KR101483729B1 - Auto cutter of cubic fiber media and controlling method the same - Google Patents

Abstract

The present invention relates to a three-dimensional fabric cutter which is provided with a disc cutter which is cut in the widthwise and lengthwise directions to automatically cut a nonwoven fabric made of PP or PE having two or more kinds of yarns mixed therein into a predetermined size to pelletize, And a control method thereof.
The present invention relates to a work table, A fabric input means in which a nonwoven fabric fabric made of at least one kind of yarn is supplied to an object to be worked; Intermittent feeding means for feeding the nonwoven fabric input from the far end feeding means by a predetermined length; A longitudinal axis cutting means provided at one side of the intermittent feeding means for performing longitudinal cutting on the conveyed nonwoven fabric end; A transverse axis cutting means provided at one side of the longitudinal axis cutting means and cutting the end portion of the nonwoven fabric cut in the longitudinal direction at a predetermined interval in the transverse direction to pelletize; Discharge means for storing the pallet cut by the driving of the abscissa cutting means; And an electric control device for controlling the driving of all the devices constituting the longitudinal axis cutting means, the transverse axis cutting means and the discharge means.

Description

Technical Field [0001] The present invention relates to an automatic cutter for cutting a three-dimensional fiber material,

The present invention relates to a three-dimensional fiber filter material cutting device for pulverizing pellets (small pellets) made of PP or PE used as filter media, and more particularly to a three- The nonwoven fabrics, which are obtained by fusing mixed fibers by physical or chemical methods, are cut in the transverse direction and the longitudinal direction to produce a fiber material having a predetermined size and shape, and the operation process required for the production of the fiber material And a control method thereof.

The increase in living standards will lead to an increase in the volume of industrial wastewater, wastewater, sanitary wastewater, and livestock wastewater, including increased water content. Thus, as the amount of wastewater discharged increases sharply, environmental problems such as serious water pollution are emerging. Generally, there are many problems due to an increase in the ratio of inorganic and organic components in wastewater. Therefore, efforts and research activities to remove inorganic and organic components have been actively conducted. As a result, the standard activated sludge method using the floating growth of microorganisms and the modified method thereof are almost universally applied in domestic sewage, farmed wastewater and industrial wastewater treatment.

First, the method of treating wastewater by the activated sludge method is to fix the microorganisms to the contact material, which is the carrier, to purify the microorganisms. This activated sludge method has a high biochemical reaction rate and promotes autoxidation of sludge so that the amount of surplus sludge is small and shows excellent treatment efficiency in treatment of low concentration wastewater. The most important parameter of the contact oxidation method using the contact material is the performance of the contact material. Usually, various materials such as sand, gravel, glass, ceramics, charcoal, plastic and fiber are used as contact media.

In the case of sand, gravel, glass, etc., the contact surface is smooth and difficult to adhere to microorganisms. The ceramic is used as a porous material, and its performance is excellent. However, it is difficult to manufacture and economical. In addition, polyethylene, polypropylene, polyvinyl chloride and nylon fibers have been used as filter media for plastics and textile materials. However, despite the advantage of easy processing, the microbial adhesion rate is low and the specific surface area is small, Research and development are required.

Despite the disadvantages of the conventional materials, which have been difficult to manufacture and economical in the past, a filter incorporating ceramic pellets as a carrier has been widely used as a final filter for filtering wastewater. The reason is that a labyrinthine flow path is formed between the porous pellets, and a plurality of holes are formed in each of the porous pellets to flow in the labyrinthine flow path. Since the filter made by collecting the porous pellets has a very complicated flow path, the wastewater passing through the filter is filtered with high efficiency. However, since the pellets themselves have a lump structure and the pellets have no pores therein, the filters manufactured using small pellets of the loess material have limitations in showing high-efficiency filtration performance.

In the case of fiber filter media, a mesh-type or fusible fiber filter is proposed which removes the foreign matter contained in the raw water passing through the water channel or the water tank.

In the mesh type fiber filter, foreign matter is trapped on the inner surface of the fiber filter when raw water is passed through, and only the treated water is discharged. However, in the coagulation filtration method in which the foreign matter in the raw water is largely agglomerated by the medicinal agent (coagulant) and then filtered, the medicinal agent (coagulant) In addition, since the micro-pores of the mesh-type fiber filter are closed, the cleaning effect is extremely reduced. In addition, the fusing fiber filter is formed by weaving the villas formed by twisting a thread having a predetermined length on one side of the mother board, By molding, various kinds of foreign substances contained in raw water are filtered out in the course of passing through the fume filter, and only the treated water is discharged outside.

However, since all of the above-mentioned fibrous filter materials are structured to woven fibers into a net shape or weave villas on a plate, they can not be used singly, and they are installed in a disk filter device such as a separate rotary drum, Therefore, there is a problem that the installation cost is large and the installation restriction is very limited according to the water channel structure. In addition, in the case of the fused-model filter, the foreign matters filtered by the villi during washing may be introduced into the treated water again, so that it is very troublesome to remove only the fused model from the filter device.

In order to overcome such a problem, a structure in which a fibrous filter material is formed into a granular pellet and is supported on a water channel has been proposed. However, the conventional particulate filter media has many problems in producing pellets using a cutting device.

That is, in the conventional three-dimensional fiber filter material cutter, a frame having a certain shape is formed by using a press method, a nonwoven fabric is put under the frame, and pressed by a press to produce a three- And the fabric material was cut in the transverse and longitudinal directions to produce a fiber material having a three-dimensional structure. However, the cutter structure is disadvantageous in that the fibrous filter material cut when the frame is pressed by a press is put on the frame, and then the frame is cleaned and then used again. In addition, since the process consists of pressurizing with a press and then re-feeding the fabric, it is not a completely automated process structure. In particular, since the fiber material is manually cut and pelletized, There was a very low problem.

Accordingly, it is an object of the present invention to provide a nonwoven fabric made of PP or PE mixed with two or more types of yarn, The present invention has been made in view of the above problems, and it is an object of the present invention to provide a three-dimensional fiber filter material cutting automation apparatus and a control method thereof, which can cut and pelletize a three-dimensional fiber filter material.

According to an aspect of the present invention, A fabric input means in which a nonwoven fabric fabric made of at least one kind of yarn is supplied to an object to be worked; Intermittent feeding means for feeding the nonwoven fabric input from the far end feeding means by a predetermined length; A longitudinal axis cutting means provided at one side of the intermittent feeding means for performing longitudinal cutting on the conveyed nonwoven fabric end; A transverse axis cutting means provided at one side of the longitudinal axis cutting means and cutting the end portion of the nonwoven fabric cut in the longitudinal direction at a predetermined interval in the transverse direction to pelletize; Discharge means for storing the pallet cut by the driving of the abscissa cutting means; And an electric control device for controlling the driving of all the devices constituting the longitudinal axis cutting means, the transverse axis cutting means and the discharge means.

As described above, according to the present invention, the nonwoven fabrics produced by mixing two or more types of yarns are put into the apparatus, and the nonwoven fabric is automatically cut into pellets by using a disk cutter driven in the transverse direction and the longitudinal direction, It is possible to increase the production efficiency.

Since the pellet filter material produced through the present invention is produced by connecting thin fibers having a small thickness, innumerable pores are formed in the pellet itself. According to the above-described pellet structure, a labyrinthine flow path is formed between the pellets, and a finer labyrinthine flow path is formed in the pellet, so that the wastewater passing through the filter can be filtered with high efficiency.

1 is a front view showing the construction of one embodiment of a three-dimensional fiber filter material cutter according to the present invention,
Fig. 2 is a schematic view showing a configuration of a longitudinal axis cutting portion, which is a substantial portion of the present invention;
Fig. 4 is a schematic view showing the installation state of the ring knife and the circular MC nylon in the longitudinally cut section shown in Fig. 2,
Fig. 5 is a schematic view showing a configuration of a transverse cut part, which is a substantial part of the present invention,
Fig. 6 is a side view of Fig. 5 showing the driving state of the second disk cutter,
7 is a schematic view showing a configuration of a rodless cylinder which is a main part of the present invention,
8 is a floor chart showing a control method of a three-dimensional fiber filter material cutting machine according to the present invention.

The above-mentioned objects, features and advantages will become more apparent from the following detailed description in conjunction with the accompanying drawings. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The apparatus for cutting a three-dimensional fiber filter material according to the present invention is capable of improving the productivity of the filter material by automatically cutting the nonwoven fabric mixture in which two or more kinds of yarns are mixed in the lateral and longitudinal directions.

FIG. 1 is a front view showing the construction of one embodiment of a three-dimensional fiber filter material cutting machine according to the present invention, FIG. 2 is a schematic view showing a constitution of a longitudinal axis cutting part which is a main part of the present invention, FIG. 5 is a schematic view showing a configuration of a horizontal axis cutting portion which is a main part of the present invention, FIG. 6 is a side view of FIG. 5 showing a driving state of a second disk cutter, Fig. 2 is a schematic view showing a configuration of a rodless cylinder which is a main part of the invention.

The fibrous filter material proposed in the present invention is a nonwoven fabric fabric 100 obtained by mixing two or more types of PP or PE yarns used as filter media.

As shown in Fig. 1, the present invention mainly relates to a work table 1; A fabric input part 2 provided on the work table 1; A vertical axis cutting portion 20 installed on one side of the far-end feeding portion 2 and slitting the raw material supplied thereto from the feeding portion 2 in the longitudinal direction (far-end feeding direction); A horizontal axis cutting portion 30 provided at one side of the vertical axis cutting portion 20 to cut the fabric having passed through the vertical axis cutting portion 20 in the transverse direction (direction perpendicular to the direction of the far-end feed); A discharge unit 40 provided at one side of the abscissa cutting unit 30 for discharging the cut fabric, and an electric control unit 50.

As shown in FIG. 1, the raw material input unit 2 is disposed at an upper portion of one side of the work table 1, and includes a raw material supply roll 4 for supplying the nonwoven fabric 100; A guide roller 6 installed at one side of the far-end feed roll 4 and conveying the nonwoven fabric pulled out therefrom to a cutting position; A fabric loading sensor 8 installed at a front end of the guide roller 6 to detect the insertion of the nonwoven fabric; And a tip detecting sensor 10 for detecting the state of the nonwoven fabric 100 being inserted by a predetermined length and stopping the guide roller 6 to stop the introduction of the fabric.
In the configuration of the raw material input unit 2, when the input of the raw material through the raw material input sensor 8 is sensed, this signal is applied to the electric control unit 50. When the leading edge detection sensor 10 senses the fabric that is fed by the guide roller 6 for a predetermined length, the leading edge detection sensor 10 applies the signal to the electrical control unit 50. The electric control unit 50 controls the guide roller 6 to stop according to the front end detection signal of the far end.

As shown in FIGS. 2 and 4, the longitudinal cutting section 20 includes a pinion 22a that receives power from the outside to rotate and drives the nonwoven fabric 100 by a predetermined length, And a rack 22b which is installed in the feeding direction of the pinion 22 and meshes with the pinion 22a to guide the movement of the pinion 22a. The nonwoven fabric 100, A rack pinion (22) for intermittently feeding the nonwoven fabric (100) to cut into a size; A clutch bearing (24) mounted on a pinion (22a) shaft of the rack pinion (22); A first disk cutter 26 provided at one side of the rack pinion 22 at regular intervals and provided with a plurality of ring knives 26a for rotating the nonwoven fabric 100 in a longitudinal direction (direction of conveying the nonwoven fabric) Wow; And a circular MC nylon roller 28 positioned at the lower end of the first disk cutter 26 and for preventing the edge of the ring knife 26a from being detached when the ring knife 26a cuts the nonwoven fabric .

Here, the first disc cutter 26 and the circular MC nylon roller 28 rotate in a direction in which they contact each other.

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As shown in FIGS. 5 and 6, the abscissa axis cutting portion 30 is provided with a plurality of ring knives 32a that are positioned at regular intervals and rotationally driven in a horizontal axis, and are provided on the upper portion of the nonwoven fabric, A plurality of second disk cutters (32, 32 ') for cutting the untreated nonwoven fabrics at regular intervals in the transverse direction to pelletize them; A lifting cylinder (34) for lifting the second disk cutter (32, 32 ') so as to contact the nonwoven fabric fabric (100) only during the cutting operation; A loadless cylinder (36) for moving the second disk cutter (32, 32 ') in the horizontal axis so that the plurality of second disk cutters (32, 32') cross each other to cut the nonwoven fabric; And a plate type MC nylon 38 positioned at the lower end of the second disk cutter 32 and preventing the edge of the ring knife 32a from being detached when the ring knife 32a cuts the nonwoven fabric.

7, the rodless cylinder 36 includes a piston 74 provided inside a stainless steel tube 71 in which A and B ports 72 and 73 are formed on both sides thereof; A slider 75 provided outside the stainless steel tube 71 and N and S pole magnets 76 provided on the piston 74 and the slider 75, respectively.
The slider 75 is fitted in the lifting cylinder 34 and the lifting cylinder 34 moves left and right together with the moving section of the slider 75.

The piston 74 is moved to the left by the pressure of the air as the air is introduced into the B port 73 and the slider 75 connected to the magnet 76 is moved to the left . The lifting cylinder 34 moves together with the section in which the slider 75 moves and descends at the moved position so that the second disk cutter 32 cuts the fabric.

The rodless cylinder 36 having the above-described configuration is provided so as to be installed in a narrow space and to prevent the cylinder from coming out.

The outlet part 40 is 1, a is connected to the front end of the plate-like MC nylon 38, a state off the pelletized media is an air stripper 42 and; A hopper 44 for discharging the filter material that has passed through the air stripper 42 and a discharge box 46 for storing the pellet-shaped filter material connected to the hopper 44.

The electric control device 50 is a device for controlling the driving of various devices constituting the vertical axis cutting portion 10, the horizontal axis cutting portion 20 and the discharge portion 40. The electric control device 50 includes first and second disk cutters 26 and 32, A counter set for setting the number of times of operation; A manual / auto switch for automatically or manually driving the first and second disc cutters 26 and 32; A timer for setting an air blowing time, and an on / off switch for controlling start and stop of operation. The configuration of the electric control device 50 is well known in the art and will not be described in detail.

The operation state of the present invention configured as described above will be described with reference to the control method of Fig.

First, the initialization of each device is performed (S12). After the nonwoven fabric 100 is fed from the raw material feeding roll 4 and passed through the guide roller 6, the raw material feeding sensor 8 senses this, The signal sensed by the far-end feed sensor 8 is applied to the electric control device 50 to drive the guide roller 6, the rack pinion 22 and the first disk cutter 26. The nonwoven fabric 100 is fed by the rotation of the guide roller 6 and the nonwoven fabric 100 is fed by a stroke in which the pinion 22a of the rack pinion 22 moves along the rack 22b do. When the nonwoven fabric 100 is conveyed by a predetermined length, the leading end sensor 10 senses the leading end of the nonwoven fabric 100 and the signal is transmitted to the electric control device 50 to stop the guide roller 6 (S13 and S14) .

The ring knife 26a of the first disk cutter 26 driven by the control signal of the electric control device 50 rotates to rotate the nonwoven fabric 100 in the longitudinal direction Direction (the direction of the fabric advancing) (S15). At this time, the circular MC nylon roller 28 provided at the lower end of the first disk cutter 26 rotates in a direction in contact with the ring knife 26a, so that the ring knife 26a is protected.

When the three sections of the nonwoven fabric 100 in the longitudinal direction are completed, the two second disk cutters 32 and 32 'are lowered by the driving of the lifting cylinder 34 to come into contact with the fabric nonwoven fabric laterally. At this time, the two second disk cutters 32 and 32 'move in the direction intersecting with each other by the operation of the rodless cylinder 36, and perform the lateral trimming operation (S16). As a result, the nonwoven fabrics cut in the longitudinal direction are also cut in the lateral direction to be pelletized in cubic form. The pellet is dropped into the air stripper 42, and the pellet filter material is separated from the pellet filter material. The separated pellet filter material is stored in the discharge box 46 through the hopper 44 (S17).

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, but will be apparent to those skilled in the art without departing from the technical idea of the present invention.

1: Work table 2:
4: fabric feed roll 6: guide roller
8: Fabric feed sensor 10: Lead tip sensor
20: longitudinal axis cutting section 22: rack pinion
24: clutch bearing 26: first disc cutter
28: Circular MC nylon roller 30:
32, 32 ': second disk cutter 34: lift cylinder
36: rodless cylinder 38: plate type MC nylon
40: discharging part 42: air stripper
44: hopper 46: discharge box
50: electric control unit 100: nonwoven fabric

Claims (12)

bench;
A fabric input means in which a nonwoven fabric fabric made of at least one kind of yarn is supplied to an object to be worked;
Intermittent feeding means for feeding the nonwoven fabric input from the far end feeding means by a predetermined length;
A longitudinal axis cutting means provided at one side of the intermittent feeding means for performing longitudinal cutting on the conveyed nonwoven fabric end;
A transverse axis cutting means provided at one side of the longitudinal axis cutting means and cutting the end portion of the nonwoven fabric cut in the longitudinal direction at a predetermined interval in the transverse direction to pelletize;
Discharge means for storing the pallet cut by the driving of the abscissa cutting means; And
An electric control device for controlling the driving of all the devices constituting the longitudinal axis cutting means, the transverse axis cutting means,
, ≪ / RTI &
The fabric feeding means includes a fabric feeding roll located at an upper side of the work table and supplying a nonwoven fabric fabric; A guide roller installed at a side of the fabric feed roll for conveying a nonwoven fabric drawn from the fabric roll to a cutting position, a fabric feed sensor installed at a tip of the guide roller for detecting insertion of the nonwoven fabric, And a tip detecting sensor for detecting a state in which the nonwoven fabric is inserted by a predetermined length and stopping the insertion of the fabric,
The intermittent feeding means includes a pinion for receiving power from the outside and rotating and driving the nonwoven fabric for a predetermined length, a rack provided in the advancing direction of the nonwoven fabric and engaged with the pinion to guide the movement of the pinion A rack pinion,
The longitudinal axis cutting means includes a clutch bearing installed on an axis of the intermittent feed means; A first disk cutter installed at one side of the intermittent conveying means and having a plurality of ring knives for rotating and driving the nonwoven fabric in the longitudinal direction; And a circular MC nylon roller positioned at the lower end of the first disc cutter and for preventing the ring knife from being detached when the nonwoven fabric is cut,
Wherein the abscissa cutting means includes a plurality of second disk cutters provided on an upper portion of the nonwoven fabric and configured to pellet the nonwoven fabric cut in the longitudinal direction at predetermined intervals in the transverse direction, ; A lifting cylinder for lifting and lowering the second disk cutter to contact the nonwoven fabric fabric only during cutting operation; And a plate type MC nylon disposed at a lower end of the second disk cutter and for preventing the ring knife from being detached when the ring knife cuts the nonwoven fabric, and the plurality of second disk cutters cross each other, And a loadless cylinder for moving the disc cutter in a horizontal direction so as to cut the three-dimensional fiber filter material.
delete delete delete The method according to claim 1,
Wherein the first disc cutter and the circular MC nylon rollers are rotated in a direction tangential to each other.
delete delete The method according to claim 1,
The electric control device
A counter set for setting the number of times of operation of the first and second disk cutters;
A manual / auto switch for automatically or manually driving the first and second disc cutters;
A timer for setting an air blowing start time; And
And an on / off switch for controlling start and end of operation. The method according to claim 1,
The discharge means
An air stripper installed at one side of the transverse shaft cutting means for pouring pelletized filter media;
A hopper for discharging the filter material having passed through the air stripper; And
And a discharge box for containing a pellet-shaped filter medium connected to the hopper and discharged. A first step in which a raw material input sensor detects that a nonwoven fabric is fed from a raw material supplying roll;
A second step of driving the guide roller, the rack pinion, and the first disk cutter by a signal sensed by the far-end feed sensor to the electric control device;
The nonwoven fabrics are fed by the rotation of the guide rollers. The nonwoven fabric is transported by a stroke in which the pinions of the rack pinion move along the rack. When the nonwoven fabric is transported by a predetermined length, A third step of stopping the driving of the roller;
A fourth step in which the first disk cutter driven by the control signal of the electric control device rotates and devides the tail of the nonwoven fabric in the longitudinal direction (direction of the far end) in the process of feeding and transporting the nonwoven fabric;
When the three sections of the nonwoven fabric in the longitudinal direction are completed, the two second disk cutters are moved in the mutually intersecting directions by the operation of the rodless cylinder by the driving of the lifting cylinder, A fifth step of subdividing into a pellet filter material in a state of a pellet; And
A sixth step of separating the pellet filter material from the pellet filter material while being dropped on the air stripper and storing the pellet filter material in a discharge box
And controlling the cutting of the three-dimensional fiber filter material.

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