CN114380132B - Automatic winding machine for marine thermal insulation pipe material - Google Patents

Abstract

The invention relates to the technical field of marine equipment, and discloses an automatic marine insulating pipe material winding machine, which solves the problem that a wound product is difficult to take out and comprises a bottom plate, wherein a support frame is arranged at the bottom end of the bottom plate, side plates are symmetrically arranged at the top end of the bottom plate, a disassembly and assembly component is arranged in each side plate, a compression component is arranged between the two side plates, each disassembly and assembly component comprises a middle groove arranged in each side plate, a movable rod is inserted in each middle groove, a supporting block is arranged on the front surface of each movable rod, a rotating groove is formed in each supporting block, and a rotating block is arranged in each rotating groove; in operation, the ejector blocks are unscrewed through the screw rods, and return to the inside of the clamping groove under the action of the first springs, so that the movable rods can be pulled out of the middle groove, and after the movable rods at two sides are pulled out, the winding rods can be detached from the supporting blocks at two sides due to the fact that the winding rods are clamped with the rotating blocks at two sides, winding and discharging work is completed, and winding efficiency is improved.

Description

Automatic winding machine for marine thermal insulation pipe material

Technical Field

The invention belongs to the technical field of marine equipment, and particularly relates to an automatic winding machine for marine thermal insulation pipe materials.

Background

The heat preservation construction of the marine engineering pipeline belongs to a key part in the whole engineering construction, and as the special construction environment of the marine engineering generally has large temperature variation of the working environment, according to related data, the temperature of a part of coastal areas is at minus 20 ℃, and the stability and reliability of pipeline transportation can be affected under the condition of extremely low temperature, even the phenomena of solidification of medium in the pipeline, breakage of the pipeline and the like are accompanied, so that the heat preservation design of the pipeline is required to be enhanced for ensuring the stable operation of the marine engineering pipeline, the pipeline is preserved, the protection technology for preventing the pipeline transportation medium from condensing or freezing is required, and for the general oil (gas) pipeline, the most common method is to additionally wrap a heat preservation layer on the pipeline, and the heat preservation layer is formed by pressing closed-pore type hard polyurethane foam plastic and is covered with skin protection.

In the winding process of the marine heat-insulating pipe material, when the winding is finished, the wound product is not easy to take out.

Disclosure of Invention

Aiming at the situation, in order to overcome the defects of the prior art, the invention provides the automatic winding machine for the marine thermal insulation pipe material, which effectively solves the problem that a wound product is not easy to take out.

In order to achieve the above purpose, the present invention provides the following technical solutions: the automatic winding machine for the marine thermal insulation pipe material comprises a bottom plate, wherein a supporting frame is arranged at the bottom end of the bottom plate, side plates are symmetrically arranged at the top end of the bottom plate, a disassembly and assembly component is arranged in each side plate, and a compression component is arranged between the two side plates;

the disassembly and assembly comprises a middle groove formed in the side plate, a movable rod is inserted into the middle groove, and a supporting block is mounted on the front face of the movable rod.

Preferably, the inside of supporting shoe has been seted up and has been rotated the groove, and the internally mounted in groove has changeed the piece, and two changes one side that the piece is close to each other and all installs the connecting rod, and the connecting rod runs through to the outside of supporting shoe, and the pole groove has been seted up to one side of connecting rod, and the spacing groove has been seted up to the inside equiangle in pole groove, one of them the output shaft of first motor is installed to one side of changeing the piece, first motor and supporting shoe fixed connection, joint unit is installed to the one end of movable rod.

Preferably, the clamping unit comprises a clamping groove formed in the inner portion of the movable rod, one end of the movable rod is in threaded connection with a screw rod, the screw rod penetrates through the clamping groove, one end of the screw rod is rotationally connected with a triangular block, one side of the triangular block is provided with a jacking block, the front face of the jacking block is provided with a first magnetic block, the first magnetic block is inserted into the jacking groove, the jacking groove is formed in one side of the movable rod, one end of the jacking block is provided with an oblique angle, and the oblique angle is matched with the triangular block.

Preferably, a limiting plate is arranged on one side of the top block, a first spring is arranged on the front surface of the limiting plate, one end of the first spring is fixedly connected with the inner wall of the clamping groove, and an adsorption assembly is arranged on one side of one supporting block.

Preferably, the adsorption component comprises a rotary groove formed in one side of one supporting block, a rotary ring is connected to the rotary groove in a rotary mode, a mounting ring is arranged on one side of the rotary ring, an inner gear ring is arranged on the inner wall of the mounting ring, a baffle is arranged on one side of the mounting ring, fan blades are arranged on the inner wall of the baffle at equal angles, a transmission gear is connected with the inner side of the inner gear ring in a meshed mode, the transmission gear is connected with the supporting block in a rotary mode, an outer gear ring is connected with the bottom end of the transmission gear in a meshed mode, the outer gear ring is arranged on the outer side of the rotary block, a communication groove is formed in the rotary block, and a winding rod is arranged between the two connecting rods.

Preferably, the stopper is installed to the equal angle in both ends of rolling pole, stopper and spacing groove joint.

Preferably, the inside of rolling pole has seted up inside groove, and inside groove is linked together with the intercommunication groove, and the outer wall equidistance and the equiangular degree of rolling pole have seted up the intercommunicating pore.

Preferably, the compressing assembly comprises a chute symmetrically arranged inside the side plate, the inside of the chute is slidably connected with a sliding block, a rotating shaft is rotationally connected between the sliding blocks on two sides, an output shaft of a second motor is arranged at one end of one rotating shaft, the second motor is fixedly connected with the sliding block, a second spring is arranged on the front surface of the sliding block, one end of the second spring is fixedly connected with the inner wall of the chute, belts are arranged on the outer sides of the two rotating shafts, side rods are arranged on one sides of the upper sliding block and the lower sliding block, and one ends of the two side rods are rotationally connected with a connecting block.

Preferably, the lantern ring is installed in the outside of axis of rotation, installs the connecting rod between two lantern rings, and the back of connecting rod installs the second magnetic path, and the magnetism of second magnetic path is opposite with the magnetism of first magnetic path.

Compared with the prior art, the invention has the beneficial effects that:

1) In operation, after the screw rods are unscrewed, the ejector blocks return to the inside of the clamping grooves under the action of the first springs, so that the movable rods can be pulled out of the middle grooves, and after the movable rods at the two sides are pulled out, the winding rods can be detached from the supporting blocks at the two sides due to the fact that the winding rods are clamped with the rotating blocks at the two sides, winding and discharging work is completed, and winding efficiency is improved;

2) In operation, the rolling rod is driven to rotate through the rotating block, the external gear ring rotates and then drives the transmission gear to rotate, the transmission gear is meshed with the internal gear ring, the fan blades are driven to rotate, negative pressure is generated in the internal groove, and then the inner wall of the marine heat-insulating pipe material wound on the outer side of the rolling rod is adsorbed and fixed through the communicating hole, so that the marine heat-insulating pipe material is prevented from loosening during rolling, and the rolling stability is improved;

3) In operation, when the winding rod is rotated to wind, the second motor is started at the moment to drive the rotating shaft to rotate, so that the belt moves, the belt is clung to the marine insulation pipe material which is being wound, and the moving directions are opposite, so that the marine insulation pipe material is tightly pressed, and looseness is avoided when the marine insulation pipe material is wound;

4) In operation, when the marine thermal insulation pipe material outside the winding rod is thickened along with winding, the sliding block is driven to move inside the sliding groove, so that the attractive force of the first magnetic block is increased, the winding rod is enabled to move outwards, the belt moves back under the action of the second spring, and when the belt is in the balance position, the pressing force between the belt and the marine thermal insulation pipe material returns to the original value, so that the pressing effect of the belt on the marine thermal insulation pipe material is more stable.

Drawings

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate the invention and together with the embodiments of the invention, serve to explain the invention.

In the drawings:

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is a schematic view of the assembly and disassembly structure of the present invention;

FIG. 3 is a schematic view of the internal structure of the support block according to the present invention;

FIG. 4 is a schematic diagram of a structure of a clamping unit according to the present invention;

FIG. 5 is a schematic view of an adsorption module according to the present invention;

fig. 6 is a schematic structural view of the compressing assembly of the present invention.

In the figure: 1. a bottom plate; 2. a support frame; 3. a side plate; 4. disassembling and assembling the assembly; 401. a middle groove; 402. a movable rod; 403. a support block; 404. a rotating groove; 405. a rotating block; 406. a first motor; 407. a connecting rod; 408. a rod groove; 409. a limit groove; 410. a clamping unit; 4101. a clamping groove; 4102. a screw; 4103. triangular blocks; 4104. an ejection groove; 4105. a top block; 4106. bevel angle; 4107. a limiting plate; 4108. a first spring; 4109. a first magnetic block; 5. an adsorption assembly; 501. a rotary groove; 502. a swivel; 503. a mounting ring; 504. an inner gear ring; 505. a baffle; 506. a fan blade; 507. a transmission gear; 508. an outer toothed ring; 509. a communication groove; 510. a winding rod; 511. an inner groove; 512. a limiting block; 513. a communication hole; 6. a compression assembly; 601. a chute; 602. a slide block; 603. a rotating shaft; 604. a second motor; 605. a second spring; 606. a belt; 607. a side bar; 608. a connecting block; 609. a collar; 610. a connecting rod; 611. and a second magnetic block.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention; all other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the first embodiment, as shown in fig. 1 to 6, the invention comprises a bottom plate 1, a supporting frame 2 is arranged at the bottom end of the bottom plate 1, side plates 3 are symmetrically arranged at the top end of the bottom plate 1, a disassembly and assembly component 4 is arranged in the side plates 3, and a compression component 6 is arranged between the two side plates 3.

In the second embodiment, on the basis of the first embodiment, the dismounting component 4 comprises a middle groove 401 formed in the side plate 3, a movable rod 402 is inserted in the middle groove 401, a supporting block 403 is mounted on the front surface of the movable rod 402, a rotating groove 404 is formed in the supporting block 403, a rotating block 405 is mounted in the rotating groove 404, connecting rods 407 are mounted on one sides of the two rotating blocks 405, which are close to each other, the connecting rods 407 penetrate through the outer sides of the supporting blocks 403, a rod groove 408 is formed on one side of each connecting rod 407, limiting grooves 409 are formed in the inner sides of the rod groove 408 at equal angles, an output shaft of a first motor 406 is mounted on one side of one rotating block 405, the first motor 406 is fixedly connected with the supporting block 403, a clamping unit 410 is mounted on one end of the movable rod 402, the clamping unit 410 comprises a clamping groove 4101 formed in the movable rod 402, one end of the movable rod 402 is in threaded connection with a screw 4102, the screw 4102 penetrates into the clamping groove 4101, one end of the screw 4102 is rotationally connected with a triangular block 4103, one side of the triangular block 4103 is provided with a jacking block 4105, the front surface of the jacking block 4105 is provided with a first magnetic block 4109, the first magnetic block 4109 is inserted into an ejection groove 4104, the ejection groove 4104 is formed in one side of the movable rod 402, one end of the jacking block 4105 is provided with a bevel 4106, the bevel 4106 is matched with the triangular block 4103, one side of the jacking block 4105 is provided with a limiting plate 4107, the front surface of the limiting plate 4107 is provided with a first spring 4108, one end of the first spring 4108 is fixedly connected with the inner wall of the clamping groove 4101, and one side of one supporting block 403 is provided with an adsorption component 5;

when the external winding of the winding rod 510 is finished, the screw 4102 is unscrewed at this time, so that the top block 4105 returns to the inside of the clamping groove 4101 under the action of the first spring 4108, so that the movable rod 402 can be pulled out from the middle groove 401, and after the movable rods 402 on two sides are pulled out, the winding rod 510 can be detached from the supporting blocks 403 on two sides due to the clamping connection between the winding rod 510 and the rotating blocks 405 on two sides, thereby completing winding and blanking work and improving winding efficiency.

In the third embodiment, on the basis of the second embodiment, the adsorption assembly 5 includes a rotating groove 501 formed on one side of one supporting block 403, a rotating ring 502 is rotatably connected in the rotating groove 501, a mounting ring 503 is mounted on one side of the rotating ring 502, an inner gear ring 504 is mounted on the inner wall of the mounting ring 503, a baffle 505 is mounted on one side of the mounting ring 503, fan blades 506 are mounted on the inner wall of the baffle 505 at equal angles, a transmission gear 507 is connected with the inner side of the inner gear ring 504 in a meshed manner, the transmission gear 507 is rotatably connected with the supporting block 403, an outer gear ring 508 is connected with the bottom end of the transmission gear 507 in a meshed manner, the outer gear ring 508 is mounted on the outer side of the rotating block 405, a communication groove 509 is formed in the inner side of the rotating block 405, a winding rod 510 is mounted between the two connecting rods 407, limiting blocks 512 are mounted at equal angles at two ends of the winding rod 510, the limiting blocks 512 are clamped with the limiting grooves 409, an inner groove 511 is formed in the inner side of the winding rod 510, the inner groove 511 is communicated with the communication groove 509, and communication holes 513 are formed at equal angles on the outer wall of the winding rod 510;

in the winding process, after the first motor 406 is started at this time, the output shaft of the first motor 406 drives the rotating block 405 to rotate, so that the rotating block 405 drives the winding rod 510 to rotate, and then drives the rotating block 405 on the other side to rotate, so that the outer gear ring 508 drives the transmission gear 507 to rotate after rotating, and the transmission gear 507 is meshed with the inner gear ring 504, so as to drive the installation ring 503 to rotate, and then drive the fan blade 506 to rotate, so that negative pressure is generated inside the communication groove 509, and because the inner groove 511 is communicated with the communication groove 509, negative pressure is generated inside the inner groove 511, and then the inner wall of the marine heat-insulating pipe material wound on the outer side of the winding rod 510 is adsorbed and fixed through the communication hole 513, so that the marine heat-insulating pipe material is prevented from loosening during winding, and winding stability is improved.

In the fourth embodiment, based on the third embodiment, the compressing assembly 6 includes a chute 601 symmetrically opened in the side plate 3, the inside of the chute 601 is slidingly connected with a slide block 602, a rotation shaft 603 is rotatably connected between the slide blocks 602 at two sides, one end of one rotation shaft 603 is provided with an output shaft of a second motor 604, the second motor 604 is fixedly connected with the slide block 602, the front surface of the slide block 602 is provided with a second spring 605, one end of the second spring 605 is fixedly connected with the inner wall of the chute 601, the outer sides of the two rotation shafts 603 are provided with belts 606, one sides of the upper and lower slide blocks 602 are provided with side rods 607, one ends of the two side rods 607 are rotatably connected with a connecting block 608, the outer sides of the rotation shaft 603 are provided with lantern rings 609, a connecting rod 610 is installed between the two lantern rings 609, the back surface of the connecting rod 610 is provided with a second magnetic block 611, and the magnetism of the second magnetic block 611 is opposite to that of the first magnetic block 4109;

when the winding rod 510 rotates to wind, the second motor 604 is started at this time, and the rotating shaft 603 is driven to rotate, so that the belt 606 moves, the belt 606 is clung to the marine insulation pipe material being wound, the moving direction is opposite, the marine insulation pipe material is tightly pressed, loosening of the marine insulation pipe material is avoided when the marine insulation pipe material is wound, when the marine insulation pipe material outside the winding rod 510 is thickened along with winding, the sliding block 602 is pushed to move inside the sliding groove 601, so that the distance between the second magnetic block 611 and the first magnetic block 4109 is increased, the attractive force of the first magnetic block 4109 is increased, the 802 is moved inside the winding rod 801, the winding rod 510 moves outwards, the belt 606 moves back under the action of the second spring 605 at this time, and the pressing force between the belt 606 and the marine insulation pipe material returns to the original value at this time when the winding rod is at the balance position, so that the pressing effect of the belt 606 on the marine insulation pipe material is more stable.

Claims (3)

1. Ocean insulating tube material automatic winding machine, including bottom plate (1), its characterized in that: the bottom end of the bottom plate (1) is provided with a supporting frame (2), the top end of the bottom plate (1) is symmetrically provided with side plates (3), the inside of each side plate (3) is provided with a disassembly and assembly component (4), and a compression component (6) is arranged between the two side plates (3);

the disassembly and assembly (4) comprises a middle groove (401) formed in the side plate (3), a movable rod (402) is inserted into the middle groove (401), a supporting block (403) is mounted on the front face of the movable rod (402), a rotating groove (404) is formed in the supporting block (403), a rotating block (405) is mounted in the rotating groove (404), connecting rods (407) are mounted on one sides, close to each other, of the two rotating blocks (405), the connecting rods (407) penetrate through the outer sides of the supporting blocks (403), rod grooves (408) are formed in one sides of the connecting rods (407), limit grooves (409) are formed in the inner sides of the rod grooves (408) at equal angles, an output shaft of a first motor (406) is mounted on one side of one rotating block (405), the first motor (406) is fixedly connected with the supporting block (403), and a clamping unit (410) is mounted on one end of the movable rod (402);

the clamping unit (410) comprises a clamping groove (4101) formed in the movable rod (402), one end of the movable rod (402) is connected with a screw rod (4102) in a threaded mode, the screw rod (4102) penetrates into the clamping groove (4101), one end of the screw rod (4102) is rotatably connected with a triangular block (4103), one side of the triangular block (4103) is provided with a jacking block (4105), the front surface of the jacking block (4105) is provided with a first magnetic block (4109), the first magnetic block (4109) is inserted into an ejection groove (4104), the ejection groove (4104) is formed in one side of the movable rod (402), one end of the jacking block (4105) is provided with a bevel (4106), the bevel (4106) is matched with the triangular block (4103), one side of the jacking block (4105) is provided with a limiting plate (4107), the front surface of the limiting plate (4107) is provided with a first spring (4108), one end of the first spring (4108) is fixedly connected with the inner wall of the clamping groove (4104), and one side of the supporting block (403) is provided with an adsorption component (5);

the adsorption component (5) comprises a rotary groove (501) formed in one side of one supporting block (403), a rotary ring (502) is connected to the rotary groove (501) in a rotary mode, a mounting ring (503) is mounted on one side of the rotary ring (502), an inner gear ring (504) is mounted on the inner wall of the mounting ring (503), a baffle (505) is mounted on one side of the mounting ring (503), fan blades (506) are mounted on the inner wall of the baffle (505) at equal angles, a transmission gear (507) is connected to the inner side of the inner gear ring (504) in a meshed mode, the transmission gear (507) is connected with the supporting block (403) in a rotary mode, an outer gear ring (508) is connected to the bottom end of the transmission gear (507) in a meshed mode, the outer gear ring (508) is mounted on the outer side of the rotary block (405), a communication groove (509) is formed in the rotary block (405), a winding rod (510) is mounted between the two connecting rods (407), limiting blocks (512) are mounted at equal angles on two ends of the winding rod (510), the limiting blocks (512) are clamped with the limiting grooves (409), inner grooves (511) are formed in the inner side of the winding rod (510), the inner grooves (511) in a meshed mode, the outer grooves (509) are communicated with the outer walls of the inner grooves (509), and the communication holes (513) are formed in equal angles.

2. The automatic marine insulation pipe material winding machine according to claim 1, wherein: compressing tightly subassembly (6) including the symmetry set up in inside spout (601) of curb plate (3), the inside sliding connection of spout (601) has slider (602), rotate between slider (602) of both sides and be connected with axis of rotation (603), the output shaft of second motor (604) is installed to one end of one of them axis of rotation (603), second motor (604) and slider (602) fixed connection, second spring (605) are installed in the front of slider (602), the one end and the inner wall fixed connection of spout (601) of second spring (605), belt (606) are installed in the outside of two axis of rotation (603), side lever (607) are all installed to one side of two upper and lower sliders (602), the one end rotation of two side levers (607) is connected with connecting block (608).

3. The automatic marine insulation pipe material winding machine according to claim 2, wherein: the outside of axis of rotation (603) is installed lantern ring (609), installs connecting rod (610) between two lantern rings (609), and second magnetic path (611) are installed to the back of connecting rod (610), and the magnetism of second magnetic path (611) is opposite with the magnetism of first magnetic path (4109).