KR20200107177A - Position alignment apparatus - Google Patents

Abstract

The present invention relates to a position alignment device which can align a position by accurately rotating an object even for the object with a top cover having an irregular shape. To this end, the position alignment device comprises: a clamping unit which holds the object moving along a conveyor; a rotational alignment unit which rotates the object held by the clamping unit in a circumferential direction with respect to a central axis and aligns the object in one direction; and an upper end support unit located above the object to support an upper end when the object rotates. The upper end support unit includes: an upper end block connected to a plate and positioned at the upper end of the object; and a ball installed at intervals in an arc shape on the front of the upper end block and protruding from the front of the upper end block to freely rotate.

Description

Position alignment device {POSITION ALIGNMENT APPARATUS}

The present disclosure relates to a positioning device.

For example, in the process of transferring a cylindrical object such as a beverage container, a rotational alignment device has been developed and used in order to uniformly align the direction of the object.

The rotational alignment device has a structure in which the object to be conveyed along the conveyor is gripped and rotated so that the object is directed in a predetermined direction.

The rotational alignment device enables a plurality of objects to be constantly directed in the same direction. Through the rotational alignment device, it is possible to improve the efficiency of processing the object in the subsequent process.

Recently, as various types of containers have been developed according to the preferences of consumers, the development of a new position alignment device is required. In the case of a container having an irregularly shaped top cover, a positional alignment failure occurs because the container is not properly rotated with a conventional device.

In addition, when dew forms on the surface of the container according to the contents contained in the container, there is a problem that a sensing error occurs due to slip or scattering of dew, and thus the position is not properly aligned.

In addition, the conventional device has low precision due to the cam driving method, and since the positions of all components must be adjusted one by one when resetting, the work is difficult and time consuming.

Accordingly, improving the structure of the conventional positioning device to more accurately position objects of various shapes and conditions can provide many advantages to users.

An object of the present invention is to provide a position alignment device capable of aligning the position by accurately rotating the object even for an object having an irregular shape top cover.

The present object is to provide a position alignment device capable of precisely aligning an object by improving the conventional cam driving method to facilitate resetting and to drive more precisely.

The present task is to provide a position alignment device capable of accurately rotating an object to align its position regardless of dew formation on the object surface.

The position alignment device of this embodiment may have a structure that is disposed on one side of a conveyor that transports an object having a circular horizontal cross-section and rotates the object in a circumferential direction with respect to a central axis to face a certain direction.

The position alignment device includes a clamping unit for gripping an object to be moved along the conveyor, a rotational alignment unit for rotating the object gripped by the clamping unit in a circumferential direction with respect to a central axis to align in one direction, and a position on the top of the object Thus, it may include an upper end support for supporting the upper end when the object is rotated.

The clamping unit includes plates disposed on both sides of the conveyor width direction, a driving unit for moving each of the plates in a moving direction of the conveyor and in the width direction of the conveyor, and a roller installed on each plate and contacting the side of the object when the plate is moved by the driving unit I can.

The driving unit is disposed in a direction perpendicular to the conveyor to move the plate in a direction perpendicular to the conveyor, and the first linear motor is disposed in a direction parallel to the conveyor, and the first linear motor is installed to move the plate in a direction parallel to the conveyor. It may include a second linear motor to move to.

The rotation alignment unit is connected to at least one of the rollers installed on the plate to rotate the roller, and a sensor unit installed on the plate and configured to detect a reference mark formed on the side of the object to control rotational driving of the rotation drive unit. Can include.

The sensor unit includes a sensor that detects a reference mark, and a barrel installed on the front of the bracket on which the sensor is installed, protruding forward, and having an open front surface, and the sensor and the barrel are arranged to be inclined downward toward the object with respect to the horizontal plane Can be

The roller includes two support rollers installed on one plate and supporting the object at two spaced apart along the circumferential direction, and a rotation roller installed on the other plate to contact the object and rotate the object, the It may be a structure that supports three points of an object.

It may further include an auxiliary roller that is spaced apart from the rotating roller and is rotatably installed on the plate and prevents separation of the object.

The rotating roller may have a structure in which a plurality of rolls are stacked along an axial direction to contact a plurality of contact points at intervals on the side of the object.

The upper support portion may include an upper block connected to the plate and positioned at the upper end of the object, and a ball installed at intervals in an arc shape on the front of the upper block and protruding from the front of the upper block to freely rotate.

The upper support portion may have a structure in which the balls are alternately arranged along an arc having a relatively large diameter and an arc having a relatively small diameter.

The upper support portion may further include an elastic portion for applying an elastic force to the ball.

The elastic portion may include a fastening groove formed in the upper block to allow the ball to move up and down, and an elastic spring installed in the fastening groove to apply an elastic force to the ball.

As described above, according to the present embodiment, the balls arranged in a circumferential shape support the upper end of the object, so that even if the upper cover of the object is not uniform and irregular as a whole, it can support the upper end of the object and rotate smoothly. Accordingly, it is possible to increase the versatility for the shape of the top cover of the object.

In addition, by moving the clamping unit through a linear driving method using a linear motor, it is possible to move the clamping unit more precisely compared to a link structure or a cam driving method using a conventional articulated arm. In addition, it is possible to position the object more precisely, and by moving in a straight line, there is an advantage in that it is easy to adjust the position or adjust the set value when resetting.

Since it is not affected by dew on the surface of the object, it is possible to accurately rotate the object to align the position.

1 is a schematic perspective view of a position alignment device according to the present embodiment.
2 is a schematic front view of a position alignment device according to the present embodiment.
3 is a schematic plan view of a positioning device according to the present embodiment.
4 is a schematic view showing a sensor unit of the position alignment device according to the present embodiment.
5 and 6 are schematic views showing the upper end support of the position alignment device according to the present embodiment.

Hereinafter, an embodiment of the present invention will be described in detail. However, this is presented as an example, and the present invention is not limited thereby, and the present invention is only defined by the scope of the claims to be described later. The embodiments described later may be modified in various forms without departing from the concept and scope of the present invention. As far as possible, the same or similar parts are indicated using the same reference numerals in the drawings.

The terminology used below is only for referring to specific embodiments, and is not intended to limit the present invention. Singular forms as used herein also include plural forms unless the phrases clearly indicate the opposite. The meaning of “comprising” as used in the specification specifies a specific characteristic, region, integer, step, action, element and/or component, and other specific characteristic, region, integer, step, action, element, component and/or group It does not exclude the existence or addition of

Hereinafter, preferred embodiments of the present invention will be described. However, the following examples are only preferred examples of the present invention and the present invention is not limited to the following examples.

1 to 3 show the structure of the position alignment device according to the present embodiment.

As shown, the position alignment device 100 is disposed on one side of the conveyor 200 for transporting the object P having a circular horizontal cross section, and rotates the object P in a circumferential direction with respect to the central axis. It may be a structure that faces toward.

In the following description, the x-axis direction of FIG. 1 is referred to as a conveyor transport direction or a traveling direction, and the y-axis direction is referred to as a width direction of the conveyor or both sides of the conveyor.

The object P is, for example, a cylindrical container containing a beverage, and has a tapered shape whose diameter decreases toward the lower end, and the upper end may be formed in an irregular shape. The irregular shape may mean that it is not entirely flat, or that a groove or protrusion is formed on one side and is asymmetric. The object P may itself have an irregular upper end, and may have a structure in which a cover having an irregular upper end is separately combined. The type or shape of the object P may be variously modified.

Hereinafter, in the present embodiment, as shown in FIG. 2, a positional alignment of an object P having a cylindrical shape having a tapered side and having an irregularly shaped cover at the top will be described as an example.

A transfer unit (not shown) is disposed in front of the conveyor 200 to sequentially supply the object P. The object P is continuously conveyed along the conveyor 200. Facilities for performing each process including alignment of positions along the conveyor 200 may be arranged. The object P can be converted into a final product through each facility while moving along the conveyor.

Position alignment device 100 of the present embodiment, a clamping portion for gripping the object P that is moved along the conveyor 200, the object P gripped by the clamping portion is rotated in a circumferential direction with respect to a central axis in one direction. It may include a rotational alignment unit to align, and an upper support unit 150 positioned above the object to support the upper end when the object is rotated.

Accordingly, the object P is rotated by the rotational alignment unit in a state held by the clamping unit to align the position. In this process, the upper support part 110 supports and supports the upper end of the object P, so that the object P having an irregular upper end can be smoothly rotated so that the position can be accurately aligned.

In a state in which the object P is continuously moved along the conveyor 200, the clamping unit grips the object P while moving like the object P and aligns the object P at regular intervals.

The clamping unit is a plate (110, 112) disposed on both sides of the conveyor 200), a driving unit for moving each plate in the direction of the conveyor 200 and the width of the conveyor 200, installed on each plate when moving the plate by the driving unit It may include rollers 114 and 134 in contact with the side of the object P.

In this embodiment, the clamping unit may perform a gripping operation on the three objects P. The number of operations of the object P by the clamping unit may be variously modified.

Two plates 110 and 112 form a pair and are disposed on both sides of the conveyor 200 in the width direction. For convenience of description below, each plate is classified as a first plate 110 and a second plate 112, and when referred to as a plate, it may refer to both a first plate and a second plate.

The first plate 110 may be formed to have a size capable of gripping three objects P. The first plate 110 may be provided with a support roller 114 supporting the object P at one side. Two support rollers 114 are provided for one object (P), and the two support rollers 114 are spaced apart from each other to support the object (P). Thus, the first plate 110 is provided with six support rollers 114 for supporting each of the three objects P at intervals. An upper roller 116 for supporting the object P in contact with the upper side of the object P may be further provided above each of the support rollers 114. The upper roller 116 is disposed on the same axis as the support roller 114 and supports the object P above the support roller 114 to prevent the object P from falling. The upper roller 116 is also provided with six on the first plate 110 like the support roller 114 at the bottom and is disposed at intervals.

Like the first plate 110, the second plate 112 may be formed to have a size capable of gripping three objects P. A rotation roller 134 for supporting the object P and rotating the object P may be installed on one side of the second plate 112. The rotation roller 134 is rotated by an external force to support the object P in contact with the object P from the opposite side of the object P with respect to the support roller 114 of the first plater, ) Is forced to rotate. The structure of rotating the object P by the rotating roller 134 will be described again later.

In this way, the support roller 114 and the rotation roller 134 respectively installed on the first plate 110 and the second plate 112 contact both sides of the object P to support the object P. . Here, the roller may refer to both the support roller 114 and the rotation roller 134 or even the upper roller 116. The roller is a circular rotating body, and the outer circumference may be made of elastic silicone rubber.

As shown in Figure 3, the clamping part of this embodiment is arranged along the outer circumferential surface of the object (P) two support rollers 114 and one rotation roller 134 to support the object (P) three points do. Accordingly, the object P is more accurately adhered to and supported by the roller, and the support for the object P can be increased. In addition, even when the object P is not properly placed on the conveyor 200, the roller supports the object P in three places, so that the object P can be pushed by the roller and aligned to the correct position. In this embodiment, the first plate 110 is further provided with an upper roller 116 in addition to the support roller 114 to come into contact with the object P, but the upper roller 116 is the rotation axis of the support roller 114 Since it is disposed on the same axis as and, it is the same that the roller supports three points along the circumferential direction of the object P.

When the roller supports the object (P) by two or more points, the support force for the object (P) is weak or it is difficult to push the incorrectly placed object (P) to the correct position and place it. If this is weak, there is a risk of being damaged by the roller.

In addition, the clamping part of the present embodiment may further include an auxiliary roller 118 installed on the second plate 112 and spaced apart from the rotating roller 134 to prevent the object P from being separated. The auxiliary roller 118 may be installed to be freely rotatable on the second plate 112. In this embodiment, the auxiliary roller 118 is in a state in which the object P is in contact with the support roller 114 and the rotation roller 134 and is supported in a fixed position, and a predetermined distance without contacting the outer peripheral surface of the object P Can be installed to fall off. That is, when the second plate 112 moves, the auxiliary roller does not contact the object P and does not support the object P, but acts as a stopper to block the object P by being close to the object P.

Accordingly, in this embodiment, while supporting the object P by three points by the rollers 114 and 134, it is possible to prevent the object P from being separated from the conveyor 200 through the auxiliary roller 118.

The drive unit moves the two plates 110 and 112 while drawing a rectangular trajectory, respectively. The trajectories in which the two plates move are opposed to each other with the conveyor 200 interposed therebetween.

To this end, the driving unit of the present embodiment is disposed in the width direction of the conveyor 200 to move the plate in the width direction of the conveyor 200, the first linear motor 120, the first linear motor 120 is disposed in the moving direction of the conveyor. It may include a second linear motor 122 is installed to move the plate in a direction parallel to the moving direction of the conveyor. The driving units are provided on both sides of the conveyor to individually drive each plate. Each driving unit located on both sides of the conveyor has the same structure.

The second linear motor 122 is disposed parallel to the conveyor 200, and the first linear motor 120 is disposed in a direction perpendicular to the conveyor 200. Accordingly, the plates 110 and 112 are respectively moved back and forth toward the object placed on the conveyor by the first linear motor 120, and are moved back and forth along the object moving direction by the second linear motor 122. Therefore, the plates move while drawing a trajectory in a rectangular shape, respectively.

When the first linear motor 120 is driven, the plates 110 and 112 slide along the guide of the first linear motor and move in the width direction of the conveyor 200. Accordingly, the rollers 114 and 134 installed on the plate are moved toward the object P placed on the conveyor 200 to hold the object P or move outward from the object P to release the gripping state.

When the second linear motor 122 is driven, the first linear motor 120 slides along the guide and moves in the moving direction of the conveyor 200. Since the plates 110 and 112 are installed in the first linear motor 120, the plates 110 and 112 are moved in the moving direction of the conveyor 200 according to the driving of the second linear motor 122. Accordingly, each of the plates 110 and 112 moves in the moving direction of the conveyor 200 while moving at the same speed as the conveying speed of the conveyor 200. Accordingly, the rollers 114 and 134 installed on each of the plates 110 and 112 may be moved along the conveyor 200 like the object P while holding the object P placed on the conveyor 200.

In this way, as the first linear motor 120 and the second linear motor 122 are rotated forward and backward according to the set value, each plate can move while drawing a rectangular trajectory. Accordingly, while the object P moves along the conveyor 200, the support roller 114 and the rotation roller 134 installed on the plate may be moved in contact with the object P or separated from the object P. have. Accordingly, through this movement, the clamping unit is transported along the conveyor 200 while supporting the object P.

In this embodiment, the plate can be driven more precisely by moving the plate in a straight line using a linear motor as a driving unit for moving the plate.

In the conventional case, it was difficult to accurately move the plate as it was driven by a link structure or a cam driving method by an articulated arm. Accordingly, in the related art, misalignment of an object frequently occurs, and when the device setting value is changed, all positions of various arms or cams must be accurately set, which makes the work difficult and difficult.

In the present embodiment, the roller can more accurately grasp and position the object through the linear movement structure through the linear motor, and it is easy to adjust the position of each component or adjust the set value when resetting by moving in a straight line.

When each plate is moved with the object while holding the object by the driving of the driving unit, the rotational alignment unit is driven to rotate the object.

The rotation alignment unit is connected to the rotation roller 134 installed on the second plate 112 to rotate the rotation roller 134, the rotation driving unit installed on the plate and detecting the reference mark formed on the side of the object P It may include a sensor unit that controls the rotational drive of the.

The rotation drive unit may include a drive motor 130, a pulley 136 and a belt 138 for transmitting power by connecting between the rotation shaft of the drive motor 130 and the rotation shaft of the rotation roller 134. When the driving motor 130 is rotationally driven, power is transmitted through the pulley 136 and the belt 138, so that the rotation roller 134 is rotated. The rotation drive unit is individually provided on each rotation roller 134 to rotate and align each object P.

In this embodiment, the rotational roller 134 may have a structure in which a plurality of rolls 132 are stacked along the axial direction to divide and contact the side of the object P. The roll 132 may have a structure in which a silicon rubber having elasticity is provided around a disk having a relatively thin thickness.

A plurality of rolls 132 are stacked to form a rotating roller 134. The distance between the roll 132 and the roll 132 can be variously modified. Each roll 132 may have a different diameter depending on the object (P). For example, as mentioned, when the object P has a tapered structure, the diameter of each roll 132 may gradually decrease or increase according to the side inclination angle of the object P. Accordingly, each roll 132 of the rotating roller 134 with respect to the tapered object P can be in close contact with all of the side surfaces of the object P.

The rotating roller 134 comes into contact with a plurality of contact points on the side of the object P through each roll 132. Contacting with a plurality of contact points may mean that the entire front surface of the roller is not in surface contact, but is continuously contacted at intervals.

Accordingly, by minimizing the occurrence of slip between the rotating roller 134 and the surface of the object (P), it is possible to rotate the object (P) more accurately.

In the conventional case, the entire surface of one roller is in contact with the object surface to rotate the object, and there is a problem that slips frequently occur between the rollers depending on the object surface condition. In particular, when cold contents are contained in the object, dew is formed on the surface of the object due to a temperature difference with the outside, and thus slip occurs as the roller and the object slide. Accordingly, the object is not precisely aligned with rotation.

Since the rotating roller 134 of this embodiment is divided into a plurality of rolls 132 and is in contact with the object P, even if a slip occurs in one of the rolls 132, the state of close contact with the object P is maintained by the other roll. It is maintained so as to prevent slip occurrence. Therefore, even when dew is condensed on the surface of the object P, the plurality of rolls 132 remain in close contact with the object P, so that the rotating roller 134 can accurately rotate and align the object P. .

As shown in FIG. 4, the sensor unit may include a sensor 140 that detects the reference mark of the object P. The sensor 140 is for detecting the reference mark displayed on the side of the object P, and, for example, an optical sensor or the like may be used. The sensor 140 is connected to a controller (not shown) that controls the rotation driving unit and applies a reference mark detection signal to the controller. Under the control of the controller according to the detection signal of the sensor 140, the rotation drive unit stops the rotation of the rotation roller 134, thereby rotating and aligning the object P in a fixed position. The moment when the reference mark is detected by the sensor 140 or after a certain period of time has elapsed from the detection, the rotation of the rotation roller 134 is stopped, and the rotation of the object P is stopped. Accordingly, the object P is stopped while facing a certain direction to align the position.

The sensor unit may further include a barrel 142 installed on the front surface of the sensor 140 and protruding forward and having an open front surface. The barrel 142 prevents foreign substances from flowing into the sensor 140.

In addition, in this embodiment, the sensor 140 and the barrel 142 may be disposed to be inclined downward toward the object P with respect to the horizontal plane. Through this structure, the sensor unit can more accurately detect the reference mark on the surface of the object P.

The barrel 142 blocks foreign substances flying toward the sensor 140 according to the rotation of the object P, thereby preventing defective sensing due to the foreign substances.

For example, when dew is condensed on the surface of the object P, as the object P rotates, the dew splashes outward and scatters. The dew is scattered in the horizontal direction by the centrifugal force caused by the rotation of the object P and is carried away. Accordingly, foreign substances, including dew scattered in the horizontal direction by the centrifugal force, are blocked by the barrel 142 and do not contact the sensor 140. In addition, since the barrel 142 of the present embodiment is disposed to be inclined downward and the sensor 140 is located at the upper tip of the barrel 142, the dew scattered into the barrel 142 also does not touch the sensor 140. Therefore, even if the foreign matter is scattered according to the rotation of the object P, contamination of the sensor 140 from the foreign matter is prevented by the barrel 142, so that accurate measurement can be made.

In the conventional case, since the sensor 140 is disposed in the horizontal direction, foreign matter scattered from the object P by centrifugal force contaminates the sensor 140, resulting in poor measurement.

In this embodiment, the downward inclination angle R between the sensor 140 and the barrel 142 may be 20° to 25°. When the inclination angle R is out of the above range, contamination of the sensor 140 due to foreign matter appears, and it is difficult to properly sense the reference mark on the surface of the object P.

The upper support part 150 supports and supports the upper end of the object P, and prevents the object P from being lifted upward in the process of rotating the object P. Since the upper support part 150 supports and supports the upper end of the object P, the object P is smoothly rotated so that the position can be accurately aligned.

The object (P) is supported by the support roller (114) and the rotation roller (134), and the object (P) in close contact with the rotation roller (134) according to the rotational drive of the rotation roller (134) It is rotated in one direction. At this time, by the pressing force of the rotating roller 134, the object P is subjected to an upward pressing force and is lifted upward, and the upper support part 150 supports the upper end of the object P when the object P rises. While regulating it, the object P can be rotated smoothly.

When the sensor 140 detects the reference mark on the side of the object P while the object P rotates, the rotation of the object P stops, and all three objects P are positioned in the same direction. do.

In this process, the upper support part 150 of the present embodiment may stably support the object P to be rotatable regardless of the shape or flow of the upper surface of the object P.

To this end, the upper support part 150 of the present embodiment is connected to the first plate 110 to be spaced apart in an arc shape on the front of the upper block 152 and the upper block 152 located at the upper end of the object P. It may include balls 154 and 155 that are installed and protrude from the front of the upper block 152 and rotate freely.

As shown in FIG. 5, a plurality of balls 154 and 155 are arranged in an arc shape and are evenly arranged on the top of the object P as a whole, and are in point contact with the object P to support and support the top of the object P. The number or spacing of the balls 154 and 155 may be variously modified.

The upper block 152 may be fixedly installed on the first plate 110 through a separate bracket 151. The upper block 152 is a circular plate structure, and may be formed to have a diameter that can sufficiently cover the upper portion of the object P. The upper block 152 is disposed in a horizontal state and is installed to be positioned directly above the object P while the support roller 114 of the first plate 110 grips the object P.

Balls 154 and 155 that roll freely are installed on the lower surface of the upper block 152, that is, the front surface facing the upper end of the object P. The balls 154 and 155 form a completely round spherical shape and are installed to be freely rotatable in any direction while partially exposed to the outside of the upper block 152.

In a state in which the object P does not rotate, there is a gap between the balls 154 and 155 and the object P, so that the balls 154 and 155 are not in contact with the object P. Accordingly, when the first plate 110 is moved to the object P and the roller 114 of the clamping part grips the object P, the upper block 152 is also smoothly moved above the object P, so that the object ( P) It can be located at the top.

When the object P is lifted upward in the process of rotating the object P, the upper block 152 located above the object P stably presses and supports the object P. The spherical balls 154 and 155 installed on the upper block 152 rotate freely even if they contact the upper end of the object P during the rotational movement of the object P, so that the object P is not damaged and the object rotates smoothly. do.

In this way, the upper support part 150 of the present embodiment has a structure including the balls 154 and 155 and may be in point contact with the object P through the balls 154 and 155. Accordingly, even in the case of the object P having an irregular shape other than a flat surface, the upper support portion 150 can smoothly rotate the object P while supporting the upper end of the object P.

For example, even when a groove is formed on the top or cover of the object P and is not flat or has an irregular upper surface, the upper support portion 150 of the present embodiment is the object P through point contact by the balls (154, 155). ) Rotates smoothly while supported.

However, in the case of a structure in which a conventional roller is provided to make line contact or surface contact with the top of the object, it is only possible to support the object having a flat top surface. In the case of a non-flat or asymmetric irregular object with a groove formed on the upper surface as described above, a phenomenon in which the object is not rotated occurs because the roller is caught in the groove formed on the upper surface of the object.

As shown in FIG. 5, the upper support part 150 of this embodiment may have a structure that applies an elastic force to the balls 154 and 155.

To this end, the upper support part 150 is formed in the upper block 152 so that the balls 154 and 155 can be moved up and down, and is installed inside the fastening groove 156 to provide elastic force to the balls 154 and 155. It may further include an elastic spring 158 to apply.

Accordingly, in the process of rotating the object P, the balls 154 and 155 can be elastically moved up and down along the irregular portion of the top of the object P. Accordingly, even with the object P having an irregular upper end, the balls 154 and 155 are elastically flowed up and down, so that the upper end of the object P can be stably supported.

In addition, as shown in FIG. 6, in the present embodiment, the upper support portion 150 may have a structure in which the balls 154 and 155 are alternately arranged along an arc having a relatively large diameter and an arc having a relatively small diameter.

The balls 154 arranged along an arc having a relatively small diameter and the balls 155 arranged along a relatively large arc may have the same structure, only different installation positions.

Each of the balls 154 and 155 is alternately arranged along the circumferential direction of the upper block 152 to form a zigzag shape. Each of the balls 154 and 155 is uniformly disposed in front of the upper block 152 along two arcs.

Accordingly, even when the object P shakes in the process of rotating the object P, the upper end of the object P can be stably supported. That is, when the central axis is shaken while the object P is rotated, the position of the top of the object P is different. Even if the center of the object P is eccentric from the center of the upper block 152 according to the flow of the object P, the balls 154 and 155 arranged with different diameters continue to support the upper end of the object P. Accordingly, even if the central axis of the object P is shaken, the upper end of the object P is pressed by the balls 154 and 155 to maintain a stably supported state.

In this way, the balls 154 and 155 arranged in a zigzag shape with different diameters continue to stably support the upper end of the shaking object P, so that the object P can accurately rotate to align the position.

Although the exemplary embodiments of the present invention have been shown and described as described above, various modifications and other embodiments may be made by those skilled in the art. These modifications and other embodiments are all considered and included in the appended claims and will not depart from the true spirit and scope of the present invention.

100: position alignment device 110,112: plate
114: support roller 116: upper roller
120: first linear motor 122: second linear motor
130: drive motor 132: roll
134: rotating roller 140: sensor
142: barrel 150: upper support
152: upper block 154,155: ball
156: fastening groove 158: elastic spring

Claims (8)

It is a position alignment device that is arranged on one side of a conveyor that transports an object having a circular horizontal cross section and rotates the object in a circumferential direction with respect to the central axis so that it faces in a certain direction.
The position alignment device includes a clamping part for gripping an object to be moved along the conveyor, a rotational alignment part for rotating the object gripped by the clamping part in a circumferential direction with respect to a central axis to align in one direction, and an upper portion of the object. It includes an upper support portion that is positioned to support the upper end when rotating the object,
The clamping unit includes plates disposed on both sides of the conveyor width direction, a driving unit for moving each of the plates in a moving direction of the conveyor and in the width direction of the conveyor, and a roller installed on each plate and in contact with the side of the object when the plate is moved by the driving unit. and,
The top support portion is connected to the plate, the top block positioned at the top of the object, and a position alignment device including a ball that is installed at intervals in an arc shape on the front of the top block and protrudes from the front of the top block to freely rotate. The method of claim 1,
The driving unit is disposed in a direction perpendicular to the conveyor to move the plate in a direction perpendicular to the conveyor, and the first linear motor is disposed in a direction parallel to the conveyor, and the first linear motor is installed to make the plate parallel to the conveyor. Position alignment device comprising a second linear motor to move in the direction. The method of claim 1,
The roller includes two supporting rollers installed on one plate and supporting the object at two spaced apart along the circumferential direction, and a rotation roller installed on the other plate to contact the object and rotate the object, the Position alignment device with a structure that supports three points. The method of claim 3,
Position alignment device further comprising an auxiliary roller that is spaced apart from the rotation roller and is rotatably installed on the plate to prevent separation of the object. The method of claim 3,
The rotating roller is a position alignment device in which a plurality of rolls are stacked along an axial direction to contact a plurality of contact points at intervals on the side of the object. The method according to any one of claims 1 to 5,
The upper support portion, the position alignment device of the structure in which the balls are alternately arranged along a relatively large diameter arc and a relatively small diameter arc. The method of claim 6,
The upper support portion further includes an elastic portion for applying an elastic force to the ball,
Wherein the elastic portion is formed in the upper block, the position alignment device including a fastening groove that allows the ball to move up and down, and an elastic spring installed in the fastening groove to apply an elastic force to the ball. The method of claim 7,
The rotation alignment unit is connected to at least one of the rollers installed on the plate to rotate the roller, and a sensor unit installed on the plate and configured to detect a reference mark formed on the side of the object to control rotational driving of the rotation drive unit. Including,
The sensor unit includes a sensor for detecting a reference mark, and a barrel installed on the front of the bracket on which the sensor is installed and protruding forward, and the front is opened,
The sensor and the barrel are arranged to be inclined downward toward an object with respect to a horizontal plane.

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