting mode is replaced, and the adjusting efficiency and the adjusting precision are improved;

2. the control device reduces the investment of manpower and material resources, is beneficial to improving the production efficiency and the applicability, and reduces the labor intensity of workers.

Drawings

The invention will be further described with reference to the accompanying drawings.

FIG. 1 is a schematic view of the control device of the present invention;

FIG. 2 is a schematic view of the supporting frame of the present invention;

FIG. 3 is a schematic view of a first control member of the present invention;

FIG. 4 is a schematic view of a first support table according to the present invention;

FIG. 5 is a schematic view of the slider configuration of the present invention;

FIG. 6 is a schematic view of a first connector structure of the present invention;

FIG. 7 is a schematic view of the structure of the adjusting member of the present invention;

FIG. 8 is a schematic view of a second control member of the present invention;

FIG. 9 is a schematic view of a second support stage according to the present invention;

FIG. 10 is a schematic view of the sliding support construction of the present invention;

FIG. 11 is a schematic view of the guide block structure of the present invention;

fig. 12 is a schematic view of the screw structure of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Multimachine numerical control hydraulic pressure sheet material tubulation forming machine controlling means that connects in parallel, controlling means include support frame 1, as shown in fig. 1, are equipped with array distribution's first control 2 on the support frame 1, and one side of support frame 1 is equipped with support piece 4, is equipped with regulating part 5 on the support piece 4, is equipped with array distribution's second control 6 on the support frame 1, first control 2 and 6 dislocation distribution of second control.

The support frame 1 includes a square support frame 11, and as shown in fig. 2, support legs 12 are arranged below the square support frame 11 in an array.

The first control part 2 comprises a first connecting plate 21, as shown in fig. 3, first supporting tables 22 are arranged at two ends of the first connecting plate 21, sliding blocks 23 are arranged on the first supporting tables 22 in a sliding mode, first forming rollers 24 are arranged between the first supporting tables 22 in a rotating mode, second forming rollers 25 are arranged between the sliding blocks 23 in a rotating mode, an air cylinder 27 is arranged on the first connecting plate 21, a fixing part of the air cylinder 27 is fixedly connected with a first connecting part 26, and an output shaft of the air cylinder 27 penetrates through the first connecting part 26 to be fixedly connected with the first connecting plate 21.

The first supporting platform 22 includes a first mounting seat 221, as shown in fig. 4, a first connecting block 222 is disposed on the first mounting seat 221, a first rotating connecting hole 223 is disposed on the first connecting block 222, first guide rods 224 symmetrically distributed are disposed on the first connecting block 222, one end of each first guide rod 224 is fastened to the first connecting block 222, a second connecting block 225 is disposed at the other end of each first guide rod, a first through hole 226 is disposed on the second connecting block 225, and the first control element 2 is mounted and fixed on the square supporting frame 11 through the first mounting seat 221.

The slider 23 is provided with first guide holes 232 which are symmetrically distributed, as shown in fig. 5, the slider 23 is provided with a second rotation connection hole 231, and the slider 23 is slidably connected with the first guide rod 224 through the first guide holes 232.

The first forming roller 24 rotates in the first rotation coupling hole 223, and the second forming roller 25 rotates in the second rotation coupling hole 231.

The first connecting member 26 includes a second connecting plate 261, as shown in fig. 6, connecting rods 263 are disposed at two ends of the second connecting plate 261, and a second through hole 262 is disposed on the second connecting plate 261.

The output shaft of the cylinder 27 passes through the second through hole 262 to be fastened to the first connecting plate 21, and the first connecting member 26 passes through the first through hole 226 to be fastened to the slider 23 by the connecting rod 263.

The first forming roller 24 and the second forming roller 25 at one end are both provided with double chain wheels 20, the other first forming roller 24 and the other second forming roller 25 are both provided with single chain wheels 10, and one end of the first forming roller 24 at one end is provided with a motor 3.

The adjusting part 5 comprises a supporting frame body 51, as shown in fig. 7, a placing groove 511 is arranged on the supporting frame body 51, a threaded rod 52 is rotationally arranged in the placing groove 511, an adjusting block 521 is arranged at one end of the threaded rod 52, a sliding block 53 is slidably arranged in the placing groove 511, two ends of the sliding block 53 are respectively provided with a limiting block 531, a first threaded hole 532 matched with the threaded rod 52 is arranged on the sliding block 53, an adjusting sprocket 54 is rotationally arranged on the sliding block 53 at one end, and the adjusting part 5 is fixed on the supporting part 4 through the supporting frame body 51.

The first forming rollers 24 are in matched and rotary connection with the single chain wheel 10 through the chain and the double chain wheel 20, the second forming rollers 25 are in matched and rotary connection with the single chain wheel 10 through the chain and the double chain wheel 20, and the first forming rollers 24 and the second forming rollers 25 are in matched and rotary connection with the double chain wheel 20 and the adjusting chain wheel 54 through the chain.

The second control element 6 comprises second support platforms 61 which are symmetrically distributed, as shown in fig. 8, the second support platforms 61 comprise sliding support elements 62 which are distributed in an array, the sliding support elements 62 are matched with each other two by two, guide blocks 63 are arranged on the sliding support elements 62, a screw rod 64 is rotatably arranged on the second support platforms 61, and a rotating handle 65 is arranged at one end of the screw rod 64.

The second supporting platform 61 includes second mounting seats 611 symmetrically distributed, as shown in fig. 9, third connecting blocks 612 are disposed on the second mounting seats 611, second guide rods 614 symmetrically distributed are disposed between the third connecting blocks 612, third guide rods 613 symmetrically distributed are disposed on the third connecting blocks 612, one end of each third guide rod 613 is fixedly connected to the third connecting block 612, a fourth connecting block 615 is disposed at the other end of each third guide rod, fourth guide rods 616 symmetrically distributed are disposed between the fourth connecting blocks 615, a fifth connecting block 617 is disposed on the fourth connecting block 615, a third rotating connecting hole 618 is disposed on the fifth connecting block 617, and the second control element 6 is mounted and fixed on the square supporting frame 11 through the second mounting seats 611.

The sliding support 62 includes a symmetrical square slide rail 621, a sixth connecting block 622 is disposed at one end of the square slide rail 621, a seventh connecting block 623 is disposed at the other end of the square slide rail 621, a symmetrical second guiding hole 624 is disposed on the sixth connecting block 622, a symmetrical third guiding hole 625 is disposed on the seventh connecting block 623, an eighth connecting block 626 is disposed on the seventh connecting block 623, a second threaded hole 627 is disposed on the eighth connecting block 626, the sliding support 62 is slidably connected with the second guiding rod 614 through the second guiding hole 624, and the third guiding hole 625 is slidably connected with the fourth guiding rod 616.

The guide block 63 includes a guide block main body 631, as shown in fig. 11, the guide block main body 631 is provided with symmetrically distributed square sliding holes 632, both sides of the guide block main body 631 are provided with third threaded holes 633 distributed in an array, the guide block main body 631 is provided with a guide groove 634, the guide block 63 slides on the square sliding rail 621 through the square sliding holes 632, the guide block 63 is fixed on the sliding support 62 by a screw rod matching with the third threaded holes 633,

the screw rod 64 includes a connection column 641, as shown in fig. 12, two sides of the connection column 641 are respectively provided with a bidirectional screw rod 642, one end of the bidirectional screw rod 642 is fixedly connected with the connection column 641, the other end of the bidirectional screw rod 642 is provided with a rotation shaft 643, the screw rod 64 is rotatably connected with the third rotation connection hole 618 through the rotation shaft 643, and the bidirectional screw rod 642 is matched with the second threaded hole 627.

When the device is used, the adjusting block 521 is rotated to loosen the chain between the double chain wheel 20 and the adjusting chain wheel 54, the sliding block 23 is positioned on the first supporting table 22 to slide through the extension and contraction of the air cylinder 27, the distance between the first forming roller 24 and the second forming roller 25 is adjusted, the rotating adjusting block 521 is rotated to tension the chain between the double chain wheel 20 and the adjusting chain wheel 54, the rotating handle 65 is rotated to adjust the distance between the sliding supporting pieces 62 on the same two-way screw rod 642, the screw rod in the third threaded hole 633 is rotated to enable the guide block 63 to be positioned on the sliding supporting piece 62 to slide, the diameter of the tube body of the plate manufacturing tube is adjusted, and the screw rod in the third threaded hole 633 is rotated to fix the guide block 63 on the sliding supporting piece 62.

In the description herein, references to the description of "one embodiment," "an example," "a specific example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed.

Claims (10)

1. The control device comprises a support frame (1), and is characterized in that first control pieces (2) distributed in an array manner are arranged on the support frame (1), a support piece (4) is arranged on one side of the support frame (1), an adjusting piece (5) is arranged on the support piece (4), second control pieces (6) distributed in an array manner are arranged on the support frame (1), and the first control pieces (2) and the second control pieces (6) are distributed in a staggered manner;

the support frame (1) comprises a square support frame body (11), and support legs (12) distributed in an array manner are arranged below the square support frame body (11);

the first control part (2) comprises a first connecting plate (21), two ends of the first connecting plate (21) are respectively provided with a first supporting platform (22), sliding blocks (23) are arranged on the first supporting platforms (22) in a sliding mode, first forming rollers (24) are arranged between the first supporting platforms (22) in a rotating mode, second forming rollers (25) are arranged between the sliding blocks (23) in a rotating mode, an air cylinder (27) is arranged on the first connecting plate (21), and a fixing piece of the air cylinder (27) is connected with a first connecting piece (26) in a fastening mode;

the first supporting platform (22) comprises a first mounting seat (221), a first connecting block (222) is arranged on the first mounting seat (221), a first rotating connecting hole (223) is formed in the first connecting block (222), first guide rods (224) which are symmetrically distributed are arranged on the first connecting block (222), one end of each first guide rod (224) is fixedly connected with the first connecting block (222), a second connecting block (225) is arranged at the other end of each first guide rod, and a first through hole (226) is formed in the second connecting block (225);

first guide holes (232) are symmetrically distributed on the sliding block (23), and second rotating connecting holes (231) are formed in the sliding block (23);

the first connecting piece (26) comprises a second connecting plate (261), connecting rods (263) are arranged at two ends of the second connecting plate (261), and second through holes (262) are formed in the second connecting plate (261);

the first forming roller (24) and the second forming roller (25) at one end are both provided with double chain wheels (20), the other first forming roller (24) and the other second forming roller (25) are both provided with single chain wheels (10), and one end of the first forming roller (24) at one end is provided with a motor (3);

the adjusting piece (5) comprises a supporting frame body (51), a placing groove (511) is formed in the supporting frame body (51), a threaded rod (52) is arranged in the placing groove (511) in a rotating mode, an adjusting block (521) is arranged at one end of the threaded rod (52), a sliding block (53) is arranged in the placing groove (511) in a sliding mode, limiting blocks (531) are arranged at two ends of the sliding block (53), a first threaded hole (532) matched with the threaded rod (52) is formed in the sliding block (53) at one end, an adjusting chain wheel (54) is arranged on the sliding block (53) at one end in a rotating mode, and the adjusting piece (5) is fixed on the supporting piece;

the second control part (6) comprises second supporting tables (61) which are symmetrically distributed, the second supporting tables (61) comprise sliding supporting pieces (62) which are distributed in an array manner, the sliding supporting pieces (62) are matched in pairs, a guide block (63) is arranged on each sliding supporting piece (62), a screw rod (64) is rotatably arranged on each second supporting table (61), and one end of each screw rod (64) is provided with a rotating handle (65);

the second supporting platform (61) comprises second mounting seats (611) which are symmetrically distributed, third connecting blocks (612) are arranged on the second mounting seats (611), second guide rods (614) which are symmetrically distributed are arranged between the third connecting blocks (612), third guide rods (613) which are symmetrically distributed are arranged on the third connecting blocks (612), one end of each third guide rod (613) is fixedly connected with the third connecting block (612), a fourth connecting block (615) is arranged at the other end of each third guide rod, fourth guide rods (616) which are symmetrically distributed are arranged between the fourth connecting blocks (615), a fifth connecting block (617) is arranged on each fourth connecting block (615), and a third rotating connecting hole (618) is arranged on each fifth connecting block (617);

the sliding support piece (62) comprises square sliding rails (621) which are symmetrically distributed, one end of each square sliding rail (621) is provided with a sixth connecting block (622), the other end of each square sliding rail is provided with a seventh connecting block (623), the sixth connecting block (622) is provided with second guide holes (624) which are symmetrically distributed, the seventh connecting block (623) is provided with third guide holes (625) which are symmetrically distributed, the seventh connecting block (623) is provided with an eighth connecting block (626), and the eighth connecting block (626) is provided with a second threaded hole (627);

the guide block (63) comprises a guide block main body (631), square sliding holes (632) are symmetrically distributed on the guide block main body (631), third threaded holes (633) are distributed on two sides of the guide block main body (631) in an array manner, and guide grooves (634) are formed in the guide block main body (631);

the screw rod (64) comprises a connecting column (641), two sides of the connecting column (641) are respectively provided with a bidirectional screw rod (642), one end of the bidirectional screw rod (642) is fixedly connected with the connecting column (641), and the other end of the bidirectional screw rod is provided with a rotating shaft (643).

2. The control device for a multi-machine parallel numerical control hydraulic plate pipe-making forming machine according to claim 1, characterized in that the output shaft of the cylinder (27) passes through the first connecting piece (26) to be tightly connected with the first connecting plate (21).

3. The control device of a multi-machine parallel numerical control hydraulic plate pipe-making forming machine according to claim 1, characterized in that the first control member (2) is fixedly mounted on the square support frame (11) by a first mounting seat (221).

4. The control device of the multi-machine parallel numerical control hydraulic plate pipe-making forming machine according to claim 1, characterized in that the slide block (23) is slidably connected with the first guide rod (224) through a first guide hole (232), the first forming roller (24) rotates in a first rotating connection hole (223), and the second forming roller (25) rotates in a second rotating connection hole (231).

5. The control device for the multi-parallel numerical control hydraulic plate pipe-making and forming machine according to claim 1, characterized in that the output shaft of the cylinder (27) is fixedly connected with the first connecting plate (21) through the second through hole (262), and the first connecting piece (26) is fixedly connected with the sliding block (23) through the first through hole (226) through the connecting rod (263).

6. The control device for the multi-machine parallel numerical control hydraulic plate pipe-making forming machine is characterized in that the first forming rollers (24) are in matched and rotary connection with the single chain wheel (10) through chains and double chain wheels (20), the second forming rollers (25) are in matched and rotary connection with the single chain wheel (10) through the chains and the double chain wheels (20), and the first forming rollers (24) and the second forming rollers (25) are in matched and rotary connection with the double chain wheels (20) and the adjusting chain wheels (54) through the chains.

7. The control device of a multi-machine parallel numerical control hydraulic plate pipe-making forming machine according to claim 1, characterized in that the second control member (6) is fixedly mounted on the square support frame (11) by means of a second mounting seat (611).

8. The control device of a multiple-parallel numerically controlled hydraulic sheet forming machine according to claim 1, characterized in that said sliding support (62) is slidably connected to a second guide rod (614) through a second guide hole (624), and a third guide hole (625) is slidably connected to a fourth guide rod (616).

9. The control device of a multi-machine parallel numerical control hydraulic sheet pipe-making forming machine according to claim 1, characterized in that the guide block (63) slides on a square slide rail (621) through a square slide hole (632), and the guide block (63) is fixed on the slide support (62) through a screw rod matched with a third threaded hole (633).

10. Control device for a multi-machine parallel numerical control hydraulic sheet metal pipe-making and forming machine according to claim 1, characterized in that said screw (64) is rotatably connected to the third rotary connection hole (618) through a rotary shaft (643) and is engaged to the second threaded hole (627) through a bidirectional screw (642).

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