KR101078713B1 - Fiber supplying apparatus for axial reinforcement of continuous pipe - Google Patents

Abstract

PURPOSE: A device for supplying reinforcing fibers for reinforcing an axial side of a continuous pipe is provided to improve reinforcement capability of a pipe by successively stacking longitudinal reinforcing layers of a pipe by winding. CONSTITUTION: A device for supplying reinforcing fibers for reinforcing an axial side of a continuous pipe comprises a feeding member(110) and a mobile member(120). The feeding member releases downward reinforcing fibers, supplied from a bobbin(40), by using members engaged with each other. The feeding member supplies the reinforcing fiber to the surface of a consecutively manufactured pipe(30). The mobile member shuttles the feeding member in a longitudinal direction so that the reinforcing fiber is provided to the longitudinal direction of the pipe. The reinforcing fiber adheres closely between first and second rotating transfer belts.

Description

Fiber supplying apparatus for axial reinforcement of continuous pipe

The present invention relates to a reinforcing fiber supply device for axial reinforcement of the continuous pipe, and more particularly to a reinforcing fiber supply device for the axial reinforcement of the continuous pipe for reinforcing the longitudinal direction of the composite pipe.

Composite pipe (GRP Pipe) produced by the continuous filament winding method generally has to be resistant to internal pressure and external pressure, and is manufactured mainly by the filament winding method in which strength is concentrated in the circumferential direction.

Most pipes used for water supply and sewage pipes are buried underground, and only the external pressure and pressure resistance need to be satisfied, and the strength in the longitudinal direction does not act as a main variable.

However, since the composite pipe installed on the ground is installed in such a manner as to install and fasten the support at regular intervals, self-weight may be generated between the supports and the deflection may be caused by the weight of the fluid in the pipe. Breakage can often occur.

Conventionally, in order to solve such a problem, a method of cutting the reinforcing fiber to a predetermined length and arranging it in the longitudinal direction of the pipe and using a previously woven in a predetermined narrow width is used. This method increases the strength in the longitudinal direction of the pipe, but in the manufacturing process, the fiber does not adhere to the pipe, or the outer part of the pipe may cause loss of material or increase the production price due to the use of woven products. There is a drawback to this. In addition, when the reinforcing fibers are not connected in a timely manner by the operator in the process of connecting the reinforcing fibers in the longitudinal direction, there may be a problem that the product may be defective and cause the production delay of the product.

The present invention is arranged above the pipe which is continuously manufactured by winding the fiber on the rotating mandrel, and continuously providing the reinforcing fiber with respect to the longitudinal direction of the pipe while reciprocating in the longitudinal direction thereof. It is an object of the present invention to provide a reinforcing fiber supply apparatus for axial reinforcement of a continuous pipe that can improve the reinforcing capacity for the.

The present invention relates to a reinforcing fiber supply apparatus for axial reinforcement of continuous pipes, in which fibers are wound on a rotating mandrel and arranged above the pipe being continuously manufactured to reinforce the longitudinal direction of the pipe. Using a plurality of rotating members, the reinforcing fiber provided from the bobbin is released downward to supply the reinforcing fiber to the surface of the pipe being continuously manufactured, and the reinforcing fiber to be supplied in the longitudinal direction of the pipe. And a moving means for reciprocating the supply means with respect to the longitudinal direction, wherein the reinforcing fiber provides a reinforcing fiber supply device for axial reinforcement of continuous pipes impregnated in the resin.

Here, the supply means, the first roller is rotated by a first drive source, and facing the first roller, when the first roller is rotated in accordance with the operation of the first drive source is rubbed with the first roller It includes a second roller of a non-powered rotation, wherein the reinforcing fiber can be in close contact between the rotating first roller and the second roller.

The supply means includes a third roller rotated by a second driving source, a fourth roller disposed below the third roller, and a first conveyance belt wound integrally with the third roller and the fourth roller. And a first roller having a first roller, and a fifth roller and a sixth roller facing the third roller and the fourth roller, respectively, and integrally wound around the fifth roller and the sixth roller, according to the operation of the second driving source. And a second conveying part having a second conveying belt which is rotated by friction with the first conveying belt when the first conveying belt is rotated, wherein the reinforcing fiber is the rotating first conveying belt and the second conveying belt. It can come in close contact with it and descend.

Here, the reinforcing fiber supply apparatus for axial reinforcement of the continuous pipe, the guide plate is disposed between the bobbin and the supply means, the guide plate is formed with a plurality of guide holes for passing through the reinforcing fibers provided from the plurality of bobbins, respectively. It may include.

The reinforcing fiber supply device for axial reinforcement of the continuous pipe may include the plurality of guide holes formed in a direction crossing the longitudinal direction of the pipe, and the interlocking directions of the members correspond to the longitudinal direction of the pipe. Can be.

In addition, the reinforcing fiber supply apparatus for the axial reinforcement of the continuous pipe may further include an air injector for sucking the reinforcing fiber passed through the supply means and distributes it on the surface of the pipe.

The reinforcing fiber supply device for axial reinforcement of the continuous pipe may further include a resin supply unit supplying a resin onto the reinforcing fiber so that the reinforcing fiber is impregnated into the resin.

The moving means may include a cam rotated by a third driving source, and a driving bar having one end and the other end rotatably coupled to one side circumference of the cam and the supply means, respectively, to the third driving source. When the cam is rotated, one end of the driving bar may move along the circumference of the cam while reciprocating the supply means in the longitudinal direction of the pipe.

According to the reinforcing fiber supply apparatus for axial reinforcement of a continuous pipe according to the present invention, the fiber is wound on a rotating mandrel and disposed above the pipe which is continuously manufactured to reinforce the reinforcing fiber in the longitudinal direction of the pipe. As the reciprocating movement forward and backward in the longitudinal direction while providing continuously, it is possible to improve the reinforcement ability to the longitudinal direction of the pipe and there is an advantage that can be produced at a low production price.

1 is a schematic front view in which the reinforcing fiber supply apparatus for axial reinforcement of a continuous pipe according to an embodiment of the present invention is disposed above the pipe.
Figure 2 is a schematic plan view of the reinforcing fiber supply device shown in FIG.
Figure 3 is a schematic front view of the reinforcing fiber supply apparatus for the axial reinforcement of the continuous pipe according to another embodiment of the present invention.
Figure 4 is a schematic front view showing a reinforcing fiber supply apparatus for axial reinforcement of the continuous pipe according to another embodiment of the present invention.

1 is a schematic front view in which the reinforcing fiber supply apparatus for axial reinforcement of a continuous pipe according to an embodiment of the present invention is disposed above the pipe.

Referring to FIG. 1, the reinforcing fiber supply device 100 for axial reinforcement of the continuous pipe is disposed above the pipe 30 which is continuously manufactured by winding the fiber on the rotating mandrel 10. To reinforce the longitudinal direction of the pipe 30. The reinforcing fiber supply device 100 serves to provide the reinforcing fibers 50 wound around the bobbin 40 in the longitudinal direction of the pipe 30 on the surface of the pipe 30 being continuously manufactured.

The reinforcing fiber 50 may be the same as the material of forming the pipe 30. For example, it may include at least one of glass fiber, carbon fiber or aramid fiber. In addition, the reinforcing fiber 50 is impregnated in the resin and cured like the existing material of the pipe 30. That is, the reinforcing fibers 50 are disposed in the lengthwise direction on the fiber material wound in the circumferential direction on the mandrel 10, and all are cured in the state impregnated in the resin. The hardened pipe 30 is cut and produced to a desired length.

The continuous pipe manufacturing method is classified into steel band type and collect type according to the mold used. In the case of FIG. 1, the fibers are spirally wound on the steel band 20, and thus the pipe is continuously manufactured. Of course, the present invention is not necessarily limited thereto, and of course, the present invention can be applied to all types of continuous pipe manufacturing processes.

Figure 2 is a schematic plan view of the reinforcing fiber supply device shown in FIG. 1 and 2, the reinforcing fiber supply device 100 includes a guide plate 130, a supply unit 110, a moving unit 120, and an air injector 140.

The guide plate 130 is disposed between the bobbin 40 and the supply means 110. A plurality of guide holes 131 are formed in the guide plate 130 in a direction crossing the longitudinal direction of the pipe 30.

The guide plate 130 passes the reinforcing fibers 50 provided from the plurality of bobbins 40 through the plurality of guide holes 131 corresponding thereto. For example, one strand of reinforcing fiber 50 is provided from each bobbin 40, and they are individually passed through respective guide holes 131 corresponding thereto. The distance between the guide holes 131 and the number of the guide holes 131 are not necessarily limited by FIG. 2. In addition, the guide holes 131 may be arranged in a multi-matrix form, not in a line.

As the reinforcing fibers 50 provided from the bobbin 40 along the guide plate 130 are passed to match the alignment of the guide holes 131, the individual strands of the reinforcing fibers 50 are not agglomerated with each other. I can guide it. Accordingly, the reinforcing fibers 50 can be evenly lowered at the set interval when provided to the supply means (110).

The supply means 110 uses a plurality of members (ex, rollers, belts) to rotate in engagement with each other, by unwinding the reinforcing fibers 50 provided from the bobbin 40 downward, the pipe is continuously produced It is supplied on the surface of 30. Here, it can be seen that the directions in which the members are engaged with each other correspond to the longitudinal direction of the pipe 30. This allows several reinforcing fibers 50 to be provided at one time in the longitudinal direction of the pipe 30.

One embodiment of the supply means 110 includes a first roller 111, the second roller 112. The first roller 111 is rotatable by the first drive source 113, such as a motor. The first roller 111 and the first drive source 113 may be connected to each other by a belt or the like, but the connection structure is not necessarily limited thereto.

The second roller 112 is disposed to face the first roller 111. The second roller 112 corresponds to a non-powered roller which is rotated by friction with the first roller 111 when the first roller 111 is rotated according to the operation of the first driving source 113.

At this time, the reinforcing fiber 50 is in close contact with the rotating between the first roller 111 and the second roller 112 is lowered. That is, while the reinforcing fibers 50 are pulled downward by the first rollers 111 and the second rollers 112, the reinforcing fibers 50 wound on the bobbin 40 are released and lowered. That is, the reinforcing fiber 50 is pulled downward by the rotational force of the first roller 111 and the second roller 112 is lowered.

At this time, the reinforcing fiber 50 descending through the supply means 110 is provided on the pipe 30 that is continuously manufactured to reinforce the surface of the pipe (30). Here, when the reinforcing fiber 50 is provided on the pipe 30, the air injector 140 is used so that the reinforcing fiber 50 is blown out and not separated or lost.

The air injector 140 sucks the reinforcing fibers 50 passing through the supply means 110 and effectively disperses them on the surface of the pipe 30 that is continuously manufactured. According to this, the reinforcing fiber 50 can be directly and uniformly lowered on the surface of the pipe 30 by the air pressure of the air injector 140, thereby solving the problem of external detachment or loss of the reinforcing fiber 50. Can reduce the manufacturing cost.

The moving means 120 reciprocates the supply means 110 with respect to the longitudinal direction of the pipe 30 so that the reinforcing fibers 50 are supplied in the longitudinal direction of the pipe 30. Thereby, reinforcement with respect to the longitudinal direction of the pipe 30 is attained.

The moving means 120 may be implemented by reciprocating the supply means 110 on the rail. At this time, the rail is formed in a direction corresponding to the longitudinal direction of the pipe (30).

In addition, the moving unit 120 includes a cam 121 and a driving bar 122. The cam 121 is rotated by a third drive source 123 such as a motor. One end portion and the other end portion of the driving bar 122 are rotatably coupled to one side circumference of the cam 121 and the supply means 110, respectively.

1 and 2, the supply means 110 is provided with a body plate 150 corresponding to the body. At this time, the shaft of the first roller 111 and the second roller 112 is pivotally coupled on the body plate 150. The other end of the driving bar 122 is directly coupled to the body plate 150. In addition, one end of the guide plate 130 is fixed to the body plate 150, so that when the body plate 150 moves, the guide plate 130 and the supply means 110 are moved together at once.

Operation according to the moving means 120 is as follows. When the cam 121 is rotated by the third driving source 123, one end of the driving bar 122 moves along the circumference of the cam 121, while pulling and pushing the supply means 110 to move the pipe. It reciprocates in the longitudinal direction of (30).

In this case, the reciprocating range may be determined based on the shape of the cam 121. For example, the longer the left and right length (eg, diameter in the case of a circle) of the cam 121, the wider the range of the reciprocating movement. In the case of Figure 2 it should be understood that the diameter of the cam 121 is shown small for convenience of description. The cam 121 does not necessarily need to be circular, but may be implemented in various shapes such as an ellipse and a rectangle. Here, the cam 121 is to move the supply means 110 by pulling and pushing the drive bar 122 by rotation, the present invention encompasses all of the configuration of this technical category.

In addition, the reciprocating speed of the moving means 120 may be determined according to the operation of the third drive source 123. As the reciprocating speed is higher, a large amount of reinforcement work can be performed in a short time with respect to the longitudinal direction of the pipe 30. In addition, by adjusting the reciprocating speed of the moving means 120 in preparation for the winding speed of the material for forming the pipe 30, it is possible to adjust not only the longitudinal strength of the pipe 30 but also the overall reinforcement strength of the pipe 30. .

The reinforcing fiber 50 is impregnated in the resin and cured. To this end, the reinforcing fiber supply device 100 is provided with a resin supply unit (not shown) for supplying a resin on the reinforcing fiber 50 so that the reinforcing fiber 50 is impregnated into the resin.

For example, the resin supply unit may be provided on the bobbin 40 side to impregnate the resin on the reinforcing fiber 50 before passing through the supply means 110. As another example, the resin supply unit one side of the supply means 110 or the air injector 140 to directly supply the resin on the reinforcing fiber 50 passing through the supply means 110 or the air injector 140. It may be provided on one side of. As another example, the resin supply unit may be disposed on one side of the manufactured pipe 30 to directly supply the resin onto the reinforcing fibers 50 already sprayed in the longitudinal direction of the pipe 30. The reinforcing fibers impregnated in the resin are later cured together with the pipe forming material through a heating device (not shown).

Figure 3 is a schematic front view of the reinforcing fiber supply apparatus for the axial reinforcement of the continuous pipe according to another embodiment of the present invention. In this case, the supply means 210 includes a first transfer unit and a second transfer unit.

The first transfer part includes a third roller 211, a fourth roller 212, and a first transfer belt 213. The third roller 211 is rotated by the second driving source 217. The fourth roller 212 is spaced apart below the third roller 211. Here, the shafts of the third roller 211 and the fourth roller 212 are provided on the body plate 150. The first conveyance belt 213 is integrally wound around the third roller 211 and the fourth roller 212.

In addition, the second transfer part includes a fifth roller 214, a sixth roller 215, and a second transfer belt 216. The fifth roller 214 and the sixth roller 215 face the third roller and the fourth roller, respectively. Here, the shafts of the fifth roller 214 and the sixth roller 215 are pivotally coupled on the auxiliary plate 151 spaced below the body plate 150.

In addition, the second conveyance belt 216 is integrally wound around the fifth roller 214 and the sixth roller 215, and the first conveyance belt 213 according to the operation of the second driving source 217. When is rotated by friction with the first transfer belt 213 is rotated.

At this time, the reinforcing fiber 50 is in close contact with the rotating between the first conveying belt 213 and the second conveying belt 216 is lowered. In the case of the embodiment of Figure 3, unlike the roller of the embodiment of Figure 1, the reinforcing fiber 50 is a form that passes between the conveying belt, widening the contact area when the reinforcing fiber 50 is lowered and the contact length By increasing the can guide the lowering process of the reinforcing fiber 50 more effectively.

When the pipe 30 is being manufactured while the pipe forming material (fiber) is continuously wound on the rotating mandrel 10 on the reinforcing fiber supply device 100 for axial reinforcement of the continuous pipe as described above, The reinforcing fiber 50 is supplied onto the pipe 30 to be manufactured. In this case, the fiber in the winding direction and the reinforcing fiber 50 in the longitudinal direction may be cured by being entangled with each other in real time, thereby increasing the strength of the pipe 30 in multiple directions.

In addition, the reinforcing fiber supply apparatus 100 for axial reinforcement of the continuous pipe is wound on one layer of the pipe 30 according to the wound fibers, and then the reinforcing fibers 50 in the longitudinal direction thereon Can supply At this time, the winding fiber layer of the pipe and the longitudinal reinforcing layer are formed separately around the upper portion of the pipe, and then hardened integrally to form one pipe.

Figure 4 is a schematic front view showing a reinforcing fiber supply apparatus for axial reinforcement of the continuous pipe according to another embodiment of the present invention. This shows an example in which the reinforcing fiber supply device 100 is individually disposed for each layer 30a and 30b of the pipe, so that the reinforcing process may be sequentially performed for each layer. That is, the first layer 30a by winding, the longitudinal reinforcement layer for the first layer 30a, and the longitudinal reinforcement layer for the second layer 30b and the second layer 30b by winding are sequentially stacked and the pipe 30 Strengthen the reinforcement ability of).

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

10: mandrel 20: steel band
30: pipe 40: bobbin
50: reinforcing fiber 100: reinforcing fiber supply device
110,210: supply means 111: first roller
112: second roller 113: first driving source
120: vehicle 121: cam
122: drive bar 123: third drive source
130: guide plate 131: guide hole
140: injector 150: body plate
160: auxiliary plate 211: third roller
212: fourth roller 213: first conveyance belt
214: fifth roller 215: sixth roller
216: second transfer belt 217: second drive

Claims (8)

In the reinforcing fiber supply apparatus for axial reinforcement of a continuous pipe which is arranged above the pipe which is continuously manufactured by winding the fiber on a rotating mandrel,
Supplying means for unwinding the reinforcing fibers provided from the bobbin downward using a plurality of members rotating in engagement with each other and feeding them onto the surface of the pipe being continuously manufactured; And
And moving means for reciprocating the supply means with respect to the longitudinal direction so that the reinforcing fibers are supplied in the longitudinal direction of the pipe,
The reinforcing fibers are impregnated in the resin,
The supply means,
A first conveying part having a third roller rotated by a second driving source, a fourth roller spaced below the third roller, and a first conveying belt integrally wound around the third roller and the fourth roller; And
The first and second rollers are integrally wound on the fifth and sixth rollers and the fifth and sixth rollers facing the third and fourth rollers, and the first conveyance belt is rotated according to the operation of the second driving source. And a second transfer part having a second transfer belt rotated by friction with the first transfer belt,
The reinforcing fiber is a reinforcing fiber supply apparatus for the axial reinforcement of the continuous pipe descends in close contact between the rotating first conveying belt and the second conveying belt. In the reinforcing fiber supply apparatus for axial reinforcement of a continuous pipe which is arranged above the pipe which is continuously manufactured by winding the fiber on a rotating mandrel,
Supplying means for unwinding the reinforcing fibers provided from the bobbin downward using a plurality of members rotating in engagement with each other and feeding them onto the surface of the pipe being continuously manufactured;
Moving means for reciprocating said supply means with respect to said longitudinal direction so that said reinforcing fibers are supplied in the longitudinal direction of said pipe; And
Air injector for sucking the reinforcing fiber passed through the supply means to distribute on the surface of the pipe,
The reinforcing fiber is a reinforcing fiber supply device for axial reinforcement of the continuous pipe impregnated in the resin. In the reinforcing fiber supply apparatus for axial reinforcement of a continuous pipe which is arranged above the pipe which is continuously manufactured by winding the fiber on a rotating mandrel,
Supplying means for unwinding the reinforcing fibers provided from the bobbin downward using a plurality of members rotating in engagement with each other and feeding them onto the surface of the pipe being continuously manufactured; And
And moving means for reciprocating the supply means with respect to the longitudinal direction so that the reinforcing fibers are supplied in the longitudinal direction of the pipe,
The reinforcing fibers are impregnated in the resin,
The moving means,
A cam rotated by the third drive source; And
One end and the other end includes a drive bar coupled to each of the one side circumference of the cam and the supply means rotatably,
When the cam is rotated by the third driving source, one end of the driving bar moves along the circumference of the cam while the reinforcing fiber for the axial reinforcement of the continuous pipe for reciprocating the supply means in the longitudinal direction of the pipe. Feeding device. The method according to claim 2 or 3,
The supply means,
A first roller rotated by a first driving source; And
And a non-powered second roller facing the first roller, the friction being rotated by the first roller when the first roller is rotated according to the operation of the first driving source.
The reinforcing fiber is a reinforcing fiber supply apparatus for axial reinforcement of the continuous pipe descends in close contact between the rotating first roller and the second roller. The method according to claim 2 or 3,
The supply means,
A first conveying part having a third roller rotated by a second driving source, a fourth roller spaced below the third roller, and a first conveying belt integrally wound around the third roller and the fourth roller; And
The first and second rollers are integrally wound on the fifth and sixth rollers and the fifth and sixth rollers facing the third and fourth rollers, and the first conveyance belt is rotated according to the operation of the second driving source. And a second transfer part having a second transfer belt rotated by friction with the first transfer belt,
The reinforcing fiber is a reinforcing fiber supply apparatus for the axial reinforcement of the continuous pipe descends in close contact between the rotating first conveying belt and the second conveying belt. The method according to any one of claims 1 to 3,
And a guide plate disposed between the bobbin and the supply means, the guide plate having a plurality of guide holes respectively passing through the reinforcing fibers provided from the plurality of bobbins. The method according to claim 3,
And an air injector for sucking the reinforcing fibers passing through the supply means and dispersing the reinforcing fibers on the surface of the pipe. The method according to any one of claims 1 to 3,
Reinforcing fiber supply apparatus for the axial reinforcement of the continuous pipe further comprises a resin supply unit for supplying a resin on the reinforcing fibers to impregnate the reinforcing fibers into the resin.

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