KR100723239B1 - Clamping system - Google Patents

Abstract

The present invention relates to a mold clamping device capable of minimizing the amount of hydraulic oil required for mold clamping and boosting operation, maximizing processing ease and space efficiency during manufacturing, and ensuring a stable mold opening and closing process.

The mold clamping device according to the present invention is provided on one side of the movable plate and the stationary plate, the movable plate and the stationary plate to be spaced apart in parallel to the plate conveying cylinder for selectively moving back and forth the movable plate, the movable plate, fixed plate At least one tie bar is fixed to any one of the at least one tie bar and the tie bar teeth are formed sequentially on the surface in the axial direction along the axial direction, and the movable plate located on the axis line of the tie bar or It is provided on the inside of the stationary plate, at least one shaped piston having a central opening in the center portion to enable the penetrating, movement of the tie bar, and is provided along the circumferential direction inside the mold piston, the fastening of the tie bar A plurality of fastening teeth which can be detachably attached to a groove part and a tie bar tooth, and the said other from the said fastening tooth A rotary plate provided at a position spaced in the axial direction of the bar, and one end of which is connected to the fastening tooth, and the other end of which is connected to the rotary plate, which is configured to transmit the rotational driving force of the rotary plate to the respective fastening teeth And a tooth guide member.

Molding, Injection, Molding, Mold

Description

Clamping system

1 is a front sectional view of a clamping device according to a first embodiment of the present invention;

Figure 2 is a perspective view of the tie bar and the clamping piston of the clamping device according to the present invention.

3a to 3c are reference views for explaining the operation of the mold clamping apparatus according to the present invention.

Figures 4a to 4c is a reference diagram showing the fastening process of the tie bar and the clamping piston of the clamping device of the present invention according to Figures 3a to 3c.

5A and 5B are cross-sectional views taken along line A-A 'of FIG. 3A and line B-B' of FIG. 3C, respectively.

Figure 6 is a reference diagram showing the rotation means of the rotating plate according to another embodiment of the present invention.

7 is a front sectional view of a clamping device according to a second embodiment of the present invention.

8 is a front sectional view of a clamping device according to a third embodiment of the present invention;

Description of the main parts of the drawing

100: mold clamping device 110: fixed plate

111: first mold 120: moving mold

121: second mold 122: central opening

130: tie bar 131: tie bar

132: fastening groove 140: shaped piston

141: fastening tooth seating groove 142: fastening tooth

142a: Tightening tooth protrusion 142b: Tie bar tooth groove

143: fastening guide member 144: first loss

145: second loss 150: rotating plate

151: fastening guide groove 152: fine gear

160: inlet piston 170: pinion

The present invention relates to a mold clamping device, and more particularly, a mold clamping device capable of minimizing the amount of hydraulic oil required for mold clamping and boosting operation, maximizing processing ease and space efficiency during manufacturing, and ensuring a stable mold opening and closing process. It is about.

The injection molding machine is largely composed of an injection apparatus and a mold clamping apparatus, and the mold clamping apparatus basically controls the opening and closing operations of the mold, that is, the mold opening and closing operations. In the state where the mold closing operation of the mold clamping device is completed, a predetermined molten material is injected from the injection apparatus into the mold. At this time, the molten material flowing into the mold is usually introduced at a high pressure. Therefore, the mold must be strongly fastened so that the mold is not opened by the high pressure molten material.

Most conventional clamping apparatuses are essentially provided with a predetermined fastening means for the strong fastening of the mold. However, the fastening means provided in the conventional mold clamping device is not suitable for high-speed operation or complicated processing process has the disadvantage of increasing the cost of the device.

The present invention has been made to solve the above problems, it is possible to minimize the amount of the hydraulic oil required for the mold clamping and boosting operation, to maximize the ease of processing and space efficiency during manufacturing and to ensure a stable mold opening and closing process The purpose is to provide a clamping device.

The mold clamping device according to the present invention for achieving the above object is provided on one side of the movable plate and the fixed plate, the movable plate and the fixed plate to be spaced apart in parallel to the plate transfer cylinder for selectively moving the movable plate back and forth; At least one tie bar having one end fixed to any one of the movable die and the fixed die, and having at least one tie bar and a tie bar having a concave-convex shape on a surface thereof in an axial direction, and at least one tie bar on the axis line of the tie bar It is provided on the inside of the movable plate or fixed plate, located in the at least one cylindrical piston having a central opening in the center portion to enable the penetration, movement of the tie bar, and provided in the circumferential direction on the inner side of the cylindrical piston And a plurality of fastening teeth capable of selectively detaching the fastening groove of the tie bar and the tie bar tooth. And a rotary plate provided at a position spaced apart from the fastening tooth in the axial direction of the tie bar, one end of which is connected to the fastening tooth, and the other end of which is connected to the rotary plate, thereby providing rotational driving force of the rotary plate to each of the fastening teeth. It characterized in that it comprises a fastening guide member to serve to deliver.

Preferably, the fastening tooth has a tie bar tooth groove and a fastening tooth protrusion having a shape corresponding to the tie bar tooth and the fastening groove portion of the tie bar.

Preferably, a fastening tooth seating groove is provided in an annular shape along the periphery of the center opening so that the plurality of fastening teeth is circumferentially seated in the fastening tooth seating groove.

Preferably, a plurality of fastening tooth guide grooves are provided on the rotary plate toward the center from the outside of the rotary plate, and the fastening tooth guide member is movable within each of the fastening tooth guide grooves.

Preferably, each of the fastening tooth guide grooves includes a groove start point and a groove end point, and the groove end point is located closer to the center of the rotating plate than the groove start point.

Preferably, each of the engagement guide grooves has a predetermined curvature.

Preferably, the hydraulic piston is provided on one side of the rotating plate to enable the rotation of the rotating plate by the operation of the inlet piston.

Preferably, a fine gear is formed on the rotating plate, and a pinion engaged with the fine gear is provided on one side of the rotating plate, and a driving motor for transmitting a driving force to the pinion is provided to drive the rotating plate. It rotates.

Preferably, each of the fastening teeth guide member is connected to each of the fastening teeth, as the fastening teeth guide member moves in the fastening teeth guide groove during the rotational movement of the rotating plate, each of the fastening teeth is the rotating plate Moving in the center direction or the radial direction of the fastening value and whether the tie bar is fastened.

According to a feature of the present invention, according to the method in which a plurality of fastening teeth are fastened to the tie bars by the rotational movement of the rotating plate, it is possible to simply configure the fastening-related device, and the inertia of the fastening teeth is not large, advantageous for high-speed operation and tie The processing of the bar can be simplified.

Hereinafter, a mold clamping apparatus according to the present invention will be described in detail with reference to the accompanying drawings. 1 is a front sectional view of a clamping apparatus according to a first embodiment of the present invention, Figure 2 is a perspective view showing a tie bar and a clamping piston of the clamping apparatus according to the present invention.

As shown in FIG. 1, the mold clamping apparatus 100 according to the first exemplary embodiment of the present invention includes a fixed mold 110 and a movable mold 120. The stationary plate 110 and the movable plate 120 are spaced apart and provided in parallel. The first mold 111 and the second mold 121 are provided on the surfaces of the fixed mold 110 and the movable mold 120 that face each other. The fixed mold 110 is provided with a first mold 111 having a yaw shape, and the movable mold 120 facing the first mold 111 has a second mold having an iron shape ( 121 may be provided.

The stationary plate 110 and the movable plate 120 are integrally connected by a tie bar 130, and the movable plate 120 is movable back and forth along the tie bar 130. That is, the tie bar 130 guides the movement of the movable die 120, and thus, the first die 111 of the fixed die 110 and the second die 121 of the movable die 120. Whether or not the mold is in progress. The tie bar 130 is composed of at least one or more fixed to one side of the fixed plate 110 or the movable plate 120, the driving force for the movement of the movable plate 120 is the movable plate 120 and It is obtained from the template transfer cylinder 101 provided on one side of the stationary plate (110).

On the surface of the tie bar 130, a plurality of tie bar teeth 131 are arranged at regular intervals along the axial direction of the tie bar 130. Between the tie bar 131 and the tie bar 131 is defined as a fastening groove 132. Here, the width of the tie bar 131 and the width of the fastening groove 132 may not have the same size.

Meanwhile, at least one mold piston 140 is provided inside the movable mold 120. Each of the clamping pistons 140 is positioned on the axis line of the tie bar 130, and a central portion of each of the clamping pistons 140 is opened to allow penetration of the tie bars 130.

The inside of each of the mold piston 140 is provided with a coupling tooth seating groove 141 which is a space in which the coupling tooth 142 to be described later is seated. The fastening tooth seating groove 141 may be in spatial contact with the central opening 122 of the body piston 140, and may be implemented in a ring shape along the circumference of the central opening 122. A plurality of fastening teeth 142 are seated and provided in the fastening tooth seating groove 141 in a circumferential direction, and each of the fastening teeth 142 is a tie bar tooth 131 and a fastening groove part of the tie bar 130. A fastening tooth protrusion 142b and a tie bar groove 142a having a shape corresponding to 132 may be provided. That is, on the surface of the fastening tooth 142, the tie bar groove 142a and the fastening tooth protrusion 142b having the uneven shape may be repeatedly arranged in the axial direction of the tie bar 130. Of course, the fastening tooth 142 may be configured with only one fastening protrusion protrusion 142b without the tie bar groove 142a.

On the other hand, the rotary plate 150 is provided at a position spaced apart in the axial direction of the tie bar 130 from the fastening tooth 142. The rotary plate 150 may be rotated by a predetermined driving means. Specifically, as shown in FIG. 1, the hydraulic plate 160 may be connected to one side of the rotary plate 150 to rotate the rotary plate 150. 6 or a predetermined drive in which a fine gear 152 is formed around the rotating plate 150 and a pinion 170 engaged with the fine gear 152 is provided. The rotating plate 150 may be rotated through a motor (not shown). Here, the central opening 122 is provided at the central portion of the rotating plate 150 as in the clamping piston 140 to allow the tie bar 130 to penetrate and move.

A plurality of fastening tooth guide grooves 151 having a predetermined length are formed on the rotating plate 150, and the fastening tooth guide member 143 is positioned in each of the fastening tooth guide grooves 151, so that the fastening tooth guide member is positioned. 143 is movable in the space in the fastening guide groove 151. A description of the movement of the fastening tooth guide member 143 will be described later.

Each of the fastening tooth guide members 143 is fixed and supported on one side of the respective fastening teeth 142. That is, the fastening tooth guide member 143 has a number corresponding to the number of the plurality of fastening teeth 142 provided in the fastening tooth seating groove 141 in the circumferential direction, and each of the fastening tooth guide members The fastening tooth guide groove 151 at which one end of the 143 is positioned is also provided in the rotating plate 150 by the number corresponding to the number of the fastening teeth 142. Meanwhile, each fastening guide groove 151 provided on the rotating plate 150 may have a predetermined length, and thus a groove starting point 151a and a groove ending point 151b may be defined. The groove ending point 151b may be defined. ) Is located closer to the center of the rotating plate 150 relative to the home starting point 151a. In addition, each of the fastening tooth guide groove 151 is preferably formed to have a predetermined curvature.

As described above, the rotating plate 150 may be rotated by a predetermined driving means, and each of the coupling tooth guide members 143 may rotate in the coupling tooth guide groove 151 by the rotation of the rotating plate 150. Movement in, i.e., movement between the home start point 151a and the home end point 151b becomes possible. In addition, the respective fastening tooth guide members 143 are connected to and fixed to the respective fastening teeth 142, and thus the fastening teeth 142 are also moved when the respective fastening tooth guide members 143 are moved. . At this time, the fastening tooth guide groove 151 is formed so that the groove starting point 151a and the groove end point 151b are not positioned at the same distance from the center of the rotating plate 150, so that the fastening teeth of the fastening guide member 143 The fastening tooth 142 moves in the direction of contraction or expansion with respect to the center of the rotating plate 150 during the movement in the guide groove 151. Specifically, when the fastening tooth guide member 143 moves from the home start point 151a to the home end point 151b, the fastening tooth 142 is formed by the fastening tooth seating groove 141 in the clamp piston 140. The movement in the circumferential direction is moved in the direction toward the center of the rotating plate 150 in a constrained state, when the fastening tooth guide member 143 moves from the groove end point 151b to the groove start point 151a. The fastening tooth 142 moves in a direction radiated from the center of the rotating plate 150. Here, when the fastening tooth 142 moves in the direction toward the center of the rotating plate 150, the fastening tooth protrusion 142b of the fastening tooth 142 fits into the fastening groove 132 of the tie bar 130. The tie bar tooth groove portion 142a of the fastening tooth 142 is engaged with the tie bar tooth 131 of the tie bar 130, so that the tie bar 130 and the clamping piston 140 can be fastened.

As the fastening tooth guide member 143 is moved by the rotation of the rotating plate 150, although not shown in the drawing, the moving space of the fastening tooth guide member 143 should be secured inside the clamp piston 140. For reference, the rotating plate 150 may be provided inside the mold piston 140 in addition to the outside of the mold piston 140 as in the above-described embodiment, which is provided inside the mold piston 140. In this case, a space (not shown) corresponding to the shape of the rotating plate 150 is provided in the mold piston 140.

On the other hand, one side of the mold piston 140 is provided with a first oil chamber 144 and a second oil chamber 145. The first oil chamber 144 is a space in which high-pressure hydraulic oil is supplied, and when hydraulic oil is supplied to the first oil chamber 144, mold clamping between the first mold 111 and the second mold 121 is performed by the pressure of the hydraulic oil. This can be solidified. On the other hand, the second oil chamber 145 is a space in which the hydraulic oil of low pressure is supplied, and when the hydraulic oil is supplied to the second oil chamber 145, the backward movement of the clamp piston 140 becomes possible.

In addition to the clamping apparatus according to the first embodiment of the present invention having the above configuration, the present invention provides a clamping apparatus having various modified configurations. For example, referring to the clamping apparatus according to the second exemplary embodiment of the present invention, as shown in FIG. 7, the tie bar 130 is fixed to the movable plate 120, and the clamping piston 140 and the fastening tooth 142 are shown. And the rotating plate 150 and the like is provided in the stationary plate (110). Compared with the clamping device according to the first embodiment, the clamping piston 140, the fastening tooth 142, the rotating plate 150, and the like, which are provided in the moving mold plate 120 of the clamping device according to the first embodiment, are described. It can be seen that the fastening related members and the boosting related members such as the first and second oil chambers 144 and 145 are provided in the stationary plate 110 of the second embodiment. That is, according to the first embodiment and the second embodiment, a fastening-related member such as the clamping piston 140, the fastening tooth 142, the rotating plate 150, and the like, and the pressure of the first and second oil chambers 145, etc. may be increased. The associated member may be selectively provided at any one of the movable die 120 and the stationary die 110, but the function and role of the fastening related member and the boosting related member are not changed at any position.

According to the clamping apparatus of the third embodiment of the present invention in addition to the first and second embodiments, as shown in FIG. 8, the fastening teeth 142 and the rotating plate 150 are provided in the movable die 120. The clamp piston 140, the first and second oil chambers 145, and the like may be provided in the stationary plate 110. Also in the third embodiment, the functions and roles of the respective components are the same as those in the first and second embodiments.

In the above description, the mold clamping apparatus according to the first, second and third embodiments of the present invention has been described as an example of being applied to an injection molding machine. However, the mold clamping apparatus according to the present invention is a general industrial apparatus requiring mold clamping in addition to the injection molding machine. Applicable to, of course.

On the other hand, the operation of the mold clamping apparatus according to the present invention having the configuration as described above is as follows. For reference, the operation description of the mold clamping apparatus is based on the mold clamping apparatus according to the first embodiment of the present invention. Figures 3a to 3c is a reference diagram for explaining the operation of the clamping apparatus according to the present invention, Figures 4a to 4c shows the fastening process of the tie bar and the clamping piston of the clamping apparatus of the present invention according to Figures 3a to 3c. 5A and 5B are cross-sectional views taken along line AA ′ of FIG. 3A and BB ′ of FIG. 3C, respectively.

The operation of the mold clamping apparatus according to the present invention is largely divided into a mold opening state in which the mold is released and a mold closing state in which the mold is fastened. First, the state of mold opening is as follows. The mold opening state is a state in which the mold is released as described above, and as shown in FIG. 3A, the first mold 111 of the fixed mold 110 and the second mold 121 of the movable mold 120 are separated from each other. Is located. At this time, the tie bar 130 forms a state passing through the mold piston 140 and the central opening 122 of the rotating plate 150 of the movable die 120.

In the mold opening state, the mold closing process is performed. The mold closing process may be classified into a high speed transfer process, a fastening process, and a boosting process.

First, in the high speed transfer process, the movable die 120 moves the tie bar 130 by the die transfer cylinder 101 provided at one side of the movable die 120 and the fixed die 110 in the mold opening state. Accordingly, it refers to a process of moving at high speed toward the stationary plate 110. Through the high-speed transfer process, the second mold 121 of the movable die 120 and the first mold 111 of the stationary die 110 are close to each other, as shown in FIG. 3B, but not in contact with each other. do. That is, the second mold 121 of the movable mold 120 and the first mold 111 of the fixed mold 110 may have a fine distance when the fixed transfer process is completed to prevent mold damage due to rapid mold fastening. spaced while maintaining d).

On the other hand, when the high-speed transfer process is completed as shown in Figure 4b the fastening tooth 142 is located in the fastening tooth seating groove 141 of the clamping piston 140, and also the fastening tooth 142 The fastening tooth guide member 143 connected to the is positioned at the groove starting point 151a of the fastening tooth guide groove 151.

The fastening process is performed in a state where the high speed transfer process is completed. The fastening process refers to a process in which the tie bar 130 and the clamping piston 140 are fastened. To this end, first, the rotating plate 150 is rotated by using a predetermined driving means. Specifically, the hydraulic piston 160 may be connected to one side of the rotating plate 150 to rotate the rotating plate 150 (see FIG. 1) or to form a fine gear 152 around the rotating plate 150. And the pinion 170 engaged with the fine gear 152, the rotating plate 150 may be rotated through a predetermined driving motor (see FIG. 6).

As shown in FIGS. 3C, 4C, and 5B, each of the fastening guide members 143 is rotated by the rotation plate 150, and thus the end of the groove is defined from the groove starting point 151a of the fastening guide guide groove 151. 151b). At this time, as described above, since the groove end point 151b of the coupling tooth guide groove 151 is closer to the center of the rotating plate 150 than the groove starting point 151a, the coupling tooth guide member 143 is It moves toward the center from the outside of the rotating plate (150). Accordingly, each of the fastening teeth 142 connected to each of the fastening tooth guide members 143 moves toward the center axis of the tie bar 130, and finally, the fastening teeth of the fastening teeth 142. The protrusion 142b is engaged with the fastening groove 132 of the tie bar 130, and the tie bar groove 142a of the fastening tooth 142 is engaged with the tie bar 131 of the tie bar 130. The fastening operation of the tie bar 130 and the clamping piston 140 is completed.

In the state in which the fastening between the tie bar 130 and the clamping piston 140 is completed, a boosting process is performed. First, when high pressure hydraulic oil is supplied to the first oil chamber 144 provided on one side of the clamping piston 140, a load by the hydraulic pressure of the hydraulic fluid is applied to the clamping piston 140, and finally, the movable mold plate ( It is delivered to the second mold 121 of 120. As a result, the first mold 111 of the first fixed mold 110 and the second mold 121 of the movable mold 120 are fastened, and for reference, the high pressure hydraulic oil flows into the first oil chamber 144. The movable plate 120 may be moved fine forward.

The mold closing process is completed through the above series of processes, that is, the high speed transfer process, the fastening process, and the boosting process. Meanwhile, the mold opening process after the mold closing process may be performed in the reverse order. Specifically, after the hydraulic oil of the first oil chamber 144 is discharged, low pressure hydraulic oil is supplied to the second oil chamber 145. After moving the clamping piston 140 backward, the rotating plate 150 is rotated to release the fastening state between the fastening tooth 142 and the tie bar 130. At this time, when the fastening state between the fastening tooth 142 and the tie bar 130 is released, the fastening tooth guide member 143 is a groove starting point 151a from the groove end point 151b of the fastening tooth guide groove 151. The fastening tooth 142 is moved to the fastening tooth seating groove 141 of the mold piston 140.

As described above, the operation of the mold clamping apparatus as described above is based on the mold clamping apparatus according to the first embodiment of the present invention, but the mold clamping process is also performed in the mold clamping apparatus according to the second and third embodiments. The high speed transfer process, the fastening process, and the boosting process may be applied in the same manner.

The clamping device according to the present invention has the following effects.

By adopting a method in which a plurality of fastening teeth are fastened to the tie bar by the rotational movement of the rotating plate, the fastening-related device can be simply configured and the inertia of the fastening teeth is not large, which is advantageous for high speed operation and simplifies the processing of the tie bar. Can be. In addition, as the process of boosting the pressure using a small amount of hydraulic oil has the advantage of high energy efficiency and a small installation area of the device due to the small size of the oil chamber and the hydraulic piston storing the hydraulic oil.

In addition, as the high-speed transfer process and the boosting process are separated, the transfer speed for mold opening and closing is fast, and uniform mold clamping force can be applied to the entire surface of the mold when the mold is fastened, thereby improving work reliability.

Claims (9)

A movable plate and a fixed plate spaced apart from each other and arranged in parallel; A template transfer cylinder provided on one side of the movable plate and the fixed plate to selectively move the movable plate back and forth; At least one tie bar having one end fixed to any one of the movable plate and the fixed plate, the fastening groove having a concave-convex shape on the surface along the axial direction and the tie bar sequentially arranged; At least one mold piston provided on an inner side of the movable plate or the stationary plate positioned on an axis line of the tie bar, and having a central opening formed at a central portion thereof to allow the tie bar to penetrate and move; A plurality of fastening teeth provided along the circumferential direction of the clamping piston and capable of selectively detaching the fastening groove of the tie bar and the tie bar teeth; A rotating plate provided at a position spaced apart from the fastening tooth in the axial direction of the tie bar; One end is connected to the fastening teeth, the other end is made to include a fastening tooth guide member which is connected to the rotating plate to transfer the rotational driving force of the rotating plate to each of the fastening teeth, A plurality of fastening tooth guide grooves are provided on the rotating plate toward the center from the outside of the rotating plate, and the fastening tooth guide member is movable within each of the fastening tooth guide grooves. Each of the fastening tooth guide members is connected to each of the fastening teeth, and as the fastening tooth guide member moves in the fastening tooth guide groove during the rotational movement of the rotating plate, the respective fastening teeth of the fastening teeth guide center direction or Moving device in the radial direction, characterized in that the fastening device and the tie bar is fastened. The clamping device of claim 1, wherein the fastening teeth have a tie bar groove and a fastening tooth protrusion having a shape corresponding to the tie bar teeth and the fastening groove of the tie bar. According to claim 1, wherein the inner side of the cylindrical piston which is in spatial contact with the central opening is provided with a fastening tooth seating groove in a ring shape along the circumference of the central opening so that a plurality of fastening teeth in the circumferential direction is seated in the fastening tooth seating groove. Clamping apparatus characterized in that the. delete delete delete The mold clamping device of claim 1, wherein a hydraulic piston is provided at one side of the rotary plate to enable rotation of the rotary plate by the operation of the inlet piston. According to claim 1, wherein the fine gear is formed on the rotating plate, the pinion which is engaged with the fine gear on one side of the rotating plate is provided with a drive motor for transmitting a driving force to the pinion is driven by the drive motor Molding apparatus, characterized in that the rotating plate is rotated. delete

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