CN112848447B - Control rock wool thickness's pleating press behind pressurization - Google Patents

Abstract

The invention relates to the technical field of rock wool production, and discloses a pleating and pressurizing machine for controlling the thickness of pressurized rock wool, which comprises a base, a support column, a top plate, a bottom roller, a top roller, a moving assembly and an extrusion assembly, wherein the top end of the base is fixedly connected with the support column, the top end of the support column is fixedly connected with the top plate, the bottom end of the inner wall of the top plate is movably connected with the top roller, the top end of the base is movably connected with the bottom roller, and the top end of the base is positioned on the right side of the bottom roller and is movably connected with the moving assembly; thereby slide the thickness on control pressurization rock wool layer in the fixed block through electronic slider, meanwhile, the cover post is pushing away the pulling force that the spring pull rod was overcome to the ejector pad and is to rock wool pad direction motion for bottom roll and top roll are when compressing the rock wool layer, the rock wool quilt that can not appear is extruded the condition, and the both sides that use from the rock wool pad through two removal subassemblies and extrusion subassembly prevent that the rock wool layer from being extruded between bottom roll and the top roll, thereby improve the utilization ratio of rock wool.

Description

Control rock wool thickness's pleating press behind pressurization

Technical Field

The invention relates to the technical field of rock wool production, in particular to a pleating and pressurizing machine for controlling the thickness of pressurized rock wool.

Background

Rock wool is formed by volcanic eruption, in the process of simulation in the industrial production process, rock wool is made from high-quality basalt, dolomite and other ores through a series of processing, in the process of producing the rock wool, the stripped rock wool fiber is sent to be conveyed, then is piled up layer by a machine, then is compressed into a compact rock wool cushion through a pleating and pressurizing machine, then burrs at two sides of the rock wool cushion are cut and removed by a cutting machine, burrs can appear at two sides of the rock wool cushion when the rock wool cushion is compressed by the pressurizing machine, the burrs are uneven, a plurality of rock wool can fall off, it is known that the rock wool can damage the lung after being sucked by human body, in addition, the fallen rock wool needs to be recollected and then is re-finished, not only the production cost is increased, but also the health of workers is affected, therefore, we propose a pleating press for reducing rock wool fall and controlling the thickness of the rock wool after pressing.

Disclosure of Invention

In order to achieve the aim of reducing rock wool falling, the invention provides the following technical scheme: the utility model provides a control pressurization back rock wool thickness's pleating presser, includes base, support column, roof, bottom roll, top roll, removal subassembly and extrusion subassembly, base top and support column fixed connection, support column top and roof fixed connection, roof inner wall bottom and top roll swing joint, base top and bottom roll swing joint, the base top is located the bottom roll right side and removes subassembly swing joint, remove subassembly top and extrusion subassembly swing joint.

As optimizing, it comprises fixed block, flexible cover, connecting axle, electronic slider, driving chain, round piece, protruding gyro wheel and transmission tooth post to remove the subassembly, flexible cover inner wall rotates with the connecting axle to be connected, connecting axle left side and bottom roll fixed connection, flexible cover bottom and base fixed connection, the fixed block is located flexible cover right side and base top fixed connection, fixed block inner wall and electronic slider sliding connection, electronic slider inner wall rotates with the connecting axle to be connected, the connecting axle outer wall is located electronic slider inner wall and driving chain swing joint, connecting axle right side and round piece meshing, the transmission tooth post rotates with the fixed block inner wall to be connected, removes subassembly control bottom roll and reciprocates for thickness when bottom roll and top roll pressurization rock wool can be controlled.

Preferably, the outer wall of the round block is rotationally connected with the convex roller, the round block is meshed with the transmission toothed column through the convex roller, and sliding friction force generated when the round block moves relative to the transmission toothed column is reduced and converted into rolling friction force.

As an optimization, the extrusion assembly comprises a push block, a convex column, a transmission sleeve, a coil spring, a transmission belt, a movable rod, a spiral groove, a sleeve column, a sleeve block, a strip-shaped slide block, a ring groove, a circular slide block, a convex block, a rotating rod, a first spring, a ratchet wheel, a pawl, a second spring, a guide rod and a sliding column, wherein the sliding column is in sliding connection with the bottom end of the inner wall of the top plate;

preferably, the guide rod is movably connected with the inner wall of the coil spring, the top end of the coil spring is fixedly connected with a first spring, the top end of the first spring is fixedly connected with a rotating rod, the bottom end of the rotating rod is positioned on the left side of the first spring and is rotatably connected with the coil spring, and the right side of the convex block is fixedly connected with the convex column, so that the rotating rod always keeps a tendency of rotating in the counterclockwise direction;

as an optimization, the top end of the inner wall of the sleeve column is connected with a bar-shaped sliding block in a sliding manner, the top end of the bar-shaped sliding block is fixedly connected with the sleeve block, the spiral groove is formed in the outer wall of the movable rod, the annular groove is formed in the left side of the spiral groove and formed in the outer wall of the movable rod, the inner wall of the spiral groove is connected with the circular sliding block in a sliding manner, and the top end of the circular sliding block is fixedly connected with the sleeve column, so that the circular sliding block can move into the annular groove from the spiral groove;

preferably, the top end of the pawl is rotationally connected with the transmission sleeve, the inner wall of the transmission sleeve is fixedly connected with the second spring, the bottom end of the second spring is fixedly connected with the pawl, and the transmission tooth column is fixedly connected with the inner wall of the ratchet wheel, so that the pawl always keeps a clockwise rotation trend.

Preferably, the number of the supporting columns, the number of the moving assemblies and the number of the extruding assemblies are two, and the supporting columns, the moving assemblies and the extruding assemblies are symmetrically arranged relative to the vertical center line of the base.

As optimization, a first driving motor is arranged in the transmission chain, a second driving motor is arranged in the electric sliding block, so that the transmission chain can drive the connecting shaft to rotate, and the electric sliding block can slide in the inner wall of the fixed block.

As optimization, the sliding column bottom and the telescopic sleeve are fixedly connected, a rectangular sliding block is fixedly mounted on the right side of the sliding column, and the outer wall of the rectangular sliding block is connected with the top plate in a sliding mode, so that the sliding column can stably slide on the inner wall of the top plate.

Preferably, the sleeve column is fixedly provided with a rectangular plate on the left side, the magnetic bead is movably connected to the left side of the inner wall of the rectangular plate, the magnetic block is fixedly arranged on the inner wall of the push block, and the magnetic bead and the magnetic block attract each other, so that the push block and the top plate attract each other.

As optimization, the bottom end of the sleeve block is fixedly connected with the fixed block, the left side of the transmission belt is movably connected with a connecting rod, the bottom end of the connecting rod is rotatably connected with the fixed block, and the top end of the connecting rod is meshed with the movable rod, so that the transmission belt can drive the movable rod to rotate.

Preferably, the bottom end of the transmission sleeve is rotatably connected with the fixed block, the bottom ends of the convex columns are fixedly connected with the fixed block, and the number of the convex columns is two and the two convex columns are symmetrically arranged relative to the vertical center line of the coil spring.

The invention has the beneficial effects that: thereby slide the thickness on control pressurization rock wool layer in the fixed block through electronic slider, meanwhile, the movable rod is pushing away the cover post and is removing left through helicla flute and circular slider's mating reaction, when the movable rod continues to rotate and makes circular slider move the annular from the helicla flute in, circular slider moves in the annular, make the cover post remain at this position all the time, the cover post is pushing away the pulling force that the spring pull rod was overcome to the ejector pad to the rock wool pad direction motion, make bottom roll and top roll when compressing the rock wool layer, the rock wool quilt that can not appear is extruded the condition, both sides that use from the rock wool pad through two cooperation of removing subassembly and extrusion subassembly prevent that the rock wool layer from being extruded between bottom roll and the top roll, thereby improve the utilization ratio of rock wool.

Drawings

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

FIG. 2 is a schematic view of the structure of FIG. 1, partially broken away, according to the present invention;

FIG. 3 is an enlarged view of the structure at A in FIG. 2 according to the present invention;

FIG. 4 is a schematic view of the engagement structure of the round block and the transmission gear column according to the present invention;

FIG. 5 is an enlarged view of the structure at B in FIG. 2 according to the present invention;

FIG. 6 is a schematic view of the movable rod and sleeve post structure of the present invention;

FIG. 7 is an enlarged view of the structure of FIG. 6 at C according to the present invention;

FIG. 8 is a schematic view of a coil spring and a boss of the present invention;

FIG. 9 is a schematic view of the ratchet and the driving sleeve of the present invention.

In the figure: 100. a base; 200. a support pillar; 300. a top plate; 400. a bottom roll; 500. a top roll; 600. a moving assembly; 601. a fixed block; 602. a telescopic sleeve; 603. a connecting shaft; 604. an electric slider; 605. a drive chain; 606. a round block; 607. a convex roller; 608. a transmission tooth column; 700. an extrusion assembly; 701. a push block; 702. a convex column; 703. a transmission sleeve; 704. a coil spring; 705. a transmission belt; 706. a movable rod; 707. a helical groove; 708. sleeving a column; 709. sleeving blocks; 710. a bar-shaped slider; 711. a ring groove; 712. a circular slider; 713. a bump; 714. rotating the rod; 715. a first spring; 716. a ratchet wheel; 717. a pawl; 718. a second spring; 719. a guide bar; 720. a sliding post; 721. a spring pull rod.

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 obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

Referring to fig. 1, a pleating and pressurizing machine for controlling the thickness of pressurized rock wool comprises a base 100, a support column 200, a top plate 300, a bottom roller 400, a top roller 500, a moving assembly 600 and an extruding assembly 700, wherein the top end of the base 100 is fixedly connected with the support column 200, the top end of the support column 200 is fixedly connected with the top plate 300, the bottom end of the inner wall of the top plate 300 is movably connected with the top roller 500, the top end of the base 100 is movably connected with the bottom roller 400, the top end of the base 100 is positioned at the right side of the bottom roller 400 and is movably connected with the moving assembly 600, and the top end of the moving assembly 600 is movably connected with the extruding assembly 700;

referring to fig. 1, there are two supporting columns 200, two moving assemblies 600 and two squeezing assemblies 700, which are symmetrically disposed about a vertical center line of the base 100;

according to fig. 1, thereby extrude rock wool layer through bottom roll 400 and top roll 500 and form tight rock wool pad, through removing the distance between assembly 600 control bottom roll 400 and the top roll 500 to the thickness of control rock wool pad, in addition, exert thrust to the rock wool layer both sides that are pressurizeed through extrusion subassembly 700, make the rock wool silk significantly reduced that drops.

Referring to fig. 1-5, the moving assembly 600 includes a fixed block 601, a telescopic sleeve 602, a connecting shaft 603, an electric slider 604, a transmission chain 605, a round block 606, a convex roller 607 and a transmission tooth post 608, wherein an inner wall of the telescopic sleeve 602 is rotatably connected to the connecting shaft 603, a left side of the connecting shaft 603 is fixedly connected to the bottom roller 400, a bottom end of the telescopic sleeve 602 is fixedly connected to the base 100, the fixed block 601 is located at a right side of the telescopic sleeve 602 and is fixedly connected to a top end of the base 100, an inner wall of the fixed block 601 is slidably connected to the electric slider 604, a second driving motor is disposed in the electric slider 604, an inner wall of the electric slider 604 is rotatably connected to the connecting shaft 603, an outer wall of the connecting shaft 603 is located at an inner wall of the electric slider 604 and is movably connected to the transmission chain 605, a first driving motor is disposed in the transmission chain 605, a right side of the connecting shaft 603 is engaged with the round block 606, and the transmission tooth post 608 is rotatably connected to an inner wall of the fixed block 601;

according to fig. 3, a connecting rod is fixedly installed at the top end of the round block 606, the outer wall of the connecting rod is connected with a connecting sleeve in a sliding manner, the left side of the connecting sleeve is fixedly connected with the electric slider 604, a first bevel gear is fixedly installed at the top end of the connecting rod, a second bevel gear is meshed with the top end of the first bevel gear, and the left side of the second bevel gear is fixedly connected with the connecting shaft 603.

Referring to fig. 4, the outer wall of the round block 606 is rotatably connected to the convex roller 607, the round block 606 is engaged with the transmission gear column 608 through the convex roller 607, and according to fig. 3, when the round block 606 is driven by the electric slider 604 to move up and down, the round block 606 can also smoothly drive the transmission gear column 608 to continuously rotate, and the friction force is small.

Referring to fig. 1-9, the pressing assembly 700 comprises a pushing block 701, a protruding post 702, a driving sleeve 703, a coil spring 704, a transmission belt 705, a movable rod 706, a spiral groove 707, a sleeve column 708, a sleeve block 709, a strip-shaped sliding block 710, a ring groove 711, a circular sliding block 712, a protrusion 713, a rotating rod 714, a first spring 715, a ratchet 716, a pawl 717, a second spring 718, a guide rod 719 and a sliding column 720, wherein the sliding column 720 is slidably connected with the bottom end of the inner wall of the top plate 300, the right side of the inner wall of the sliding column 720 is fixedly connected with a spring pull rod 721, the left side of the spring pull rod 721 is fixedly connected with the pushing block 701, the right side of the pushing block 701 is movably connected with the sleeve column 708, so that the right side of the movable rod 706 is movably connected with the transmission belt 705, the right side of the transmission belt 705 is movably connected with the outer wall 703 of the driving sleeve, the top end of the transmission sleeve 703 is fixedly connected with the guide rod 719, the bottom end of the transmission sleeve 703 is rotatably connected with a fixed block 601, the bottom end of the protruding post 702 is fixedly connected with the fixed block 601, two convex columns 702 are arranged symmetrically with respect to the vertical center line of the coil spring 704;

referring to fig. 2, a rectangular plate is fixedly mounted on the left side of the sleeve column 708, magnetic beads are movably connected to the left side of the inner wall of the rectangular plate, a magnetic block is fixedly mounted on the inner wall of the push block 701, and the magnetic beads and the magnetic block attract each other, so that the push block 701 is smoothly pushed by the rectangular plate to move towards the rock wool layer;

referring to fig. 8, the guide rod 719 is movably connected to the inner wall of the coil spring 704, the top end of the coil spring 704 is fixedly connected to the first spring 715, the top end of the first spring 715 is fixedly connected to the rotating rod 714, the bottom end of the rotating rod 714 is located at the left side of the first spring 715 and rotatably connected to the coil spring 704, and the right side of the protrusion 713 is fixedly connected to the boss 702;

according to fig. 8, the guide rod 719 rotates inside the coil spring 704, and after the movement of the winding strip inside the coil spring 704 to the limit, the guide rod 719 carries the coil spring 704 against the spring force of the first spring 715 on the rotary rod 714, so that the coil spring 704 also rotates together;

referring to fig. 6, the top end of the inner wall of the sleeve column 708 is slidably connected to a bar-shaped slider 710, the top end of the bar-shaped slider 710 is fixedly connected to a sleeve block 709, a spiral groove 707 is formed in the outer wall of the movable rod 706, a ring groove 711 is formed in the outer wall of the movable rod 706 at the left side of the spiral groove 707, the inner wall of the spiral groove 707 is slidably connected to a circular slider 712, and the top end of the circular slider 712 is fixedly connected to the sleeve column 708;

according to fig. 6, when the movable rod 706 rotates, the sleeve column 708 moves to the left through the cooperation of the spiral groove 707 and the circular slider 712;

referring to fig. 9, the top end of the pawl 717 is rotatably connected to the transmission sleeve 703, the inner wall of the transmission sleeve 703 is fixedly connected to the second spring 718, and the bottom end of the second spring 718 is fixedly connected to the pawl 717;

according to fig. 9, the ratchet 716 is rotated counterclockwise by the pawl 717 carrying the driving sleeve 703, and when the driving sleeve 703 is reversed, the ratchet 716 does not rotate.

Referring to fig. 2, the bottom end of the sliding column 720 is fixedly connected to the telescopic sleeve 602, a rectangular sliding block is fixedly installed on the right side of the sliding column 720, and the outer wall of the rectangular sliding block is slidably connected to the top plate 300;

according to fig. 2, the sliding column 720 is stably slid on the inner wall of the top plate 300 by the rectangular slider.

Referring to fig. 5, the bottom end of the sleeve 709 is fixedly connected to the fixed block 601, the left side of the transmission belt 705 is movably connected to a connecting rod, the bottom end of the connecting rod is rotatably connected to the fixed block 601, and the top end of the connecting rod is engaged with the movable rod 706, so that the transmission belt 705 drives the movable rod 706 to rotate.

In use, referring to fig. 1-9, a first driving motor is arranged in a driving chain 605 to operate, so that the driving chain 605 drives a connecting shaft 603 to rotate, a third driving motor is arranged in a top roller 500 to pressurize a rock wool layer through the rotation of a bottom roller 400 and the top roller 500, a second driving motor is arranged in an electric sliding block 604 to operate, so that the electric sliding block 604 slides in a fixed block 601 to control the thickness of the pressurized rock wool layer, the electric sliding block 604 drives a round block 606 to rotate, the connecting shaft 603 drives the round block 606 to rotate, the round block 606 drives a driving toothed column 608 to rotate through a convex roller 607, the convex roller 607 converts sliding friction generated when the round block 606 moves up and down relative to the driving toothed column 608 into rolling friction to reduce friction, the driving toothed column 608 drives a ratchet 716 to rotate, the ratchet 716 drives a driving sleeve 703 to rotate through a pawl 717, the driving sleeve 703 drives a guide rod 719 to rotate, and the guide rod 719 overcomes the acting force of a coil spring 704 to rotate, the coil spring 704 rotates anticlockwise, at the moment, due to the existence of the first spring 715, the rotating rod 714 and the bump 713, the coil spring 704 is fixed in place, the guide rod 719 rotates inside the coil spring 704, after the coil strip inside the coil spring 704 moves to the limit, the guide rod 719 carries the coil spring 704 to overcome the elastic force of the first spring 715 on the rotating rod 714, so that the coil spring 704 also rotates together, the transmission sleeve 703 carries the transmission belt 705 to rotate, the transmission belt 705 carries the movable rod 706 to rotate, the movable rod 706 pushes the sleeve column 708 to move leftwards through the cooperation effect of the spiral groove 707 and the circular sliding block 712, when the movable rod 706 continues to rotate so that the circular sliding block 712 moves from the spiral groove 707 to the ring groove 711, the circular sliding block 712 moves in the ring groove 711, so that the sleeve column 708 is always kept at the position, the sleeve column 708 pushes the push block 701 to move towards the rock wool pad direction against the tensile force of the spring tension 721, so that the bottom roller 400 and the top roller 500 are in the rock wool layer, when the pleating press is stopped, the coil spring 704 enables the guide rod 719 to rotate reversely under the cooperation of the rotating rod 714 and the bump 713, the guide rod 719 drives the transmission sleeve 703 to rotate reversely, the transmission sleeve 703 drives the movable rod 706 to rotate reversely through the transmission belt 705, at the moment, the spring pull rod 721 pulls the push block 701 to move rightwards, the push block 701 pushes the sleeve column 708 to keep the trend of moving rightwards, the circular sliding block 712 enters the spiral groove 707, the sleeve column 708 moves rightwards, the push block 701 returns to the original position, when the pleating press is restarted, the push block 701 can extrude the rock wool pad to enable the two sides of the rock wool pad not to be extruded between the top roller 500 and the bottom roller 400, the rock wool layers are prevented from being extruded between the bottom roller 400 and the top roller 500 through the cooperation of the two moving assemblies 600 and the extruding assembly 700, and therefore the utilization rate of rock wool extrusion is improved.

In summary, the thickness of the rock wool layer is controlled by sliding the electric sliding block 604 in the fixed block 601, at the same time, the movable rod 706 pushes the sleeve column 708 to move leftwards through the cooperation of the spiral groove 707 and the circular sliding block 712, when the movable rod 706 continues to rotate so that the circular sliding block 712 moves from the spiral groove 707 to the ring groove 711, the circular sliding block 712 moves in the ring groove 711, so that the sleeve column 708 is always kept at the position, the sleeve column 708 pushes the push block 701 to move towards the rock wool pad direction against the tensile force of the spring pull rod 721, so that the rock wool layer is prevented from being squeezed out between the bottom roller 400 and the top roller 500 when the bottom roller 400 and the top roller 500 compress the rock wool layer, and the rock wool layer is prevented from being squeezed out between the bottom roller 400 and the top roller 500 through the cooperation of the two moving assemblies 600 and the squeezing assembly 700, so that the utilization rate of the rock wool layer is improved.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical scope of the present invention and the equivalent alternatives or modifications according to the technical solution and the inventive concept of the present invention within the technical scope of the present invention.

Claims (3)

1. The utility model provides a rock wool thickness's pleating presser after control pressurization, includes base (100), support column (200), roof (300), bottom roll (400), top roll (500), removes subassembly (600) and extrusion subassembly (700), its characterized in that: the top end of the base (100) is fixedly connected with a supporting column (200), the top end of the supporting column (200) is fixedly connected with a top plate (300), the bottom end of the inner wall of the top plate (300) is movably connected with a top roller (500), the top end of the base (100) is movably connected with a bottom roller (400), the top end of the base (100) is positioned on the right side of the bottom roller (400) and is movably connected with a moving assembly (600), and the top end of the moving assembly (600) is movably connected with an extrusion assembly (700);

the moving assembly (600) consists of a fixed block (601), a telescopic sleeve (602), a connecting shaft (603), an electric sliding block (604), a transmission chain (605), a round block (606), a convex roller (607) and a transmission tooth column (608), wherein the inner wall of the telescopic sleeve (602) is rotatably connected with the connecting shaft (603), the left side of the connecting shaft (603) is fixedly connected with a bottom roller (400), the bottom end of the telescopic sleeve (602) is fixedly connected with a base (100), the fixed block (601) is positioned at the right side of the telescopic sleeve (602) and fixedly connected with the top end of the base (100), the inner wall of the fixed block (601) is slidably connected with the electric sliding block (604), the inner wall of the electric sliding block (604) is rotatably connected with the connecting shaft (603), the outer wall of the connecting shaft (603) is positioned at the inner wall of the electric sliding block (604) and movably connected with the transmission chain (605), and the right side of the connecting shaft (603) is meshed with the round block (606), the transmission tooth column (608) is rotationally connected with the inner wall of the fixed block (601);

the outer wall of the round block (606) is rotatably connected with the convex roller (607), and the round block (606) is meshed with the transmission gear column (608) through the convex roller (607);

the extrusion assembly (700) consists of a push block (701), a convex column (702), a transmission sleeve (703), a coil spring (704), a transmission belt (705), a movable rod (706), a spiral groove (707), a sleeve column (708), a sleeve block (709), a strip-shaped sliding block (710), an annular groove (711), a circular sliding block (712), a convex block (713), a rotating rod (714), a first spring (715), a ratchet wheel (716), a pawl (717), a second spring (718), a guide rod (719) and a sliding column (720), wherein the sliding column (720) is in sliding connection with the bottom end of the inner wall of the top plate (300), the right side of the inner wall of the sliding column (720) is fixedly connected with a spring pull rod (721), the left side of the spring pull rod (721) is fixedly connected with the push block (701), the right side of the push block (701) is movably connected with the sleeve column (701), the right side of the movable rod (706) is movably connected with the transmission belt (705), and the right side of the transmission belt (703), the top end of the transmission sleeve (703) is fixedly connected with the guide rod (719);

the guide rod (719) is movably connected with the inner wall of the coil spring (704), the top end of the coil spring (704) is fixedly connected with the first spring (715), the top end of the first spring (715) is fixedly connected with the rotating rod (714), the bottom end of the rotating rod (714) is positioned at the left side of the first spring (715) and is rotatably connected with the coil spring (704), and the right side of the convex block (713) is fixedly connected with the convex column (702);

the top end of the inner wall of the sleeve column (708) is in sliding connection with a strip-shaped sliding block (710), the top end of the strip-shaped sliding block (710) is fixedly connected with a sleeve block (709), the spiral groove (707) is formed in the outer wall of the movable rod (706), the ring groove (711) is formed in the left side of the spiral groove (707) and formed in the outer wall of the movable rod (706), the inner wall of the spiral groove (707) is in sliding connection with the circular sliding block (712), and the top end of the circular sliding block (712) is fixedly connected with the sleeve column (708);

the top end of the pawl (717) is rotatably connected with the transmission sleeve (703), the inner wall of the transmission sleeve (703) is fixedly connected with a second spring (718), and the bottom end of the second spring (718) is fixedly connected with the pawl (717);

the bottom end of the sliding column (720) is fixedly connected with the telescopic sleeve (602), a rectangular sliding block is fixedly installed on the right side of the sliding column (720), and the outer wall of the rectangular sliding block is slidably connected with the top plate (300);

a rectangular plate is fixedly installed on the left side of the sleeve column (708), magnetic beads are movably connected to the left side of the inner wall of the rectangular plate, a magnetic block is fixedly installed on the inner wall of the push block (701), and the magnetic beads and the magnetic block are mutually attracted;

the bottom end of the sleeve block (709) is fixedly connected with a fixed block (601), the left side of the transmission belt (705) is movably connected with a connecting rod, the bottom end of the connecting rod is rotatably connected with the fixed block (601), and the top end of the connecting rod is meshed with a movable rod (706);

the bottom end of the transmission sleeve (703) is rotatably connected with the fixed block (601), the bottom ends of the convex columns (702) are fixedly connected with the fixed block (601), and the number of the convex columns (702) is two and is symmetrically arranged relative to the vertical center line of the coil spring (704).

2. The pleating and pressurizing machine for controlling the thickness of the pressurized rock wool as claimed in claim 1, wherein: the supporting column (200), the moving assembly (600) and the extruding assembly (700) are two and are symmetrically arranged relative to the vertical center line of the base (100).

3. The pleating press for controlling the thickness of pressurized rock wool according to claim 1, wherein: a first driving motor is arranged in the transmission chain (605), and a second driving motor is arranged in the electric sliding block (604).

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