KR102053852B1 - Width-wire feeding apparatus for wire-mesh manufacture equipment - Google Patents

Abstract

According to the present invention, a wire feeder for automatically supplying the horizontal wires arranged in a grid-like horizontally in the wire mesh manufacturing equipment in the state further connected to the wire mesh manufacturing equipment inside; And a wire cutter for cutting a horizontal wire supplied through the wire feeder to a predetermined length in a state in which the wire mesh manufacturing facility is connected to the upper portion.

Description

Horizontal wire feeder for wire mesh manufacturing equipment {WIDTH-WIRE FEEDING APPARATUS FOR WIRE-MESH MANUFACTURE EQUIPMENT}

The present invention relates to a lateral wire supply device for wire mesh manufacturing equipment, and more particularly, it is installed in connection with a common wire mesh manufacturing equipment that manufactures and produces lattice wire mesh to automatically supply a horizontally arranged wire (lateral wire) (and It relates to a transverse wire feeder for wire mesh manufacturing equipment that can be cut).

The 1985 Mexico earthquake, the 1995 Kobe earthquake in Japan, the 2001 Indian earthquake, etc. came to be a catastrophe that caused social instability and huge economic losses along with numerous casualties.

Korea also suffered massive damage from the 2016 Gyeongju earthquake, which was the largest in the Korean peninsula since the earthquake in 1978, including Hongseong Earthquake in 1978, Sariwon Earthquake in 1982, and Yeongwol Earthquake in 1996. Data from the Korea Meteorological Administration (KMA) show that the number and probability of earthquakes are increasing.

As such, strengthening the seismic design standards and improving the system of the earthquake should be the first priority to prepare for earthquakes that are occurring worldwide.

Meanwhile, a wire mesh is mainly used as a stiffener of concrete structures. The wire mesh includes grid wires having a diameter of 2.6 mm to 6 mm at intervals of 5 cm to 20 cm. It refers to a wire mesh (lattice / metal mesh) that is interlaced by electric welding in a lattice image and applied to pavement or foam concrete to reinforce the rigidity of concrete structures. Used as

In other words, the above wire mesh reinforcement for building structures, pavement of mechanized farming roads, apartment underground parking lot and outdoor concrete pavement, road pavement, crack control of floor slab concrete and reinforcement retaining wall, as well as reinforcement for road drainage pipe concrete It is mainly used as a reinforcement for concrete pouring, such as slopes of subways and tunnels, reinforcing bars of the surface, and is also used for various purposes and purposes in various fields.

In this regard, through the Republic of Korea Patent Publication No. 10-2002-0029183, a manufacturing apparatus of a wire mesh for building panels used to provide a suitable strength to the building panel has been disclosed.

1 is a side view showing the configuration of the manufacturing apparatus of the wire mesh for building panels according to the prior art, Figure 2 is a lateral wire supply mechanism and welding mechanism and wire in the manufacturing apparatus of the wire mesh for building panels according to the prior art As an enlarged side view showing the configuration of the mesh feed mechanism, the conventional wire mesh manufacturing apparatus for building panels, as shown in the figure, the spot and the transverse wire supply mechanism 840 in the center of the main frame 850 On one side of the welding mechanism 860 is a plurality of wire support 820 on which the longitudinal wires (w-1) cut in advance by the length corresponding to the length of the wire mesh to be manufactured are placed in parallel, and the wire support ( 820, the front end of the longitudinal wires (w-1) to be placed on the same line and aligned neatly, as well as the lateral wire feed mechanism (840) and spot The wire aligning rod 830 for conveying toward the fold opening 860 is mounted, and the other side of the lateral wire supply mechanism 840 and the spot welding mechanism 860 is provided with a longitudinal wire w-1 and a spot. Finger 827 for holding the welded lateral wire w-2, chain link 828 with the finger 827 fixed, drive sprocket wheel 829 and driven sprocket for circular rotation of the chain link 828 A wire mesh feed mechanism 825 consisting of a wheel 829 'and a drive motor 831 for intermittently rotating the drive sprocket wheel 829 is mounted.

According to the prior art, while feeding several longitudinal wires w-1 intermittently, the transverse wires w-2 are intermittently supplied one by one, and the contact portions (cross contact points) of these wires are spot welded. In manufacturing the wire mesh, the longitudinal wires (w-1) cut in advance by a length corresponding to the length of the wire mesh to be manufactured are parallel to the plurality of wire support 820 on which the recesses 810 are formed at regular intervals. With the step of placing and aligning the front ends of the longitudinal wires w-1 with the wire aligning band 830 moving in the longitudinal direction of the longitudinal wires w-1, they are also aligned horizontally. A process for moving the direction wire (w-2) to the position to be supplied and welded, and intermittently pulling and transporting by grasping the lateral wire (w-2) spot-welded to the longitudinal wire (w-1) Wire mesh by process It is prepared.

This makes it possible to produce good quality wire mesh with good productivity, but it is cumbersome for the operator to cut and prepare the transverse wires (w-2) in advance, and also a plurality of the transverse wires so cut. Since (w-2) must be placed on the lateral wire supply mechanism 840, the manufacturing process of the lattice wire mesh is possible, and thus, the entire process automation cannot be performed due to the process characteristics in which the operator must partially intervene in the manufacturing process. As a result, there are bound to be a problem in that a limit is followed to speed up the manufacturing process and improve productivity.

Furthermore, as described above, a worker must directly put a plurality of crosswise wires w-2 cut in advance on the crosswise wire loading table 812 of the crosswise wire supply mechanism 840. There has been a problem that is not free from the danger of safety accidents.

(Patent 0001) Republic of Korea Patent Publication No. 10-2002-0029183 (published date: 2002. 04. 18.) (Document 0002) Republic of Korea Patent Registration No. 10-0536271 (Registration Date: 2005. 12. 06.) (Document 0003) Republic of Korea Patent No. 10-1658882 (Registration Date: September 13, 2016)

An object of the present invention is to solve the above problems, it is simply connected to the installation without the need to change the structure of the existing wire mesh manufacturing equipment automatically supply the lateral wire and through the automatic cutting to a predetermined length In another aspect, the present invention provides a lateral wire supply device for a wire mesh manufacturing facility that does not require human involvement in the wire mesh manufacturing process.

In order to achieve the above object, the present invention, a wire feeder for automatically supplying the horizontal wires arranged in a grid-like horizontal wire in the state connected to the wire mesh manufacturing equipment side to the inside of the wire mesh manufacturing equipment; And a wire cutter for cutting a horizontal wire supplied through the wire feeder to a predetermined length in a state in which the wire mesh manufacturing facility is connected to the upper portion.

In addition, the wire feeder, the main body of the device main body, which is mounted on the device main body, and the wire feeder continues to be transferred to the wire mesh manufacturing equipment side, and further mounted on the device body In the state, the sub-feeder to assist the transfer of the lateral wire in conjunction with the main feeder, and is further mounted on the device body, while the lateral wire feed supplied to the wire mesh manufacturing equipment side by the main feeder and the sub-feeder At least one feeding guider for guiding, a stator for straightening the lateral wire in a state disposed between the main feeder and the sub feeder on the device body, and installed in the device body, the main feeder and the It consists of a subfeeder and a dynamometer that produces and delivers the power required to drive the stator.

In addition, the wire cutting machine is fixedly mounted at a predetermined position of the upper end of the wire mesh manufacturing equipment by a binding bracket, the drive cylinder is carried out hinged to the rod front end and the rod cylinder is carried out according to the pressure entry and exit, Cutting blades for cutting the transverse wires transferred into the wire mesh manufacturing equipment through the wire feeder based on a series of up and down rotations associated with the rod retraction action, and a coupler for hinge coupling between the rods and the cutting blades. It is composed of a hinge shaft for hinge coupling the other end of the cutting blade to the device body.

In addition, the device body is composed of a device frame is provided with an internal space, the main plate and the sub-feeder and the top plate is integrally assembled on the top of the device frame for mounting the feed guide and the stator, the The main feeder is provided with a pair of first feeding rolls that rotate in a state of being stacked up and down and in close contact with each other, and any one of the first feeding rolls disposed on the upper side is provided with a lowering pressure by a pressure spring. As the mutual close contact with the other first feeding roll disposed on the lower side is maintained, the transverse wires can be compressed.

In addition, the stator rotates simultaneously with the turn housing that rotates by the dynamometer in the longitudinal direction, and is coaxially rotated in the turn housing, and imparts various external forces to the lateral wire passing through the turn housing. Or a plurality of stress blocks for straightening the straightened or curved portions to be straightened, and a plurality of binding panels for fixing the stress blocks to the turn housing.

In the turn housing, a plurality of the stress blocks are arranged in the longitudinal direction, and a mounting space that can be evenly arranged is provided at an inner side, and hinge parts assembled to the bearing units are protruded by predetermined lengths from both ends of the longitudinal direction. In the center of the hinge portion, a second through hole for transverse wire passage is formed through, and in the upper and lower surfaces facing each other in the mounting space, arrangement grooves for positioning the binding panels are formed inwardly at a predetermined interval, In the center of the lateral wire close contact surface of the stress block, a position groove for inward acceptance and external force of the lateral wire is added inwardly along the longitudinal direction is formed.

In addition, the dynamometer is built in the device body, the first power generating unit for producing power and transmitting the power to the main feeder, and the first power generating unit by being connected to the main feeder and the sub-feeder, And a power transmission unit for allowing power transmitted through the sub feeder to be applied to the sub feeder, and a second power generation unit for generating power and transmitting the power to the stator in a state more inherent in the device body. The driven part is driven by the power supply, the first drive motor, the driven shaft is coupled to any one of the first feeding rolls of the main feeder is driven driven by the rotational force from the drive gear axially coupled to the drive shaft of the first drive motor It is a timing belt which circulates the gear, the drive gear and the driven gear together and circulates in one direction when the drive gear rotates to achieve simultaneous rotation of the driven gear. The power transmission unit, a first chain gear for the simultaneous rotation during the rotation of the first feeding roll in the state coupled to any one of the first feeding rolls of the main feeder, the second feeding roll of the sub feeder A second chain gear that receives power from the first chain gear while being axially coupled to one of the two gears, the first chain gear and the second chain gear are enclosed together, and the first chain gear rotates in one direction; It is composed of a timing chain to achieve the simultaneous rotation of the second chain gear, the second power generating unit, the second drive motor for rotationally driven by the power supply, the shaft is coupled to one side of the stator and the drive shaft of the second drive motor A driven pulley that rotates simultaneously by receiving rotational force from an axially coupled drive pulley, and simultaneously encloses the drive pulley and the driven pulley and circulates in one direction when the drive pulley rotates simultaneously. It consists of a drive belt forming the former.

As apparent from the above description, the horizontal wire supply device for wire mesh manufacturing equipment of the present invention is automatically connected to the existing wire mesh manufacturing equipment so that the horizontal wire is automatically supplied, thereby improving the speed and accuracy of the manufacturing process. Brings the effect of.

In addition, there is an effect of eliminating manpower shortages and reducing labor costs by automating all processes that do not require manpower, and securing worker safety from accident risks caused by worker intervention.

Along with this, as well as achieving the various effects described up to now, as described above, it is possible to provide compatible characteristics without requiring the structural change of the existing wire mesh manufacturing equipment, and to show the profit generation effect of the company and related industries. It is a useful invention.

1 is a side view showing the configuration of the manufacturing apparatus of the wire mesh for building panels according to the prior art.
Figure 2 is an enlarged side view showing the configuration of the wire mesh for building panels according to the prior art, the configuration of the lateral wire supply mechanism, the welding mechanism and the wire mesh feed mechanism.
3a to 3c is a front view, a plan view and a side view showing the installation relationship of the lateral wire supply apparatus for wire mesh manufacturing equipment according to the present invention.
4 to 5b is a perspective view, a front view and a plan view showing the configuration of the wire feeder in the lateral wire supply device for wire mesh manufacturing equipment according to the present invention.
6 and 7 are exploded perspective and front cross-sectional view showing the structuring relationship of the wire cutter in the lateral wire supply device for wire mesh manufacturing equipment according to the present invention.
Figure 8 (a) (b) is a cross-sectional view showing the stator operation relationship of the wire cutter in the lateral wire supply device for wire mesh manufacturing equipment according to the present invention.
Figure 9a and Figure 9b is an enlarged view showing the configuration and operation relationship of the wire cutter in the lateral wire supply device for wire mesh manufacturing equipment according to the present invention.
10 and 11 (a) and (b) are a perspective view and a plan view showing an exemplary structure of a wire mesh manufactured by a lateral wire supply device for a wire mesh manufacturing facility according to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

First of all, in adding reference numerals to the components of the drawings, it should be noted that the same reference numerals have the same reference numerals as much as possible even if displayed on different drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

3A to 3C are front views, plan views, and side views showing the installation relationship of the wire mesh manufacturing apparatus for the horizontal wire supply device according to the present invention, and FIGS. 4 to 5B are the horizontal cross section for the wire mesh manufacturing equipment according to the present invention. A perspective view, a front view, and a plan view showing a configuration of a wire feeder in a wire supply device, and FIGS. 6 and 7 show a structure of a strut of a wire cutter in a lateral wire supply device for a wire mesh manufacturing facility according to the present invention. 8 (a) and (b) are exploded perspective views and a front sectional view, respectively, illustrating a stator operation relationship of a wire cutter in a lateral wire supply device for a wire mesh manufacturing apparatus according to the present invention, and FIGS. Enlarged view showing the structural relationship and operation relationship of the wire cutting machine in the lateral wire supply device for wire mesh manufacturing equipment according to the present invention And, Figs. 10 and 11 (a) (b) is a perspective view and a plan view showing an exemplary structure of the wire mesh produced by the transverse wire feeder for the wire mesh production equipment in accordance with the present invention.

As shown in Figure 3a to 3c, the wire mesh manufacturing equipment horizontal wire supply device (A) according to the present invention, the wire mesh manufacturing equipment 900 is arranged in a grid-like horizontally in a state further connected to the side Wire feeder (1) for supplying the lateral wire (w-2), and lateral wire (w-2) supplied through the wire feeder (1) in a state in which the wire mesh manufacturing facility (900) is further installed It is configured to include a wire cutter 2 for cutting a predetermined length).

The wire feeder 1 is an automatic supply means for the horizontal wires w-2 arranged horizontally in the manufacture of the lattice-shaped wire mesh m using the wire mesh manufacturing facility 900. FIGS. As shown in 5b, a wire mesh is drawn by pulling the device body 11 serving as the base of the device and the wires mounted on the device body 11 and unwinded from bobbins (not shown). The take-up transfer of the main feeder 12, which is continuously transferred to the manufacturing facility 900, and the transverse wires w-2 associated with the main feeder 12 in a state of being further mounted on the apparatus main body 11; The lateral wire w-2 which is further mounted on the assisting sub feeder 13 and the apparatus main body 11 and supplied to the wire mesh manufacturing facility 900 by the main feeder 12 and the sub feeder 13. ) At least one feeding guider 14 for guiding the transfer, and the main feeder 12 on the machine body 11. And a stator 15 for straightening the lateral wire w-2 in a state disposed between the sub feeder 13 and the main feeder 12 in a state of being installed inside the apparatus main body 11. And a dynamometer 16 which produces and transmits the power required for driving the stator 15 and the subfeeder 13.

The apparatus main body 11 includes an apparatus frame 111 having an internal space for accommodating additional apparatus, the main feeder 12, the sub feeder 13, the feeding guider 14, and the stator 15. It is composed of a top plate 112 that is integrally assembled on the top of the device frame 111 for mounting.

The main feeder 12 is provided with a pair of first feeding rolls 121 and 122 that rotate correspondingly in a state of being stacked up and down and in close contact with each other. The first feeding roll 122 of the lateral wire (w-2) is maintained in close contact with the other first feeding roll 121 disposed on the lower side by applying the lowering pressure by the pressure spring (s) Compression transfer is possible.

On the other hand, by configuring a pair of the first feeding roll 121, 122 in a pair, the transfer of the lateral wire (w-2) using the pair of the first feeding roll 121, 122 It is desirable to be able to increase the capability.

Like the main feeder 12, the sub feeder 13 includes a pair of second feeding rolls 131 and 132 that rotate in a state of being stacked up and down and closely adhered to each other. Bar, any one of the second feeding roll 132 disposed on the upper side is also kept in close contact with the other second feeding roll 131 disposed on the lower side by applying the lowering pressure by the pressure spring (s). According to this, the lateral feed (w-2) can be crimped and conveyed.

The feeding quider 14 equalizes the transfer of the lateral wire w-2 unloaded from the bobbin mentioned above, and allows the lateral wire w-2 to pass through the center. The first through hole 141 for flow suppression is formed in the longitudinal direction.

The straighter 15 has a turn housing 151 which rotates by the dynamometer 16 in the longitudinal direction as shown in FIGS. 6 to 8 (a) and (b), and the A plurality of stresses are applied to the transverse wire (w-2) passing through the turn housing 151 in a state in which it is simultaneously rotated in the turn housing 151 and a straightening is achieved to straighten the bent or bent portion. Block 152 and a plurality of binding panels 153 for fixing the stress block 152 to the turn housing 151.

In addition, the turn housing 151 has a plurality of stress blocks 152 arranged in the longitudinal direction, and the mounting space 150 which can be evenly arranged is provided on the inside, and the bearing housings b are assembled from both ends in the longitudinal direction. Each hinge portion 151-1 is formed to protrude a predetermined length, and a second through hole 151-11 for passing the horizontal wire w-2 is formed in the center of the hinge portion 151-1. .

In addition, the upper and lower surfaces facing each other in the mounting space 150, the placement grooves 150-1 for positioning the binding panels 153 are formed inwardly with a predetermined interval.

In addition, a position groove 152-1 in the center of the contact surface of the lateral wire (w-2) of the stress block 152, so that the bending may be added when the internal acceptance and external force of the lateral wire (w-2) are applied. It is formed inward along this longitudinal direction.

The dynamometer 16 generates a power in a state inherent in the internal space of the apparatus frame 111 of the apparatus main body 11 and generates a first power generating unit 161 for transmitting the power to the main feeder 12. ), And the power transmission so that the power transmitted through the first power generation unit 161 is imparted (transmitted) to the sub feeder 13 by being installed in connection with the main feeder 12 and the sub feeder 13. The unit 162 and a second power generation unit 163 for generating power and transmitting the power to the stator 15 in a state more inherent in the internal space of the apparatus frame 111.

Here, the first power generation unit 161, any one of the first driving motor (161-1) and the first feeding roll (121, 122) of the main feeder 12 to rotate the drive by power supply A driven gear 161-2 and a driving gear 161- that are axially coupled to each other and are rotated simultaneously by receiving rotational force from the drive gear 161-11 coupled to the drive shaft of the first drive motor 161-1. 11) and the driven gear 161-2 together with the timing belt 161-3 which rotates in one direction when the driving gear 161-11 rotates to achieve simultaneous rotation of the driven gear 161-2.

In addition, as described above, when a pair of the first feeding rolls 121 and 122 are configured in a pair, all of the pair of the first feeding rolls 121 and 122 may be rotated. In order to ensure that the first interlocking gear 161-4 is axially coupled to each of the first feeding rolls 121 and 122, the gears are disposed between the first interlocking gears 161-4. It is preferable to have a second interlocking gear 161-5 to engage in interlocking rotation so that all of the first feeding rolls 121 and 122 can be rotated.

The power transmission unit 162 rotates the first feeding rolls 121 and 122 while being axially coupled to any one of the first feeding rolls 121 and 122 of the main feeder 12. The first chain gear 162-1 which performs simultaneous rotation at a time, and the first chain gear 162 axially coupled to any one of the second feeding rolls 131 and 132 of the sub feeder 13. Rotation of the first chain gear 162-1 by enclosing the second chain gear 162-2 and the first and second chain gears 162-1 and 162-2 received from --1). It is composed of a timing chain 162-3 which rotates in a single direction to achieve simultaneous rotation of the second chain gear 162-2.

In addition, the second power generating unit 163 is axially coupled to the second driving motor 163-1 and the stator 15, which are driven to rotate by power supply, and the second driving motor 163-1. Receives rotational force from the drive pulley 163-11 coupled to the drive shaft of the driven pulley 163-2 and simultaneously rotates the drive pulley 163-11 and the driven pulley 163-2, It is composed of a drive belt (163-3) for synchronous rotation of the driven pulley (163-2) by being circulated in one direction during the rotation of the drive pulley (163-11).

The wire cutting machine 2 is an automatic cutting means for cutting the lateral wire w-2, which is fed and supplied through the wire feeder 1 in a state of being connected to the wire mesh manufacturing facility 900, to a predetermined length. 9A and 9B, the binding bracket 20 is fixedly mounted at a predetermined position of the upper end of the wire mesh manufacturing facility 900 while the advancing and retracting action of the rod 211 is performed by pressure ingress. The wire mesh manufacturing facility 900 is hinged to the end of the rod 211 and the rod 211 is carried out through the wire feeder 1 based on the up and down rotation of one end in connection with the rod 211 retraction. Cutting blade 22 for cutting the transverse wire (w-2) transferred to the inside, a coupler 23 for hinge coupling between the rod 211 and the cutting blade 22, and the device body 910 Hinge shaft (24) for hinge coupling the other end of the cutting blade (22) It is configured.

Here, the drive cylinder 21 is preferably any one of a hydraulic cylinder or a pneumatic cylinder suitable for carrying out the retracting / retracting action of the rod 211 by the hydraulic and pneumatic injection and discharge relationship.

In addition, the cutting blade 22 is rotated up and down by the rod 211 of the driving cylinder 21 based on the advancing and retracting action, so that the wire mesh manufacturing equipment 900 is formed by the wire feeder 1. It is a metal blade which can cut | disconnect the lateral wire w-2 conveyed inwardly efficiently.

Unexplained reference numeral 112-1 denotes a defense that surrounds the outside of the stator to block the exposure for the purpose of preventing an accident that may be caused by the external exposure of the wire during the straightening of the wire by the strut of the wire cutter. It is a defense cover.

Referring to the action of the wire mesh manufacturing equipment horizontal wire supply device (A) according to the present invention having the above configuration in detail as follows.

First, as shown in Figures 3a to 3c, by connecting the horizontal wire supply device (A) according to the present invention in the existing wire mesh manufacturing equipment 900, transverse to the inside of the wire mesh manufacturing equipment (900) In addition to the automatic supply of the wire (w-2), it is possible to automatically cut to a predetermined length, thereby enabling automation of the overall wire mesh (m) manufacturing process without the operator involved.

In more detail, the longitudinal wires (w-1) are supplied to the wire mesh manufacturing equipment 900, and the intermittent transfer means 920 provided on one side of the device body 910 of the wire mesh manufacturing equipment 900 is provided. The longitudinal wires w-1 are continuously conveyed and supplied along the process direction by the forward and backward reciprocating motions within a predetermined range along the process direction.

And, as described above, the longitudinal wires w-1 conveyed along the fixed direction are uniformly and precisely conveyed by the conveyance guide means 930 installed on the other side of the device body 910.

In addition, as described above, in connection with a process in which the longitudinal wire w-1 is transferred along the process direction, the unit matching means 940 and the electric welding means 950 may be linked to each other. By the matching means 940, the horizontal wire (w-2) is raised to the upper end of the longitudinal wire (w-1) fed in the process direction at a predetermined interval, and at the same time the electric welding means ( 950) As the cross-contact between the longitudinal wires w-1 and the transverse wires w-2 overlapped with each other in a cross shape according to the operation is performed by spot welding, the longitudinal wires w-1 and the transverse wires ( As w-2) is bonded to each other, the structure of the lattice-shaped wire mesh m is achieved.

Thereafter, as the longitudinal wire w-1 is cut to a predetermined length by the standard shear 960 of the wire mesh manufacturing facility 900, all the manufacturing processes of the wire mesh m may be completed.

In this process, the lateral wire (w-2) is automatically supplied to the wire mesh manufacturing facility 900 by the wire feeder 1 of the present invention, and as shown in Figure 9a and 9b, Of course, the straightening is achieved according to the operation of the stator 15, and as the lateral wire w-2 is automatically cut to a predetermined length by the wire cutting machine 2 of the present invention, the grid-shaped wire mesh m It is not necessary for people (workers) to be involved in all processes for manufacturing and production.

In summary, according to the lateral wire supply apparatus for wire mesh manufacturing equipment according to the present invention, the lateral wire (w-2) is automatically supplied by interlocking and installing in the existing wire mesh manufacturing equipment 900. It can achieve the effect of rapidity and improved precision.

In addition, by automating the entire process that does not require human resources, labor shortages and labor costs can be reduced, and workers' safety can be secured from accident risks caused by worker's process intervention.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains various modifications, changes, and substitutions without departing from the essential characteristics of the present invention. will be. Accordingly, the embodiments disclosed in the present invention and the accompanying drawings are not intended to limit the technical spirit of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by the embodiments and the accompanying drawings. . The protection scope of the present invention should be interpreted by the claims below, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

A: Cross wire feeder, 1: Wire feeder
2: wire cutting machine, 11: device body
12: main feeder, 13: sub feeder
14: feeding guider, 15: strator
16: dynamometer, 20: binding bracket
21: driving cylinder, 22: cutting blade
23: coupler, 24: hinge shaft
111: device frame, 112: top plate
112-1: defense cover, 121, 122: first feeding roll
131, 132: second feeding roll, 141: first through
150: mounting space, 150-1: placement groove
151: turn housing, 151-1: hinge
151-11: second through hole, 152: stress block
152-1: position groove, 153: binding panel
161: first power generation unit, 161-1: first drive motor
161-2: driven gear, 161-3: timing belt
161-4: first interlocking gear, 161-5: second interlocking gear
161-11: drive gear, 162: power transmission unit
162-1: 1st Chain Gear, 162-2: 2nd Chain Gear
162-3: timing chain, 163: second power generating unit
163-1: second drive motor, 163-2: driven pulley
163-3: driving belt, 163-11: driving pulley
211: loading

Claims (7)

A wire feeder for automatically supplying lateral wires arranged horizontally in a lattice shape to the inside of the wire mesh manufacturing facility, in a state in which the wire mesh manufacturing facility is connected to the side of the wire mesh manufacturing facility; And,
A wire cutter for cutting a horizontal wire supplied through the wire feeder to a predetermined length in a state in which the wire mesh manufacturing facility is more connected to the wire mesh manufacturing facility.
The wire feeder, the device body to be the base of the device,
A main feeder mounted on the apparatus main body, which draws wires and continuously transfers them to the wire mesh manufacturing facility;
A sub feeder which is further mounted on the device main body to help the transverse wires to be connected to the main feeder;
At least one feeding guider which is further mounted on the apparatus main body and guides the transverse wire transfer supplied to the wire mesh manufacturing facility by the main feeder and the sub feeder;
A stator for straightening the transverse wires in a state disposed between the main feeder and the sub feeder on the device body;
It is composed of a dynamometer for producing and transmitting the power required for driving the main feeder, the sub-feeder and the stator in a state installed inside the device body,
The stator includes a turn housing for performing a rotational movement by the dynamometer in the longitudinal direction,
A plurality of stress blocks simultaneously rotating in a state assigned to the turn housing, and applying a multilateral external force to the transverse wires passing through the turn housing so as to achieve a straightening of straightening the bent or bent portion;
It consists of a plurality of binding panels for fixing the stress block to the turn housing,
The dynamometer, the first power generating unit for producing power and transmitting to the main feeder in a state inherent in the device body,
A power transmission unit connected to the main feeder and the sub feeder so that the power transmitted through the first power generation unit is imparted to the sub feeder;
In a state more inherent in the device body, it is composed of a second power generation unit for producing power and transmitting to the strut,
The first power generation unit is coupled to any one of the first drive motor, the first feeding motor of the main feeder rotationally driven by the power supply and transmits the rotational force from the drive gear axially coupled to the drive shaft of the first drive motor. Receives a simultaneous rotation of the driven gear, the drive gear and the driven gear together and consists of a timing belt for synchronous rotation of the driven gear by circulating in one direction when the drive gear rotates,
The power transmission unit may include a first chain gear that rotates simultaneously when the first feeding roll rotates while being axially coupled to any one of the first feeding rolls of the main feeder, and any of the second feeding rolls of the sub feeder. A second chain gear that receives power from the first chain gear in an axially coupled state, the first chain gear and the second chain gear are enclosed together, and the second chain gear is circulated in one direction when the first chain gear rotates; Consists of a timing chain that achieves simultaneous rotation of the chain gear
The second power generation unit, the second drive motor for rotational drive by power supply, the driven pulley axially coupled to one side of the stator and the rotational power received from the drive pulley axially coupled to the drive shaft of the second drive motor to rotate at the same time, the Transverse wire supply apparatus for wire mesh manufacturing equipment, comprising a drive belt for synchronously rotating the driven pulley by circulating a driving pulley and the driven pulley together in one direction when the driving pulley rotates.
delete The method of claim 1
The wire cutting machine is fixed to a fixed position of the upper end of the wire mesh manufacturing equipment by the binding bracket, while the drive cylinder is carried out the retraction action according to the pressure entry and exit,
A cutting blade which is hinged to the rod end and cuts transverse wires transferred into the wire mesh manufacturing equipment through the wire feeder based on one end of up and down rotation associated with the rod retraction action;
A coupler for hinge coupling between the rod and the cutting blade;
Horizontal wire supply apparatus for wire mesh manufacturing equipment, characterized in that the hinge shaft for hinge coupling the other end of the cutting blade to the device body.
The method of claim 1
The device body, and the device frame is provided with an internal space,
The main feeder and the sub-feeder and the top plate is integrally assembled to the upper end of the device frame for mounting the feeding guider and the stator,
The main feeder is provided with a pair of first feeding rolls for corresponding rotation in a state of being stacked up and down and in close contact with each other, and any one of the first feeding rolls disposed on the upper side is provided with a descending pressure by a pressure spring. The horizontal wire feeder for wire mesh manufacturing equipment, characterized in that the pressing of the transverse wire is possible as the mutually maintained close contact with the other first feeding roll disposed below the furnace.
delete The method of claim 1,
The turn housing is provided with a mounting space that can be arranged evenly by arranging a plurality of the stress blocks in the longitudinal direction,
From both ends in the longitudinal direction, hinge portions assembled to the bearing units are formed to protrude a predetermined length, respectively.
In the center of the hinge portion, a second through hole for transverse wire passage is formed through,
On the upper and lower surfaces facing each other in the mounting space, arrangement grooves for positioning the binding panels are formed inwardly at a predetermined interval,
In the center of the lateral wire contact surface of the stress block, a horizontal groove supply device for the wire mesh manufacturing equipment, characterized in that the position grooves for inward acceptance and external force of the lateral wire to be added inwardly formed along the longitudinal direction .
delete

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