KR102166735B1 - Heating press with label supply structure - Google Patents

Abstract

The present invention relates to a hot press, and more particularly, by configuring a label supply means to automatically supply the label according to the lifting operation of the heating plate on one side, so that the label is automatically supplied when the heating plate rises. The present invention relates to a hot press having a label supply structure in order to improve work efficiency according to the automatic supply of labels, and in particular, to ensure the safety of workers by eliminating the need for an operator to enter the lower part of the heating plate.

Description

Heating press with label supply structure

The present invention relates to a hot press, and more particularly, in configuring a hot press, by forming a label supply structure for hot pressing the label on one side, it is possible to improve workability in hot pressing the label on the fabric. It relates to a hot press having a label supply structure.

In general, various types of cloths such as mountaineering clothes and hats must be provided with a waterproof function. For waterproofing, the waterproof fabric and the outer shell are bonded to each other by thermal compression, or flattened when wrinkles occur. Separate labels, etc. are attached to distinguish products.

On the other hand, in order to heat-press fabrics such as mountaineering clothes or hats as described above and attach labels, there is a small iron that can be held and used with one hand. It may be possible with a device or a heat press device.

Thus, as in Patent Application Registration No. 10-1508868, there has been proposed a hot press that enables hot compression of the fabric by raising and lowering the heating plate while the fabric is placed on the upper part of the worktable.

However, the conventional devices as described above have a thermocompression function, and in order to thermally compress labels by overlapping them separately, the operator places the labels on top of the fabric and drives the heating plate to perform thermocompression and attachment. In the supply of inbar and barbell, a considerable amount of time is required, and the work efficiency is significantly reduced, and there is a serious problem that threatens the safety of the worker in particular.

In addition, there is a problem in that it is difficult to accurately adjust the position when supplying the label.

Korean Patent Registration Publication No. 10-1508868.

The present invention has been invented to solve the above problems, and by configuring a label supply means to automatically supply the label according to the lifting operation of the heating plate on one side, the label is automatically supplied when the heating plate is raised. In particular, a hot press with a label supply structure to ensure the safety of workers by not requiring the operator to enter the lower part of the heating plate, in particular, improves work efficiency due to the automatic supply of labels. It is an object of the present invention to provide.

As a specific means for achieving the above object, while lifting and lowering from the top of the thermocompression bonding workbench and the thermocompression bonding workbench on which the fabric is mounted on the upper part of the main body, it is installed on the post and mounted on the thermocompression worktable while lifting and lowering through cylinder operation. In a heat press having a heat-compressed portion made of a heating plate for performing heat-compression by applying heat to the fabric to be formed,
It is configured to further include a label supply means capable of automatically supplying a label to be attached to one side of the thermal compression unit,
The label supply means,
A lifting cylinder mounted on an installation bracket fixed to the post and having a lifting rod operating up and down;
A lifting platform connected to the front end of the lifting rod to vertically and downwardly lifting according to the operation of the lifting cylinder, and having a guide rod vertically penetrating through the installation bracket to guide the lifting platform;
A rotating cylinder protruding from one side of the lifting platform through a cylinder bracket and having a horizontal rod operating horizontally;
A shaft portion vertically formed in front of the elevator platform at the front side of the horizontal rod to provide a horizontal rotational force;
A pivoting bar whose rear end is hinged to the front end of the horizontal rod, the rear side is coupled to the shaft, and the front side protrudes toward one side of the thermocompression unit to advance to the top of the thermocompression working table when rotating;
An adsorption unit vertically formed at the tip of the pivoting bar to provide an adsorption force by operating a vacuum device; And
It is formed in the main body at one side of the thermocompression unit, the label is stacked and stored, and comprises a label input unit for discharging the labels stacked one by one by the adsorption unit,
The adsorption unit,
A shaft pipe vertically penetrating and protruding downward from the tip of the pivoting bar and fixed to the pivoting bar;
The shaft pipe is formed to penetrate and protrude from the bottom of the shaft, and the spring is bulging to have a downward elasticity from the inside, a locking protrusion is formed around the upper end, and an elastic adsorption hole is formed at the lower end, and the spring is burnt to have a downward elasticity in the inside of Through suction tube and
It consists of a vacuum hose with one end connected to the upper end of the adsorption pipe and the other end connected to a vacuum device to impart air adsorption power to the adsorption port.
The rotation bar is further formed with an elevating intermittent sensor for controlling the rise of the elevating cylinder, and a sensor reaction zone that reacts with the elevating intermittent sensor is further formed at the upper end of the adsorption tube,
The label input unit,
A support shaft vertically installed on one side of the body;
A label mounting plate formed on an upper end of the support shaft, configured in a rectangular plate shape to mount a label, and have guide grooves formed in all directions; And
A threaded portion is formed at each lower end, which can be achieved by including a plurality of spacing adjustment bars that penetrate each guide groove from the top and fasten nuts from the bottom.

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As described above, in the hot press having the label supply structure of the present invention, a label supply means is configured to move up and down, adsorption and rotation on one side of the thermal compression unit, but when the heating plate is raised, one label is adsorbed and rotated in the label supply unit to attach. Since it is possible to supply the upper part of the fabric, it is possible to quickly and accurately supply the label for the labeling operation, thereby reducing the working time, and thus, the work efficiency can be significantly improved. .

In addition, since the label is automatically supplied without the need for the operator to enter and supply the label to the lower portion of the heating plate, the effect of ensuring the safety of the operator can be obtained.

1 is an overall perspective view of a hot press having a label supply structure.
Figure 2 is a front view of a hot press having a label supply structure of the present invention.
Figure 3 is a side view of a hot press having the present invention label supply structure.
Figure 4 is a perspective view of a label supply means of a hot press having a label supply structure of the present invention.
5 is a plan view of a label supply means of a hot press having a label supply structure of the present invention.
6 is a cross-sectional view of an adsorption unit of a hot press having a label supply structure of the present invention.
7 is a diagram showing the main part of the label input part of the hot press having the present invention label supply structure.
Figure 8 is a main portion of the fabric hanger of the hot press having a label supply structure of the present invention.
Figure 9 is a main portion of the fabric hanger of the hot press having the present invention label supply structure.
Figure 9 is a fabric mounting state of the hot press having the present invention label supply structure.
Figure 10 is a label adsorption state diagram of the hot press having the present invention label supply structure.
Figure 12 is a state diagram of the label rotation supply of the hot press having the present invention label supply structure.
13 is an operating state diagram of the ion generating device of the hot press having the present invention label supply structure.

The terms or words used in this specification and claims should not be construed as being limited to their usual or dictionary meanings, and the inventor may appropriately define the concept of terms in order to describe his own invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention based on the principle that there is.

Accordingly, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and do not represent all the technical ideas of the present invention, so that they can be replaced at the time of application It should be understood that there may be various equivalents and variations.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an overall perspective view of a hot press having a label feeding structure, FIG. 2 is a front view of a hot press having a label feeding structure of the present invention, and FIG. 3 is a side view of a hot press having a label feeding structure of the present invention.

As shown in Figs. 1 to 3, the hot press 1 having the present invention label supply structure includes a thermocompression working table 110 and a thermocompression working table 110 on which the fabric is mounted at the upper part of the main body 10. On the other hand, a heat-compressed part made of a heating plate 140 installed on the post 120 to perform thermal compression by applying heat to the fabric mounted on the thermocompression working table 110 while lifting and lowering through the operation of the cylinder 130 From a heat press with 100,

It is configured to further include a label supply means 200 for automatically supplying a label to be attached to one side of the thermal compression unit 100.

At this time, the label supplying means 200 is a lifting cylinder 210, a lifting platform 220, a rotating cylinder 230, a shaft part 240, a rotating bar 250, with reference to FIGS. 4 and 5, It consists of an adsorption unit 260 and a label input unit 270.

First, the lifting cylinder 210, in constituting the hot press 1 having the label supply structure of the present invention, the upper and lower portions of the adsorption unit 260 to be described later by controlling the up and down movement of the rotating bar 250 to be described later, Adsorption of the label is possible through lowering and lowering.

To this end, the lifting cylinder 210 is formed on one side of the post 120 from the rear of the thermocompression working table 110, and is vertically upright formed through the installation bracket 211, and the lifting rod 210a operating up and down ) Is configured to appear and run downward of the installation bracket 211.

The lifting platform 220 is connected to the front end of the lifting rod 210a at a position spaced apart from the lower portion of the mounting bracket 211 in constituting the hot press 1 having the label supply structure of the present invention, and the lifting cylinder 210 ) It is configured to move up and down by operation, and it is configured in a plate shape that forms the front and rear lengths.

At this time, a guide rod 221 which is vertically installed at the rear of the lifting platform 220 and vertically penetrates the installation bracket 211 to guide the lifting during lifting operation is configured.

The rotational cylinder 230 is configured to intermittently rotate the rotational bar 250 to be described later in the hot press 1 having the label supply structure of the present invention, and the rotation of the rotational bar 250 Accordingly, the adsorption unit 260 is rotated so that it enters the top of the thermocompression working table 110 or escapes to the outside.

At this time, the rotating cylinder 230 is formed on the cylinder bracket 231 protruding to one side of the lift platform 220 and is configured to move up and down together with the lift platform 220, and when installed on the cylinder bracket 231, the horizontal direction It is hinged to have a predetermined rotational force, and a horizontal rod (230a) that appears and moves forward is configured at the front end.

The shaft portion 240 is configured to impart a horizontal rotational force of the pivoting bar 250 to be described later in constituting the hot press 1 having the label supply structure of the present invention, and a bearing in front of the lifting platform 220 (Fig. (Not shown) and so on.

The rotating bar 250 is configured to guide the rotation of the adsorption unit 260 to be described later in constituting the hot press 1 having the label supply structure of the present invention, and is rotated by the operation of the rotating cylinder 230 It is composed of a bar shape with left and right lengths.

At this time, the pivoting bar 250 is configured to be hinged to the front end of the horizontal rod 230a, and the intermediate portion is coupled to the shaft part 240 at a position eccentric to the rear end, and the front end is the thermocompression working table 110 ) Is configured to be drawn out to one side of the rear side, and the front end is configured to rotate horizontally around the shaft part 240.

That is, when the horizontal rod 230a is pulled out by the operation of the rotating cylinder 230, the rotating bar 250 rotates around the shaft part 240 so that the tip is deviated to one side of the thermocompression working table 110, and the horizontal When the rod 230a is retracted, it rotates around the shaft part 240 so that the tip of the rod 230a enters the upper part of the thermocompression working table 110.

The adsorption unit 260, in constituting the hot press 1 having the label supply structure of the present invention, is formed at the front end of the rotating bar 250 and is configured to transport the label to the top of the thermocompression working table 110. As a result, an adsorption force is provided by a separate vacuum device, and the adsorption and release of the label are possible by the adsorption force.

To this end, the adsorption unit 260 is first configured with a shaft pipe 261 with reference to FIG. 6, and the shaft pipe 261 is configured in the form of a tube body through which the center is penetrated so that it penetrates and protrudes downward through the front end of the pivoting bar 250. Is composed.

At this time, the shaft pipe 261 is a screw thread (261a) formed on the outer circumferential surface of the rotation bar 250 as the center of the nut (N) is fastened at the top and bottom to be fixed, the screw thread (261a) fastening position of the nut (N) According to this, the degree of downward protrusion can be adjusted.

In addition, the adsorption unit 260 is configured with an adsorption tube 262, the adsorption tube 262 is configured in the form of a hollow tube through which the center passes, while vertically slidable through the shaft tube 261, It is configured to protrude to the upper and lower portions of the shaft pipe 261.

At this time, the adsorption pipe 262 penetrating the shaft pipe 261 is configured to have a downward protruding force by releasing a spring (S) on the inner upper portion of the shaft pipe 261, and the mounting of the spring S is the adsorption pipe 262 A protrusion (not shown in the drawing) may be formed around the lower circumference of the protrusion, and the protrusion and the shaft pipe 261 may be configured to be burnt on the inner upper end.

In addition, a locking protrusion 263 is protruded around an upper end of the absorption pipe 262 so that the absorption pipe 262 is locked on the upper portion of the shaft pipe 261 and is prevented from being separated downward.

Further, at the lower end of the adsorption tube 262, a through-type adsorption hole 264 made of an elastic rubber or silicone material is formed.

In addition, the adsorption unit 260 is configured with a vacuum hose 266 for imparting an adsorption force to the adsorption port 264, and the vacuum hose 266 has one end connected to the upper end of the adsorption tube 262, and the other end. It is configured to be connected to a vacuum device (not shown in the drawing) such as a separate vacuum pump installed under the main body 10 or the like.

That is, when a vacuum force (suction input) is applied by the vacuum device, the suction unit 260 acts on the suction pipe 262 through the vacuum hose 266 and acts on the suction port 264 again, 264), the label can be absorbed.

On the other hand, in the present invention, the suction unit 260 may be configured to control the rise of the lifting cylinder 210 by sensing operation.

To this end, the rotation bar 250 is provided with an elevating control sensor 251 through a bracket or the like.

In addition, the upper end of the adsorption tube 262 may be configured to further include a sensor reaction table 265 that reacts with the lift control sensor 251 when the adsorption tube 262 rises.

That is, when the adsorption tube 262 rises, the lifting intermittent sensor 251 reacts with the sensor reaction table 265, and thus the lifting operation of the lifting cylinder 210 is possible.

The label input unit 270 is configured to enable supply of a label to the adsorption unit 260 in constituting the hot press 1 having the label supply structure of the present invention, and one side of the thermal compression unit 100 In the upper body 10 is configured to form the same vertical line as the adsorption unit 260.

At this time, with reference to FIG. 7, the label input unit 270 includes a support shaft 271 imported and installed above the main body 10.

In addition, the label input unit 270 includes a label mounting plate 272 in the form of a square plate that is horizontally formed at the upper end of the support shaft 271 to mount and mount the label.

At this time, guide grooves 273 and 273 ′ are configured to pass toward the center in all four directions corresponding to the four corners of the label holder 272.

In addition, the label input unit 270 is coupled to each of the guide grooves 273 and 273 ′ to allow adjustment of the gap along the guide grooves 273 and 273 ′. 275') is configured, and each spacing control bar 275, 275' is configured in a vertical bar shape, so that the label can be mounted on the label mounting plate 272 between the spacing control bars 275 and 275'. It becomes possible.

At this time, each of the spacing adjustment bars 275 and 275 ′ is configured to have a lower end supported on the upper portion of each of the guide grooves 273 and 273 ′ and protrude vertically upward, and the guide groove 273 ( 273') is formed to pass through the screw portion 276 is configured to be fastened and fixed with a nut (N) at the bottom of the label mounting plate 272.

That is, the label input unit 270 mounts a plurality of labels stacked on the label holder plate 272, but the gap adjustment bars 275 and 275' are provided in the guide groove 273 according to the size of the label to be attached. By adjusting the spacing through (273'), it enables a rigid fixed mounting.

On the other hand, in the hot press 1 having the label supply structure of the present invention, an ion generating device 300 for facilitating the attachment by modifying the surface of the fabric for labeling is provided with reference to FIGS. 1 to 3 again. It can be configured to include more.

At this time, the ion generating device 300 is first configured with an ion worktable 310 capable of mounting a fabric on one side of the body 10 at one side of the thermal compression unit 100, and the ion worktable 310 has an interior It is hollow and connected to a separate vacuum device (not shown in the drawing), and a plurality of through holes 311 are perforated in the upper portion to enable communication of air.

In addition, the ion generating device 300 includes an ion spraying unit 320 for spraying ions onto the ion working table 310.

At this time, the ion injection unit 320 is configured with a nozzle mount 321 first, and at this time, the nozzle mount 321 is configured to be able to move in X, Y, and Z axes.

On the other hand, in the present invention, the X, Y, and Z axis operation structure of the nozzle mount 321 is not limited, and an automatic operation structure or a screw shaft through an LM guide structure by a conventional motor and belt pulley operation is used. It will be possible to apply a variety of driving methods such as manual operation is possible.

In addition, the nozzle mount 321 receives ions generated from a separate ion generator (not shown in the drawing) installed under the main body 10 and sprays ions onto the fabric seated on the ion working table 310. The injection nozzle 322 is configured.

In addition, the ion generator 300 includes a joystick 330 that controls the automatic movement of the nozzle mount 321 or the operation of the ion spray nozzle 322 on the nozzle mount 321.

That is, when the vacuum device is operated while the fabric for surface modification is placed on the upper portion of the ion working table 310, the ion generating device 300 is applied with a vacuum force and the fabric is ionized through the through hole 311. It is adsorbed on the work table 310.

In addition, it is possible to modify the surface of the fabric by moving the nozzle mount 321 to a position to be modified through the selective movement of the X, Y, and Z axes and by spraying ions through the ion spray nozzle 322.

On the other hand, the heat press (1) having a label supply structure of the present invention can be configured to further include a fabric hanger part 400 capable of mounting fabric in performing the operation, and the fabric hanger part 400 is the main body It is constructed in the upper front of 10.

At this time, the fabric hook portion 400 is first, a pair of guide plates 410 are configured on both sides in the front upper portion of the body 10, each guide plate 410 will be described later with reference to Figs. A through-type guide groove 411 is configured in a symmetrical shape to guide the movement of the movable bar 430.

At this time, each of the guide grooves 411 is first constituted with a horizontal groove 412 forming a horizontal direction, and the rear end of the horizontal groove 412 is configured to form a locking groove 413 bent downward and forward. .

In addition, the fabric hanger part 400 is configured with a fixing bar 420 that can hang and store the fabric, and the fixing bar 420 has both ends of the fixing bar 420 in a state where both ends are spaced in front of the guide groove 411 to prevent interference. It is configured to be fixed by connecting the front of the guide plate 410.

In addition, the fabric hanger 400 is configured with a movable bar 430 that corresponds to the fixing bar 420 and moves along the guide groove 411.

At this time, the movable bar 430 is configured such that both ends thereof penetrate the guide grooves 411 on both sides and protrude to the outside of the guide plate 410.

In addition, the distal hook portion 400 is provided with a movable bar pressurizing stand 440 that allows the movable bar 430 to be forcibly moved to the front side of the guide groove 411, that is, to the front side of the horizontal groove 412.

At this time, the movable bar pressurizing table 440 is configured such that its intermediate portion is axially coupled to the guide plate 410 so as to be rotatable, and the rear thereof is a spring 441 to which the guide plate 410 is fixed, so that the front is fixed bar ( 420) is configured to rotate forcibly.

That is, the movable bar pressurization table 440 presses the front side while the movable bar 430 is located in the locking groove 413 and is fixed to the locking groove 413, and the operator is pressed to the movable bar 430. When placed in the horizontal groove 412 by applying an external force, the movable bar 430 is moved to the front side of the horizontal groove 412 by the elasticity of the spring 441, and the fabric hung on the fixing bar 420 is pressed and fixed. .

Hereinafter, the action of the hot press having the present invention label supply structure having the above configuration will be described in detail with reference to the accompanying drawings.

The heat press 1 having a label supply structure of the present invention with reference to FIGS. 1 to 9 is used to supply a label to the top of the fabric in order to attach a product label to the fabric surface such as mountaineering clothes or hats. It improves work efficiency and promotes worker safety.

For this, first, referring to FIG. 10, the operator may mount the fabric 20 stored in the fabric hanger 400 by placing the fabric 20 on the top of the thermocompression working table 110.

Thereafter, a label 30 to be attached is supplied to the upper portion of the mounted fabric 20, and the label 30 is supplied to the label supply means 200.

That is, the label supply means 200 refers to Figs. 4 to 6, first, the first rotating bar 250 is the adsorption unit 260 by the drawing operation of the horizontal rod 230a of the rotating cylinder 230 It is configured to achieve a state separated from (110), the lifting platform 220 is in a raised state by the lifting rod (210a) of the lifting cylinder (210) pulling in operation.

In addition, with reference to FIG. 7, a label 30 to be attached to the label input unit 270 is prepared, which is a label holding plate between a plurality of stacked labels 30 and space control bars 275 and 275'. It will be mounted on 272.

At this time, the label 30 is configured to have various sizes. In the present invention, by adjusting the spacing of the spacing adjustment bars 275 and 275' formed on the label holder plate 272 of the label input unit 270 It is possible to adjust the size of the label 30 and fix it by pressing the circumference.

Accordingly, when the label 30 is supplied with reference to FIG. 11, first, the lifting cylinder 210 is operated, but the lifting rod 220 descends when the lifting rod 210a is withdrawn, and thus the rotation bar 250 The adsorption unit 260 formed in) descends together, and at this time, the adsorption force is applied to the adsorption port 264 by the operation of the vacuum device so that the label 30 is adsorbed when it contacts the upper part of the label 30. .

At this time, in the process of adsorbing the label 30 as the adsorption tube 262 descends as described above, the adsorption tube 262 is in contact with the label 30 and rises at the same time. 265 is to react with the lifting intermittent sensor 251, the lifting cylinder 210 is operated to lift the lifting platform 220 and the label 30 adsorbed to the suction port 264 rises together.

Meanwhile, in the process of adsorbing the label 30 when the adsorption port 264 descends as described above, the adsorption tube 262 slides up and down inside the shaft tube 261, and the adsorption port 264 is a label When it is adsorbed on the upper part of (30), a predetermined sliding rise is made, so that the shock can be absorbed.

Thereafter, referring to FIG. 12, the rotation cylinder 230 is operated. When the horizontal rod 230a is pulled in by the operation of the rotation cylinder 230, the rear end of the rotation bar 250 is the shaft part 240 At the same time, the front end of the rotation bar 250, that is, the adsorption unit 260, is rotated to the upper portion of the thermocompression working table 110 while being rotated rearward.

The lifting cylinder 210 is operated, but when the lifting rod 210a is withdrawn, the lifting platform 220 descends, and the suction unit 260 formed on the pivoting bar 250 descends together. When released, the label 30 is seated on the upper portion of the fabric 20.

At this time, the adsorption tube 262 descends as described above and in the process of seating the label 30, the adsorption tube 262 is brought into contact with the worktable 110 and rises at the same time. 265 is to react with the elevator intermittent sensor 251, and by raising the elevator cylinder 210, the elevator platform 220 is raised.

Thereafter, the horizontal rod 230a is retracted and the rotation bar 250 is rotated and returned to the outside of the thermocompression working table 110 of the adsorption unit 260.

Thereafter, the heating plate 140 is lowered and attached to the fabric 20 and the label 30 by applying heat pressure to the fabric 20 and the label 30 as in a typical thermocompression bonding operation.

In this case, while the heating plate 140 is lowered and thermally pressurized as described above, the lifting cylinder 210 works together to perform the adsorption process of the label 30 for supplying the next label 30.

On the other hand, in the present invention, the supplying process of the label 30 has been described step by step, but this is only an example, and practically, an operation program built in the hot press 1 having the label supply structure of the present invention It will be natural that it is automatically operated by (shown).

That is, the hot press 1 having the label supply structure of the present invention as described above automatically supplies the label 30 in the process of attaching the label 30 to the fabric 20 by the thermal compression unit 100 As this becomes possible, work efficiency is further improved, such as reduction of working time due to the supply of prompt and accurate labels, and in particular, the worker's safety is secured because the worker does not need to supply labels individually.

On the other hand, in the case of attaching the label 30 to the fabric 20 as described above in the hot press 1 having the label supply structure of the present invention, when the fabric 20 is a water-repellent fabric coated with water, the attachment is easy. It is possible not to do so, by modifying the surface of the fabric for attaching the label 30, so that the label 30 can be easily attached, which is made possible by the ion generating device 300. .

For this, referring to FIG. 13, prior to labeling, the fabric 20 is placed on the ion working table 310 of the ion generating device 300 and vacuum-adsorbed through the through hole 311 In the operation of the joystick 330, the position of the ion spray nozzle 322 is adjusted and the surface of the fabric 20 is modified by spraying ions.

Accordingly, by performing the thermocompression of the label 30 in the thermocompression unit 100 as described above with respect to the modified position as described above, easy label attachment is possible.

As described above, the hot press having the label supply structure of the present invention improves work efficiency further, such as enabling easy supply of labels to the hot press for label attachment. This makes it easier and more robust to heat compression of the label.

100: thermocompression unit 110: thermocompression worktable
120: post 130: cylinder
140: heating plate
200: label supply means 210: lifting cylinder
211: mounting bracket 220: lifting platform
221: guide rod 230: rotating cylinder
231: cylinder bracket 240: shaft
250: rotation bar 251: lift intermittent sensor
260: adsorption unit 261: shaft pipe
262: adsorption tube 263: gully stone part
264: adsorption port 265: sensor reaction table
266: vacuum hose 270: label input unit
271: support shaft 272: label mounting plate
273,273': Guide groove 275,275': Spacing adjustment bar
276: threaded part
300: ion generator 310: ion worktable
311: through hole 320: ion injection unit
321: nozzle mounting table 322: ion spray nozzle
330: joystick
400: fabric hanger 410: guide plate
411: guide groove 412: horizontal groove
413: locking groove 420: fixing bar
430: movable bar 440: movable bar pressurization

Claims (5)

While elevating and operating at the top of the thermocompression bonding workbench 110 and the thermocompression bonding workbench 110 on which the fabric is mounted on the upper part of the main body 10, it is installed on the post 120 and is heated while lifting and lowering through the operation of the cylinder 130. In a heat press having a heat compression unit 100 made of a heating plate 140 for performing thermal compression by applying heat to the fabric mounted on the compression working table 110,
The configuration further comprises a label supply means 200 capable of automatically supplying a label to be attached to one side of the thermal compression unit 100,
The label supply means 200,
An elevating cylinder 210 having an elevating rod 210a mounted on an installation bracket 211 fixedly installed on the pillar 120 to operate up and down;
The lifting platform 220, which is connected to the front end of the lifting rod 210a, is moved up and down according to the operation of the lifting cylinder 210, and has a guide rod 221 vertically penetrating through the mounting bracket 211 on one side to guide the lifting and descending. ;
A rotating cylinder 230 protruding from one side of the lift platform 220 and having a horizontal rod 230a protruding through the cylinder bracket 231 and operating horizontally;
A shaft part 240 that is vertically formed in front of the hoisting platform 220 at the front side of the horizontal rod 230a to provide a horizontal rotational force;
The rear end is hinged to the front end of the horizontal rod 230a, the rear side is coupled to the shaft part 240, and the front side protrudes to one side of the thermocompression unit 100 and advances to the top of the thermocompression working table 110 when rotating. A rotating bar 250;
An adsorption unit 260 that is vertically formed at the front end of the rotating bar 250 and provides an adsorption force by operating a vacuum device; And
It is formed in the main body 10 at one side of the thermal compression unit 100 to store the labels stacked, and comprises a label input unit 270 that allows the labels stacked by the adsorption unit 260 to be discharged one by one, and ,
The adsorption unit 260,
A shaft pipe 261 vertically penetrating and protruding downward from the front end of the pivoting bar 250 and fixed to the pivoting bar 250;
The shaft pipe 261 penetrates and protrudes downward, and a spring (s) is burnt to have a downward elasticity from the inside, a locking protrusion 263 is formed around the top, and an elastic adsorption hole 264 is formed at the bottom. And, the through-type adsorption pipe 262 which is burnt spring (s) to have a downward elasticity in the inside of the shaft pipe 261; And
One end is connected to the upper end of the adsorption pipe 262 and the other end is connected to a vacuum device, and comprises a vacuum hose 266 for imparting air adsorption force to the adsorption port 264,
The rotation bar 250 is further formed with an elevating intermittent sensor 251 for controlling the rise of the elevating cylinder 210, and a sensor reaction table 265 that reacts with the elevating intermittent sensor 251 at the upper end of the adsorption tube 262. ) Is configured to be formed more,
The label input unit 270,
A support shaft 271 vertically installed on one side of the body 10;
A label mounting plate 272 formed on an upper end of the support shaft 271 and configured in a rectangular plate shape to mount a label, and guide grooves 273 and 273 ′ formed in all directions; And
Including a plurality of spacing adjustment bars 275 and 275 ′ that are formed at the bottom of each of the threaded portions 276 to pass through each of the guide grooves 273 and 273 ′ from the top and fasten the nuts (N) from the bottom. A heat press having a label supply structure, characterized in that it comprises.
delete delete The method of claim 1,
In the main body 10,
The configuration further comprises an ion generating device 300 for modifying the surface of the fabric for attaching the label,
The ion generating device 300,
An ion worktable 310 mounted on one side of the thermal compression unit 100 from the top of the main body 10, hollow inside and formed with a plurality of through holes 311 at the top, and connected to a vacuum device; And
Ions are mounted on a nozzle mounting table 321 operating in X, Y, and Z axes spaced apart from the top of the ion working table 310 to receive ions generated from the ion generator and spray the ions onto the fabric seated on the ion working table 310 Ion injection unit 320 having an injection nozzle 322; And
A hot press having a label supply structure, characterized in that it comprises a joystick (330) formed on the nozzle mount (321) to regulate movement of the nozzle mount (321) or injection of ions.
The method of claim 1,
The front upper portion of the main body 10 is configured to further include a fabric hanger 400 capable of storing the hanger of the fabric to be worked,
The fabric hanger 400,
Both sides of the main body 10 are protruding from both sides, and guide grooves 411 formed of locking grooves 413 extending downward and forward from the rear end of the horizontal groove 412 and the horizontal groove 412 are formed on each side. A pair of guide plates 410;
A fixing bar 420 having both ends connecting the front of both guide plates 410 without interference with the guide groove 411;
A movable bar 430 whose both ends are inserted and protruded into the guide groove 411 to move along the guide groove 411; And
The spring 441 is built up on the guide plate 410, and the rear is fixed to the guide plate 410, and the front supports the movable bar 430 and the movable bar 430 is supported by the spring 441 elasticity. A hot press having a label supply structure, characterized in that it comprises a movable bar pressurizing stand 440 to move to the front of the guide groove 411.

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