KR20190113345A - Manufacturing apparatus of mesh for cable tray, and mesh for cable tray manufactured by the manufacturing apparatus of mesh for cable tray - Google Patents

Abstract

According to a mesh net manufacturing device for a cable tray and the mesh net for a cable tray manufactured by the mesh net manufacturing device for a cable tray, the mesh net manufacturing device for a cable tray includes a mesh net width adjustment unit and thus enables a width of the mesh net for a cable tray to be easily and variably adjusted to a required width, and has an advantage to be able to actively respond to the manufacture of the mesh net for a cable tray of various widths.

Description

An apparatus for manufacturing a common sphere mesh network and a mesh apparatus for a common sphere manufactured by the apparatus for manufacturing a common sphere mesh network {Manufacturing apparatus of mesh for cable tray, and mesh for cable tray manufactured by the manufacturing apparatus of mesh for cable tray}

The present invention relates to a mesh mesh manufacturing apparatus for a cavity ball, and a mesh mesh for a cavity ball produced by the mesh mesh manufacturing device for the cavity.

The mesh for cable tray is a facility installed underground for the improvement of aesthetics, the preservation of road structure and the smooth communication of traffic by accommodating underground facilities such as electricity, gas and water supply facilities, communication facilities, and sewage facilities. to be.

Examples of such co-phrases are those of the patent document set forth below.

These joints are manufactured in various forms, among which the joints are constructed at a position higher than the pavement along the edge of the tunnel to accommodate wires, drains, and communication lines therein.

As described above, for the hollow ball to be installed at the edge of the tunnel, since the durability and rigidity to withstand the strong impact is required due to the characteristics of the installation site, it is generally manufactured by casting, and then installed at the installation site, such a hollow ball It is the mesh network for the cavity sphere that forms the skeleton of concrete.

In general, the mesh mesh for the cavity ball is manufactured in a form in which the wire is welded in the form of a lattice, the apparatus for manufacturing such a mesh ball mesh network is a device for manufacturing the mesh ball for the cavity ball.

In the conventional apparatus for producing mesh meshes for common spheres, the mesh meshes for community spheres in the form of lattice are manufactured in such a manner that the wires supplied are joined by welding in a state in which the wires are arranged in a grid form.

However, according to the conventional apparatus for manufacturing a mesh ball for common spheres as described above, since the width of the cavity ball mesh network cannot be adjusted, the mesh ball mesh network for the cavity ball is manufactured only in an unchangeable width while being preset in the mesh ball mesh manufacturing device for the cavity ball. Since it is not possible to actively cope with the production of the mesh ball mesh for the various widths, and thus to be used to cut the mesh ball mesh mesh produced in a uniform width to the required width, the remaining mesh ball mesh for cutting There was a serious problem of waste of the mesh network for the joint ball to be discarded.

In addition, according to the conventional apparatus for manufacturing mesh meshes for common spheres, the spacing between the mesh raw materials, such as the wires constituting the mesh sphere mesh network, cannot be adjusted, and thus, each mesh that is set in advance in the mesh mesh manufacturing apparatus for the common spheres and cannot be changed. Since only the spacing between the raw material can be manufactured for the mesh mesh mesh, there is a problem that the spacing between each of the mesh raw material is variously variable can not be manufactured.

Korean Patent No. 10-1237275, Registered Date: February 20, 2013, Name of Invention: Cover Structure of Road Tunnel Joint Utility Model Registration No. 20-0294247, Registered Date: October 24, 2002 Patent Publication No. 10-2018-0010429, Publication Date: Jan. 31, 2018, Title of the invention: Formwork for forming the cavity and drain of the tunnel

An object of the present invention is to provide an apparatus for manufacturing a joint sphere mesh network capable of actively responding to the production of a cavity sphere mesh network of various widths and a mesh sphere for a cavity sphere manufactured by the apparatus for producing a cavity sphere.

Another object of the present invention is to provide an apparatus for manufacturing mesh balls for a cavity ball, which can be produced by varying the spacing between the respective raw materials of the mesh and the mesh mesh for mesh balls produced by the mesh ball manufacturing device for cavity balls.

An apparatus for manufacturing a mesh tool for a cavity tool according to an aspect of the present invention is a mesh tool for a cavity tool consisting of a plurality of longitudinal mesh raw materials and a plurality of widthwise mesh raw materials crossing each of the longitudinal mesh raw materials at positions spaced apart from each other in the width direction. As a net can be manufactured,

A longitudinal mesh raw material supply member for supplying the respective longitudinal mesh raw materials in a longitudinal direction of the cavity tool mesh network; A widthwise mesh raw material supply member for supplying the respective widthwise mesh raw materials in the width direction of the cavity tool mesh network; A mesh raw material joining member for joining each of the longitudinal mesh raw materials supplied by the longitudinal mesh raw material supply member and the widthwise mesh raw material supplied by the widthwise mesh raw material supply member; And a mesh network width adjusting unit that can adjust the length of the widthwise mesh raw material to the predetermined desired width so that the width of the cavity mesh mesh can be made to a predetermined desired width.

According to an aspect of the present invention, there is provided a mesh network for a cavity tool; Consists of a plurality of width direction mesh raw material to traverse the longitudinal mesh material at positions spaced apart from each other in the width direction,

Longitudinal mesh raw material supply member for supplying each said longitudinal mesh raw material to the longitudinal direction of the said hollow ball mesh network, and widthwise mesh raw material supply member for supplying each said width direction mesh raw material in the width direction of the said hollow ball mesh network. And a mesh raw material joining member for joining each of the longitudinal mesh raw materials supplied by the longitudinal mesh raw material supply member and the widthwise mesh raw material supplied by the widthwise mesh raw material supply member, and the mesh mesh for the cavity tool. Produced by the mesh mesh manufacturing apparatus for the hollow sphere comprising a mesh network width adjusting unit that can adjust the length of the width direction mesh raw material to the predetermined desired width, so that the width of the width can be made to the predetermined desired width It is characterized by.

An apparatus for manufacturing a mesh tool for a cavity tool according to another aspect of the present invention is a mesh tool for a cavity tool consisting of a plurality of longitudinal mesh raw materials and a plurality of widthwise mesh raw materials crossing each of the longitudinal mesh raw materials at positions spaced apart from each other in the width direction. As a net can be manufactured,

A longitudinal mesh raw material supply member for supplying the respective longitudinal mesh raw materials in a longitudinal direction of the cavity tool mesh network; A widthwise mesh raw material supply member for supplying the respective widthwise mesh raw materials in the width direction of the cavity tool mesh network; A mesh raw material joining member for joining each of the longitudinal mesh raw materials supplied by the longitudinal mesh raw material supply member and the widthwise mesh raw material supplied by the widthwise mesh raw material supply member; And varying positions of the respective widthwise mesh raw materials in contact with the respective longitudinal mesh raw materials in accordance with the preset desired intervals such that the intervals between the respective widthwise mesh raw materials are made at a predetermined desired interval. And a mesh raw material spacing adjusting unit.

According to another aspect of the present invention, there is provided a mesh network for a cavity tool; Consists of a plurality of width direction mesh raw material to traverse the longitudinal mesh material at positions spaced apart from each other in the width direction,

Longitudinal mesh raw material supply member for supplying each said longitudinal mesh raw material to the longitudinal direction of the said hollow ball mesh network, and widthwise mesh raw material supply member for supplying each said width direction mesh raw material in the width direction of the said hollow ball mesh network. And a mesh raw material joining member for joining each of the longitudinal mesh raw materials supplied by the longitudinal mesh raw material supply member and the widthwise mesh raw material supplied by the widthwise mesh raw material supply member, and the respective widthwise meshes. A mesh material spacing adjusting unit capable of varying the position of each of the widthwise mesh raw materials in contact with each of the longitudinal mesh raw materials in accordance with the predetermined desired spacing so that the spacing between the raw materials can be made at a predetermined desired spacing; It is characterized in that it is manufactured by a mesh mesh manufacturing apparatus for the cavity.

According to the common sphere mesh network manufactured by the apparatus for producing a common sphere mesh network according to an aspect of the present invention and the apparatus for producing a common sphere mesh network, as the common sphere mesh network manufacturing apparatus includes a mesh network width adjusting unit, The width of the cavity ball mesh network can be easily and variably adjusted to the required width, there is an effect that can actively respond to the manufacture of the mesh ball mesh for a variety of widths.

According to the common sphere mesh network manufactured by the apparatus for producing the common sphere mesh network and the common sphere mesh network manufacturing apparatus according to another aspect of the present invention, as the apparatus for producing the common sphere mesh network includes a mesh raw material spacing adjusting unit, The spacing between the respective widthwise mesh raw materials constituting the hollow sphere mesh network can be easily and variably adjusted to the required intervals, and accordingly between the respective widthwise mesh raw materials even in the hollow sphere mesh network made of a single body. There is an effect that the interval can be varied to be manufactured.

1 is a perspective view showing a mesh mesh for the cavity sphere manufactured by the apparatus for manufacturing a cavity sphere mesh network according to an embodiment of the present invention.
Figure 2 is a perspective view schematically showing the configuration of the mesh mesh manufacturing apparatus for a cavity ball according to an embodiment of the present invention.
Figure 3 is a perspective view showing the adjusted appearance of the mesh network width adjusting unit constituting the mesh mesh manufacturing apparatus for the cavity according to an embodiment of the present invention.
Figure 4 is a perspective view showing an adjusted state of the mesh material gap adjusting unit constituting the apparatus for manufacturing a mesh mesh mesh joint according to an embodiment of the present invention.
Figure 5 is a perspective view showing a widthwise mesh raw material supply member constituting the mesh mesh manufacturing apparatus for the cavity sphere according to an embodiment of the present invention.

Hereinafter, with reference to the drawings will be described with respect to the mesh ball manufacturing apparatus for the cavity sphere according to the embodiments of the present invention and the mesh mesh for manufacturing the cavity ball mesh network manufacturing apparatus.

1 is a perspective view showing a mesh mesh for the cavity sphere manufactured by the apparatus for producing a mesh ball according to an embodiment of the present invention, Figure 2 is a configuration of the apparatus for manufacturing a mesh ball mesh for joint according to an embodiment of the present invention Figure 3 is a perspective view schematically, Figure 3 is a perspective view showing the adjusted appearance of the mesh network width adjusting unit constituting the mesh mesh manufacturing apparatus for the cavity according to an embodiment of the present invention, Figure 4 is an embodiment of the present invention Figure 5 is a perspective view showing an adjusted state of the mesh material spacing adjusting unit constituting the apparatus for manufacturing a mesh ball according to the present invention, Figure 5 is a widthwise mesh raw material supply member constituting the mesh mesh manufacturing device for a cavity according to an embodiment of the present invention Is a perspective view.

Referring to Figures 1 to 5 together, the hollow mesh mesh 10 according to the present embodiment is manufactured by the hollow mesh mesh network manufacturing apparatus 100 according to the present embodiment, a plurality of longitudinal mesh raw material ( 30) and a plurality of transverse mesh raw materials 20 which traverse each of the longitudinal mesh raw materials 30 at positions spaced apart from each other in the width direction.

The longitudinal mesh raw material 30 and the widthwise mesh raw material 20 may be formed in the form of metal wires each having a predetermined diameter.

As shown in FIG. 1, the cavity mesh mesh 10 as a single body has a distance d1 between the respective widthwise mesh raw materials 20 in the length l direction of the cavity mesh mesh 10. , d2 and d3 may be freely variable to be different from each other, and the width w of the common sphere mesh network 10 may also be freely variable, which will be described in detail below.

The mesh mesh manufacturing device 100 for the cavity is a longitudinal mesh raw material supply member 110, the widthwise mesh raw material supply member 120, the mesh net width control unit 101, the mesh raw material coupling member 130 It includes, it is to be able to manufacture the mesh mesh 10 for the cavity.

The longitudinal mesh raw material supply member 110 supplies the respective longitudinal mesh raw materials 30 in the longitudinal direction of the hollow mesh mesh 10.

The longitudinal mesh raw material supply member 110 is accommodated in a form in which the longitudinal mesh raw material 30 formed to have a predetermined length is wound a plurality of times, so that the longitudinal mesh raw material supply member 110 is gradually loosened and supplied.

The widthwise mesh raw material supply member 120 supplies a widthwise mesh continuous material 25 in a form in which a plurality of the widthwise mesh raw materials 20 are continuously connected in the width direction of the hollow mesh mesh 10. will be.

The widthwise mesh raw material supply member 120 is accommodated in a form in which the widthwise mesh continuous material 25 formed to have a predetermined length is wound a plurality of times, and then is gradually supplied and supplied.

In detail, the widthwise mesh raw material supply member 120 is formed in a widthwise mesh supply frame 121 placed on the mounting surface thereof, and a circular plate shape having a predetermined area on the widthwise mesh supply frame 121. The widthwise mesh seating plate 122 is mounted in a state where the widthwise mesh continuous material 25 is wound a plurality of times, and the widthwise mesh seating plate protrudes at a predetermined height on the widthwise mesh seating plate 122. The widthwise mesh winding body 123 which can be rotated independently of the widthwise and the widthwise mesh continuous material 25 is wound on the outer circumferential surface a plurality of times, and the width relative to the widthwise mesh seating plate 122. Width direction mesh rotation means 124, such as an electric motor, which can rotate the direction mesh winding body 123 relative, and said width direction mesh continuous supplied by the said width direction mesh winding body 123, and supplied. A pair of widthwise mesh guide rollers 125 for guiding the material 25 toward the mesh network width adjusting unit 101 and a pair of widthwise mesh guide rollers 125 for supporting the ash 25 to stay in a predetermined airspace. The guide roller support 126 and the guide roller support 126 are connected to the widthwise mesh supply frame 121 so that the guide roller support 126 can be rotated relative to the widthwise mesh supply frame 121, and the guide roller support ( A guide roller rotary support 127 through which 126 is rotatably penetrated, a support extension 128 projecting a predetermined length horizontally from the guide roller rotation support 127, the support extension 128 and the width direction A support elastic body 129 which provides elasticity by connecting a mesh supply frame 121 to smoothly rotate the guide roller support 126, and the widthwise mesh on the guide roller support 126 And including in the roller 125, tensioning member 170 to adjust the tension in the width direction continuous mesh material 25 is caught in.

The support elastic body 129 is presented by a spring or the like, when the guide roller support 126 is rotated by the tension control member 170, the guide roller support 126 is pulled or pushed to a certain elasticity to the The rapid rotation of the guide roller support 126 is prevented and buffered so that the rotation is smooth.

The tension control member 170 is a tension control driven pulley 172 connected to the guide roller support 126, a tension control belt 173 that one side is caught by the tension control driven pulley 172, and the Tension adjustment driving pulley 171 caught on the other side of the tension adjusting belt 173, and the tension of the electric motor, etc., which is fixed to the width direction mesh supply frame 121, which can rotate the tension control driving pulley 171 Adjusting means 174.

As the tension adjusting means 174 is operated, the tension adjusting circular pulley 171, the tension adjusting belt 173, and the tension adjusting driven pulley 172 are sequentially rotated in the forward or reverse direction, and the guide roller. The support 126 is rotated accordingly, so that the tension of the widthwise mesh continuous material 25 caught in the widthwise mesh guide roller 125 on the guide roller support 126 can be adjusted.

Of course, the above-described belt and pulley structure of the tension adjusting member 170 is exemplary, and various other methods such as a gear structure may be applied.

When configured as described above, as the width direction mesh rotating means 124 is rotated, the width direction mesh winding body 123 is rotated, and thus the width direction was wound on the width direction mesh winding body 123 The mesh continuous material 25 is unwound and passed between the pair of widthwise mesh guide rollers 125 and then supplied to the mesh network width adjusting unit 101.

At this time, when the tension of the width direction mesh continuous member 25 is different from the required tension, the tension control member 170 is operated so that the tension of the width direction mesh continuous member 25 corresponds to the required tension. Adjust it if possible.

In detail, when the feeding speed of the widthwise mesh continuous material 25 is relatively slow compared to the required speed, when the tension of the widthwise mesh continuous material 25 becomes relatively larger than the required tension, the guide roller The tension adjusting member 170 moves the guide roller support 126 such that the portion where the widthwise mesh guide roller 125 is connected to the upper portion of the support 126 is relatively close to the widthwise mesh supply frame 121. Rotate

On the other hand, when the feeding speed of the widthwise mesh continuous material 25 is relatively faster than the required speed, and the tension of the widthwise mesh continuous material 25 is relatively smaller than the required tension, the The tension adjusting member 170 moves the guide roller support 126 such that a portion to which the widthwise mesh guide roller 125, which is the upper portion of the guide roller support 126, is connected is relatively far from the widthwise mesh supply frame 121. Rotate).

The mesh net width adjusting unit 101 sets the length of the widthwise mesh continuous member 25 to the predetermined desired width so that the width of the common mesh mesh 10 can be set to a predetermined desired width. It can be cut to fit.

In detail, the mesh net width adjusting unit 101 includes a mesh raw material cutting member 140 capable of cutting the widthwise mesh continuous material 25 supplied by the widthwise mesh raw material supply member 120, and Cutting position variable member 150 which moves the mesh raw material cutting member 140 to a position where cutting of the widthwise mesh continuous material 25 is required so that the widthwise mesh continuous material 25 is cut to the predetermined width. ).

In more detail, the mesh raw material cutting member 140 is a continuous material cutting base 144 on which the width direction mesh continuous material 25 is placed, and a continuous material cutting disposed on the continuous material cutting base 144. A cutting blade 142 capable of cutting the widthwise mesh continuous material 25 lowered from the body 141 and the continuous material cutting body 141 and placed on the base 144 for cutting the continuous material; The blade lifting means 143, such as a pneumatic pneumatic cylinder, which can raise and lower the cutting blade 142 with respect to the continuous material cutting body 141.

In addition, the cutting position variable member 150 and the cutting position variable body 152 connected to the continuous material cutting body 141, the guide member 155 for guiding the movement of the cutting position variable body 152 and The cutting position variable push body 151 capable of pushing or pulling the cutting position variable body 152 and the cutting position variable push body 151 to move the cutting position variable body 152 may be moved. External force applying body 153 for applying an external force to the.

The cutting position variable body 152 is connected to the continuous material cutting body 141, is formed in the shape of a bar formed in the same cross-sectional shape with a predetermined length, the guide body 155 is the cutting position variable body 152 ) May be inserted into or withdrawn from the inside thereof, and the cutting position variable body 152 is guided by the guide 155 when inserted into or withdrawn from the guide 155 to be a constant path, Here, it may be moved along a longitudinal path of the widthwise mesh continuous material 25 supplied to the mesh width control unit 101.

For example, the cutting position variable push body 151 may be formed in a long rod shape having a predetermined length with threads formed on an outer surface thereof.

An end of the cutting position variable push body 151 is rotatably connected to the cutting position variable body 152, and may push or pull the cutting position variable body 152 while being rotated.

Reference numeral 154 denotes a push body fixture which is fixed to the frame of the mesh tool manufacturing apparatus 100 for the cavity ball, and through which the cutting position variable push body 151 may pass.

The inner surface of the hole through which the cutting position variable push body 151 penetrates from the push body fixing body 154 is formed with a thread that can engage with a thread of the cutting position variable push body 151, When the cutting position variable push body 151 is rotated in one direction, the cutting position variable push body 151 is advanced to push the cutting position variable body 152, and the cutting position variable push body ( When the 151 is rotated in the other direction, the cutting position variable push body 151 is reversed to pull the cutting position variable body 152.

For example, the external force applying body 153 may be formed in the form of a handle connected to the cutting position variable push body 151 to be rotated by an operator holding by hand and applying an external force.

Of course, the external force applying body 153 may also be presented to be able to automatically rotate the cutting position variable push body 151, such as an electric motor.

When the worker holds the external force applying body 153 by hand and rotates in one direction, the cutting position variable push body 151 is also advanced toward the guide body 155 while being rotated in one direction, and thus the cutting position. As the variable body 152 is pushed, its position is moved to a position relatively close to the guide body 155, and the widthwise mesh raw material 20 is formed by being cut by the mesh raw material cutting member 140. The width can be made relatively narrow.

On the other hand, when the operator holds the external force applying body 153 by hand and rotates in the other direction, the cutting position variable push body 151 is also rotated in the other direction and is retracted away from the guide body 155, and As the cutting position variable body 152 is pulled, the position thereof is moved to a position relatively far from the guide body 155, and the widthwise mesh raw material cut and formed by the mesh raw material cutting member 140 ( 20 can be made relatively wider.

By the operation as described above, it is possible to manufacture by varying the width of the mesh mesh 10 for the cavity.

The mesh raw material coupling member 130 is each of the longitudinal mesh raw materials 30 supplied by the longitudinal mesh raw material supply member 110 and the width supplied by the widthwise mesh raw material supply member 120. The directional mesh continuous material 25 joins the widthwise mesh raw material 20 formed by being cut by the mesh network width adjusting unit 101.

The mesh material coupling member 130 may be presented as a spot welder by way of example. Reference numeral 131 denotes a welding portion for which such spot welding is performed, and a plurality of welding portions 131 may be disposed on the mesh raw material coupling member 130 by the number of the longitudinal mesh raw materials 30.

On the other hand, the mesh tool manufacturing apparatus 100 for a cavity ball according to the present embodiment further includes a mesh raw material spacing adjusting unit 102.

The mesh raw material spacing adjusting unit 102 is each widthwise mesh raw material in contact with each longitudinal mesh raw material 30 so that the spacing between the respective widthwise mesh raw materials 20 can be made at a predetermined desired interval. The position of 20 can be varied according to the predetermined required interval.

In detail, the mesh raw material spacing adjusting unit 102 moves the mesh raw material grip member 150 which picks up each of the longitudinal mesh raw materials 30 and the mesh raw material grip member 150 by moving the mesh raw material grip member 150. And a mesh raw material supply gap adjusting member 160 for adjusting the interval at which the respective widthwise mesh raw materials 20 are placed on the 30.

In more detail, the mesh raw material grip member 150 includes a mesh raw material penetrating member 152 through which the respective longitudinal mesh material 30 penetrates, and each longitudinal mesh material penetrating the mesh raw material penetrating member 152. It includes a mesh raw material tongs body 151 capable of picking up 30.

The mesh raw material penetrating member 152 is formed in a hollow circular cylinder shape so that each of the longitudinal mesh raw materials 30 supplied from the longitudinal mesh raw material supply member 110 may penetrate.

The mesh raw material clamp main body 151 picks up each of the longitudinal mesh raw material 30 penetrating the mesh raw material penetrating body 152 may be presented in various ways. For example, a through hole communicating with the mesh raw material through body 152 is formed in the mesh raw material tongs body 151, and protrudes into the through hole inside the mesh raw material tongs body 151 or again. When the tongs that can be shrunk into the mesh material tongs body 151 are installed, the tongs protrude into the through hole of the mesh material tongs body 151 by oil pressure supplied from the outside, so that the mesh material tongs main body The length of the longitudinal mesh raw material 30 penetrating through the 151 is pinched and fixed, or the tongs are contracted into the mesh raw material tongs body 151 to penetrate the mesh raw material tongs body 151 Fixing to the directional mesh raw material 30 may be released.

Reference numeral 153 denotes a pneumatic pressure transmission pipe connected to a pneumatic pressure applying means such as an external pneumatic pump, and the tongs may be operated by the pneumatic pressure supplied through the pneumatic pneumatic cutting pipe 153.

In addition to the above manner, the grip on the longitudinal mesh raw material 30 is possible in various ways.

The mesh raw material tongs body 151 and the mesh raw material penetrating body 152 are a plurality of longitudinal mesh raw materials 30 penetrating one by one, and correspond to the plurality of longitudinal mesh raw materials 30 in correspondence with the mesh raw materials 30. The tongs body 151 and the mesh raw material penetrating body 152 may also be arranged side by side in plurality.

In addition, the mesh raw material supply gap adjusting member 160 is a plate-shaped supply interval adjusting base 161 of a predetermined area to which the mesh raw material tongs body 151 is fixed, and the lower portion of the supply gap adjusting base 161 A supply gap adjusting body 162 to be connected, a supply gap adjusting push body 163 for pushing or pulling the supply gap adjusting body 162 so that the supply gap adjusting body 162 is moved, and A feed gap adjustment power means 164 for providing power for operation of the feed gap adjustment push body 163.

For example, the supply gap adjusting push body 163 may be formed in a long rod shape having a predetermined length with threads formed on an outer surface thereof.

The supply gap adjusting body 162 has a through hole through which the supply gap adjusting push body 163 is formed, and an inner surface of the through hole through which the supply gap adjusting push body 163 penetrates the supply gap adjusting push body ( When the thread for engagement with the thread of 163 is formed, when the supply gap adjusting push body 163 is rotated in one direction by an external force, the supply gap adjusting body 163 is supplied to the supply gap adjusting body 162. And the supply gap adjusting body 162 and the supply gap adjusting base 161 connected thereto are relatively close to the mesh material coupling member 130, and the feed gap adjusting push body 163 is relatively close. ) Rotates in the other direction, the supply gap adjusting push body 163 pulls the supply gap adjusting body 162, and thus the supply gap adjusting body 162 and Associated with the feed interval control base 161 becomes relatively apart from the mesh spar coupling member 130.

For example, a step motor may be applied to the supply gap adjusting power means 164. In this case, the power generated from the supply gap adjustment power means 164 is transmitted between the supply gap adjustment power means 164 and the supply gap adjustment power means 164 to the supply gap adjustment push body 163. Power transmission means 165 is disposed.

For example, the power transmission means 165 may include a motive pulley 166 connected to the rotational shaft of the supply interval adjusting power means 164, and a driven pulley 168 connected to the supply interval adjustment push body 163. And a power transmission belt 167 connecting the driven pulley 166 and the driven pulley 168. Then, when the power transmission means 165 is operated to rotate the motive pulley 166 in one direction, the power transmission belt 167 is also rotated in one direction and the driven pulley 168 is also in one direction linked thereto. Rotational direction, and thus, the supply gap adjusting push body 163 is rotated in one direction, and the power transmission means 165 is operated to rotate the driving pulley 166 in the other direction. 167 is also rotated in the other direction and in conjunction with the driven pulley 168 is also rotated in the other direction, so that the supply gap adjusting push body 163 can be rotated in the other direction.

In addition to the configuration as described above, a variety of methods, such as a combination of gears may be applied to the power transmission means 165, of course.

Here, as the RPM and the like of the supply interval adjusting power means 164 is adjusted, the longitudinal mesh raw material 30 in the state picked up by the mesh raw material grip member 150 and the mesh raw material grip member 150 is The speed of approaching the mesh material coupling member 130 is changed to the required speed, and the falling speed of the widthwise mesh material 20 formed by being cut by the mesh material cutting member 140 is kept constant, thereby The spacing between the widthwise mesh raw materials 20 can be adjusted to the required spacing.

For example, when the RPM of the supply gap adjusting power means 164 is operated in a relatively larger state, the longitudinal mesh raw material 30 in the state picked up by the mesh raw material grip member 150 is the mesh raw material. The speed of approach toward the engagement member 130 becomes relatively greater, and thus the spacing between the widthwise mesh material 20 becomes relatively wider.

On the other hand, when the RPM of the supply gap adjustment power means 164 is operated in a relatively smaller state, the longitudinal mesh raw material 30 of the state picked up by the mesh raw material grip member 150 is coupled to the mesh raw material The speed of approach toward the member 130 becomes relatively smaller, so that the spacing between the widthwise mesh raw materials 20 becomes relatively narrower.

Hereinafter, with reference to the drawings will be described the operation of the mesh ball manufacturing apparatus 100 for a cavity sphere according to this embodiment.

First, the longitudinal mesh raw material 30 is supplied from the longitudinal mesh raw material supply member 110 to be gripped by the mesh raw material grip member 150. In this state, according to the operation of the supply gap adjusting power means 164, the longitudinal mesh raw material 30 in the state picked up by the mesh raw material grip member 150 is predetermined toward the mesh raw material engaging member 130. Approaching speed.

At this time, the above operation is performed in such a state that the operating conditions such as RPM of the supply gap adjusting power means 164 are adjusted accordingly to achieve the required interval between the widthwise mesh raw material 20.

Meanwhile, the widthwise mesh raw material 20 formed by cutting the widthwise mesh continuous material 25 supplied from the widthwise mesh raw material supply member 120 by the mesh raw material cutting member 140 has a predetermined time interval. To fall toward the longitudinal mesh raw material 30 on the mesh raw material coupling member 130.

At this time, the operation of the mesh raw material cutting member 140 is adjusted by the cutting position variable member 150 in accordance with the above operation so that the width of the mesh mesh 10 for the cavity to achieve the required width is as described above. Is done.

As described above, when the longitudinal mesh raw material 30 and the widthwise mesh raw material 20 are stacked on the mesh raw material coupling member 130, the longitudinal direction of the mesh raw material coupling member 130 is extended by the mesh raw material coupling member 130. The overlapped portions of the mesh raw material 30 and the widthwise mesh raw material 20 are combined.

Then, the supply gap adjusting power means 164 is operated with the mesh raw material grip member 150 releasing the longitudinal mesh raw material 30 so that the mesh raw material grip member 150 is connected to the mesh raw material. In the original position away from the coupling member 130, in such a state that the mesh raw material grip member 150 again holds the longitudinal mesh raw material 30 in the original position, and the above operation is repeated in such a state, thereby The mesh mesh 10 for the cavity may be manufactured continuously.

As described above, as the apparatus for manufacturing the mesh ball for the cavity sphere 100 includes the mesh network width adjusting unit 101, the width of the cavity ball mesh network 10 can be easily and variably adjusted to the required width. It will be able to actively respond to the manufacture of the mesh mesh 10 for the cavity of various widths.

In addition, as the apparatus for manufacturing the mesh tool for co-ball 100 includes the mesh material gap adjusting unit 102, the interval between the respective widthwise mesh material 20 constituting the mesh ball 10 for the cavity ball. The required spacing can be easily and variably adjusted, and thus the spacing between the respective widthwise mesh raw materials 20 can be manufactured in various ways even in the hollow mesh mesh 10 made of a single body. .

While the invention has been shown and described with respect to specific embodiments thereof, those skilled in the art can variously modify the invention without departing from the spirit and scope of the invention as set forth in the claims below. And that it can be changed. Nevertheless, it will be clearly understood that all such modifications and variations are included within the scope of the present invention.

According to the present invention, the apparatus for manufacturing a community mesh mesh network and the community mesh network manufactured by the apparatus for manufacturing a community sphere mesh network can actively respond to the production of community sphere mesh networks having various widths, and each mesh raw material Since the spacing between the various can be produced, it is said that the industrial applicability is high.

100: mesh network manufacturing apparatus for the cavity ball
101: mesh net width adjusting unit
102: mesh raw material spacing unit
110: longitudinal mesh raw material supply member
120: widthwise mesh raw material supply member
130: mesh material joining member
150: mesh raw material grip member
160: mesh material supply gap adjusting member

Claims (7)

As a plurality of longitudinal mesh raw material and a plurality of longitudinal mesh raw material which can cross each of the longitudinal mesh raw material at a position spaced apart from each other in the width direction to produce a mesh mesh for the hollow sphere,
A longitudinal mesh raw material supply member for supplying the respective longitudinal mesh raw materials in a longitudinal direction of the cavity tool mesh network;
A widthwise mesh raw material supply member for supplying a widthwise mesh continuous material in a form in which a plurality of the widthwise mesh raw materials are continuously connected in a width direction of the cavity tool mesh network;
A mesh network width adjusting unit capable of cutting the length of the width direction mesh continuous material to the predetermined desired width so that the width of the cavity mesh mesh can be made to a predetermined desired width; And
The longitudinal direction mesh raw material supplied by the longitudinal mesh raw material supply member and the widthwise mesh continuous material supplied by the widthwise mesh raw material supply member are cut by the mesh network width adjusting unit and formed in the width direction Mesh mesh manufacturing apparatus for a hollow sphere, including; mesh raw material coupling member for bonding the mesh raw material. The method of claim 1,
The mesh net width adjusting unit
A mesh raw material cutting member capable of cutting the widthwise mesh continuous material supplied by the widthwise mesh raw material supply member;
Manufacturing a mesh mesh for hollow spheres characterized in that it comprises a cutting position variable member for moving the mesh raw material cutting member to the position where the cutting of the width direction mesh continuous material so that the width direction mesh continuous material is cut to the predetermined width. Device. The method of claim 2,
The mesh raw material cutting member
A base for cutting continuous materials on which the widthwise mesh continuous material is placed;
A continuous member cutting body disposed over the base for cutting the continuous member,
A cutting blade capable of cutting the widthwise mesh continuous material lowered from the continuous material cutting body and placed on the base for cutting the continuous material;
A blade elevating means capable of elevating the cutting blade relative to the continuous material cutting body,
The cutting position variable member
A cutting position variable body connected to the continuous material cutting body;
A guide for guiding movement of the cutting position variable body;
A cutting position variable push body capable of pushing or pulling the cutting position variable body to move the cutting position variable body;
An apparatus for manufacturing a common sphere mesh network comprising an external force applying body for applying an external force to the cutting position variable push body. The method of claim 1,
The mesh mesh manufacturing apparatus for the cavity ball
A mesh capable of varying the position of each widthwise mesh material in contact with the respective longitudinal mesh material to match the preset desired distance so that the spacing between each widthwise mesh material can be made at a predetermined desired interval. Raw material spacing adjusting unit; Mesh network manufacturing apparatus for the cavity sphere further comprises. The method of claim 4, wherein
The mesh raw material spacing adjusting unit
A mesh raw material grip member for picking up each of the longitudinal mesh raw materials;
And a mesh raw material supply gap adjusting member for adjusting the interval at which the respective widthwise mesh raw materials are placed on the longitudinal mesh raw material by moving the mesh raw material grip member. The method of claim 5,
The mesh material grip member is
A mesh raw material penetrating body through which the longitudinal mesh raw materials pass,
A mesh raw material tongs body capable of picking up each of the longitudinal mesh raw materials penetrating the mesh raw material through member,
The mesh raw material supply gap adjusting member
A supply gap adjusting base to which the mesh raw material tong body is fixed;
A feed spacing body connected to the feed spacing base;
A feed gap adjusting push body capable of pushing or pulling the feed gap adjusting body to move the feed gap adjusting body;
An apparatus for manufacturing a mesh tool for a hollow ball, characterized in that it comprises a power supply interval control power means for providing power for the supply gap adjustment push body operation. A plurality of longitudinal mesh raw materials; And
A mesh network for cavity spheres comprising: a plurality of widthwise mesh raw materials that traverse each of the longitudinal mesh raw materials at positions spaced apart from each other in a width direction.
The longitudinal direction mesh raw material supply member which supplies each said longitudinal mesh raw material in the longitudinal direction of the said mesh tool mesh mesh, and the width direction of the form which the several width direction mesh raw material continued in the width direction of the said mesh tool mesh network continuously. A widthwise mesh material supply member for supplying a mesh continuous material, and the width of the widthwise mesh continuous material is cut according to the predetermined desired width so that the width of the mesh tool mesh for the cavity can be made to a predetermined desired width. The mesh network width adjusting unit, each of the longitudinal mesh raw materials supplied by the longitudinal mesh raw material supply member, and the widthwise mesh continuous material supplied by the widthwise mesh raw material supply member to adjust the mesh network width. Mesh raw material joining the widthwise mesh raw material formed by cutting by the unit A hollow sphere mesh net manufactured by a hollow sphere mesh net manufacturing apparatus including a joining member.

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