JP6244880B2 - Glass tube forming method - Google Patents

Description

  The present invention relates to a technology of a glass tube forming apparatus and a glass tube forming method for continuously forming glass tubes, and more particularly to a technique of a plurality of annealers provided in the glass tube forming device.

Conventionally, for example, glass tubes used for medical ampules and fluorescent fluorescent tubes are mainly formed by the Danner method.
In the Danner method, a ribbon-like molten glass is wound around an outer peripheral surface of a sleeve that is provided in a muffle furnace and is rotated about an axis while a tip portion is directed obliquely downward. The molten glass wound around the sleeve gradually becomes a layer of uniform thickness and flows to the tip of the sleeve. Compressed air is jetted to the tip of the sleeve, and a tube drawing device (traction device) is disposed in front of the sleeve, that is, downstream, and the molten glass is fed to the tip of the sleeve by the traction force of the tube drawing device. The tube is drawn (pulled) from the part to become a glass tube.
The glass tube drawn by the tube drawing device is once roughly cut into a predetermined length by the glass tube cutting device, and then both ends are re-cut and mouth-fired by the re-cutting / mouth-burning device.
Thus, the glass tube is continuously formed by the Danner method.

By the way, between the sleeve and the tube drawing device, a plurality of annealers are continuously arranged in a line along the tube drawing direction of the glass tube. In addition, a plurality of support rollers are pivotally supported along the tube drawing direction inside each annealer.
The glass tube drawn obliquely downward from the tip of the sleeve is guided into the plurality of annealers while drawing a catenary (suspension line) shape, and is supported by being grounded and supported by a plurality of support rollers. It is pulled in the pulling direction.
Thereby, the glass tube is gradually cooled (removed) while being formed linearly.

Here, generally, when the contact start position of the glass tube drawn out from the sleeve with the support roller in the annealer is too close to the sleeve, the molten glass that starts to contact the support roller is still in a high temperature state. For this reason, the support roller is brought into contact with the ground in a state where the viscosity is low, and the glass tube tends to be distorted into an elliptical shape in cross section, which is likely to cause a defective quality of the glass tube.
On the other hand, if the grounding start position of the glass tube drawn out from the sleeve and the support roller in the annealer is too far from the sleeve, the glass tube that starts grounding to the support roller has cooled too much in the air. Thus, the support roller is grounded in a state where the viscosity is high, and the correction from the curved shape to the linear shape is not sufficiently performed after the ground contact, which is likely to cause a quality defect of the glass tube.

For this reason, in order to maintain the quality of the glass tube, it is necessary that the glass tube starts to contact the support roller in the annealer at least at a location having an appropriate viscosity.
In other words, it is necessary that the glass tube starts to contact the support roller in the annealer from a predetermined temperature state where the viscosity becomes appropriate.
Therefore, conventionally, for example, by providing a damper that can be opened and closed at the opening (exit part) of the muffle furnace, adjusting the opening and closing amount of the damper (opening area of the outlet part), and setting the temperature in the muffle furnace, The temperature of the molten glass was maintained while raising the temperature to a predetermined temperature, and the glass tube was adjusted so that the viscosity of the glass tube was appropriate at the location where the glass tube started to contact the support roller in the annealer (for example, , See "Patent Document 1").

JP-A-48-93610

  However, when the viscosity of the glass tube at the contact start position with the support roller is adjusted by adjusting the temperature setting in the muffle furnace, it takes time until the adjusted temperature in the muffle furnace becomes stable. The viscosity of the glass tube could not be adjusted. Further, since the temperature in the muffle furnace is changed, it is necessary to appropriately adjust other molding conditions of the glass tube such as a tube drawing speed.

  The present invention has been made in view of the above-described current problems, and at a point where the glass tube starts to contact the support roller in the annealer quickly without changing the temperature in the muffle furnace. It is an object of the present invention to provide a glass tube forming apparatus and a glass tube forming method capable of adjusting the viscosity of the glass tube to be appropriate and maintaining the glass tube quality constant.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

Method of forming a glass tube according to claim 1 of the present invention is a molding process of the glass tube for forming glass tube equipped with a annealer for annealing the glass tube which is tube drawing molding, the annealers glass tube Are arranged in parallel in a straight line along the tube pulling direction, have a plurality of support rollers for supporting the glass tube, and are movable in the vertical direction and / or rotatable in the vertical direction. The molded glass tube is checked for cross-sectional distortion and axial curvature, and the annealer is moved vertically and / or rotated to a predetermined position based on the confirmation result. It is characterized by that.

  As effects of the present invention, the following effects can be obtained.

According to the molding method for a glass tube according to claim 1 of the present invention, the ground starting position relative to the support rollers of a glass tube which is molded, it is possible to quickly adjust without temperature change in the muffle furnace, the glass It becomes possible to maintain the quality of the tube constant.

The side view which showed the whole structure of the glass tube forming apparatus which concerns on one Embodiment of this invention. The process figure which showed the procedure at the time of adjusting the height and inclination | tilt angle of an annealer. For example, it is a diagram showing the state of the annealer when adjusting the height / tilt angle of the annealer when a cross-sectional distortion is seen with respect to the glass tube, (a) adjusting the height / tilt angle The side view which showed the state of the last annealer, (b) The side view which showed the state of the annealer immediately after adjusting height and the angle of inclination. For example, when an axial curvature is seen with respect to a glass tube, it is the figure which showed the state of the annealer at the time of adjusting the height and inclination angle of an annealer, Comprising: (a) adjusts height and inclination angle The side view which showed the state of the annealer just before performing, (b) The side view which showed the state of the annealer just after adjusting height and an inclination angle.

  Next, embodiments of the invention will be described.

[Glass tube forming apparatus 100]
First, an overall configuration of a glass tube forming apparatus 100 (hereinafter simply referred to as “forming apparatus 100”) embodying the present invention will be described with reference to FIG.
In addition, regarding the following description, for convenience, the vertical direction in FIG. 1 is described as the vertical direction of the molding apparatus 100.
In FIG. 1, the direction of the arrow A is defined as the tube drawing direction (conveying direction) of the glass tube G.

The shaping | molding apparatus 100 which concerns on this embodiment is an apparatus for shape | molding the glass tube G continuously by the Danner method.
Forming apparatus 100 mainly includes glass melting furnace 1, the sleeve 2, the drive device 3 to the sleeve 2 is driven to rotate, muffle furnace 4 for storing sleeve 2, annealer 5, tube drawing apparatus 6, the cutting apparatus 7, and the conveyor 8 Etc.

The glass melting furnace 1 is a furnace for melting a glass raw material to produce a molten glass M.
Molten glass M produced in the glass melting furnace 1 is supplied to the sleeve 2 in the muffle furnace 4.

Next, the sleeve 2 will be described.
The sleeve 2 is used as a bar jig for drawing the molten glass M into a tube shape.
The sleeve 2 is made of a cylindrical refractory. Also, one end 2a of the sleeve 2 is formed in a tapered shape that gradually decreases in diameter toward the tip.

In the muffle furnace 4, the sleeve 2 is disposed with one end 2 a (hereinafter referred to as “tapered end 2 a” as appropriate) facing obliquely downward. Further, the shaft 31 of the driving device 3 is inserted from the other end of the sleeve 2 to the tapered end 2a.
As a result, the sleeve 2 is connected to the shaft 31 and is driven to rotate by the driving device 3.
The molten glass M supplied to the muffle furnace 4 is wound by the sleeve 2 and drawn out into a cylindrical shape.

Next, the muffle furnace 4 will be described.
The muffle furnace 4 is a furnace for maintaining the temperature of the molten glass M when the molten glass M supplied from the glass melting furnace 1 is formed into a cylindrical shape by the sleeve 2 in a predetermined high temperature state.
The muffle furnace 4 is formed in a box shape in the present embodiment, for example, and is disposed below the glass melting furnace 1.

  A supply port 4a is perforated on the upper surface of the muffle furnace 4 and immediately above the base 2b of the mandrel 2, and the molten glass M flows directly from the glass melting furnace 1 onto the base 2b through the supply port 4a. Supplied.

On the other hand, in the muffle furnace 4, an opening 4 b is formed on the surface (wall surface) facing the tapered end 2 a of the mandrel 2.
The opening 4 b is provided with a damper 41, and the opening 4 b is opened and closed by the raising and lowering operation of the damper 41.
The atmosphere in the muffle furnace 4 is maintained at a predetermined high temperature by adjusting the opening / closing amount of the opening 4b (opening area of the opening 4b) based on the stop position of the damper 41.
Thereby, in the muffle furnace 4, the temperature of the molten glass M at the time of being drawn out from the sleeve 2 into a tube shape is raised to and maintained at a predetermined high temperature state.

The molten glass M drawn obliquely downward from the taper end 2a is formed into a tube shape, becomes a glass tube G, and is drawn from the opening 4b to the outside of the muffle furnace 4.
Thereafter, the glass tube G passes through the inside of the muffle cover 42 while drawing a catenary (suspension line) shape, and is introduced into the plurality of annealers 5.

Next, the annealer 5 will be described.
The annealer 5 is an apparatus for forming the glass tube G while slowly cooling the glass tube G drawn from the muffle furnace 4.
The annealer 5 is, for example, a frame member 51, a plurality of support rollers 52, 52... Supported by the frame member 51, and a rectangular box that covers these frame members 51 and support rollers 52, 52. It is comprised by the shape-like cover member 53 grade | etc.,.

The rotation axis of each support roller 52 extends in the horizontal direction and in a direction perpendicular to the drawing direction of the glass tube G (the direction of arrow A in FIG. 1).
Further, the plurality of support rollers 52, 52,... Are arranged so as to be linearly arranged along the drawing direction of the glass tube G (the conveyance direction of the glass tube G), and are supported by the frame member 51. Yes.
On the other hand, the frame member 51 is formed so as to extend along the arrangement direction of the plurality of support rollers 52, 52..., And is movable in the vertical direction as described later. It is arranged to be rotatable in the vertical direction around one end or the other end.
Thereby, the annealer 5 can move in the vertical direction and can rotate in the vertical direction.

  And a plurality of the annealers 5, 5... Are provided on the downstream side of the muffle furnace 4, and the plurality of support rollers 52, 52, 52, 52 provided in each annealer 5 are arranged in the drawing direction of the glass tube G. It arrange | positions continuously so that it may arrange | position in a line along.

  The glass tube G led into the plurality of annealers 5... Having the above structure is supported from below by the plurality of support rollers 52. ).

Here, in the present embodiment, each annealer 5 is provided with a movable mechanism portion (not shown) of manual type or automatic type, and the height and inclination angle of each annealer 5 can be easily set by this movable mechanism unit. The configuration is variable.
Further, the frame members 51 and 51 of the adjacent annealers 5 and 5 are connected to each other between the annealers 5 and 5 by a connection mechanism portion (not shown), and are rotated up and down around the connection mechanism portion. Connected as possible.

Then, as will be described later, based on the catenary shape of the glass tube G introduced from the muffle furnace 4, the movable mechanism of the annealer 5 (hereinafter referred to as “upstream annealer 5 </ b> A” as appropriate) located on the most upstream side. .., By appropriately adjusting the height and the inclination angle of the upstream portion annealer 5A, among the plurality of support rollers 52, 52... The height of the roller 52 and the inclination angle between the horizontal direction and the arrangement direction of the plurality of support rollers 52.
In addition, as the height and the inclination angle of the upstream annealer 5A are adjusted, the heights and inclination angles of the plurality of annealers 5, 5... Connected in a row on the downstream side of the upstream annealer 5A are also synchronized. Adjusted.
For example, in the adjacent annealers 5 and 5, the downstream end of the annealer 5 located on the upstream side and the upstream end of the annealer 5 located on the downstream side are made equal to each other, and the annealer located on the downstream side. 5 can be made to follow the shape of the glass tube G by making the inclination angle with respect to the horizontal plane of 5 1-20 degrees smaller than the inclination angle with respect to the horizontal plane of the annealer 5 positioned on the upstream side.

Next, the tube drawing device 6 will be described.
The tube drawing device 6 is a device for pulling the glass tube G at a constant speed and conveying it toward the cutting device 7 on the downstream side of the plurality of annealers 5.
The pipe drawing device 6 is provided with a pair of upper and lower endless belts 65 and 65.
Then, the glass tube G is conveyed to the cutting device 7 by pulling the tube with the endless belts 65 and 65 while pulling and pulling the glass tube G in the downstream direction.

Next, the cutting device 7 will be described.
The cutting device 7 is a device for cutting the glass tube G sent out from the tube drawing device 6 every fixed length.
The glass tube cut by the cutting device 7 is conveyed to the next process by the conveyor 8.

  In the molding apparatus 100 configured as described above, the glass tube G is supplied with the molten glass M melted in the glass melting furnace 1 to the sleeve 2, and then the endless of the conveying roller 52 of the annealer 5 and the tube drawing device 6. The molten glass M is drawn out from the tip of the sleeve 2 by a belt 65 or the like, drawn into a tube, and gradually cooled by the annealer 5 to be molded.

[How to adjust the Annealer 5]
Next, a method for adjusting the height and inclination angle of the annealer 5 will be described with reference to FIGS.
In the following description, for convenience, the vertical direction in FIGS. 3 and 4 is described as the vertical direction of the annealer 5.
3 and 4, the direction of arrow A is described as the tube drawing direction (conveying direction) of the glass tube G.

First, as shown in FIG. 2, in the state in which the glass tube G is continuously formed by the forming apparatus 100, the confirmation step (S <b> 101) is performed on any formed glass tube G. .
Specifically, in the confirmation step (S101), distortion of a cross-sectional shape deformed into a substantially elliptical shape (hereinafter referred to as “cross-sectional distortion” as appropriate) is observed with respect to an arbitrarily formed glass tube G. And whether or not a curvature in the axial direction (hereinafter, referred to as “axial curvature” as appropriate) is observed.

As a result, when neither the cross-sectional distortion nor the axial curvature is observed for the glass tube G to be confirmed, the quality of the glass tube G to be molded is maintained, and It is determined that adjustment of the height and the inclination angle is unnecessary.
On the other hand, when either cross-sectional distortion or axial center curvature is observed for the glass tube G to be checked, the quality of the glass tube G to be molded is not maintained, and the checking step (S101) Based on the result, an adjustment step (S102) described later is performed.

  In addition, about the specific method of the verification test | inspection of the cross-sectional distortion and axial center curvature of the glass tube G implemented in a confirmation process (S101), for example, the glass tube G sampled after recutting is used for a micrometer or a dial gauge. It may be measured using a measuring instrument such as, or alternatively, a measuring device using a laser beam or the like is separately provided in front of the cutting device 7 and automatically measured using this measuring device. Also good.

  As a result of the confirmation step (S101), when any of the cross-sectional distortion or the axial curvature is observed for the glass tube G, the adjustment step (S102) is performed based on the result of the confirmation step (S101). The frame member 51 of the upstream annealer 5A is moved up and down to a predetermined position and rotated by the movable mechanism (not shown) of the upstream annealer 5A described above, and the upstream annealer 5A. The heights and inclination angles of the plurality of annealers 5, 5... Located downstream are adjusted in synchronism with a holding mechanism (not shown) of the above-described annealer 5.

Here, generally, the cross-sectional distortion starts the ground contact with the support rollers 52, 52... In the annealer 5 at a position where the glass tube G drawn from the sleeve 2 is too close to the sleeve 2. This is likely to occur in some cases.
That is, since the glass tube G in a position that is too close to the sleeve 2 is still in a high temperature state and has a low viscosity, the glass tube G grounded to the support roller 52 at the contact start position with the support roller 52 is Deflection is caused by the pressure received from 52, and the cross-sectional shape is distorted into a substantially elliptical shape.

On the other hand, in the case of axial curvature, when the grounding between the glass tube G drawn from the sleeve 2 and the support rollers 52, 52,... It is thought that it is easy to occur.
That is, the glass tube G at a position where the separation distance from the sleeve 2 is too long is cooled in the air to become a low temperature state and has a high viscosity. Therefore, after the contact with the support roller 52, the correction from the curved shape to the linear shape is possible. It is hard to be done.

  Based on the above points, as a result of the execution of the confirmation step (S101), for example, when cross-sectional distortion is seen with respect to the glass tube G, the support roller 52 of the glass tube G drawn from the sleeve 2 and In the adjustment step (S102), the height and the inclination angle of the annealer 5 are adjusted so that the contact start position of the second is separated from the sleeve 2 to an appropriate position.

  Specifically, as shown in FIG. 3A, the glass tube G drawn from the sleeve 2 is guided into a plurality of annealers 5 · 5 ··· while drawing a catenary shape. 3 (a), the glass tube G is located at the most inlet portion of the upstream annealer 5A (hereinafter referred to as “first support roller 52A” as appropriate). In the confirmation step (S101), the cross-sectional distortion is confirmed with respect to the glass tube G.

  When the result of the confirmation step (S101) is obtained, in the adjustment step (S102), the height of the upstream annealer 5A is increased by the movable mechanism portion (not shown) of the upstream annealer 5A described above. The tilt angle is adjusted as appropriate.

  That is, as shown in FIG. 3B, the grounding start position of the glass tube G with the support roller 52 (for example, the support in which the glass tube G is adjacent to the first support roller 52A in FIG. 3B). The height (the dimension H1 in FIG. 3B) of the roller 52 (hereinafter referred to as “second support roller 52B” where appropriate) is the height of the contact start position (position Px) before adjustment. .. (The dimension Hx in FIG. 3A) is set at a lower position (Hx> H1), and the arrangement direction and the horizontal plane of the plurality of support rollers 52, 52. The inclination angle (angle θ1 in FIG. 3B) is set to be smaller than the inclination angle before adjustment (angle θx in FIG. 3B) (θx> θ1).

As a result, the grounding start position of the glass tube G with respect to the support roller 52 can be separated from the mandrel 2 to an appropriate position, the occurrence of cross-sectional distortion of the glass tube G is prevented as much as possible, and the quality of the glass tube G is maintained. Can be achieved. Moreover, since the adjustment of the grounding start position of the glass tube G can be performed only by changing the height and inclination angle of the upstream portion annealer 5A, the grounding start position can be quickly adjusted.
That is, when distortion of a cross-sectional shape deformed into an approximately elliptical shape is observed for an arbitrarily formed glass tube G, it takes a long time until the temperature in the muffle furnace 4 becomes stable as in the conventional case. It is possible to suppress distortion immediately without spending time, and to maintain the quality of the glass tube quickly.

  In the present embodiment, both the height and the inclination angle of the upstream annealer 5A are adjusted, but the contact start position of the glass tube G with the support roller 52 is separated from the sleeve 2 to an appropriate position. If possible, only one of the height and the tilt angle of the upstream annealer 5A may be adjusted.

  On the other hand, as a result of the execution of the confirmation step (S101), for example, when axial curvature is seen with respect to the glass tube G, the grounding start position of the glass tube G drawn from the sleeve 2 with the support roller 52 is In the adjustment step (S102), the height and the inclination angle of the annealer 5 are adjusted so as to come closer to an appropriate position than the sleeve 2.

  Specifically, as shown in FIG. 4A, the glass tube G drawn from the sleeve 2 is guided into the plurality of annealers 5 · 5 ··· while drawing a catenary shape. Confirmation step when the ground contact start position with the support roller 52 (for example, the position Py where the glass tube G contacts the second support roller 52B in FIG. 4A) is cooled in the air and in a low temperature state. In (S101), axial curvature is confirmed for the glass tube G.

  When the result of the confirmation step (S101) is obtained, in the adjustment step (S102), the height of the upstream annealer 5A is increased by the movable mechanism portion (not shown) of the upstream annealer 5A described above. The tilt angle is adjusted as appropriate.

  That is, as shown in FIG. 4B, the ground contact start position of the glass tube G with the support roller 52 (for example, the position P2 at which the glass tube G contacts the first support roller 52A in FIG. 4B). The height (dimension H2 in FIG. 4B) is set to a position higher than the height of the ground contact start position (position Py) before adjustment (dimension Hy in FIG. 4A). (Hy <H2), the inclination angle (angle θ2 in FIG. 4B) between the arrangement direction of the plurality of support rollers 52, 52,. The angle is set larger than the angle (angle θy in FIG. 3A) (θy <θ2).

As a result, since the ground contact start position of the glass tube G with the support roller 52 can be brought close to the sleeve 2 to an appropriate position, the glass tube G is prevented from being bent as much as possible. G quality can be maintained. Moreover, since the adjustment of the grounding start position of the glass tube G can be performed only by changing the height and inclination angle of the upstream portion annealer 5A, the grounding start position can be quickly adjusted.
That is, when an axial curve is observed for an arbitrary formed glass tube G, it does not take a long time until the temperature in the muffle furnace 4 becomes stable as in the prior art. The bending can be suppressed immediately, and the quality of the glass tube can be maintained quickly.

In this embodiment, both the height and the inclination angle of the upstream annealer 5A are adjusted. However, the contact start position of the glass tube G with the support roller 52 is set to an appropriate position with respect to the sleeve 2. As long as it can make it adjoin, you may adjust only any one of the height and inclination | tilt angle of 5 A of upstream part annealers.

Further, in the adjustment step (S101), when adjusting the height and the inclination angle of the upstream portion annealer 5A, the downstream side of the upstream portion annealer 5A is adjusted along with the adjustment of the height and the inclination angle of the upstream portion annealer 5A. The heights and inclination angles of the plurality of annealers 5, 5... Connected in a row are also adjusted in synchronization.
As a result, the support roller groups 52, 52, 52,... Provided in the plurality of annealers 5, 5,... Are arranged in a line along the glass tube G introduced while drawing a catenary shape. The glass tube G can be appropriately held by the plurality of support roller groups 52, 52..., And the glass tube G can be held in a natural state without any unexpected external force being added during the conveyance. It can be transported.

5 Annealer 51 Frame member 52 Support roller 100 Glass tube forming device (forming device)
G Glass tube S101 Confirmation process S102 Adjustment process

Claims (1)

A glass tube forming method for forming a glass tube provided with an annealer for gradually cooling a drawn glass tube,
The annealer is
Arranged in parallel in a straight line along the pulling direction of the glass tube, it has a plurality of support rollers for supporting the glass tube, and is movable in the vertical direction and / or rotatable in the vertical direction. And
Check the molded glass tube for distortion of the cross-sectional shape and the presence or absence of axial curvature,
Based on the confirmation result, the annealer is moved up and down to a predetermined position and / or rotated.
A method for forming a glass tube.

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