KR101368545B1 - Transforring apparatus for revolution and rotation and cooling apparatus of extruding rubber using the same - Google Patents

Abstract

The present invention relates to a cooling device for rubber products using a transfer device using revolution and rotation. The cooling device can cool rubber products while transferring the rubber products by rotating in a spiral direction and rotating by the revolutionary power by a shaft rotation. Moreover, the cooling device can rapidly cool rubber products which have a predetermined size (width and thickness), are formed in the shape of a sheet, and have a circular, oval, triangular, or rectangular cross section in a water cooling method and can minimize the installation space thereof.

Description

Transforring Apparatus for Revolution and Rotation and Cooling Apparatus of Extruding Rubber Using The Same}

The present invention relates to a rubber product cooling apparatus using a conveying device by revolution and rotation, and more particularly, by using a revolution and rotation conveying device for conveying a rubber product while rotating in a non-powered manner by the force of the revolution by the rotation of the shaft. A rubber product cooling apparatus.

In addition, the present invention can quickly cool a rubber product having a predetermined width and thickness, consisting of a sheet or cross-sectional shape of various shapes such as circular, elliptical, triangular, square, etc., and minimizes the installation area. It relates to a rubber product cooling apparatus using a transfer device by the revolution and rotation.

In general, the rubber material provided to produce various rubber products is usually supplied in the form of a band or sheet, for example, the rubber material in the form of a band or sheet is processed by processing the rubber raw material collected from the rubber tree, etc. It is extruded in the form of the sheet which has, and it winds up through a cooling process, and is supplied to an end customer.

Here, the cooling device for performing the cooling process is a facility for rapidly cooling the hot rubber product extruded from the melter with cooling water, the guide means for supplying the rubber product extruded from the melter to the water cooling treatment means; It consists of a structure including a water cooling treatment means filled with cooling water, air cooling treatment means for drying and cooling treatment at room temperature for a certain period, and winding means for winding the rubber product in a completely cooled and dried state.

Therefore, the rubber product extruded from the melter is supplied to the water cooling treatment means by the guide means, and the rubber product thus supplied is completely cooled while passing through the air cooling treatment means gradually after being first cooled by the cooling water for a predetermined time. It is wound up and packaged and shipped as a rolled product.

Guide, water-cooling, air-cooling, winding and packaging of the rubber product is generally carried out in a continuous process of the date form. In particular, the water cooling method is more efficient than the air cooling method, but requires a very long cooling water filling space required for water cooling. Therefore, only a small water cooling treatment section was formed and then a very long distance air cooling section, which is relatively easy to install and operate, was manufactured.

However, since the conventional cooling system adopts a cooling method combining a water cooling method and an air cooling method, there is a problem that the size of the device is very large and the installation space is also very largely occupied. Subsequently, the cooling efficiency is lowered, and as a result, since the moving speed of the rubber product must be set very slowly for sufficient cooling, there is a disadvantage in terms of productivity.

Korean Registered Patent No. 10-1175715 (Registered on August 14, 2012)

Technical problem to be solved by the present invention in order to solve the above-mentioned problems, the rubber product cooling by using the transfer device by the revolution and rotation while rotating the rubber product in the spiral direction while rotating in a non-powered by the force of the revolution by the rotation of the shaft Presenting the device.

In addition, another technical problem to be achieved by the present invention is a water-cooling method for a rubber product having a predetermined size (width and thickness) and configured in a sheet shape or a cross-sectional shape in various shapes such as circular, oval, triangular, square, etc. The present invention provides a rubber product cooling device using a conveying device based on an orbit and a rotating device that can be cooled quickly and minimize an installation area.

In addition, another technical problem to be achieved by the present invention is to determine the number of guide rails for moving the rubber product in the helical direction and the number of the tooth grooves of the first rotating body to be matched thereto according to the size (width and thickness) of the rubber product. Thus, to provide a rubber product cooling apparatus using a transfer device by the revolution and rotation can be applied to any rubber product having a variety of sizes (width and thickness).

The solution to the problem of the present invention is not limited to those mentioned above, and other solutions not mentioned can be clearly understood by those skilled in the art from the following description.

As a means for solving the above technical problem, the rubber product cooling apparatus according to the present invention, a cooling tank filled with a cooling water therein, a drum installed inside the cooling tank and rotates about a rotating shaft, Plates spaced apart from each other at a predetermined distance on one side and protrudingly arranged on one side of the plate, are eccentrically disposed about the center of the plate with a trajectory of a circle or an ellipse, and the ends are the same at predetermined intervals. One or two or more guide rails disposed on the shaft and radially disposed on one side of the drum, and tooth grooves engaged with the guide rail in a disk-shaped rotating body are formed along the circumferential direction, The tooth groove rotates (rotates) while the tooth groove moves along the guide rail by the rotation (rotation) of the drum. A first rotating body having a different angle of rotation per revolution of the second rotating body disposed on one side of the first rotating body and rotating together with the second rotating body opposite to the second rotating body on the other side of the drum; A third rotating body, a rotating member rotating between the second rotating body and the third rotating body, a rubber product wound while moving spirally on the rotating member, and disposed on one side of the cooling tank. An inlet device for introducing the rubber product into the cooling tank, a discharge device disposed on the other side of the cooling tank in a diagonal direction with the inlet device, and discharging the rubber product while discharging the rubber product from the cooling tank; Conveyor device for transporting the rubber product discharged from the discharge device, and is mounted to the end of the conveyor device and is applied in a zigzag form to collect the rubber product by a swing operation The swing lever and the rotation speed of the drum according to the width and thickness of the rubber product to control the time the rubber product is discharged from the cooling tank, the inlet device, the discharge device, the conveyor device, the An operation panel having a control unit for controlling the operation of the swing lever, a plurality of switches for controlling the operation of the rubber product cooling device, and a button for inputting data including the width and thickness of the rubber product, and the operation panel It may be configured to include a display screen for displaying the data input through, and displays the operation and device information of the rubber product cooling apparatus.
The second and third rotating bodies may be composed of one of a sprocket, a timing gear, a chain gear, and a spur gear, and the rotating member may be configured as a chain or a timing belt according to the second and third rotating bodies. The rubber product may have a predetermined width and thickness, may have a predetermined width and thickness, may be configured in a sheet form, or may have any one of circular, oval, triangular, and rectangular shapes in cross section.
Tooth grooves of the first rotating body are formed in plural at predetermined intervals according to the number of the guide rails, and when the two guide rails are two, four at 90 ° intervals, six at 60 ° intervals, and 40 ° intervals. It may be formed of any one of nine, when the guide rail is five may be formed of any one of 12 at 30 ° intervals, 15 at 24 ° intervals, 18 at 20 ° intervals.

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According to the present invention, a rubber product having a predetermined size (width and thickness) in the axial length direction and rotating in a non-powered manner by the rotational force by the rotation of the shaft and having various shapes such as sheet, circle, oval, triangle, square, etc. Can be transported

In addition, by continuously cooling the rubber product wound spirally on the drum by using the cooling water filled in the tank, it is possible to improve the cooling efficiency and increase the production speed.

In addition, the shape of the guide rail is improved and the overall height is changed according to the size (width and thickness) of the rubber product, and the number of grooves of the first rotating body engaged with the guide rail is changed to the number, shape and size of the guide rail. Various shapes (for example, 4, 6, 9, 12, 15, 18, etc.) to vary the angle of rotation of the first rotating body per rotation of the drum (for example, 120 °, 160 °) , 180 °, 240 °, etc.), the feeding distance of the rubber product can be changed according to the size of the rubber product.

In addition, it is possible to ensure smooth operation performance between the guide rail and the first rotating body without interference or jamming, and above all, it is advantageous in terms of the installation area and facility operation in the factory, such as to significantly reduce the overall size of the device. .

In addition, it has the effect that the rubber product is continuously cooled by the cooling water in the cooling tank can significantly improve the production speed, reduce the number of operating personnel, and can prevent contamination of the product itself while working safely.

In addition, since the first rotating body rotates without a force along the guide rail by the idle force of the rotating shaft to move the rubber product, it is possible to significantly reduce the electricity consumption. In particular, since the first rotating body is disposed radially around the rotating shaft, the installation space is significantly reduced, thereby improving the space utilization, and also having an easy installation work.

The effects of the present invention are not limited to those mentioned above, and other effects that are not mentioned will be clearly understood by those skilled in the art from the following description.

1 to 8 is a view of a rubber product cooling apparatus according to a first embodiment of the present invention,
1 is a plan view of a rubber product cooling apparatus,
2 is a side view of a rubber product cooling device,
3 is a front view of the rubber product cooling apparatus,
Figure 4 is a side view of the rubber product cooling apparatus,
5 is a partially cutaway perspective view of the rubber product cooling apparatus,
6 is a schematic perspective view showing a rotating device of a rubber product cooling device,
7 is a side cross-sectional view of a rubber product cooling device,
8 to 12 is a view of the rubber product cooling apparatus according to a second embodiment of the present invention,
8 is a perspective view of a simulator of a transfer device of a rubber product cooling device,
9 and 10 are perspective views of a simulator of the guide rail and the first rotating body of the transfer device,
11 is a plan view showing an embodiment of the guide rail of the rubber product cooling apparatus,
12 is a cross-sectional view taken along line AA ′ of FIG. 11.
13 is a plan view showing the configuration of a first rotating body of a rubber product cooling apparatus according to a third embodiment of the present invention.
14 is a plan view showing a configuration of a first rotating body of a rubber product cooling apparatus according to a fourth preferred embodiment of the present invention.
15 to 17 is a view of the rubber product cooling apparatus according to a fifth embodiment of the present invention,
15 is a plan view showing an embodiment of a guide rail of the rubber product cooling apparatus,
16 is a cross-sectional view taken along line BB ′ of FIG. 12;
17 is a plan view showing an embodiment of a first rotating body of the rubber product cooling apparatus.
18 and 19 are cross-sectional view showing a cross-sectional example of the guide rail of the rubber product cooling apparatus according to a preferred embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In order to clearly explain the present invention in the drawings, parts not related to the description are omitted, and similar parts are denoted by similar reference numerals throughout the specification.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

First embodiment

1 to 8 is a view of a rubber product cooling apparatus according to a first embodiment of the present invention, Figure 1 is a plan view of the rubber product cooling device, Figure 2 is a side view of the rubber product cooling device, Figure 3 is a rubber 4 is a front view of the product cooling device, FIG. 4 is a side view of the rubber product cooling device, FIG. 5 is a partially cutaway perspective view of the rubber product cooling device, FIG. 6 is a schematic perspective view showing a rotating device of the rubber product cooling device, and FIG. Side section of rubber product chiller.

As shown in FIGS. 1 to 7, the rubber product cooling apparatus 100 is provided with a cooling tank 110 filled with coolant therein, and is installed in the cooling tank 110 and has a rotation axis 120 as the center. The rotating drum 121, the plate 170 and the plate 170, which are spaced apart from each other by a predetermined distance on one side of the drum 121, and disposed on one side of the plate 171, each having an eccentric or circular trajectory First and second guide rails 171 and 172 disposed so as to be radially disposed on one side of the drum 121, and the first and second guide rails 171 and 172 by rotation (idle) of the drum 121. A plurality of first rotating body 130 to rotate while moving along the), the second rotating body 140 is disposed on one side of the first rotating body 130 and rotates together, and the drum 121 A plurality of third rotating body 150 and the second rotating body 140 and the third rotating body 150 disposed radially on the other side The rotating member 160 rotates therein, and the rubber product 10 wound around the rotating member while moving in a spiral shape. Here, the rubber product may have a predetermined size (width and thickness), and may be configured in a sheet form or in various shapes such as a circle, an oval, a triangle, a rectangle, and the like in a first embodiment. The product is shown as an example.

In addition, the rubber product cooling device 100 is disposed on one side of the cooling tank 110, the inlet device 180 for introducing the rubber product 10 into the cooling tank 110, and the cooling tank The drying device is disposed on the other side of the 110 in a diagonal direction with the inlet device 180 and removes moisture after applying the diluent 310 while discharging the rubber product 10 from the cooling tank 110. 300, the conveyor device 400 for conveying the rubber product 10 discharged from the drying apparatus 300, and the rubber product 10 is mounted to the end of the conveyor device 400 by a swinging operation. ) Includes a swing lever (450) loaded in the collection box (20) in a zigzag form.

In addition, the rubber product cooling apparatus 100 may include a controller, an operation panel, and a display screen, although not shown in the drawing. Here, the controller may control the time the rubber product 10 is discharged from the cooling tank 110 by controlling the rotation speed of the drum 121 according to the width and thickness of the rubber product 10, The operation of the inflow apparatus 180, the drying apparatus 300, the conveyor apparatus 400, and the swing lever 450 may be controlled. The operation panel may include a plurality of switches for controlling the operation of the rubber product cooling apparatus 100 and buttons for inputting data including a width and a thickness of the rubber product, and the display screen may include the operation panel. Through the input data can be displayed, the operation and device information of the rubber product cooling apparatus can be displayed.

The rubber product cooling device 100 is provided with a cooling tank 110 is filled with a predetermined amount of cooling water 114 for cooling the rubber product 10, the melter (1) on one side of the cooling tank 110 An inlet device 180 for introducing the rubber product 10 which is discharged and proceeds from the not shown) is installed, and the rubber product 10 cooled by the coolant is discharged on the other side of the cooling tank 110. Drying apparatus 300 is installed to. At this time, the inflow apparatus 180 and the drying apparatus 300 are located in a diagonal direction with each other.

The inlet device 180 enters the rubber product 10 in the hot melt state drawn out from the melt extruder (not shown) into the cooling tank 110 by the guide roller 181. Accordingly, the rubber product 10 starts to wind from one side and proceeds along a path that winds along the spiral direction and exits to the opposite side.

In this case, the cooling water 114 filled in the cooling tank 110 may be sufficient in an amount such that the drum 121 to be described later can be locked to a predetermined height. In this case, the height of the cooling water 114 may have a height of half or more or less than half of the cooling tank 110. The cooling tank 110 may be replaced or charged with a new coolant 114 at any time through the water supply valve 112 and the drain valve 113 installed on one side.

The drum 121 is installed inside the cooling tank 110, and the drum 121 is supported by the rotating shaft 120 rotatably fixed to both ends of the cooling tank 110, and the rotating shaft 120. ) Is rotated about the central axis.

The rotation of the rotary shaft 120 and the drum 121 is rotated by the drive motor 125, the drive motor 125 is installed outside the cooling tank 110 is the rotation shaft via the coupler 126. 126 is connected.

The drum 121 installed in this way is locked in a predetermined height (for example, 1/2 or more or less) of the total volume in the cooling water 114 filled in the cooling tank 110, and the rest is The state is exposed to the outside. Accordingly, the rubber product 10 wound on the drum 121 side (substantially wound on a rotating member to be described later) is repeatedly rotated in the air and the cooling water 114 by the rotation of the drum 121. As it is exposed, cooling takes place.

First and third rotating bodies 130 and 150 are disposed at ends of one side and the other side of the drum 121, and the rotating member 160 is installed between the second and third rotating bodies 140 and 150. have. The first and third rotary bodies 130 and 150 may be configured in a plurality of combinations arranged in a radial form while following the rotation axis 120 of the drum 121. The combination of the first and third rotary bodies 130 and 150 is disposed symmetrically on both sides with the drum 121 interposed therebetween. In addition, the first and third rotary bodies 130 and 150 are matched with each other one by one.

The first and third rotary bodies 130 and 150 may be installed in a structure supported by the brackets 122 and 123 which are installed along the circumference of the end of the rotary shaft 120.

The first rotating body 130 has a plurality of protrusions (gears of gears) are formed at the same interval on the disk-shaped rotating body, the second rotating body having a smaller size than the first rotating body 130 on one side 140 is disposed. In this case, the second rotating body 140 may be coupled to the first rotating body 130 or may be integrally formed with the first rotating body 130. Therefore, the second rotating body 140 is rotated together when the first rotating body 130 rotates. In this case, the second rotating body 140 may be composed of one of a sprocket, a timing gear, a chain gear, and a spur gear. The third rotating body 150 may be configured of one of the same sprocket, timing gear, chain gear, and spur gear as the second rotating body 140.

The second and third rotating bodies 140 and 150 are connected to each other by the rotating member 160 to rotate. The rotating member 160 may be configured as a chain or a belt according to the configuration of the second and third rotating bodies 140 and 150. For example, the rotating member 160 may be configured as a chain when the second and third rotating bodies 140 and 150 are configured with a sprocket or a chain gear, and the second and third rotating bodies 140 and 150 may be used. ) May be configured as a timing belt.

In addition, the rubber product cooling apparatus 100 has a "c" shape in the trajectory of the rotating member 160 in order to prevent the intermediate portion of the rotating member 160 from being bent by the weight of the rubber product 10. The bracket 124 may be mounted on a bracket fixed to the rotation shaft 120 to allow a uniform rotation operation without sagging of the rotation member 160.

One side of the drum 121 is spaced apart from the plate 170 at a predetermined distance. The plate 170 has a hole (see 174 of FIG. 12) for inserting the rotating shaft 120 at the center thereof, and two first and second guide rails 171 and 172 are disposed at one side thereof. . The first and second guide rails 171 and 172 may be arranged to protrude in a circular shape on one side of the plate 170, and may be eccentrically divided with a trajectory of a circle or an ellipse, respectively. In this case, the first and second guide rails 171 and 172 may be installed on the plate 170 by the support 173 or may be integrally formed with the plate 170. When the first and second guide rails 171 and 172 are installed as the support 173, a plurality of support 173 may be configured on one guide rail.

The first rotating body 130 is formed in a disk-like rotating body with protrusions (gears of teeth) or tooth grooves at equal intervals along the circumferential direction. The first rotating body 130 is rotated (idle) with the drum 121 while the drum 121 is rotated by the rotating shaft 120. In addition, the first rotating body 130 is such that the tooth groove between the protrusion (the teeth of the gear) and the protrusion is meshed with the first or second guide rails (171, 172) of the plate 170. Therefore, the first rotating body 130 rotates (rotates) along the first or second guide rails 171 and 172 of the plate 170 while rotating (rotating) by the rotation of the drum 121.

Tooth grooves formed in the first rotatable body 130 may be tapered on the front and rear sides, respectively, based on the direction in which the first or second guide rails 171 and 172 proceed. In contact with the first or second guide rails 171 and 172, in particular, when entering the rail side, friction with the rail can be prevented.

Substantially, the rotatable member 160, which is also a portion where the rubber product 10 is wound and moves the rubber product 10 in the axial direction to form a spiral wound, has the second and It is connected between the third rotating body (140, 150).

Accordingly, the rotation member 160 may be operated in the axial direction by the rotation (rotation) of the second and third rotation bodies 140 and 150, and eventually, the rubber product 10 may be wound while advancing in the axial direction. I can give it.

In particular, the first or second guide rails 171 and 172 are provided as a means for inducing rotation (rotation) of the first rotating body 130 to operate the rotating member 160.

The first or second guide rails 171 and 172 are parts for inducing rotation (rotation) of the first rotating body 130 through contact guides with teeth formed in the disc of the first rotating body 130. It is disposed on one side of the plate 170. The plate 170 is installed at one side of the cooling tank 110, and is disposed side by side in a vertical position at a predetermined distance to one side of the first rotating body 130.

In particular, the first and second guide rails 171 and 172 have a non-circular shape, for example, an ellipse trajectory, not a circular shape, and are separately mounted on the front surface of the plate 170 so as to be eccentrically opposite to each other. It is installed in a structure arranged over the section.

That is, referring to the front view of FIG. 11, based on the center of the plate 170, the first guide rail 171 is eccentrically below the center, and the second guide rail 172 is eccentrically above the center. Unlike the circular plate 170, the first and second guide rails 171 and 172 form a non-circular shape and are symmetrical to each other in an inclined direction with respect to the center of the plate 170.

At this time, the interval between the neighboring ends of the first and second guide rails 171 and 172 may be equal to the interval between the tooth grooves of the first rotating body 130, and thus the first rotating body 130 ) Is rotated while the first or second guide rails (171, 172) are guided through one tooth groove, and then proceeds to the end of the rail and transfers to the other rail through the next tooth groove. You will receive a rotation guide.

In addition, the first and second guide rails 171 and 172 may have a height difference within the entire section of each rail. That is, taking the first guide rail 171 as an example, the height gradually decreases from one end portion of the rail into which the first rotating body 130 enters to the middle portion of the rail, and then continues from the middle portion of the rail to the first guide rail 171. The guide rail 130 may have a height difference in a form in which the height gradually increases toward the other end of the rail from which the guide rail 130 extends. In addition, like the first guide rail 172, the first guide rail 172 may have the same height difference.

On the contrary, the first and second guide rails 171 and 172 gradually increase in height from one end portion of the rail into which the first rotating body 130 enters to the middle portion of the rail, and then continue from the middle portion of the rail. The guide rail 130 may have a height difference in a form in which the height gradually decreases toward the other end of the rail from which the guide rail 130 extends.

In addition, the first and second guide rails 171 and 172 may be formed at the same height in the entire rail section.

The first and second guide rails 171 and 172 which have a non-circular shape and have a difference in height, and optimize the shapes of the first and second guide rails 171 and 172, and also fit the shapes of the first and second guide rails 171 and 172. By setting the number of the tooth grooves of the 130 to an optimal number, the interference with the first and second guide rails 171 and 172 does not occur while the first rotating body 130 rotates while rotating (idling). Can be implemented. As a result, it is possible to secure excellent operating characteristics between the first rotating body 130 and the first and second guide rails 171 and 172. Above all, the size of the first rotating body 130 is a predetermined size. While maintaining the conveying distance of the rotating member 160 can be increased, a wide rubber product 10, for example, a rubber product 10 having a wide width of 500mm or more can be cooled without overlapping.

Subsequently, the rubber product 10 introduced into the cooling tank 110 through the inlet device 180 is fixed to the closest rotating member 160 by a separate fixing iron (not shown). In this state, when the driving motor 125 is operated, the rotating shaft 120 rotates to rotate the drum 121, and the first attached to the drum 121 according to the rotation of the drum 121. The rotating body 130 is rotated (idle) with the drum 121. At this time, the first rotating body 130 is in a state in which the tooth groove is engaged with the first and second guide rails (171, 172) of the plate 170. Therefore, when the first rotating body 130 rotates (idle) with the drum 121, the first rotating body 130 moves along the first and second guide rails 171 and 172 to rotate (rotate). ) Accordingly, the rotating member 160 rotates in the axial direction of the drum 121 by the rotation (rotation) of the first rotating body 130.

Therefore, the rubber product 10 fixed to the rotating member 160 is rotated (rotated) while the drum 121 rotates (idle), so that the rotating shaft (120) rotates in the axial direction. At the same time as the rotation of the rotation of the drum 121, that is, the rotating member 160 is wound while moving in a spiral shape. At this time, each of the rotating members 160 is rotated by the same length in the axial length direction at the same time as the rotation of the rotary shaft 120.

The operating principle is that the first and second guide rails 171 and 172 separately mounted to the plate 170 are divided into two sides so as to be eccentrically opposite from the center of the plate 170, respectively, and the first rotating body 130 is a state in which one tooth groove is engaged with the first and second guide rails (171, 172). Therefore, when the first rotating body 130 revolves simultaneously in the rotational direction of the shaft by the rotation of the rotating shaft 120, the first rotating body 130 by the eccentricity of the first and second guide rails 171, 172. ) Is sliding and rotating. The amount of eccentricity is coincided with the circumferential pitch of the first rotating body 130 at the point where the divided end portions of the first and second guide rails 171 and 172 are located, whereby the first rotation is caused by the rotation of the rotating shaft 120. The first rotating body 130 rotates as much as the eccentricity of the first and second guide rails 171 and 172, and reaches the end of one guide rail so that the end of the other guide rail and another tooth groove are engaged with each other to rotate in connection.

Accordingly, the first and second guide rails 171 and 172 divided by the divided eccentric shafts simultaneously rotate the plurality of first rotating bodies 130 by rotating and revolving the rotating shaft 120. Since the continuous rotation of the first rotating body 130 rotates the second rotating body 140 in conjunction with the first rotating body 130, when the rotating shaft 120 is rotated in turn, the rotating member ( 160 rotates at the same time as the revolution. Therefore, the rubber product 10 fixed to the rotating member 160 is wound while moving in a spiral shape along the axial direction by the simultaneous rotation of the drum 121 and the rotating member 160.

The rubber product 10 is rapidly cooled by being immersed in the cooling water filled in the cooling tank 110 while being wound in a spiral shape along the axial direction by the simultaneous rotation of the drum 121 and the rotating member 160. At this time, since the rubber product 10 moves while winding in a spiral shape, the time immersed in the cooling water 114 increases in proportion to the length of the rotating shaft 120, thereby cooling by the cooling water 114. The efficiency can be improved.

Subsequently, the rubber product 10 cooled in the cooling tank 110 is discharged to the drying apparatus 300. The drying apparatus 300 allows the rubber product 10 discharged from the cooling tank 110 to pass through the diluent 310 filled in the enclosure to bury the diluent 310 in the rubber product 10. . In this case, the diluent 310 may be composed of a powder in a liquid state or powder form in which water and a diluent (for example, powder, etc.) are mixed at a predetermined ratio. The diluent 310 serves to prevent the rubber products 10 from adhering to each other when the rubber product 10 is wound or loaded.

As shown in FIG. 4, the drying apparatus 300 includes a first driving roller 330 disposed on one side of the upper end of the body 301 and a second driving roller disposed on the other side of the upper end of the body 301. 380, the rubber product 10 moving through the first and second driving rollers 330 and 380, and the diluent 310 are disposed below one side of the first driving roller 330. The first air cylinder 320 is disposed above the housing and the upper portion of the housing and presses the rubber product 10 with the first guide roller 322 from above to pass through the diluent 310. And a second guide roller 361 disposed rotatably above the first and second driving rollers 330 and 380 and pressing the rubber product 10 at a predetermined angle from above. The two guide rollers 330 and 380 are disposed above the second guide roller 361 so as to be rotatable integrally with each other. At least one upper air injector 371 and 372 for drying the upper surface, and the second guide roller 361 and the upper air injectors 371 and 372 depending on whether the rubber product 10 is installed or operated, have a predetermined angle. At least one lower air injector 373,374 disposed below the second air cylinder 340 and the first and second driving rollers 330 and 380 to dry the lower surface of the rubber product 10. ) Is included.

In addition, the drying apparatus 300 further includes a lid 305 for opening and closing the upper portion of the body 201 by a third air cylinder (not shown) disposed on the side of the body 301.

The drying apparatus 300 sprays the high pressure air to the rubber product 10 transported by the first and second guide rollers 322 and 361 and the first and second driving rollers 330 and 380. Remove the lump and the water of the diluent 310, buried on the back of the (10) and to make the diluent 310 uniformly distributed.

The rubber product 10 discharged from the drying apparatus 300 is transferred to the swing lever 450 through the conveyor apparatus 400, and the swing lever 450 mounted at the end of the conveyor apparatus 400. ) Is loaded in a zigzag form in the collection box 20 while moving left and right.

As shown in FIG. 2, the conveyor apparatus 400 includes driving rollers 420 and 430 disposed at a predetermined distance on one side of the body 401, and driving rollers 440 on the other side thereof. A drive motor 410 for driving the drive rollers 420 and 430 is provided below. The swing lever 450 is installed at an end of the driving roller 440 in the direction in which the driving roller 440 is installed, and an air cylinder 460 is installed above the driving roller 430 to which the rubber product 10 moves. have. The air cylinder 460 presses the rubber product 10 moving above the driving roller 430 with a guide roller (not shown) at a predetermined pressure to smoothly move the rubber product 10.

As described above, the rubber product cooling apparatus 100 includes a circumferential surface (specific volume) of the drum 121 rotating the rubber product 10 entering the cooling tank 110 by the driving motor 125. As a result, it is wound around the rotating member 160 in a spiral shape. In this case, the first rotating body 130 disposed on one side of the drum 121 is guided along the first and second guide rails 171 and 172 while rotating (idle) with the drum 121. It will rotate. In addition, the second rotating body 140 coupled with the first rotating body 130 is rotated by the rotation of the first rotating body 130 to rotate the rotating member 160. The rotating member 160 is wound in a spiral shape while moving the rubber product 10 in the axial direction of the drum 121 while rotating between the second and third rotating bodies 140 and 150.

The rubber product 10 is wound in a spiral shape by the rotation of the drum 121 and is immersed in the cooling water 114 filled in the cooling tank 110 several times while being rotated, thereby cooling.

After the cooling process, the rubber product 10 is discharged through the drying apparatus 300 and the diluent 310 is buried in the rubber product 10, and then the upper air injectors 371 and 372 and the lower air injectors 373 and 374. ) To remove moisture after draining. Thereafter, the rubber product 10 discharged through the drying device 300 is transferred through the conveyor device 400 and loaded in a zigzag form in the collection box 20 by the swing lever 450.

As such, the rubber product 10 wound while moving to one side by the rotation of the drum 121 and the rotation of the rotating member 160 is quickly locked in the cooling water 114 filled in the cooling tank 110. In addition, since the rubber product 10 is wound in a spiral shape in proportion to the length of the drum 121, the rubber product 10 may be cooled, and thus the cooling time of the cooling water 114 may be relatively long. You can increase it.

Second Embodiment

8 to 12 is a view of a rubber product cooling apparatus according to a second embodiment of the present invention, Figure 8 is a perspective view of the simulator of the transfer device of the rubber product cooling apparatus, Figures 9 and 10 of the transfer apparatus FIG. 11 is a perspective view illustrating a simulator of a guide rail and a first rotating body, and FIG. 11 is a plan view illustrating an embodiment of a guide rail of a rubber product cooling apparatus, and FIG. 12 is a cross-sectional view taken along line AA ′ of FIG. 11.

As shown in FIGS. 8 to 12, the second embodiment of the rubber product cooling device is formed of four teeth grooves 211 of the first rotating body 210 at intervals of 90 °. Different from the embodiment and the rest of the configuration is the same.

The first rotating body 210 has four tooth grooves 211 formed at the same interval, that is, 90 ° intervals are formed in the disk-shaped rotating body, the size of the first rotating body 210 than the first rotating body 210 The small second rotating body 140 is arranged. In this case, the second rotating body 140 may be coupled to the first rotating body 130 or may be integrally formed with the first rotating body 130. Accordingly, the second rotating body 140 rotates together when the first rotating body 210 rotates. In this case, the second rotating body 140 may be composed of one of a sprocket, a timing gear, a chain gear, and a spur gear. The third rotating body 150 may be configured of one of the same sprocket, timing gear, chain gear, and spur gear as the second rotating body 140.

The second and third rotating bodies 140 and 150 are connected to each other by the rotating member 160 to rotate. The rotating member 160 may be configured as a chain or a belt according to the configuration of the second and third rotating bodies 140 and 150. For example, the rotating member 160 may be configured as a chain when the second and third rotating bodies 140 and 150 are configured with a sprocket or a chain gear, and the second and third rotating bodies 140 and 150 may be used. ) May be configured as a timing belt.

One side of the drum (see 121 of FIG. 1) is provided with a plate 170 spaced apart from the predetermined distance. The plate 170 has a hole (see 174 of FIG. 11) for inserting the rotating shaft 120 at the center thereof, and two first and second guide rails 171 and 172 are disposed at one side thereof. . The first and second guide rails 171 and 172 are protruded in a circular shape on one side of the plate 170, and are divided and eccentrically disposed about the center of the plate 170 with a trajectory of a circle or an ellipse, respectively. The ends are arranged to overlap on the same axis at predetermined intervals. In this case, the first and second guide rails 171 and 172 may be installed on the plate 170 by the support 173 or may be integrally formed with the plate 170. When the first and second guide rails 171 and 172 are installed as the support 173, a plurality of support 173 may be configured on one guide rail.

In addition, the first rotating body 210 is formed in the circumferential direction of the tooth groove 211 is meshed with the first and second guide rails (171, 172) a plurality of spaced apart at a predetermined interval depending on the number of the guide rails Can be formed. In this case, the first and second guide rails 171 and 172 have eccentric separation distances at both ends of the first and second guide rails 171 and 172 from the distance (circumferential pitch) between the tooth grooves 211 of the first rotating body 210.

The first rotatable body 210 is configured in such a state that the tooth groove 211 is inserted or engaged with the first and second guide rails 171 and 172, and the drum 121 is rotated by the drum 121. Rotate and rotate while rotating along the first and second guide rails 171 and 172. The first rotating body 210 may be operated in a manner that rotates 180 ° per one rotation of the drum 121.

In addition, when the tooth groove 211 formed in the first rotating body 210 is based on the direction in which the first and second guide rails 171 and 172 proceed, the taper may be formed at the front and rear sides, respectively. In this way, friction with the rail can be prevented when the rail contacts the rail, particularly when entering the rail.

Looking at the relationship between the first rotating body 210 and the first and second guide rails (171, 172), the first rotating body 210 is provided with four tooth grooves 211 which are arranged at intervals of 90 °, In addition, by improving the shape of the first and second guide rails (171, 172) in a non-circular shape in conjunction with the number of the tooth groove 211 and by varying the overall height, to secure a large conveying distance of the rotating member (160) Therefore, even when the first rotary body 210 of the small size rotates rapidly, the first and second guide rails 171 and 172 may be smoothly rotated without friction or pinching. As a result, the combination of the optimum shape of the first and second guide rails 171 and 172 and the optimum number of teeth of the first rotating body 210 can effectively cool the wide rubber product 10. There is an advantage that can process a wide range of rubber product 10 without increasing the size of.

On the other hand, in the second embodiment, like the first embodiment, the rubber product has a predetermined size (width and thickness) and is formed in a sheet shape or has various shapes such as circular, elliptical, triangular, and square in cross section. It can have

Third embodiment

13 is a plan view showing the configuration of a first rotating body of a rubber product cooling apparatus according to a third embodiment of the present invention.

As shown in FIG. 13, the third embodiment of the rubber product cooling device is formed in six teeth grooves 221 of the first rotating body 220 at intervals of 60 °. And the rest of the configuration is the same.

The first rotary member 220 has six tooth grooves 221 formed at equal intervals, that is, 60 ° intervals, on the disk-shaped rotary member, and shaft holes 222 are formed at the center thereof. A plurality of fastening holes 223 are formed around the hole 222. In addition, the first rotating body 220 has a second rotating body (see 140 of FIGS. 8 to 10) smaller in size than the first rotating body 210 is fastened to the fastening hole 223 on one side thereof. have. Accordingly, the second rotating body 140 rotates together when the first rotating body 210 rotates. In this case, the second rotating body 140 may be composed of one of a sprocket, a timing gear, a chain gear, and a spur gear. On the other hand, the second rotating body 140 may be formed integrally with the first rotating body 130.

The second and third rotating bodies 140 and 150 are connected to each other by the rotating member 160 to rotate. Here, the third rotating body 150 may be composed of one of the same sprocket, timing gear, chain gear, spur gear as the second rotating body 140, the rotating member 160 is the first It may be composed of a chain or a belt according to the configuration of the second and third rotary bodies (140,150). For example, the rotating member 160 may be configured as a chain when the second and third rotating bodies 140 and 150 are configured with a sprocket or a chain gear, and the second and third rotating bodies 140 and 150 may be used. ) May be configured as a timing belt.

One side of the drum (see 121 of FIG. 1) is provided with a plate 170 spaced apart from the predetermined distance. The plate 170 has a hole (see 174 of FIG. 11) for inserting the rotating shaft 120 at the center thereof, and two first and second guide rails 171 and 172 are disposed at one side thereof. . The first and second guide rails 171 and 172 are protruded in a circular shape on one side of the plate 170, and are divided and eccentrically disposed about the center of the plate 170 with a trajectory of a circle or an ellipse, respectively. The ends are arranged to overlap on the same axis at predetermined intervals. In this case, the first and second guide rails 171 and 172 may be installed on the plate 170 by the support 173 or may be integrally formed with the plate 170. When the first and second guide rails 171 and 172 are installed as the support 173, a plurality of support 173 may be configured on one guide rail.

In addition, the first rotatable body 220 may have tooth grooves 221 meshed with the first and second guide rails 171 and 172 in a circumferential direction, and may be formed at predetermined intervals according to the number of the guide rails. have. For example, six tooth grooves 221 may be formed at intervals of 60 °. In this case, the first and second guide rails 171 and 172 have eccentric separation distances at both ends thereof with a distance (circumferential pitch) between the tooth grooves 221 of the first rotating body 220.

The first rotating body 220 is configured such that the tooth groove 221 is inserted or engaged with the first and second guide rails 171 and 172, and the drum 121 is rotated by the drum 121. Rotate and rotate while rotating along the first and second guide rails 171 and 172. The first rotating body 220 may be operated in a manner to rotate 120 ° per one rotation of the drum 121.

Here, the first and second guide rails 171 and 172 are formed in two on the plate 170, and six tooth grooves 221 of the first rotating body 220 are formed at intervals of 60 °. When the first rotating body 200 rotates by 120 ° during one rotation of the drum 121, the rotating member 160 may move 180 mm.

The tooth groove 221 formed on the first rotating body 220 may have a taper on the front and rear sides thereof, respectively, based on the direction in which the first and second guide rails 171 and 172 are carried. Thereby, friction with a rail can be prevented at the time of contact with a rail, especially when it enters a rail side.

Looking at the relationship between the first rotating body 220 and the first and second guide rails (171, 172), there are six tooth grooves 221 disposed in the first rotating body 220 at an interval of 60 degrees, In addition, by improving the shape of the first and second guide rails (171, 172) in a non-circular shape in conjunction with the number of the tooth grooves (221) and at the same time varying the overall height, to secure a large conveying distance of the rotating member (160) Due to this, even when the first rotating body 220 of a small size rotates rapidly, the first rotating body 220 may be smoothly rotated without friction or pinching with the first and second guide rails 171 and 172. As a result, the combination of the optimal shape of the first and second guide rails 171 and 172 and the optimum number of teeth of the first rotating body 220 can effectively cool the wide rubber product 10. There is an advantage that can process a wide range of rubber product 10 without increasing the size of.

In the third embodiment, like the first embodiment, the rubber product may have a predetermined size (width and thickness) and may have various shapes such as a sheet, a circle, an ellipse, a triangle, and a rectangle.

Fourth embodiment

14 is a plan view showing a configuration of a first rotating body of a rubber product cooling apparatus according to a fourth preferred embodiment of the present invention.

As shown in FIG. 14, a fourth embodiment of the rubber product cooling device is formed in nine teeth grooves 231 of the first rotating body 230 at intervals of 40 °. And the rest of the configuration is the same.

The first rotary member 230 has nine tooth grooves 231 formed at the same interval, that is, 40 ° intervals, on the disk-shaped rotary member, and a shaft hole 232 is formed at the center thereof. A plurality of fastening holes 233 are formed around the hole 232. In addition, the first rotating body 230 has a second rotating body (see 140 of FIGS. 8 to 10) smaller in size than the first rotating body 230 is fastened to the fastening hole 233 on one side thereof. have. Therefore, the second rotating body 140 rotates together when the first rotating body 230 rotates. In this case, the second rotating body 140 may be composed of one of a sprocket, a timing gear, a chain gear, and a spur gear.

The second and third rotating bodies 140 and 150 are connected to each other by the rotating member 160 to rotate. Here, the third rotating body 150 may be composed of one of the same sprocket, timing gear, chain gear, spur gear as the second rotating body 140, the rotating member 160 is the first It may be composed of a chain or a belt according to the configuration of the second and third rotary bodies (140,150). For example, the rotating member 160 may be configured as a chain when the second and third rotating bodies 140 and 150 are configured with a sprocket or a chain gear, and the second and third rotating bodies 140 and 150 may be used. ) May be configured as a timing belt.

One side of the drum (see 121 of FIG. 1) is provided with a plate 170 spaced apart from the predetermined distance. The plate 170 has a hole (see 174 of FIG. 11) for inserting the rotating shaft 120 at the center thereof, and two first and second guide rails 171 and 172 are disposed at one side thereof. . The first and second guide rails 171 and 172 are protruded in a circular shape on one side of the plate 170, and are divided and eccentrically disposed about the center of the plate 170 with a trajectory of a circle or an ellipse, respectively. The ends are arranged to overlap on the same axis at predetermined intervals. In this case, the first and second guide rails 171 and 172 may be installed on the plate 170 by the support 173 or may be integrally formed with the plate 170. When the first and second guide rails 171 and 172 are installed as the support 173, a plurality of support 173 may be configured on one guide rail.

In addition, the first rotatable body 230 may be formed along the circumferential direction of the tooth groove 231 meshed with the first and second guide rails 171 and 172 at predetermined intervals according to the number of the guide rails. have. For example, nine tooth grooves 231 may be formed at intervals of 40 °. In this case, the first and second guide rails 171 and 172 have eccentric separation distances at both ends of the first and second guide rails 171 and 172 from the distance (circumferential pitch) between the tooth grooves 231 of the first rotating body 230.

The first rotating body 230 is configured in a state in which the tooth groove 231 is inserted or engaged with the first and second guide rails 171 and 172, and the drum 121 is rotated by the drum 121. Rotate and rotate while rotating along the first and second guide rails 171 and 172. The first rotating body 230 may be operated in a manner to rotate 160 ° per one rotation of the drum 121.

Here, the first and second guide rails 171 and 172 are formed in two on the plate 170, and nine tooth grooves 221 of the first rotating body 230 are formed at intervals of 40 °. If the first rotating body 230 rotates at 160 ° during one rotation of the drum 121, the rotating member 160 may move to 240 mm.

The tooth groove 231 formed in the first rotating body 230 may have a taper formed at the front and rear sides thereof, respectively, based on the direction in which the first and second guide rails 171 and 172 proceed. Thereby, friction with a rail can be prevented at the time of contact with a rail, especially when it enters a rail side.

Looking at the relationship between the first rotating body 230 and the first and second guide rails (171, 172), the first rotating body 230 is provided with nine tooth grooves 231 disposed at a 40 ° intervals, In addition, by improving the shape of the first and second guide rails (171, 172) in a non-circular shape and varying the overall height in connection with the number of the tooth grooves (231), to secure a large conveying distance of the rotating member (160) Therefore, even when the first rotary body 230 of a small size rotates rapidly, the first and second guide rails 171 and 172 may be smoothly rotated without friction or pinching. As a result, the combination of the optimum shape of the first and second guide rails 171 and 172 and the optimum number of teeth of the first rotating body 230 can effectively cool the wide rubber product 10. There is an advantage that can process a wide range of rubber product 10 without increasing the size of.

On the other hand, in the first to fourth embodiments of the present invention, when two guide rails are disposed on the plate 170, the tooth grooves of the first rotating bodies 130, 210, 220, and 230 are formed in plural at predetermined intervals along the circumferential direction. (First embodiment) or formed at four intervals of 90 ° (second embodiment), or formed six at 60 ° intervals (third embodiment), or formed nine at 40 ° intervals (fourth Embodiment).

In addition, although the present invention is not shown in the drawings, when two guide rails are disposed on the plate 170, the tooth grooves of the first rotating body may be formed in three at 120 ° intervals, or five at 72 ° intervals. It may be formed, or 7 formed at intervals of 51.4 °, 8 formed at intervals of 45 °, or 10 formed at intervals of 36 °.

Here, the tooth groove of the first rotating body may be determined according to the number of guide rails formed on the plate 170 and the size (width and thickness) of the rubber product.

Fifth Embodiment

15 to 17 is a view of a rubber product cooling apparatus according to a fifth embodiment of the present invention, Figure 15 is a plan view showing an embodiment of a guide rail of the rubber product cooling apparatus, Figure 16 is a BB 'of FIG. Sectional drawing of the line | wire, and FIG. 17 is a top view which shows the Example of the 1st rotating body of a rubber | gum product cooling apparatus.

In the fifth embodiment of the apparatus for cooling the rubber product, as illustrated in FIGS. 15 to 17, five guide rails 241 to 245 are formed on the plate 240, and the tooth grooves 251 of the first rotating body 250 are provided. ) Is formed of 12 pieces at intervals of 30 ° different from the first embodiment of the apparatus for cooling a rubber product, and the rest of the configuration is the same.

The first rotary member 250 is formed with twelve tooth grooves 251 formed at the same interval, that is, 30 ° intervals, in the disk-shaped rotary member, and the shaft hole 252 is formed at the center thereof. A plurality of fastening holes 253 are formed around the hole 252. In addition, the first rotating body 250 has a second rotating body (see 140 of FIGS. 8 to 10) smaller in size than the first rotating body 250 is fastened to the fastening hole 253 on one side thereof. have. Therefore, the second rotating body 140 is rotated together when the first rotating body 250 rotates. In this case, the second rotating body 140 may be composed of one of a sprocket, a timing gear, a chain gear, and a spur gear. Meanwhile, the second rotating body 140 may be formed integrally with the first rotating body 250.

The second and third rotating bodies 140 and 150 are connected to each other by the rotating member 160 to rotate. Here, the third rotating body 150 may be composed of one of the same sprocket, timing gear, chain gear, spur gear as the second rotating body 140, the rotating member 160 is the first It may be composed of a chain or a belt according to the configuration of the second and third rotary bodies (140,150). For example, the rotating member 160 may be configured as a chain when the second and third rotating bodies 140 and 150 are configured with a sprocket or a chain gear, and the second and third rotating bodies 140 and 150 may be used. ) May be configured as a timing belt.

One side of the drum (see 121 of FIG. 1) is provided with a plate 240 spaced apart from the predetermined distance. The plate 240 has a hole 247 through which the rotation shaft 120 can be inserted at the center thereof, and five first to fifth guide rails 241 to 245 are disposed at one side thereof. The first to fifth guide rails 241 to 245 are protruded in a circular shape on one side of the plate 240, and are eccentrically centered on the center of the plate 240 with a trajectory of a circle or an ellipse, respectively. Dividedly arranged, the ends are arranged so as to overlap on the same axis at predetermined intervals. In this case, the first to fifth guide rails 241 to 245 may be installed on the plate 240 by the support 246 or may be integrally formed with the plate 240. When the first to fifth guide rails 241 to 245 are installed as the support 246, a plurality of supports 246 may be configured on one guide rail.

In addition, the first rotating body 250 is formed in the circumferential direction of the tooth groove 251 to be engaged with the first to fifth guide rails (241 to 245) is formed at a predetermined interval according to the number of the guide rails Can be. For example, nine tooth grooves 251 may be formed at intervals of 30 °. In this case, the eccentric separation distances of the first to fifth guide rails 241 to 245 are equal to the distance (circumferential pitch) between the tooth grooves 251 of the first rotating body 250.

The first rotating body 250 is configured in such a state that the tooth groove 251 is inserted or engaged with the first to fifth guide rails 241 to 245, and the drum is rotated by the drum 121. While rotating with the first and fifth guide rails (241 to 245) while rotating with the rotation 121 (rotation). The first rotating body 250 may be operated in a manner to rotate 240 ° per one rotation of the drum 121.

Here, the first to fifth guide rails 241 to 245 are formed in five on the plate 240, and twelve tooth grooves 251 of the first rotating body 250 are formed at intervals of 30 °. When the first rotating body 250 rotates at 240 ° during one rotation of the drum 121, the rotating member 160 may move 360 mm.

The tooth groove 251 formed on the first rotating body 250 may have a taper on the front and rear sides, respectively, based on the direction in which the first to fifth guide rails 241 to 245 are carried. In this way, friction with the rail can be prevented when the rail contacts the rail, particularly when entering the rail.

Looking at the relationship between the first rotating body 250 and the first to fifth guide rails 241 to 245, there are twelve teeth 251 disposed on the first rotating body 250 at intervals of 30 °. In addition, by improving the shape of the first to fifth guide rails (241 to 245) in a non-circular shape in conjunction with the number of the tooth grooves 251 and at the same time varying the overall height, a large number of the rotating member 160 Even when the first rotary body 250 of the small size rotates rapidly due to the securing of the feeding distance, the first rotary body 250 may be smoothly rotated without friction or pinching with the first to fifth guide rails 241 to 245. As a result, a combination of the optimal shape of the first to fifth guide rails 241 to 245 and the optimum number of teeth of the first rotating body 250 can effectively cool the wide rubber product 10. There is an advantage that can process a wide range of rubber product 10 without increasing the size of the device.

Meanwhile, in the fifth embodiment of the present invention, when the guide rails are arranged in the plate 240 by five, the tooth grooves 251 of the first rotating body 250 will be described with an example in which 12 pieces are formed at 30 ° intervals. It was. However, the number of tooth grooves 251 of the first rotating body 250 may be formed in 15 pieces at 24 ° intervals or in 18 pieces at 20 ° intervals.

Here, the tooth groove of the first rotating body may be determined according to the number of guide rails formed on the plate 240 and the size (width and thickness) of the rubber product.

In addition, in the exemplary embodiment of the present invention, the case in which the guide rail formed on the plate is configured of two (first to fourth embodiments) and the case of five (five embodiments) has been described. 4, 6 or more can be configured. At this time, the number and spacing of the tooth grooves of the first rotating body is determined according to the number of the guide rail.

Cross section example of guide rail

18 and 19 are cross-sectional views showing examples of the guide rail of the rubber product cooling apparatus according to a preferred embodiment of the present invention.

As illustrated in FIGS. 18 and 19, the guide rail described in the embodiment of the present invention has a circular cross section (a), an ellipse (b), a triangle (c), a square (d), a rhombus (f), Parallelogram (g), tetrahedral (h), pentagonal (i), hexagonal (j), octagonal,, T-shaped (k), H-shaped (j), U-shaped, L-shaped and the like can be formed.

12 and 16, the guide rail may be fixed to the plates 170 and 240 by a plurality of guides 173 and 246. In addition, although not shown in the drawing, the guide rail may be formed by integrally molding the plates 170 and 240. In this case, the plates 170 and 240 and the guide rail may be made of a metal material including aluminum (Al) and an aluminum alloy.

The guide rail may be formed to have the same height or have a different height in the entire rail section. For example, the height gradually decreases from one end of the rail into which the first rotating body enters to the middle of the rail, and then gradually increases in height from the middle of the rail to the other end of the rail from which the rail advances. Can have a height difference.

The rubber product cooling device using the revolving and rotating device of the present invention configured as described above has a predetermined size (width and thickness) and is formed in a sheet shape or has a cross section while rotating without power due to the revolving force caused by the rotation of the shaft. The technical problem of the present invention can be solved by cooling the rubber product having any one of circular, elliptical, triangular and square shapes while rotating and transporting in a spiral direction.

It will be apparent to those skilled in the art that various modifications and changes can be made in the present invention without departing from the spirit or scope of the present invention as defined by the appended claims. It will be appreciated that such modifications and variations are intended to fall within the scope of the following claims.

Although the conveying apparatus of the present invention has been described by taking a rubber product cooling device as an example, the present invention is not limited thereto, and is configured by applying the same to a device for moving an object or a rubber product in the axial direction while rotating by a force revolving by rotation of a rotating shaft. can do.

10: Rubber product
100: rubber product cooling device
110: cooling tank 111: main panel
112: water supply valve 113: drain valve
114: coolant 120: rotating shaft
121: drum 122: bracket
123: bracket 124: bracket
125: drive motor 126: coupler
127: Belt member 130: First embodiment of the first rotating body
140: second rotating body 150: third rotating body
160: rotating member 170: plate
171: first guide rail 172: second guide rail
173: support 174: hole
180: inlet device 181: guide roller
210: second embodiment of the first rotating body 211: tooth groove
220: third embodiment of the first rotating body 221: tooth groove
222: shaft hole 223: fastening hole
230: fourth embodiment of the first rotating body 231: tooth groove
232: shaft hole 233: fastening hole
240: plate
241 to 245: first to fifth guide rails
246: support 247: hole
250: fifth embodiment of the first rotating body 251: tooth groove
252: shaft hole 253: fastening hole
300: drying apparatus 301: body
305: lid 310: thinner
320: first air cylinder 322: first guide roller
330: first driving roller 340: second air cylinder
360: pressing member 361: second guide roller
371: first air injector 372: second air injector
373: third air injector 374: fourth air injector
380: second drive roller 400: conveyor device
401 body 410 drive motor
420: drive roller 430: drive roller
440: drive roller 450: swing lever
460: Air Cylinder

Claims (8)

delete delete delete delete delete Cooling tank filled with coolant inside;
A drum installed inside the cooling tank and rotating about a rotating shaft;
Plates spaced apart from each other at a predetermined distance on one side of the drum;
One or two or more protrudingly disposed on one side of the plate, having a trajectory of a circle or ellipse, eccentrically disposed about the center of the plate, and having the ends overlapped on the same axis at predetermined intervals. Guide rails;
Is disposed radially on one side of the drum, the tooth groove which is engaged with the guide rail to the disk-shaped rotating body is formed along the circumferential direction, the tooth groove is moved along the guide rail by the rotation (idle) of the drum While rotating (rotating), the first rotating body having a different angle of rotation per rotation of the drum according to the number of the tooth groove;
A second rotating body disposed on one side of the first rotating body and rotating together;
A third rotating body disposed on the other side of the drum to face the second rotating body;
A rotating member rotating between the second rotating body and the third rotating body;
A rubber product wound around the rotating member while moving in a spiral shape;
An inlet device disposed on one side of the cooling tank and introducing the rubber product into the cooling tank;
A discharging device disposed on the other side of the cooling tank in a diagonal direction with the inflow device and discharging the rubber product while discharging the rubber product from the cooling tank;
A conveyor device for transferring the rubber product discharged from the discharge device;
A swing lever mounted at an end of the conveyor device and loaded in a zigzag form to collect the rubber product by a swing motion;
By controlling the rotation speed of the drum according to the width and thickness of the rubber product to control the time the rubber product is discharged from the cooling tank, the operation of the inlet device, the discharge device, the conveyor device, the swing lever A control unit for controlling each;
An operation panel having a plurality of switches for controlling the operation of the rubber product cooling device and buttons for inputting data including width and thickness of the rubber product; And
A display screen displaying data input through the operation panel and displaying operation and device information of the rubber product cooling apparatus;
Rubber product chiller comprising a.
The method according to claim 6,
The second and third rotating body is composed of one of a sprocket, a timing gear, a chain gear, a spur gear,
The rotating member is composed of a chain or a timing belt according to the second and third rotating bodies,
The rubber product is a rubber product cooling device having a predetermined width and thickness, has a predetermined width and thickness and is configured in the form of a sheet or in the shape of a cross section of a circle, an oval, a triangle, or a rectangle.
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