The present invention relates to glass product forming facilities in which a glass product such as a glass bottle is formed by using a mold, specifically to a gob producing device for producing a lump of molten glass supplied into the mold, which is called “gob”.
Such a gob producing device includes a molten glass feeder mechanism 1, which is called “feeder”, having an orifice 11 provided at the bottom portion of a spout 10 in which molten glass G is held, and a cutter mechanism 2 called “shear mechanism”, which is arranged right below the orifice 11, as shown in
Just after the plunger 12 turns to rise subsequent to reaching a lower dead point (see FIG. 15(3)) as shown in an example, the cutter mechanism 2 operates to cut the molten glass G which is suspended from the orifice 11 so that a gob g is produced (see FIG. 15(4)). Then the gob g falls downward and is sorted into a plurality of sections of a bottle making machine by a delivery means such as a scoop, a trough and a deflector, and then delivered to a blank mold (not shown).
A blank mold is made in various sizes and shapes in accordance with the final form of a glass bottle to be formed. In order to keep constant the quality, the capacity, the thickness and so forth of a glass bottle and prevent the occurrence of poor appearance such as wrinkles and chill marks, it is required to control the weight and shape of a gob in conformity to the size and shape of a blank mold and constantly reproduce a gob with constant weight and shape. In the molten glass feeder mechanism 1, when the plunger 12 vertically moves in the spout 10, the molten glass G is pushed out or drawn in through the orifice 11 so that the shape of the gob g is changed depending on the movement of the plunger 12. As such, when the molten glass G is pushed out through the orifice 11 so as to be suspended therefrom, the shape of the gob g such as the length thereof is determined depending on the timing at which the suspended molten glass G is cut off and the position (height) at which the suspended molten glass G is cut off.
The position at which the molten glass G is cut is initially set prior to the operation of the device by manually moving the cutter mechanism 2 in a vertical direction to perform the height adjustment.
Further, if the posture of the gob g is tilted at the time of falling, the gob g comes into contact with a mechanism such as a scoop funnel during falling, and the falling rate is decreased, thereby causing the forming condition (for example, forming time) in the blank mold to change, and therefore the gob g is required to be dropped by controlling the swing thereof when the gob g is cut off. In order to control the swing of the gob g, a half cylinder shaped guide member 3 called “drop guide” is attached at the lower side of the cutter mechanism 2, and the initial setting is performed by manually moving the guide member 3 in adjustment to the right or left and/or front or rear.
However, even if the height of the cutter mechanism 2 and the position of the guide member 3 are adjusted prior to the operation of the device, when an environment condition such as ambient temperature is changed during operation, the change affects the temperature and so forth of the molten glass G. As a result, the gob g is changed in the length thereof or dropped with a tilted posture due to the move in the center of gravity and so forth, thereby exerting an adverse impact on the quality of a glass bottle being produced.
Each time a change in the length of the gob g and so forth becomes significant, readjustment needs to be performed with respect to the positions of the cutter mechanism 2 and the guide member 3, and thus a problem occurs that a burden on an operator performing such an adjustment operation is increased.
The present invention is made in view of the aforementioned problem and has an object to provide a gob producing device, which observes a three-dimensional view of a falling gob and automatically adjusts the height of a cutter mechanism and a position of a guide member by obtaining the length and the tilt of the gob from the spatial position data thereof, whereby a correction processing is automatically applied to a change in the length of the gob and the tilt of the gob due to a change in the surrounding environment and so forth, and thus the quality of a molded product is maintained while a manual operation by an operator is no longer required for readjustment.
A first invention relates to a gob producing device comprising: a molten glass feeder mechanism which has an orifice provided at the bottom portion of a spout in which molten glass is held and a plunger vertically movably arranged in the spout to push out the molten glass through the orifice; and a cutter mechanism which is located below the orifice and cuts the molten glass pushed out from the orifice so as to be suspended therefrom, thereby producing a gob, wherein the gob producing device is further provided with a cutter position moving mechanism for adjusting the height of the cutter mechanism by vertically moving said cutter mechanism with respect to the orifice, a gob observing device for obtaining the spatial position data of the gob by observing a three-dimensional view of the gob falling after being cut by the cutter mechanism, a length measuring means for measuring the length of the gob from said spatial position data of the gob, a determining means for determining acceptance or rejection with respect to the length of the gob by comparing a measured length of the gob with a set value, a computing means for calculating correction data to correct the height of the cutter mechanism from a difference between a measured value of the length of the gob and a set value when the length of the gob is determined as being not appropriate, and a control means for moving the cutter mechanism by controlling the operation of the cutter position moving mechanism on the basis of said correction data.
In the gob producing device configured as described above, when the plunger vertically moves in the spout where the molted glass is held, the molten glass is pushed out through the orifice at the bottom portion of the spout so as to be suspended therefrom. The suspended molten glass is cut at a given timing by the cutter mechanism, and thereby the gob is produced. The three-dimensional view of the falling gob is observed by the gob observing device such that the spatial position data of the gob is obtained and the length of the gob is measured by the length measuring means from the spatial position data of the gob. The measured value of the length of the gob is compared with a set value and acceptance or rejection with respect to the length of the gob is determined by the determining means, and if determined as being not appropriate, the computing means calculates correction data to correct the height of the cutter mechanism from a difference between the measured value of the length of the gob and the set value. The control means controls the operation of the cutter position moving mechanism on the basis of the correction data calculated by the computing means and adjusts the height of the cutter mechanism by vertically moving the cutter mechanism with respect to the orifice.
In a preferable embodiment according to the first invention, said cutter position moving mechanism includes as a drive source a motor rotating respectively in a forward or backward direction so as to move the cutter mechanism in a vertical direction with respect to the orifice by a distance corresponding to the rotation angle of the motor.
According to the embodiment, by using a pulse motor for the motor, an automatic height adjustment for the cutter mechanism can be easily realized.
A second invention relates to a gob producing device comprising: a molten glass feeder mechanism which has an orifice provided at the bottom portion of a spout in which molten glass is held and a plunger vertically movably arranged in the spout to push out the molten glass through the orifice; and a cutter mechanism which is located below the orifice and cuts the molten glass pushed out from the orifice so as to be suspended therefrom thereby producing a gob, wherein the gob producing device is further provided with a guide member located below the cutter mechanism for dropping the gob with controlling the swing of the gob when the gob is cut off by the cutter mechanism, a guide position moving mechanism for adjusting the position of the guide member on the horizontal surface with respect to the falling path of the gob by moving said guide member in given two directions orthogonal to each other on the horizontal surface, a gob observing device for obtaining the spatial position data of the gob by observing a three-dimensional view of the gob falling after being cut by the cutter mechanism, a tilt measuring means for measuring the tilt of the gob in two directions orthogonal to each other on said horizontal surface thereof from said spatial position data of the gob, a determining means for determining whether or not the measured value of the tilt of the gob is within the permissible range, a computing means for calculating correction data to correct the position of the guide member on the horizontal surface thereof from the measured value of the tilt of the gob when the tilt of the gob is determined as being not within the permissible range, and a control means for moving the guide member by controlling the operation of the guide position moving mechanism on the basis of said correction data.
A third invention relates to a gob producing device wherein the gob producing device according to the aforementioned first invention is further provided with the guide member, the guide position moving mechanism, the tilt measuring means, the determining means and the control means as described above.
In the gob producing device configured as described above, when the molten glass pushed out through the orifice so as to be suspended therefrom is cut off by the cutter mechanism, the swing of the gob when the gob is cut off is controlled by the guide member. The three-dimensional-view of the falling gob is observed by the gob observing device so that the spatial position data of the gob is obtained, and the tilt of the gob in given two directions orthogonal to each other on the horizontal surface thereof is measured by the tilt measuring means from the spatial position data of the gob. The determining means determines whether or not the measured value of the tilt of the gob is within the permissible range, and when the measured value of the tilt of the gob is determined as being not within the permissible range, the computing means calculates correction data to correct the position of the guide member on the horizontal surface thereof from the measured value of the tilt of the gob. The control means controls the operation of the guide position moving mechanism on the basis of the correction data computed by the computing means and adjusts the position of the guide member by moving the guide member in the given two directions orthogonal to each other on the horizontal surface with respect to the falling path of the gob.
In the configuration of the first to third inventions as described above, the gob observing device can be constituted of, for example, three imaging devices, and the length measuring means, the tilt measuring means, the determining means, the computing means and the control means can be realized by a programmed computer.
In a preferable embodiment according to the second and third inventions, said guide position moving mechanism includes as drive sources a first and a second motors rotating respectively in a forward or backward direction so as to move the guide member by a distance corresponding to the rotation angle of the first motor in one direction among said two directions and move the guide member by a distance corresponding to the rotation angle of the second motor in the other direction among said two directions. According to the embodiment, by using pulse motors for the first and the second motors, an automatic position adjustment for the guide member can be easily realized.
According to the present invention, the three-dimensional view of a falling gob is observed and the height of a cutter mechanism or the position of a guide member on the horizontal surface thereof is automatically adjusted by obtaining the length or the tilt of the gob from the spatial position data of the gob, and thus it is possible to automatically correct a change in the length of the gob as well as the tilt of the gob due to a change in the surrounding environment, whereby it is possible to maintain the quality and so forth of a molded product. Also, a manual operation by an operator is no longer required for the readjustment of the height of a cutter mechanism and the position of a guide member, and thus the burden on an operator for adjustment operation can be significantly reduced.
A drawing illustrates a preferable embodiment for practicing the present invention. However the present invention is not limited to the embodiment, and the scope of the present invention is not limited by the embodiment.
The gob producing device shown in drawings produces gobs g which are sequentially supplied to blank molds arranged at a plurality of sections of a bottle making machine, and includes a molten glass feeder mechanism 1 and a gob observing device 6 shown in
The molten glass feeder mechanism 1 is provided with a spout 10 for holding molten glass G introduced from a glass fusing furnace (not shown) and an orifice 11 for pushing out downward the molten glass G is formed at the center bottom of the spout 10. The cutter mechanism 2 is for cutting the molten glass G which is pushed out through the orifice 11 so as to be suspended therefrom in a column-like shape by reciprocating a pair of shear blades 20A, 20B, and is arranged below the orifice 11. The cutter position moving mechanism 4 is for adjusting the height of the cutter mechanism 2 by moving the shear blades 20A, 20B upward in a direction of getting closer to the orifice 11 or downward in a direction of getting away from the orifice 11 (in a vertical direction as shown by an arrow z in the drawings and hereinafter the direction is referred to as “z direction”).
The guide member 3 is to control the swing of the molten glass G when the gob g is cut off and adjust the falling posture of the gob g and is positioned below the pair of shear blades 20A, 20B of the cutter mechanism 2. The guide position moving mechanism 5 is for adjusting the position of the guide member 3 on a virtual horizontal surface positioned at the height of the guide member 3 (two-dimensional coordinate position) by moving the guide member 3 in given two directions orthogonal to each other on the horizontal surface with respect to the falling path d of the gob g right below the orifice 11, that is, a direction to which the gob 8 is pressed by a lower side shear blade 20B (the direction is shown by an arrow x in the drawing and hereinafter is referred to as “x direction”) and a direction orthogonal to the x direction (the direction is shown by an arrow y in the drawing and hereinafter is referred to as “y direction”).
A plunger 12 and a tube 13 are vertically movably arranged inside the spout 10 of the molten glass feeder mechanism 1 as shown in
Although the cutter mechanism 2 according to this embodiment is to rotate the shear blades 20A, 20B integrally with the respective arms 21A, 21B, instead, the shear blades oppositely arranged to each other can be reciprocated.
When the molten glass G is cut off, since a pressing force f1 due to the lower side shear blade 20B is applied to the molten glass G as shown in
Further, if the center O of the shear blades 20A, 20B is deviated in the y direction from the center of gravity Gp of the suspending molten glass G as shown in
The cutter position moving mechanism 4 as shown in
The aforementioned driving force transmission mechanism 41 according to this embodiment is constituted of a feed screw rotatably supported respectively in a forward or backward direction in an upright posture at the outer surface of the spout 10 of the molten glass feeder mechanism 1, a gear mechanism 43 for transmitting the rotation of the motor 40 to the feed screw 42, and a nut member 44 fed in an upward direction or a downward direction (z direction) on the feed screw 42 as the feed screw 42 rotates either in a forward direction or in a backward direction, and the shear blades 20A, 20B of the cutter mechanism 2 are horizontally held by a shear box 45 integrally formed with the nut member 44.
A moving amount Δz either in an upper direction or in a lower direction of the shear blades 20A, 20B in the cutter mechanism 2 is equal to the moving distance of the nut member 44 fed either in an upper direction or in a lower direction on the feed screw 42. The moving distance of the nut member 44 is determined by the number of rotations of the feed screw 42 and the number of rotations of the feed screw 42 is determined by the rotation angle of the motor 40 (number of rotations), and thus the moving direction of the shear blades 20A, 20B is determined by the rotation direction of the motor and the moving amount Δz of the shear blades 20A, 20B is determined by the rotation angle of the motor 40 (number of rotations).
When the gob g is produced by cutting the molten glass G with the shear blades 20A, 20B of the cutter mechanism 2, a length L of the gob g can be adjusted by a distance D between the orifice 11 and the cutter mechanism 2, that is, by the height of the cutter mechanism 2 as shown in
Since the relationship between the moving amount Δz of the shear blades 20A, 20B and the changing amount ΔL in the length L of the gob g can be mapped to a table on the basis of preliminarily acquired experimental data, when the length L of the gob g is measured in a measuring process based on an imaging process as described below, the moving amount Δz of the shear blades 20A, 20B can be acquired from a difference ΔL between the measured value of the length L in the gob g and the set value of the length L in the gob g by referencing the table, and the rotation angle (number of rotations) of the motor 40 can be calculated from the moving amount Δz.
The guide member 3 shown in
The guide position moving mechanism 5 includes as drive sources a first and a second motors 50, 51 for moving the position of a guide, which are rotatable respectively in a forward or backward direction, and the guide member 3 is moved in the x direction with respect to a falling path d of the gob g by a distance corresponding to the rotation angle (number of rotations) of the first motor 50 via a first drive force transmission mechanism 52 while the guide member 3 is moved in the y direction by a distance corresponding to the rotation angle (number of rotations) of the second motor 51 via a second drive force transmission mechanism 53. In this embodiment, pulse motors (stepping motors) are used for the respective motors 50, 51 for moving a guide as the motor 40 for moving the cutter mechanism described above.
The first drive force transmission mechanism 52 according to this embodiment includes a support arm 54 in which the center of the length thereof is supported as a pivot point 54a at a proper position of one arm 21A of the cutter mechanism 2 and a feed screw 55 which moves the tip section of the support arm 54 in the x direction by a distance corresponding to the rotation angle (number of rotations) of the first motor 50 by rotating integrally with the first motor 50 and moving the support arm 54 in response to the rotation of the first motor 50. The feed screw 55 is screwed into a screw hole 54b which is formed at the base end section of the support arm 54 such that the tip thereof has contact with a frame of the cutter mechanism 2. An elongated hole 54c into which the support piece 31 of the guide member 3 is inserted slidably in the length direction of the support arm 54 and held in place there, is formed at the tip section of the support arm 54.
When the feed screw 55 rotates, the base end section of the support arm 54 is fed by the screw and thus the support arm 54 is moved such that the guide member 3 is moved in the x direction integrally with the tip section of the support arm 54. A spring pressure of a compressed spring 56 is constantly applied to the support arm 54 because the tip section of the support arm 54 is pressed backward with the tip of the feed screw 55 being pressed against the frame of the cutter mechanism 2.
The second drive force transmission mechanism 53 includes a rod 57 in which the tip thereof is coupled to the support piece 31 of the guide member 3 while the base end section side thereof is slidably supported by a bearing member 57b supported by said support arm 54, and a pair of gears 58, 59 which reciprocates the rod 57 in the axis direction by a distance corresponding to the rotation angle (number of rotations) of the second motor 51 thereby moving the tip thereof. The respective gears 58, 58 are engaged with each other, and one gear 58 is coupled with the second motor 51. The other gear 59 has an inside hole threaded into a screw hole 59a and a screw axis portion 57a formed at the tip section of the rod 57 is screwed into the screw hole 59a. When the gears 58, are rotated either in forward or in backward direction integrally with the second motor 51, the rod 57 is fed by the screw such that the support piece 31 of the guide member 3 is slid in the length direction of the support arm 54 and the guide member 3 is moved in the y direction.
When the gob g is produced by cutting the molten glass G with the shear blades 20A, 20B of the cutter mechanism 2, the tilt of the gob g can be adjusted by a distance t of the guide member 3 from the falling path d of the gob g in the direction of the gob g being pressed by the lower side shear blade 20B (x direction), that is, the position of the guide member 3 in the x direction as shown in
Now going back to
Each imaging device 6A to 6C is connected to an image processing device 7 and when a trigger signal is output to the image processing device 7 from a timing system 9 shown in
The image processing device 7 obtains the spatial position data of the gob g (specifically three-dimensional coordinate data) from three two-dimensional images taken by each of the imaging devices 6A to 6C and the length L and the respective tilts θx, θy in the x direction and the y direction of the gob g are measured from the spatial position data. The acceptance or rejection of a measured value of the length L and the tilts θx, θy of the gob g is determined by a control device 8, and when determining rejection the control device 8 controls the operation of the cutter position moving mechanism 4 or the guide position moving mechanism 5 and thereby correcting the height of the cutter mechanism 2 or the position of the guide member 3 on the horizontal surface thereof.
Said control device 8 is constituted of a microcomputer including a CPU 80 for principally performing control and computation, a ROM 81 for storing a program and fixed data, a RAM 82 for storing various data, and so forth as shown in
The CPU 80 executes a program stored in the ROM 81 and serially controls the input/output operations for the above-mentioned each input/output device while writing and reading data to and from the RAM 82.
Said image processing device 7 is constituted of a microcomputer including a CPU 70 for principally performing control and computation, a ROM 71 for storing a program and fixed data, and a RAM 72 used for reading and writing data as shown in
In response to the measurement result of the image processing device 7, the CPU 80 in the control device 8 sequentially performs the control step shown in FIG. 12(1) (shown by “ST” (an abbreviation of step) in the drawing), corrects the height of the cutter mechanism 2, and holds the length L of the gob g at a constant value, and performs the step shown in FIG. 13(1) thereby correcting the position of the guide member 3 on the horizontal surface thereof and correcting the posture of the gob g such that each tilt θx, θy in the x and the y directions of the gob g is within the permissible range.
First, each control step for the length correction is discussed as shown in
Next, the CPU 70 instructs the measuring unit 74 to perform processing for measuring the length L of the gob g from the spatial position data and sends the measured data to the control device 8 (ST 4, 5). The CPU 80 in the control device 8, when receiving the measured data of the length L in ST 6 shown in FIG. 12(2), determines whether or not the length L of the gob g is appropriate by comparing the measured data with a set data (ST7). If the measured data is not appropriate, the program advances from ST7 to ST8 and the CPU 70 calculates a moving amount Δz of the shear blades 20A, 20B as correction data for correcting the height of the cutter mechanism 2 from a difference ΔL between the measured value and the set value of the length L of the gob g.
When the moving amount Δz of the shear blades 20A, 20B is calculated in ST8, the program advances from ST8 to ST9 in order to correct the height of the shear blades 20A, 20B, and the CPU 80 rotates the first motor 40 by a rotation angle obtained by calculation and thereby moves the shear blades 20A, 20B by the moving amount Δz to correct the height of the shear blades.
Next, each control step for the tilt correction is discussed as shown in
Next, the CPU 70 instructs the measuring unit 74 to perform processing for measuring the tilt θx in the x direction and the tilt θy in the y direction of the gob g from the spatial position data and sends the measured data to the control device 8 (ST 4, 5). The CPU 80 in the control device 8, when receiving the measured data of the tilt θx and the tilt θy in ST 6 shown in FIG. 13(2), determines whether or not each measured data is within a permissible range (ST7). If at least either one of the tilt θx and θy is not within the permissible range, the program advances from ST7 to ST8 and the CPU 70 calculates a moving amount Δx in the x direction or a moving amount Δy in the y direction of the guide member 3 as correction data for correcting the position of the guide member 3 on the horizontal surface thereof from the measured value of the tilt θx or θy.
When the moving amount of the guide member 3 is calculated in ST8, the program advances from ST8 to ST9 in order to correct the position of the guide member 3 on the horizontal surface thereof, and the CPU 80 rotates the second and the third motors 50, 51 by a rotation angle obtained by calculation and thereby moves the guide member 3 by the moving amount to correct the position of the guide member 3 on the horizontal surface thereof.
Next, the CPU 70 instructs the measuring unit 74 to perform processing for measuring the length L and the tilt θx in the x direction and the tilt θy in the y direction of the gob g from the spatial position data and sends the measured data to the control device 8 (ST 4, 5). The CPU 80 in the control device 8, when receiving the measured data of the length L and the tilts θx and θy in ST 6 shown in FIG. 14(2), determines in the first place whether or not each measured data of the tilt θx and θy is within a permissible range (ST7). If at least either one of the tilts θx and θy is not within the permissible range, the program advances from ST7 to ST8 and the CPU 70 calculates a moving amount Δx in the x direction or a moving amount Δy in the y direction of the guide member 3 as correction data for correcting the position of the guide member 3 on the horizontal surface thereof from the measured value of the tilt θx or θy.
When the moving amount of the guide member 3 is calculated in ST8, the program advances from ST8 to ST9 in order to correct the position of the guide member 3 on the horizontal surface thereof, and the CPU 80 rotates the second and the third motors 50, 51 by a rotation angle obtained by calculation and thereby moves the guide member 3 by the moving amount to correct the position of the guide member 3 on the horizontal surface thereof.
In said ST7, if both of the tilts θx and θy are within the permissible range, the program advances from ST7 to ST10 and it is determined whether or not the length L of the gob g is appropriate by comparing the measured data of the length L with a set value. If the length L is not appropriate, the program advances from ST10 to ST11 and the CPU 70 calculates the moving amount Δz of the shear blades 20A, 20B as correction data for correcting the height of the cutter mechanism 2 from the difference ΔL between the measured value and the set value of the length L of the gob g.
When the moving amount Δz of the shear blades 20A, 20B is calculated in ST11, the program advances from ST11 to ST12 in order to correct the height of the shear blades 20A, 20B, and the CPU 80 rotates the first motor 40 by a rotation angle obtained by calculation and thereby moves the shear blades 20A, 20B by the moving amount Δz to correct the height of the shear blades.
Notably, when the steps (ST8, 9) for the correction of the tilt are performed in response to the negative determination in said ST7, the steps ST10 to 12 for the correction of the length are skipped, however if a positive determination is made for an image subsequently fed in ST7, the steps ST10 to 12 for the correction of the length are to be performed.
Number | Date | Country | Kind |
---|---|---|---|
2010-071911 | Mar 2010 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/JP2011/056940 | 3/23/2011 | WO | 00 | 9/14/2012 |