FIBER GLASS REINFORCED PLASTIC PIPE MACHINE

Technical Field

The invention relates to a pipe machine for the production of GRP (Fiber Glass Reinforced Plastic) pipes in the size range DN80-DN250 with a maximum length of 6 meters.

In particular, the invention relates to a pipe machine that can be used as a separate production line or adapted to machines that produce GRP pipes with continuous fiber winding method, suitable for use in enterprises with low volume, increases production efficiency thanks to its continuous mold feeding feature, and allows size change.

Prior Art

In the systems currently used in the production of fiber glass reinforced plastic (GRP) pipes, a mold is rotated between two bearing points. Resin, sand, circularly wound fibers and chopped fibers are applied to the mold. This basic principle is realized by many different mechanisms. At this point, after the pipe is formed, the mold is removed from the main machine and the produced pipe is removed from the mold at another station. This causes inefficiencies in both labor and production, especially time. The process is interrupted to remove the mold on which the pipe has been produced. This causes inefficiencies in the composite work. In addition, the systems in the current techniques in use today can only be used as a machine on their own.

Today, many studies have been carried out and new machines/sy stems have been developed in order to eliminate the existing disadvantages. One of these studies is the invention subject to the utility model application numbered TR 2019/01477 and titled "Extruder Head Unit Used in Plastic Pipe Production". The invention is related to the pipe head unit, which is positioned after the melt filter in extruder machines that produce plastic pipes, where the products to be produced with the extruder machine are shaped, and which contains metal molds.

Another application is the invention subject to the utility model application numbered TR 2008/05832 and titled "Fiber Glass Reinforced Polyester Pipe Production System". This invention is related to a glass fiber reinforced polyester pipe production system that enables the production of glass fiber reinforced polyester pipes used in auxiliary and tertiary pipelines in pressurized or unpressurized irrigation water transmission and distribution, in drinking water transmission and distribution networks, in main and secondary collectors in sewage systems, in the transmission of all kinds of waste water, in the use of sea water as cooling water in power plants, in the transmission of clean and waste water under the sea, in the transmission of chemicals in chemical factories and in the transmission of water containing chemicals obtained from thermal sources; and is characterized in; that it comprises of main machine body, main machine lower and feeding platforms, mandrel, mandrel bearing group, main mandrel motor, steel belt, steel belt guiding groups, polyester main tanks and pumping group, polyester delivery and dosing group, polyester delivery pipelines, main sand tank and delivery group, sand feeding group, fiber feeding system, infrared heating system, pipe cutting machine, hydraulic platforms, hydraulic platform top roller groups, pipe carrier groups, pipe ends chamfering and adjusting group, sleeve assembly bench, pipe pressure test machine, pressure water tank, pipe fittings manufacturing bench, polyester, sand, fiber glass, catalyst chemical, product (pipe), test cylinder and test head.

Another work is the invention subject to patent application numbered WO 2004/000522 and titled "Method of Manufacture of Fiber Glass Reinforced Pipes". In accordance with the invention, for the manufacture of fiber glass reinforced, in particular centrifuged, plastic pipes, a liquid, curable resin, which may contain a filler, is incorporated into a rotating matrix with glass fibers and additives for hardening, as well as sand. Several layers of sand are used. The middle sand layer is divided by a layer of fiber glass, the amount of fiber glass being measured according to a desired nominal pressure.

As a result, the existence of the need for a pipe machine that eliminates the disadvantages of the existing technique, and the inadequacy of existing solutions necessitated a development in the relevant technical field.

Brief Description of the Invention

The invention relates to a pipe machine for the production of GRP (Fiber Glass Reinforced Plastic) pipes in the size range DN80-DN250 with a maximum length of 6 meters, which meets the above-mentioned requirements, eliminates all disadvantages and brings some additional advantages. Based on the prior art, the purpose of the invention is to ensure that the pipe machine developed can be adapted and used with other existing machines that produce GRP pipes with continuous fiber winding method thanks to its special mechanism, and once the adaptation process is done, it can be ready for production during a size change or can be used as a separate production line.

The purpose of the invention is to enable the pipe machine to be adapted to existing systems, allowing the use of many existing units (raw material feeding, automation and control, main drive system and the like) and functions of the existing machine, no matter what type and by which manufacturer it is equipped, thus making it efficient for all GRP pipe producing enterprises already in operation.

A further purpose of the invention is that the pipe machine can be adapted to existing systems, thereby eliminating many investment requirements.

A further purpose of the invention is that the small overall volume of the pipe machine enables a solution to be provided for installations that do not have suitable indoor space or that cannot be expanded in any way.

A further purpose of the invention is to facilitate ease of operation, since the pipe machine can be adapted to an existing machine at any time.

Another purpose of the invention is to ensure that the production continues without interruption by taking the mold with the pipe produced on the pipe machine to the other station and applying raw material to the subsequent mold.

Another purpose of the invention is to increase the production efficiency by means of continuous mold feeding to the production section in the pipe machine.

Another purpose of the invention is to provide an easy and fast change of size by simply replacing only the wheel on the mold driving system and the mold clutch pads in the mold feeding system and the guide pipes in the main shaft with bolts and pins.

The nature and characteristics of the invention and all its advantages will be more clearly understood by means of the following figures and the detailed description written with references to these figures, therefore the evaluation should be made by taking these figures and detailed descriptions into consideration.

Brief Description of Figures In order to best understand the structure of the invention and its advantages with additional elements, it should be evaluated in combination with the figures described below.

Figure-1 is a schematic overview of the pipe machine,

Figure-2 is a schematic overview of the mold release unit,

Figure-3 is a schematic overview of the motor housing and mold driving system from the side,

Figure-4a is a schematic overview of the mold driving system from the front,

Figure-4b is a schematic overview of the mold driving system from the rear,

Figure-5 is a schematic overview of the cross section of the mold driving system,

Figure-6 is a schematic overview of the cross section of the front part of the mold driving system,

Figure-7 is a schematic overview of the front part of the mold driving system,

Figure-8 is a schematic overview of the rear part of the mold driving system,

Figure-9 is a schematic overview of the mold driving system,

Figure-10 is a schematic overview of the rear part of the mold feeding unit of the mold driving system,

Figure-11 ; is a schematic overview of the mold release unit pipe clamp structure,

Figure-12 is a schematic general view of the mold transport trolley from the side, Figure-13 is a schematic overview of the mold transport trolley.

Figure-14; is a schematic overview of the mold extrusion structure of the mold release unit.

Reference Numbers

100. Pipe machine

200. Motor housing

201. Mold axis pipe (long)

202. Main shaft

203. Mold axis pipe (short)

300. Mold driving system rear part

301. Mold driving system rear part pipe axis wheel adjusting lever

302. Mold driving system rear part pipe axis wheel

303. Mold driving system rear part main structure flange 400. Mold driving system front part

401. Eccentric plate mounting and support flange

402. Horizontal arm eccentric bearing

403. Horizontal arm steel springs

404. Locknut

405. Contra locknut

406. Spacer ring

407. Horizontal arm bushing cover

408. Bronze bearing

409. Eccentric wedge

410. Fixing locknut

411. Horizontal arm shaft

412. Horizontal arm shaft limiter

413. Vertical arm eccentric bearing

414. Vertical arm shaft

415. Vertical arm return spring

416. Mold thrust pad movable joint

417. Vertical arm limiter

418. Mold thrust pad

419. Vertical arm return spring support part

420. Horizontal arm shaft limiter fitting

421. Vertical arm steel springs

422. Horizontal arm bushing

423. Eccentric plate

424. Eccentric plate motion bearing support arms

425. Eccentric plate motion hydraulic cylinder

426. Mold driving system carrier/body flange

500. Mold ejection unit

501. Mold ejection unit body

502. GRP pipe

503. Pipe holding socket

504. Pipe rolling beams and bearing

505. Pipe rolling beams lifting cyclinder 506. Mold ejection unit body (short)

507. Longeron

600. Pipe production mold

700. Mold transport trolley

701. Mold lifting platform

702. Strength rib

703. Mold transport trolley platform rollers (wheel)

704. Mold transport trolley platform body

705. Mold

706. Mold transport trolley main body

707. Mold trolley wheels

708. Platform lifting cylinders mounting structure

709. Platform lifting cylinders

800. Mold extrusion structure

801. Mold extrusion structure motor reducer

802. Rope drum

803. Guide roller

804. Rope drum bearings

805. Rope drum bearings chassis

806. Mold extrusion structure chassis

900. Mold driving system rear feeding structure

901. Mold driving system rear feeding structure platform body

902. Mold driving system rear feeding structure platform wheels (rollers)

903. Mold driving system rear feeding structure steel bearing columns 1000. Hydraulic lifting tables and wheel assemblies

Detailed Description of the Invention

In this detailed description, the pipe machine (100) developed for the production of GRP (Fiber Glass Reinforced Plastic) pipes (502) in the size range DN80-DN250 (maximum length of 6 meters) subject to the invention is described only as an example for a better understanding of the subject matter and without any limiting effect.

The said pipe machine (100) basically comprises; a motor housing (200) made of steel material, comprising the assembly of the drive system which rotates the 0400 mm main shaft (202) of the mold driving system; a rear part (300) of the mold driving system, shown in Figure-4a, which allows the pipe molds (705) on which raw material is to be applied to be pivoted into the main shaft (202) and which is connected to the rear part of the shaft of the mold driving system to be of a suitable design for both driving and rotation of the mold (705); the front part (400) of the mold driving system shown in figure-4b, which is consistent with the size of the GRP pipe (502) to be manufactured and which allows the molds (705) driven into the main shaft (202) to rotate and to drive the mold (705) up to the value in the design in each round and where the force and drive required for the driving of the mold (705) are formed; positioned between the mold ejection unit (500) and the mold extrusion structure (800) at the mold ejection station, taking the mold (705) removed from the GRP pipe (502) on itself, being pulled by manpower or any suitable vehicle thanks to the mold trolley wheels (707), approaching the rear mold feeding unit mounted behind the main shaft (202) one after the other, and using the pneumatic compressed air cylinders on it, raising the mold (705) it carries and aligning it to the rear mold feeding system, a wheeled, mobile, specially designed, steel, mold transport trolley (700) with a platform that can be raised and lowered with a compressed air cylinder equipped with a polymer-derived roller mechanism necessary to drive the mold (705) forward while rotating, after the mold (705) is driven into the mold driving system rear feeding structure (900), lowering the compressed air cylinders and positioning to take the next mold (705) on its place in the mold ejection station again; mold driving system rear feeding structure (900), aligned to be on the same axis with the shaft axis, mounted on two legs, having a fixed platform equipped with a polymer-derived roller mechanism necessary to drive a total of 18 molds (705) on the right and left sides and 9 molds (705) at the bottom while rotating, fixed to the ground with dowels after alignment; hydraulic lifting stands and wheel assemblies (1000) for supporting the mold (705) advanced by the mold advancing system, consisting of already existing hydraulic lifting stands and wheel assemblies (1000), which, if installed on an E1 type winder machine, are located on the E1 winder machine, if installed on an NO winder machine, are located on the NO winder machine.

In the pipe machine (100) shown in Figure-2, there is also a mold ejection unit (500) in which the GRP pipe (502) produced on the mold (705) is fixed in the pipe holding sockets (503) and the mold (705) is pulled out of the GRP pipe (502); steel circular pipe production mold (600) consisting of a turned, strong, steel drawn pipe with an outer diameter suitable for the inner diameter size specified in the prescription of the GRP pipe (502) to be produced, with a steel circular pipe production mold (600) with an eyebolt end left at both ends and inside for extrusion; a rope wound on a rope drum (802) rotated by a motor reducer at a suitable power and speed, the rope and its eyebolt at the end, the mold extrusion structure (800), which is integrated with the GRP pipe (502) which is connected to the ground with a dowel and separates it from the produced pipe, after the eyebolt in the mold (705) waiting in the mold ejection unit (500) and fixed to the pipe holding socket (503) is replaced, the motor reducer is operated with a contactor starting system and the mold (705) is pulled out of the GRP pipe (502) and pulled to the mold transport trolley (700). The motor housing (200) shown in Figure-3 is already available for the E1 type winder and NO winder machines and can be built in a lower form for the mini-GRP pipe machine (100).

The motor housing (200) shown in Figure-5 includes; the mold axis pipe (long) (201) made of steel extruded material, processed in the size of the inside-outside diameter, which is placed inside the main shaft (202) and serves as the axis of the mold pipe passing through it; the steel drawn mold axis pipe (short) (203), processed in the size of the inside-outside diameter, which is placed inside the main shaft (202) and serves as the axis of the mold pipe passing through it; 0400 mm main shaft (202) of special design, made of steel extruded pipe, to which the entire mold driving system is connected/located and at the same time the motor housing (200) transmits the rotational motion received from the motor-reducer and drive system to the mold driving system and ensures the operation of the system. Said mold axis pipe (long) (201) is replaced with the one of the appropriate sizes when the mold (705) to be driven in accordance with the size of the pipe to be produced is changed. The said steel extrusion mold axis pipe (short) (203) is replaced with the one of the appropriate sizes when the mold (705) to be driven is changed in accordance with the size of the GRP pipe (502) to be produced. The aforementioned mold driving system rear part (300) is a mold driving system rear part pipe axis wheel adjusting lever (301), which can be adjusted to the desired size of the mold (705) by means of screws and nuts for the axis of the mold (705) driven into the main shaft (202), which has a polyamide-coated mold driving system rear part pipe axis wheel (302) processed in a form suitable for the curve of the outer diameter of the mold (705) size, and which has four existing mechanism parts around the periphery; mounted on the mold driving system rear part pipe axis wheel adjusting lever (301), four wheels made of polyamide-coated steel material, which are machined in a form in accordance with the curve of the outer diameter of the mold (705) size, which is driven in accordance with the size of the GRP pipe (502) to be manufactured, and of course, when the mold (705) changes, the ones suitable for that mold (705) are installed, mold driving system rear part pipe axis wheel (302); a circular, grooved, steel material mold driving system rear part main structure flange (303), which is itself connected to the main shaft (202) and to which other parts of the mold driving system rear part (300) are connected.

Mold driving system front part (400) shown in Figure-6; includes a steel, circular shaped, strong eccentric plate mounting and support flange (401), made of steel, to which the eccentric plate motion hydraulic cylinders (425) are connected and supported, which supports the bearings required for the reciprocating movement of the eccentric plate (423), which is connected to the motor housing (200), which meets the forces arising in the eccentric plate (423) pressed by the horizontal arm eccentric bearings (402) on which the mold (705) driving movement occurs, which enables the eccentric plate (423) to be activated and deactivated. There is also a horizontal arm eccentric bearing (402) which presses on the surface of the eccentric plate (423) having a difference in elevation along the circle, ensuring that the force required by the driving feature of the mold (705) is present throughout the rotation. Disc type horizontal arm steel springs (403) are positioned on the horizontal arms to which the aforementioned horizontal arm eccentric bearing (402) is connected and where the force required for the required system is generated by compressing the eccentric plate (423) with its forward movement at the beginning of production. A locking type of locknut (404) to space and secure the horizontal arm steel springs (403) on the horizontal arm shaft (411); a locking type contra locknut (405) is installed to space and secure the horizontal arm steel springs (403) on the horizontal arm shaft (411); a locking type fixing locknut (410) is installed to tighten and secure the eccentric wedge (409) after it is positioned on the horizontal arm is installed. A spacer ring (406) is provided to allow initial loading of the horizontal arm steel springs (403). In the mold driving system front part (400); horizontal arm bushing cover (407), which acts as the cover of the body forming the main structure of the horizontal arm; bronze bearing (408) made of bronze-based material that axes the movement of the horizontal arm movement shaft and provides the bearing of the movement; eccentric wedge (409) having a circular and specially designed cross- sectional form, which gives movement to the vertical arm in order to transform the inward-backward movement of the horizontal arm into the upward-downward direction in the vertical arm; circular horizontal arm shaft (411) having threaded and/or flat surfaces on which the elements in the horizontal arm are arranged. A horizontal arm shaft limiter (412) made of steel material is positioned to drive the reciprocating movement of the horizontal arm shaft (411) and to prevent the shaft end from rotating. The vertical arm eccentric bearing (413), which operates on the section profile surface of the eccentric wedge (409) in the horizontal arm, is the bearing of the mechanism that moves in accordance with the profile of the eccentric wedge (409) and makes the vertical arm move up and down. The vertical arm shaft (414), on which the elements in the vertical arm are arranged, has a circular structure with threaded and/or flat surfaces. The vertical arm return spring (415), after pressing the vertical arm on the surface of the mold (705) at the beginning of the production by the forward movement of the eccentric plate (423) of the horizontal arm and its eccentric wedge (409), rotating together in a circle on the inclined surface of the cam surface and both rotating and moving the mold (705) forward thanks to the inclined surface of the eccentric plate (423), pushes the vertical arm back after the completion of the circle round, with the horizontal arm falling into the refresh gap of the eccentric plate (423) for the new round. The mold thrust pad (418), which presses the mold (705) of the vertical arm and unites the mold (705) and the mold driving system, is connected to the mold thrust pad movable joint (416) made of steel material, which is designed as movable to eliminate misalignments in the system. The vertical arm limiter (417), thanks to its special design, ensures the connection of the vertical arm return spring support part (419) to the system and additionally prevents the vertical arm from rotating on its own axis and preventing the axis of the mold thrust pad (418) from being lost. With the movement of the vertical arm shaft (414) in the +x axis direction, it presses on the surface of the mold (705) by using the vertical force generated by the vertical arm steel springs (421) (holding the mold (705)) and again with the movement of the vertical arm shaft (414) in the -x direction and the stretched vertical arm steel springs (421) pushing the vertical arm shaft (414) upwards, it removes the pressure on the mold (705) (releasing the mold (705)), The mold thrust pad (418), whose surfaces pressing the mold (705) are rubber coated, which can be easily changed by pin connection technique in accordance with the surface form of the new mold (705) when the size of the GRP pipe (502) to be produced and the mold (705) to be advanced in connection with it is changed, is made of steel - rubber material. The aforementioned vertical arm return spring support part (419) allows the vertical arm return springs (415), which provide the reverse movement of the vertical arm group, to withstand force. A specially designed horizontal arm shaft limiter fitting (420) made of steel material is positioned to connect the horizontal arm shaft limiter

(412) to the system. The mentioned vertical arm steel springs (421) are disc type springs that produce the force that enables the vertical arm to hold and release the mold (705) by compressing/relaxing as a result of the linear motion that turns in the vertical direction through the eccentric wedge (409) and the vertical arm eccentric bearing

(413). Horizontal arm bushing (422), which is the horizontal arm body structure, is used for the bearing of the horizontal arm shaft (411). Said eccentric plate (423) starts the driving movement of the mold (705) (start of production) when it moves in the +x direction by means of the eccentric plate motion hydraulic cylinders (425), and stops the driving movement of the mold (705) when it moves in the -x direction by means of the eccentric plate motion hydraulic cylinders (425), the front surface of the horizontal arm eccentric bearing (402) has a slope, i.e. elevation difference, known in the specs along the circle, which allows the mold (705) to move forward in each shaft rotation round by the amount of this elevation difference, and a part of this surface is a strong steel structure in which there is a gap for the reinstallation of the mold advancing arms (horizontal and vertical) that reach this area. There are eccentric plate motion bearing support arms (424), which are the support structure that supports I bears the reciprocating movement of the eccentric plate (423), which is formed by the axialization of the support shaft, which is located as 3 supports around the periphery, one end of which is connected to the eccentric plate mounting and support flange (401) and the other end connected to the eccentric plate (423), with 3 bearings connected to the eccentric plate mounting and support flange (401). The eccentric plate motion hydraulic cylinders (425), which are connected to the eccentric plate mounting and support flange (401) at one end and to the eccentric plate (423) at the other end, are placed as 3 supports around the periphery and provide reciprocating movement of the eccentric plate (423). The mold driving system carrier I body flange (426), which can be easily connected to the main shaft (202) with bolts, rotates with the main shaft (202), carries the horizontal and vertical arms of the mold driving system, in a sense, it is a circular, specially designed strong steel structure that constitutes the body of the system. The mold driving system rear feeding structure (900) shown in Figure-10; includes the mold driving system rear feeding structure platform body (901), which is a bent carbon steel sheet body structure on which the mold driving system rear feeding structure platform wheels (rollers) (902) are mounted; mold driving system rear feeding structure platform wheels (rollers) (902) necessary to drive the mold (705) forward while rotating, made of polymer derivative material, with bearing structure suitable for rotation, equipped on the sides of 18 mold driving system rear feeding structure platform bodies (901) and under 9 mold driving system rear feeding structure platform bodies (901); mold driving system rear feeding structure steel bearing columns (903) made of walled carbon steel box profile.

The mold ejection unit (500) shown in Figure-11; includes the mold ejection unit body (501), which is designed to be strong, on which the mold ejection unit (500) is mounted on the ground with dowels and all other outbuildings of the mold ejection unit (500) are connected; GRP pipe (502) produced by using the raw material application system of the E1 winder or NO winder machine on which the pipe machine (100) system is installed in accordance with its recipe, which can be fixed in pipe holding sockets (503), waiting for the mold (705) to be pulled out of it; steel structure pipe holding sockets (503), of which there are 5 pieces in a mold ejection unit (500), of which the lower part and the upper cap are interchangeable by means of bolts according to the size of the produced GRP pipe (502), and which allow the upper cap of the holder to be tightly fixed by connecting with bolts when the upper caps are open, when the mold (705) and the integrated structure with the produced GRP pipe (502) on it are left in the lower part socket, 5 pieces in a mold ejection unit (500); pipe rolling beams and bearing (504) made of steel material, which enable the GRP pipe (502), which is waiting in the sockets after the mold (705) is pulled out of it, to be rolled to the edge by means of a pneumatic compressed air cylinder on lifting beams, two sets in a mold ejection unit

(500); pneumatically pressurized pipe rolling beams lifting cylinders (505), which raise and lower the steel structure, which makes it possible to roll the GRP pipe (502), which is waiting in the sockets after the mold (705) is pulled out of it, onto the beams, making it possible to roll it to the edge, which is a quantity of two in a mold ejection unit (500); mold ejection unit body (short) (506), which can be added to the mold ejection unit body

(501) by means of bolts for ease of transportation, and which, after being added, integrates as a single structure as the main body; the beam structure longeron (507), in which the pipe holding sockets (503) are fixed from the lower part by means of bolts, on the other hand, providing axial strength to the main body.

The mold transport trolley (700) shown in Figure-12 and Figure-13; a mold lifting platform (701) made of steel, which can be raised and lowered by a compressed air cylinder equipped with a polymer-derived roller mechanism for driving the mold (705) forward while rotating; plate strength ribs (702) made of carbon steel sheet, positioned 4 on a mold lifting platform (701) to add strength to the mold lifting platform (701); mold transport trolley platform rollers (wheels) (703) necessary to drive the mold (705) forward while rotating, made of polymer derivative material, having a bearing structure suitable for rotation, equipped on the sides of 28 mold lifting platforms (701) and under 14 mold lifting platforms (701); mold transport trolley platform body (704) with a body structure made of bent carbon steel sheet metal on which the mold transport trolley platform rollers (wheels) (703) are mounted; mold transport trolley main body (706) formed with walled box profiles; mold trolley wheels (707) made of load-resistant, plastic material with bearings, a total of 4 in roulette style; platform lifting cylinders mounting structure (708) made of steel material, to which pneumatic compressed air cylinders raising and lowering the mold lifting platform (701) are connected and bearing; platform lifting cylinders (709) consisting of 2 pneumatic compressed air cylinders in a trolley, which raise and lower the mold lifting platform (701), connected by hoses using quick connect fittings to the fully mechanical lever directional valve where it is positioned.

The mold extrusion structure (800) shown in Figure-14; includes the mold extrusion structure motor reducer (801) in a motor-reducer structure selected at the appropriate power and output speed, which drives the special grooved rope drum (802) where the extrusion rope is wound; the steel guide roller (803) with bearings that ensure comfortable operation of the rope wound on the rope drum (802) during the pulling process; rope drum bearings (804) with HCB bearings for axing and bearing of the rope drum (802); HCB rope drum bearings chassis (805) made of carbon steel; mold extrusion structure chassis (806) made of walled box profile, on which all the equipment of the mold extrusion structure (800) is mounted.

In order to use the pipe machine (100) subject to the invention, first of all, the main shaft (202) of the existing machine that produces GRP pipes (502) with continuous fiber winding method is removed from the motor housing (200). Instead of the removed main shaft (202), the main shaft (202) of the pipe machine (100) is installed. Then, on the inside of this main shaft (202), the parts of the mold axis pipe (long) (201) and mold axis pipe (short) (203) of the size to be produced for the axis of the pipe production mold (600) that will pass through it are applied and installed. After the main shaft (202) is installed, the mold driving system rear part (300), which is ready on the edge, is mounted to the rear part of the main shaft (202) with bolts as shown in Figure-3 and Figure-5. Then, as shown in Figure-5 and Figure-6, the eccentric plate mounting and support flange (401), with the eccentric plate (423) mounted on it, eccentric plate motion bearing support arms (424), eccentric plate motion hydraulic cylinders (425) and in its integrated form, is fixed and mounted to the mounting lugs already in the engine housing (200) by means of bolts. Afterwards, mold driving system front part (400) is mounted to the front part of the main shaft (202) with bolts by means of the mold driving system carrier/body flange (426) as shown in Figure-6. After the mounting in this area is completed, mold driving system rear feeding structure (900) is positioned on the rear side of the motor housing (200) as shown in Figure-1. The pipe production mold (600) to be used in the production is used as an axing apparatus and the mold driving system rear feeding structure (900) is axed and fixed to the ground. At the same time, the axis adjustments are made with reference to the pipe production mold (600) of the size to be produced by using the mold driving system rear part pipe axis wheel adjusting lever (301) connected to the body of the main structure flange (303) of the mold driving system rear part (300) and the mold driving system rear part pipe axis wheel (302) screw movement and locknut (404) with the clamping logic. Then, at a distance suitable for the machine where the production is carried out, i.e. in a position where it is easiest to take the GRP pipe (502) structure, which is integrated with the pipe production mold (600) and the mold (705) on which it is still manufactured, from the existing hydraulic lifting tables and wheel assemblies (1000) by means of an overhead crane and drop it on the mold ejection unit (500); mold ejection unit (500), mold transport trolley (700) and mold extrusion structure (800) are positioned as shown in Figure-2. The mold ejection unit (500) and mold extrusion unit (800) are fixed to the ground with mechanical dowels. The mold transport trolley (700) is mobile and includes mold trolley wheels (707) and is easily positioned between the mold ejection unit (500) and the mold extrusion structure (800) between the mold ejection unit (500) and the mold extrusion structure (800) using the mold trolley wheels (707) to take the pipe production mold (600) removed during the mold ejection operation. At this stage, the installation of the pipe machine (100) is completed.

Above the mold driving system rear feeding structure (900), there is a mold (705) loaded using the mold transport trolley (700). This waiting mold (705); polymer-derived mold driving system rear feeding structure platform wheels (902) with bearings on the bottom and sides, mounted on the steel mold driving system rear feeding structure platform body (901), built on the steel bearing columns (903) of the mold driving system rear feed structure (900), the mold driving system is connected to the rear part main structure flange (303) and the mold driving system is on axis with respect to the pipe production mold (600) using the rear part pipe axis wheel adjusting lever (301) of the polymer derivative, bearing wheels (302) having a compression surface curve corresponding to the outer diameter of the mold (705) are mounted, and then pass through the mold axis pipe (short) (203) and mold axis pipe (long) (201) inside the main shaft (202) to reach the mold driving system front part (400). Here, the first mold (705) is passed between the mold thrust pads (418) and the first mold (705) is completed. In the mold driving system front part (400) shown in Figure-9, the eccentric plate motion hydraulic cylinders (425) working with the existing hydraulic system of the production machine connected to the eccentric plate mounting and support flange (401) are given forward movement, with the help (bearing) of the eccentric plate motion bearing support arms (424), the eccentric plate (423) moves forward and is stopped at the end of the forward movement course of the hydraulic pistons while it is pressing the horizontal arm eccentric bearings (402). The horizontal arm eccentric bearings (402) transfer the pressure (pushing movement) applied by the eccentric plate (423) to the horizontal arm shaft (411) integrated with the horizontal arm bushing cover (407) and horizontal arm bronze bearing (408) in the horizontal arm bushing (422) and the locknuts (404) and contra locknuts (405) fixing them on the shaft. As a result of this pushing, the horizontal arm shaft (411) moves forward as permitted by the horizontal arm shaft limiter (412) and the horizontal arm shaft limiter fitting (420) together with the eccentric wedge (409), which is also connected to itself and prevented from losing its position both by fixing locknut (410), and the horizontal arm bushing (422) it compresses the horizontal arm steel springs (403) placed between the arm shaft (411) and whose load amount is adjusted by the spacer ring (406) and position locking I stabilizing locknuts (404) and contra locknut (405), and also pushes the vertical arm eccentric bearing (413) in relation with the horizontal arm eccentric wedge (409) in the downward direction. At the same time, the vertical arm moves as a whole in the forward direction and loads the vertical arm return springs (415) supported by the vertical arm return spring support part (419) and the vertical arm eccentric bearing (413) moves the vertical arm shaft (414) to which it is connected downwards. This movement also loads the vertical arm steel springs (421). The downward moving vertical arm shaft (414) presses the mold thrust pads (418) to the mold surface by using the feature of the mold thrust pad movable joint (416) that can also manage small misalignments. In this way, the mold is gripped by means of 8 sets of horizontal and vertical arms interacting with each other with the aforementioned logic. The surface of the eccentric plate (423) on which the horizontal arm eccentric bearings (402) travel has a slope, i.e. a depth difference along the circle. Therefore, the horizontal and vertical arms moved by the horizontal arm eccentric bearings (402) pressing on this inclined surface of the eccentric plate (423), which is moved forward, are finally gripped to the pipe production mold (600) at the places connected to different x coordinates. The pipe machine (100) is started by the main motor using the already existing automation system in the motor housing (200) shown in figure-7. Again, with the already existing drive system, the main shaft (202) system consisting of the main shaft (202), the mold axis pipe (long) (201) and the mold axis pipe (short) (203) and the mold driving system rear part (300) and the mold driving system front part (400) shown in Figure-8, which are connected to it, rotate together in an integrated form. During this rotation, the horizontal arm eccentric bearings (402) move forward at the pipe production mold (600), which is gripped by the horizontal and vertical arm under a certain force by the horizontal arm steel springs (403) and vertical arm steel springs (421) on both arms, while moving in a circle on the inclined surface of the non-rotating eccentric plate (423). This carrying (driving) movement ends when the relevant horizontal arm reaches the empty area on the surface of the eccentric plate (423). This is because the horizontal arm steel springs (403) of the horizontal arm are discharged and push the horizontal arm back in the direction of the eccentric plate (423). At the same time, the stretched disc springs (421) in the vertical arm, which are released from the pressure of the horizontal arm eccentric wedge (409), push the vertical arm up and this arm stops holding the pipe production mold (600). At the same time, the vertical arm, which has already moved completely in the forward direction with the push of the horizontal arm and loaded the vertical arm return springs (415), moves back in the direction of the eccentric plate (423) with the release of the vertical return springs after being released from the pressure of the horizontal arm eccentric wedge (409) and prepares itself for a new carrying (driving) cycle. In total, 8 sets of arms (horizontal + vertical) perform this movement sequentially in each rotation and drive the already rotating pipe production mold (600). As a result, for each rotation of the main shaft (202), the mold advancing system connected to the shaft will have rotated both itself and the mold and will have driven the pipe production mold (600) by the total depth difference (in mm) of the eccentric plate (amount of inclination). Now, with the rotating and driving pipe production mold (600), the raw material is applied with the existing raw material application equipment and automation system of the existing machine and the GRP pipe (502) in accordance with the recipe is produced on the mold. The mold structure integrated with the produced GRP pipe (502) is supported by the existing hydraulic support stand and wheel assemblies (1000) of the machine where the pipe machine (100) system is used. When the first pipe production mold (600) advances and leaves the mold driving system rear feeding structure (900), another pipe production mold (600) is placed on the mold driving system rear feeding structure (900), either by mold transport trolley (700) or by overhead crane and is pushed and leaned against the mold driving system rear feeding structure (900) behind the leading pipe production mold (600). In this way, a walking mold system is formed. For each size of GRP pipe (502) to be produced in the pipe machine (100) system, 3 pieces of the pipe production mold (600) and 3 pieces of the sleeve mold are required. After the GRP pipe (502) is produced on the first pipe production mold (600), the production of GRP pipe (502) is started on the second pipe production mold (600). The first pipe production mold (600) and the GRP pipe (502) integrated on it together with the hydraulic lifting stands and wheel assemblies (1000) are taken by overhead crane and mold ejection unit body (501) and the mold ejection unit (500) bolted to it of which the main roof is formed by the short body is dropped into the pipe holding sockets (503) designed in special dimensions for each size of GRP pipe (502) to be produced with the top cap open on the mold ejection unit (500) on which the longeron (507) is mounted, which both makes this main roof even stronger and makes the pipe holding slots (503) easily replaceable by bolting each time a different type of pipe is produced. The upper caps of the pipe holding sockets (503) are closed and tightened by means of bolts. The rope, which is rotated by a mold extrusion structure chassis (806) made of a carbon steel box profile fixed to the ground with a mechanical dowel and racialized by the rope drum bearings chassis (805) for rope drum bearings (804) equipped on this mold extrusion structure chassis (806), which is wound on a rope drum (802) with grooves suitable for rope winding, is inserted into the socket in the pipe production mold (600) waiting on the mold ejection unit (500) by starting the motor low speed motor reducer and the eyebolt at the end of the rope unwound from the rope drum (802). The mold extrusion structure motor reducer (801) of the mold extrusion structure (800) is rotated in the opposite direction this time and the pipe production mold (600) attached to the end of the rope is pulled out of the produced GRP pipe (502). The pipe production mold (600), which is extruded out of the GRP pipe (502), moves in the mold lifting platform (701) with increased strength of steel sheet ribs (702) that can rise and fall with the help of the mold transport trolley main body (706) of the mold transport trolley (700) to which the rising and lowering mold lifting platform (701) is connected, and the mold transport trolley platform rollers (wheel) (703) on the platform mounted on the mold transport trolley platform body (704) and the pipe production mold (600) coming out of the pipe is the mold (705) loaded on the mold transport trolley (700). The rope is wound on the rope drum (802) until the end and the mold extrusion structure (800) is made ready for the next mold ejection process. The bolts of the upper caps of the pipe holding sockets (503) of the mold ejection unit (500) are completely removed and the upper caps are set aside. The pipe rolling beams and bearings (504), which provides bearing and axis the rise and fall of these beams, are raised by pneumatic pipe rolling beams lifting cylinders (505) working with compressed air, and the GRP pipe (502) from which the pipe production mold (600) is removed is made ready to be taken from the unit by the forklift. The mold transport trolley (700), which is moved by means of mold trolley wheels (707), is positioned behind the mold driving system rear feeding structure (900) at the rear of the mold driving system with the pipe production mold (600) on it. The connection to the compressed air system of the GRP production machine, which produces with the continuous fiber winding method, to which the pipe machine (100) system is attached, is connected to the connection platform lifting cylinders (709) with quick connection apparatus, and the mold lifting platform (701), which can be raised and lowered by means of the platform lifting cylinders (709) inside the platform lifting cylinders mounting structure (708) with manual arm directional valves, is raised and when the time comes, i.e. when the mold driving system rear feeding structure (900) is empty, the pipe production mold (600) is driven into the mold driving system rear feeding structure(900) with the help of mold transport trolley platform rollers (wheel) (703). Meanwhile, the 2nd pipe production mold (600) is in production but inside the main shaft (202). The platform lifting cylinders (709) are lowered. Compressed air connections (quick-fit type connections) are removed. The mold transport trolley (700) is pulled, and the pipe production mold (600) is taken to the ejection position. The cycle continues in this way and mass production is realized.