KR102221024B1 - Wire mesh loading device - Google Patents

Abstract

The present invention relates to a wire mesh loading device, in which the unturned wire mesh and the overturned wire mesh can be automatically stacked in turn, thereby greatly improving work efficiency and reducing the volume of the loaded wire mesh by 1/2. It can be easily transported and stored, and furthermore, there is an effect that the work environment can be greatly improved since there is no fear of causing occupational diseases such as lumbar discs to workers.

Description

Wire mesh loading device}

In the present invention, not only can the unturned wire mesh and the overturned wire mesh be automatically loaded alternately in sequence, so that work efficiency can be greatly improved, and the volume of the loaded wire mesh can be reduced to 1/2, making it easy to transport and store And, furthermore, it relates to a wire mesh loading device capable of greatly improving a work environment since there is no fear of causing occupational diseases such as a lumbar disc to a worker.

In general, the wire mesh (3) that is installed to provide rigidity when constructing a building panel, wall, or floor, or to be installed for landmarks, is a plurality of longitudinal wires extending a predetermined length in the front and rear directions as shown in FIG. A plurality of transverse wires 32 extending in a predetermined length in the left and right directions on the upper part of 31 are welded in a grid shape to be manufactured.

In relation to the wire mesh (3), in recent years, a wire mesh manufacturing apparatus capable of manufacturing a wire mesh by welding vertical wires in a diagonal direction as well as being able to weld horizontal and vertical wires orthogonal to each other is a domestic registered utility model. It has been proposed as Gazette Registration No. 20-0392812.

However, most of the wire mesh manufactured by the wire mesh manufacturing apparatus proposed by the domestic Utility Model Publication Registration No. 20-0392812, etc., is manually stacked in a vertical direction by a worker, thus reducing work efficiency as well as wire mesh. It takes a lot of time for the loading operation, and furthermore, as shown in FIG. 2, the volume (H) of the loaded wire mesh (3) is too large, making it difficult to transport and store, as well as manually loading the wire mesh (3). During the process, since the worker repeatedly bends and stretches the waist region, there is a problem in a poor working environment, such as causing occupational diseases such as a lumbar disc.

Domestic Registration Utility Model Gazette Registration No. 20-0392812

The present invention was created in order to solve the above-described problems, and since it is possible to automatically and sequentially load an unturned wire mesh and an overturned wire mesh in turn, work efficiency can be greatly improved, and the volume of the loaded wire mesh is 1 Its purpose is to provide a wire mesh loading device that can be reduced to /2 so that it is easy to transport and store, and that there is no fear of causing occupational diseases such as lumbar discs to workers, so that the work environment can be greatly improved.

The present invention for achieving the above object is a wire mesh transfer unit for transferring a wire mesh in which a plurality of transverse wires are welded in a grid shape on a plurality of longitudinal wires and cut into a predetermined length; A wire mesh rotating unit that rotates the wire mesh by 180° in the vertical direction based on the center of the wire mesh transferred by the wire mesh transfer unit and turns it over; It provides a wire mesh loading device comprising a; wire mesh that is not turned over by the wire mesh rotation unit, and a wire mesh loading unit in which the wire mesh turned upside down by the wire mesh rotation part is alternately loaded.

Here, the wire mesh transfer unit includes a guide rail for guiding the transfer of the wire mesh to the wire mesh rotating part in a state in which the front and rear sides of the wire mesh cut to a predetermined length are respectively seated and supported; A guide pin that is detachably inserted into the through hole of the wire mesh by moving up and down in the direction of the through hole of the wire mesh seated on the guide rail; A lifting member for lifting the guide pin; It is preferable that the configuration includes; a transfer member for transferring the wire mesh to the wire mesh rotating part together with the guide pin and the lifting member.

In addition, it is preferable that a guide rail for preventing sagging is provided between the guide rails to prevent the wire mesh from sagging in a lower direction of the guide rail.

Further, the wire mesh rotation unit includes a receiving frame in which the wire mesh transferred by the wire mesh transfer unit is accommodated therein; A lifting member for lifting the wire mesh together with the receiving frame; It is preferable to be configured to include; a rotating member that is axially coupled to the center of the receiving frame to rotate the receiving frame.

Here, it is preferable that a separation preventing unit is provided for preventing the wire mesh from being separated from the receiving frame during the process of rotating the receiving frame by the rotating member.

As an example, a slit through which the wire mesh passes on one side and the other side of the receiving frame extends to a predetermined length from the front side of the receiving frame to the rear side, and the separation prevention part is provided on the inner surface of the slit, It is preferably made of a separation prevention pad for preventing the wire mesh from being separated from the receiving frame during the process of being in close contact with the receiving frame being rotated by the rotating member.

Here, it is preferable that an inclined surface inclined downward is formed on the inner surface of the separation prevention pad from one side to the other side of the separation prevention pad.

In another example, a slit through which the wire mesh passes on one side and the other side of the receiving frame extends a predetermined length from the front side to the rear side of the receiving frame, and the separation prevention unit moves up and down in the direction of the through hole of the wire mesh, and the A detachable pin that is detachably inserted into the through hole of the wire mesh; It is preferable to be configured to include; a lifting member for lifting the separation preventing pin.

In addition, the wire mesh loading unit and a loading frame in which the wire mesh and the overturned wire mesh are alternately loaded; A support rail provided at an upper front and a rear side of the loading frame, respectively, for sequentially seating and supporting the front and rear sides of the unturned wire mesh and the front and rear sides of the overturned wire mesh; It is preferable to include a rotating member for rotating the support rail so that the non-inverted wire mesh and the inverted wire mesh in which the support rails are sequentially seated and supported while alternately falling into the inside of the loading frame are loaded.

In addition, a wire mesh supply unit for sequentially supplying an unturned wire mesh and an overturned wire mesh from the wire mesh rotating part to the wire mesh loading part; is preferably provided.

Here, the wire mesh supply unit includes a guide pin that is detachably inserted into the through-hole of the non-turned wire mesh and the through-hole of the overturned wire mesh by lifting and lowering in the direction of the through-hole of the overturned wire mesh, respectively; A lifting member for lifting the guide pin; It is preferable to include a supply member for sequentially supplying the unturned wire mesh and the overturned wire mesh to the wire mesh loading unit together with the guide pin and the lifting member.

In the present invention, the wire mesh that is not turned over and the wire mesh that is turned over can be automatically stacked in turn and sequentially in the wire mesh loading unit through the wire mesh rotation unit, so that work efficiency can be greatly improved, and the volume of the loaded wire mesh is 1/2 As it can be reduced to, it is easy to transport and store. Furthermore, there is no need to manually load the wire mesh while repeatedly bending and stretching the waist, so there is no fear of causing occupational diseases such as lumbar discs on the waist of the worker. There is an effect that can be greatly improved.

1 is a perspective view schematically showing a wire mesh formed by welding a plurality of transverse wires in a grid shape on a plurality of longitudinal wires,
2 is a partially enlarged front view schematically showing a state in which the wire mesh of FIG. 1 is loaded,
3 is a plan view schematically showing a wire mesh loading apparatus according to an embodiment of the present invention,
Figure 4 is a partially cut-away front view of Figure 3,
5 and 6 are partially cutaway front views sequentially showing the process of transferring the wire mesh to the wire mesh rotating unit,
7 and 8 are partially cut-away front views schematically showing a process in which the wire mesh that is not turned over is supplied to the wire mesh loading unit,
9 and 10 are cross-sectional views taken along line A-A of FIG. 8 schematically showing a process in which the non-turned wire mesh falls into the wire mesh loading unit,
11 to 14 are partially cut-away front views schematically showing a process in which the wire mesh transferred to the wire mesh rotating part is turned over,
15 is a partially enlarged cross-sectional view schematically showing a departure preventing unit of an example,
16 is a partially enlarged cross-sectional view schematically showing a state in which an inclined surface is formed in the departure preventing portion of an example,
17 and 18 are cross-sectional views schematically showing the operation process of the departure prevention unit of another example,
19 is a partially cut-away front view schematically showing a state in which the inverted wire mesh is supplied to the wire mesh loading unit,
20 and 21 are cross-sectional views taken along line B-B of FIG. 18 schematically showing a process in which the inverted wire mesh falls into the wire mesh loading unit,
22 is a partially enlarged front view schematically showing a state in which an unturned wire mesh and an overturned wire mesh are sequentially stacked.

Hereinafter, a preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings. Of course, the scope of the present invention is not limited to the following embodiments, and various modifications may be made by those of ordinary skill in the art within the scope not departing from the technical gist of the present invention.

3 is a plan view schematically showing a wire mesh loading device according to an embodiment of the present invention, and FIG. 4 is a partially cutaway front view of FIG. 3.

Wire mesh loading apparatus according to an embodiment of the present invention is large, as shown in Figs. 3 and 4, comprises a wire mesh transfer unit 10, a wire mesh rotating unit 20 and a wire mesh loading unit 30.

First, a wire mesh (3 in FIG. 1) is placed on the top of a plurality of longitudinal wires (31 in FIG. 1) extending in a predetermined length in the front and rear direction of the wire mesh 3 from one side of the wire mesh 3 to the other. A plurality of transverse wires (32 in FIG. 1) extending left and right to a predetermined length may be welded in a grid shape.

The wire mesh 3 may be cut to a fixed length by a wire mesh cutting part 5 of a known shearing machine.

The wire mesh transfer part 10 may horizontally transfer the wire mesh 3 cut to a certain length by the wire mesh cutting part 5 from one side of the wire mesh 3 to the other side.

Next, the wire mesh rotating part 20 is 180° in the vertical direction of the wire mesh 3 on both sides of the wire mesh 3 with respect to the center of the wire mesh 3 transferred by the wire mesh transfer part 10 It is rotated and turned over.

Next, the wire mesh 3, which is not turned over by the wire mesh rotating part 20, and the wire mesh 3 turned upside down by the wire mesh rotating part 20, are alternately stacked inside the wire mesh loading part 30.

5 and 6 are partially cut-away front views sequentially showing the process of transferring the wire mesh to the wire mesh rotating unit.

Next, the wire mesh transfer unit 10 includes a guide rail 110, a guide pin 120, an elevating member 130 and a transfer member 140, as shown in FIGS. 3, 5 and 6 It can be configured.

The guide rail 110 may be formed to extend from one side to the other side of the wire mesh 3 to a predetermined length in a horizontal direction.

One side of the guide rail 110 so that the guide rail 110 can be arranged at regular intervals in the front and rear direction of the wire mesh cutting part 5, the front upper part of the other side opposite to one side of the wire mesh cutting part 5, and It can be connected and fixed in various ways, such as fixing bolts to the upper rear of the other side.

With the guide rail 110 seating and supporting the front and rear sides of the wire mesh 3 cut to a predetermined length, the guide rail 110 transfers the wire mesh 3 to the wire mesh rotating part 20. I can guide you.

The guide pin 120 is separated in the through hole 33 of the wire mesh 3 by moving up and down in the direction of the through hole 33 formed in plural at regular intervals on the wire mesh 3 seated on the guide rail 110 Can be inserted possibly.

The lifting member 130 may be composed of a transfer plate 131 and an actuator 132.

The transfer plate 131 may extend at regular intervals in the front and rear direction of the wire mesh 3.

Each of the upper front and rear upper portions of the transfer plate 131 may be vertically provided so that the guide pins 120 can be raised and lowered.

The actuator 132 is vertically fixed in various ways, such as bolt fixing to the front lower and rear lower portions of the transfer plate 131 in a state connected to the guide pin 120 to lift and lower the guide pin 120, etc. It can be of various types.

The transfer member 140 is provided horizontally at a predetermined height between the guide rails 110 to transfer the wire mesh 3 together with the guide pin 120 and the elevating member 130 to the wire mesh rotating part 20 I can make it.

The transfer member 140 is made of various types, such as a linear actuator capable of linearly reciprocating the transfer plate 131 from one side of the wire mesh 3 to the other direction, or an actuator including a cylinder operated by hydraulic or pneumatic pressure. I can.

Although not shown in the drawing, a support frame such as support legs for supporting the transfer member 140 to a predetermined height may be provided vertically under the transfer member 140.

Next, between the guide rails 110, a guide rail 40 for preventing sagging for preventing the middle portion of the wire mesh 3 from sagging in the lower direction of the guide rail 110 is provided along the guide rail 110. It can be extended left and right to a certain length.

One side portion of the sagging prevention guide rail 40 may be connected and fixed in various ways, such as bolt fixing on the middle portion of the other side portion of the wire mesh cutting portion 5.

The transfer plate 131 may reciprocate between the sagging prevention guide rail 40 and the transfer member 140.

Next, the wire mesh rotating part 20 may be large, as shown in FIGS. 3, 5 and 6, and may be configured to include a receiving frame 210, a lifting member 220, and a rotating member 230.

The receiving frame 210 may be formed in various shapes such as a square frame.

One front side and one side rear side of the receiving frame 210, and the other side front side and the other side rear side are formed at regular intervals in the direction from one side of the guide rail 110 to the other side above the other side of the guide rail 110 It may be accommodated in each of the receiving groove 111.

A slit 211 through which the wire mesh 3, which is not turned over, passes through the middle part of one side and the other side of the receiving frame 210 is extended to a predetermined length from the front side of the wire mesh 3 to the rear side. I can.

The wire mesh 3 transferred by the wire mesh transfer unit 10 may be horizontally accommodated in the slit 211 of the receiving frame 210.

The lifting member 220 and the rotating member 230 of the wire mesh rotating part 20 will be described in detail below for convenience of description.

7 and 8 are partially cut-away front views schematically showing a process in which the wire mesh that is not turned over is supplied to the wire mesh loading unit.

Next, a wire mesh supply unit 50 may be provided for supplying the wire mesh 3 that is not turned over from the wire mesh rotating part 20 to the wire mesh loading part 30.

As shown in FIGS. 3, 7 and 8, the wire mesh supply unit 50 may include a guide pin 510, an elevating member 520, and a supply member 530.

The guide pin 510 is accommodated in the slit 211 of the receiving frame 210 and moves upward and downward in the direction of the through-hole 33 formed at regular intervals on the other side opposite to one side of the wire mesh 3 that is not turned over. Thus, it can be detachably inserted into the through-hole 33 of the wire mesh 3 that is not turned over.

The lifting member 520 may include a lifting plate 521 and an actuator 522.

The elevator plate 521 may extend to a predetermined length in the front and rear direction of the wire mesh 3.

The guide pins 510 may be vertically formed on an upper front side and an upper rear side of the elevator plate 521.

The actuator 522 is a cylinder which is vertically provided in an eccentric state under the elevator plate 521 in a state connected to the elevator plate 521 to move the guide pin 510 up and down together with the elevator plate 521 It can be made of various types such as.

The supply member 50 may be provided horizontally in the lower direction of the receiving frame 210 at a height lower than that of the wire mesh transfer unit 10.

The supply member 50 is connected to the actuator 522 of the elevating member 520 so as to transfer the wire mesh 3 that is not overturned together with the guide pin 510 and the elevating member 520 to the wire mesh loading unit ( It can be made of various types such as actuators including cylinders supplied horizontally to 30).

Although not shown in the drawings, a support frame such as support legs for supporting the supply member 50 to a predetermined height may be provided vertically under the supply member 50.

9 and 10 are cross-sectional views taken along line A-A of FIG. 8 schematically illustrating a process of falling into the wire mesh loading portion of the non-turned wire mesh.

Next, the wire mesh loading unit 30 may be largely configured to include a loading frame 310, a support rail 320, and a rotating member 330, as shown in FIGS. 7 to 10.

The loading frame 310 may be composed of a floor frame 311 and a support leg 312.

The support legs 312 may be vertically provided on each corner of the floor frame 311.

The wire mesh 3 that is not turned over may be horizontally loaded on the top of the floor frame 311.

The top of the front side of the bottom frame 311 in a state in which the support rail 320, which can be formed in various shapes such as a'┗' shape in cross section, extends from one side of the wire mesh 3 to the other side by a predetermined length. The support rail 320 may be rotatably disposed between the support legs 312 so as to be horizontally provided at a predetermined height in a front-rearly symmetric state at the upper and rear sides.

One side and the other side of the support rail 320 may be rotatably coupled to an upper portion of the support leg 312 located in one direction and the other direction of the support rail 320, respectively.

The support rail 320 may seat and support the front and rear sides of the wire mesh 3 that are not turned over.

The rotating member 330 is connected to one side or the other side of the support rail 320, and the wire mesh 3 is not overturned in a state that is horizontally fixed in various ways, such as fixing bolts on the upper portion of the support leg 312. It may be made of various types of actuators such as a drive motor that rotates the support rail 320 so that it can fall to the floor frame 311 located in the inner direction of the support leg 312 of the loading frame 310.

11 to 14 are partially cut-away front views schematically showing a process in which the wire mesh transferred to the wire mesh rotation unit is turned over.

Next, in a state in which the wire mesh 3 that is not overturned in the loading frame 310 of the wire mesh loading part 30 is loaded, the wire mesh rotating part 20 is provided with the wire mesh rotating part ( The other wire mesh (3) transferred to 20) can be rotated 180° in the vertical direction and turned over.

To this end, the elevating member 220 of the wire mesh rotating unit 20 described above may be composed of an elevating body 221 and an actuator 222.

The lifting body 221 may be provided horizontally at a predetermined height on the front side and the rear side of the receiving frame 210, respectively.

A front middle portion and a rear middle portion of the receiving frame 210 on the upper portion of the lifting body 221 may be rotatably coupled in various ways, such as bearing coupling.

The actuator 222 is vertically provided at the lower portion of the lifting body 221 in a state connected to the lifting body 221 so as to be formed of various types such as a cylinder for lifting the wire mesh 3 together with the receiving frame 210. I can.

As shown in FIG. 2, the rotating member 230 is fixed in various ways such as bolt fixing to the upper part of the lifting body 221 in a state coupled to the front middle part and the rear middle part of the receiving frame 210. It may be made of various types of actuators such as a drive motor that rotates the receiving frame 210.

11 and 12, in a state in which the other wire mesh 3 is raised together with the receiving frame 210 by the lifting member 220, as shown in FIG. 13, by the rotating member 230 The other wire mesh 3 is rotated 180° in the vertical direction together with the receiving frame 210 so that the other wire mesh 3 can be overturned.

The other wire mesh 3 turned over with the receiving frame 210 may be lowered by the elevating member 220 and horizontally seated on the guide rail 110 as shown in FIG. 14.

15 is a partially enlarged cross-sectional view schematically showing a departure preventing unit of an example.

Meanwhile, the other wire mesh 3 is rotated 180° in the vertical direction by the rotating member 230 and the other wire mesh 3 is separated from the receiving frame 210 during the process of being overturned. It may be provided with a departure prevention unit 60 to prevent the.

As an example, the separation prevention part 60 is provided on the inner surface of the slit 211 of the receiving frame 210, as shown in Figure 15, such as rubber that is in close contact with the outer surface of the other wire mesh (3). It can be made of a release prevention pad with elastic force.

16 is a partially enlarged cross-sectional view schematically showing a state in which an inclined surface is formed in the departure preventing portion of an example.

In order to prevent the separation of the other wire mesh 3 from the receiving frame 210 with higher efficiency, as shown in FIG. 16, an inclined surface 601 is formed on the inner surface of the separation prevention pad of the separation prevention part 60 Can be formed.

The inclined surface 601 may be inclined downward (α) from one side of the separation prevention pad capable of forming the separation prevention part 60 toward the other side.

17 and 18 are cross-sectional views schematically showing an operation process of a departure prevention unit according to another example.

As another example, the departure prevention part 60 may be configured to include a separation prevention pin 610 and a lifting member 620 as shown in FIGS. 17 and 18.

The separation preventing pin 610 may move up and down in the direction of the through hole 33 of the other wire mesh 3 and may be detachably inserted into the through hole 33 of the other wire mesh 3.

The elevating member 620 is made of various types such as actuators such as cylinders that can be fixed in various ways such as bolt fixing vertically to an upper middle part of one side or an upper middle part of the other side of the receiving frame 210, etc. 610) can be moved up and down.

A lifting plate 621 for lifting and descending by the lifting member 620 may be horizontally connected and fixed on the upper part of the lifting member 620.

The separation prevention pin 610 for lifting and descending together with the elevator plate 621 in the lower portion of the other side of the elevator plate 621 in a state in which one side of the elevator plate 621 is connected and fixed to the upper portion of the elevator member 620 ) Can be vertically formed.

Alternatively, the separation prevention pin for lifting and descending together with the elevator plate 621 in a lower portion of one side of the elevator plate 621 while the other side of the elevator plate 621 is connected and fixed to the upper portion of the elevator member 620 610 may be vertically formed.

FIG. 19 is a partially cut-away front view schematically showing a state in which the inverted wire mesh is supplied to the wire mesh loading unit, and FIGS. 20 and 21 are taken along line B-B of FIG. 18 schematically showing the process of falling into the wire mesh loading unit. It is a cross-sectional view, and FIG. 22 is a partially enlarged front view schematically showing a state in which an unturned wire mesh and an overturned wire mesh are sequentially stacked.

The overturned wire mesh 3 is supplied to the wire mesh loading part 30 by the wire mesh supply part 50 in the same manner as the non-turned wire mesh 3 described above, as shown in FIGS. 19 to 22. It may fall into the wire mesh loading unit 30.

The present invention configured as described above alternates between the wire mesh 3 that is not overturned and another wire mesh 3 that is turned over to the wire mesh loading part 30 through the wire mesh rotating part 20 as shown in FIGS. 19 to 22 Not only can the work efficiency be greatly improved because it can be automatically loaded sequentially, but also the volume (H) of the loaded wire mesh 3 can be reduced to 1/2, making it easy to transport and store, and furthermore, the wire mesh (3) There is an advantage that the work environment can be greatly improved because there is no need to manually load the worker's waist while bending and stretching the waist repeatedly, so there is no fear of causing occupational diseases such as lumbar discs on the waist of the worker.

10; Wire mesh transfer unit, 20; Wire mesh rotating part,
30; Wire netting.

Claims (11)

A wire mesh transfer unit 10 for transferring a wire mesh 3 in which a plurality of transverse wires 32 are welded in a grid shape and cut into a predetermined length on a plurality of longitudinal wires 31;
The receiving frame 210 in which the wire mesh 3 transferred by the wire mesh transfer unit 10 is accommodated therein, and the receiving frame 210 are horizontally provided at a predetermined height at the front and rear sides of the receiving frame 210, respectively, and the receiving frame at the top The front middle part and the rear middle part of 210 are provided vertically in the lower part of the lifting body 221 and the lifting body 221 rotatably coupled to lift the wire mesh 3 together with the receiving frame 210 The lifting member 220 composed of an actuator 222 made of a cylinder, and the receiving frame 210 are fixed to the upper part of the lifting body 221 in a state coupled to the front middle part and the rear middle part of the receiving frame 210 Consisting of a rotating member 230 consisting of an actuator made of a driving motor that rotates 210, the wire mesh 3 is rotated 180° in the vertical direction with respect to the center of the wire mesh 3 and turned over, and the receiving frame ( A wire mesh rotating part 20 extending from a front side to a rear side of the receiving frame 210 to a predetermined length through a slit 211 through which the wire mesh 3 passes;
The receiving frame 210 to prevent separation of the wire mesh 3 from the receiving frame 210 during the process of rotating the receiving frame 210 by the rotating member 230 of the wire mesh rotating unit 20 The inclined surface ( A departure prevention part 60 in which 601 is formed;
It consists of a floor frame 311 and a support leg 312 vertically provided at each corner of the floor frame 311, and a wire mesh 3 that is not overturned by the wire mesh rotating part 20 and an overturned wire mesh 3 ) Are alternately loaded, and the front and rear sides of the wire mesh 3, which are provided on the front upper and rear upper portions of the loading frame 310, respectively, and the front and rear sides of the overturned wire mesh 3 Each of the support rails 320 that are sequentially seated and supported, and the non-inverted wire mesh (3) and the inverted wire mesh (3) for sequentially seating and supporting the support rails (320) alternate to the inside of the loading frame (310). A wire mesh loading portion 30 composed of a rotating member 330 made of a driving motor that rotates the support rail 320 so that the support rail 320 can be loaded while falling;
A wire mesh loading device comprising: a wire mesh supply unit 50 for sequentially supplying an unturned wire mesh 3 and an overturned wire mesh 3 from the wire mesh rotating part 20 to the wire mesh loading part 30 .
A wire mesh transfer unit 10 for transferring a wire mesh 3 in which a plurality of transverse wires 32 are welded in a grid shape and cut into a predetermined length on a plurality of longitudinal wires 31;
The receiving frame 210 in which the wire mesh 3 transferred by the wire mesh transfer unit 10 is accommodated therein, and the receiving frame 210 are horizontally provided at a predetermined height at the front and rear sides of the receiving frame 210, respectively, and the receiving frame at the top The front middle part and the rear middle part of 210 are provided vertically in the lower part of the lifting body 221 and the lifting body 221 rotatably coupled to lift the wire mesh 3 together with the receiving frame 210 The lifting member 220 composed of an actuator 222 made of a cylinder, and the receiving frame 210 are fixed to the upper part of the lifting body 221 in a state coupled to the front middle part and the rear middle part of the receiving frame 210 Consisting of a rotating member 230 consisting of an actuator made of a driving motor that rotates 210, the wire mesh 3 is rotated 180° in the vertical direction with respect to the center of the wire mesh 3 and turned over, and the receiving frame ( A wire mesh rotating part 20 extending from a front side to a rear side of the receiving frame 210 to a predetermined length through a slit 211 through which the wire mesh 3 passes;
A separation preventing pin 610 that is detachably inserted into the through hole 33 of the wire mesh 3 by lifting and lowering in the direction of the through hole 33 of the wire mesh 3, and an upper portion of one side of the receiving frame 210 It is fixed vertically to the middle part or the upper middle part of the other side, one side of the elevator plate 621 is fixed to the upper part, and the departure prevention pin 610 is vertically formed on the lower side of the other side of the elevator plate 621, and the elevator plate 621 During the process of rotating the receiving frame 210 by the rotating member 230 of the wire mesh rotating unit 20, consisting of a lifting member 620 consisting of a cylinder for lifting the separation prevention pin 610 with) A separation preventing unit 60 for preventing the wire mesh 3 from being separated from the receiving frame 210;
It consists of a floor frame 311 and a support leg 312 vertically provided at each corner of the floor frame 311, and a wire mesh 3 that is not overturned by the wire mesh rotating part 20 and an overturned wire mesh 3 ) Are alternately loaded, and the front and rear sides of the wire mesh 3, which are provided on the front upper and rear upper portions of the loading frame 310, respectively, and the front and rear sides of the overturned wire mesh 3 Each of the support rails 320 that are sequentially seated and supported, and the non-inverted wire mesh (3) and the inverted wire mesh (3) for sequentially seating and supporting the support rails (320) alternate to the inside of the loading frame (310). A wire mesh loading portion 30 composed of a rotating member 330 made of a driving motor that rotates the support rail 320 so that the support rail 320 can be loaded while falling;
A wire mesh loading device comprising: a wire mesh supply unit 50 for sequentially supplying an unturned wire mesh 3 and an overturned wire mesh 3 from the wire mesh rotating part 20 to the wire mesh loading part 30 .
The method according to claim 1 or 2,
The wire mesh transfer unit 10 is a guide rail 110 for guiding the transfer of the wire mesh 3 to the wire mesh rotating part 20 in a state in which the front and rear sides of the wire mesh 3 cut to a predetermined length are respectively seated and supported. )and;
A guide pin 120 that is detachably inserted into the through hole 33 of the wire mesh 3 by moving upward and downward in the direction of the through hole 33 of the wire mesh 3 seated on the guide rail 110;
A transfer plate 131 extending at regular intervals in the front-rear direction of the wire mesh 3 and vertically provided with the guide pins 120 at the front upper and rear upper portions, respectively, and the front lower part of the transfer plate 131 And an elevating member 130 comprising an actuator 132 formed of a cylinder that is vertically provided in the lower portion of the rear side and moves the guide pin 120 up and down;
Consisting of a linear actuator for linearly reciprocating the transfer plate 131 from one side of the wire mesh 3 to the other side, the wire mesh 3 together with the guide pin 120 and the elevating member 130 A wire mesh loading device comprising: a transfer member 140 for transferring to 20.
The method of claim 3,
A wire mesh loading device, characterized in that a guide rail (40) for preventing sagging is provided between the guide rails (110) to prevent the wire mesh (3) from sagging in the lower direction of the guide rail (110).
The method according to claim 1 or 2,
The wire mesh supply unit 50 moves upward and downward in the direction of the through hole 33 of the unturned wire mesh 3 and the through hole 33 of the overturned wire mesh 3, and the through hole 33 of the wire mesh 3 that is not turned over. ) And a guide pin 510 detachably inserted into the through hole 33 of the inverted wire mesh 3;
The elevating plate 521 extending in a predetermined length in the front and rear direction of the wire mesh 3 and having the guide pins 510 vertically formed in the upper and rear upper portions of the wire mesh 3, and the lower portion of the elevating plate 521 are A lifting member 520 composed of an actuator 522 formed of a cylinder for lifting the guide pin 510 together with the lifting plate 521;
The wire mesh loading part 30 is connected to the actuator 522 of the lifting member 520 so as to connect the non-turned wire mesh 3 and the turned wire mesh 3 together with the guide pin 510 and the lifting member 520 Wire mesh loading device comprising a; supply member 530 consisting of a cylinder sequentially supplied to the. delete delete delete delete delete delete

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