LT5291B - Forehearth feeder tube lift system - Google Patents

Abstract

A feeder tube assembly for a feeder bowl a glass melting furnace fore hearth. The feeder tube assembly has horizontally extending elongate support arm, and a feeder tube that is carried by the support arm at a location near an end of the support arm. The feeder tube is rotatable about its longitudinal central axis with respect to the support arm, and the support arm carries drive elements for rotating the feeder tube about its longitudinal central axis. The support arm is supported on a vertically extending servo motor actuated linear actuator, and the elevation of the support arm is adjustable by actuation of the linear actuator, a releasable brake being provided to prevent rotation of the servo motor when it is desired to prevent a change in elevation of the support arm. The position of the support arm relative to the linear actuator is independently adjustable both longitudinally of the support arm and transversely of the support arm, and the support is rotatable with respect to the linear actuat

Description

Bradin area

The present invention relates to a supply pipe arrangement for a glass melting furnace power supply reservoir. More particularly, the present invention relates to a clamping system for a releasable clamping delivery pipe in its operating position.

State of the art

U.S. Patent No. 5,718,741 to Hull et al., Assigned to the assignee of this application, the disclosure of which is incorporated herein by reference, discloses a supply channel for molten glass stream refrigeration as it flows from a glass melting furnace to a molten glass into a finished product, e.g. , such as hollow glass containers, which are widely used for packing various foods, beverages and other products. In equipment according to U.S. Patent No. 5,718,741, and many other supply channels, fused glass flows down through an orifice or a plurality of openings in the bottom of the supply reservoir at the end of the supply conduit away from the end into which the fused glass flows from the melting furnace.

In order to control the flow of molten glass from the feed tank feed tank, a vertically extending refractory tube with its lower end immersed in the feed tank to a level just above the bottom of the feed tank bottom and surrounding the opening or openings in the feed tank is provided. bottom, the ceramic tube is forced to rotate slowly during the operation of the supply channel to ensure proper mixing and uniform temperature of the molten glass flowing from the supply tank. A feed tank refractory pipe with a pipe twisting system of the conventional type is disclosed in U.S. Pat. No. 5,660,610 (DiFrank), also assigned to the assignee of this application, the assignment of which is also incorporated herein by reference. Other glass supply channel supply reservoir supply tube equipment is described in U.S. Patents 5,693,114 to Scott, 4,514,209 to Mumford, and 4,478,631 to Mumford, each of which is also incorporated herein by reference.

Occasionally, during operation of a glass manufacturing system using a supply pipe of a supply channel of the type described, the supply pipe and / or the supply tank must be removed for repair or replacement. In the case of replacement of the supply tank, the supply pipe is also turned horizontally from the location of the supply tank and raised vertically so that its lower edge does not touch the projection of the upper supply tank. It is also necessary from time to time to adjust the lifting of the feed pipe Because this type of feed pipe is quite bulky, it requires very high force to lift it from its working position. In the past, counterbalanced lifting mechanisms were used for this purpose, which generally used gearboxes with corresponding idle speeds, which made it very difficult to precisely position and move the feed tube. In addition, in these devices, the precise adjustment of the feed tube position in the horizontal plane in the X and / or Y directions was difficult to achieve due to the fact that the horizontal movements of the lifting mechanisms could not be isolated along the X or Y axes. In addition, the counterweight lifting mechanisms are bulky due to the weight of the structure, and the vertical feed tube sliding supports are worn by adjusting the tube up and down, which can transmit oscillatory movement to the tube support system and thus lead to unnecessary drop of glass drop section type (IS) glass container forming machine. It is also necessary from time to time to replace the supply tank itself. At the technical level, this required relocation of the entire feed pipe mechanism. The supply tube described in this type of apparatus is releasably supported by a plurality of clamps circumferentially spaced. In the past, it has been difficult to release clamps that typically have screw elements, the tendency of such elements to corrode feed pipe equipment in high temperature environments, and the requirement for workers to wear temperature-resistant clothing during this procedure are quite cluttered.

Disclosure of the Invention

The prior art and other problems of the present invention with prior art glass supply channel feed tank feed pipe lifting systems are avoided by a feed pipe lifting system which uses a common compound shaft servo motor, a ball bearing propeller lifting mechanism of sufficient power to maintain the clamping feed pipe support. mechanism with minimal deviation. Such a lifting mechanism has no idle speed or very low idle speed, thus allowing precise control of the lifting tube lift in the feed tank, which is important to accurately control the weight of the glass drop in the individual section machine during the manufacture of the glass container.

The feed tube lifting mechanism of the present invention can also precisely insulate the adjustment in the horizontal plane along both the X and Y axes, and can be slidable for wear due to slip friction, thereby avoiding oscillatory movement of the tube support system. The servo motor-driven ball-screw auger mechanism of the present invention is lubricated with grease that circulates in a closed system to ensure durability of the mechanism's bearings and ball sleeve and to prevent oil leakage and grease change.

In accordance with the present invention, and in an improved version of the present invention, the present invention provides improved clamps for releasably compressing a delivery tube by engaging a collar ring in a compression position about the edge of the delivery tube while the delivery tube is open relative to a pivotable support. Each such clamp has a variable radius cam that can be pivoted about a radially extending horizontal axis to provide safe contact with the clamping ring, despite lifting the feed pipe, but which may be unscrewed from the collision contact with the feed pipe to allow removal of the feed pipe for repair or replacement. after removing the first clamping ring used to clamp the edge of the delivery pipe.

Thus, it is an object of the present invention to provide an improved clamping system for compressing a feed tube used in a glass feed channel feed tank. More specifically, it is an object of the present invention to provide a clamping system that is quick to disengage, thus eliminating the need for screw latches for construction or installation.

For a better understanding of the present invention and its objects, reference is made to the drawings and the following brief description thereof, to the detailed description of the preferred embodiments and the appended definition.

Brief description of the drawings

FIG. 1 is a front elevational view of a delivery tube assembly comprising a clamping system according to a preferred embodiment of the present invention;

FIG. 2 shows a supply pipe assembly from FIG. 1 top view;

FIG. 3 is a sectional view along the line 3-3 of FIG. 2;

FIG. 4 is an enlarged partial view of the delivery tube assembly of FIG. 1, part view;

FIG. 5 is a partial sectional view taken along line 5-5 of FIG. 2;

FIG. 6 is a sectional view taken along line 6-6 of FIG. 5;

FIG. 7 is a view showing the supply pipe assembly of FIG. 1-6, fragmentary perspective view;

FIG. 8 is a view showing the supply pipe assembly of FIG. Partial front view of part 1-6 with partial sections;

FIG. 9 is a view similar to that of FIG. 8, turned at right angles;

FIG. 10 is a view showing the delivery tube assembly of FIG. 1-6 view from above;

FIG. 11 is a sectional view taken along line 11 -11 of FIG. 10; and

FIG. 12 is an enlarged view of a portion of the apparatus shown in FIGS. 8 and 9, perspective view;

FIG. 13 is a view similar to that of FIG. 7, illustrating a modified form of the apparatus shown therein; and

FIG. 14 is a partial view of a delivery tube device comprising a plurality of devices from FIG. 13, perspective view.

Detailed Description of Preferred Embodiments

The supply pipe arrangement 1 comprises a refractory supply pipe 2 which, as shown in Fig. 3, is adapted to be inserted into a generally horizontally continuous fused glass supply vessel B. the outlet end of the glass freezing supply channel, or vice versa (not shown), may be of conventional design. The feed pipe 2 is vertically oriented in the feed pipe assembly 1 and its lower end is located slightly above the inner surface of the feed tank B, thereby allowing the molten glass to flow through a gap below the feed pipe 2 to pass through an opening O in the bottom of feed tank B.

The feed pipe 2 has an outwardly projecting flange 3 at its upper end, which is clamped in the compression ring assembly 4 (Fig. 3) provided with the lifting lugs 5 (Fig. 4) and serves as a support for the supply pipe 2 on the rotatable ring assembly 6. a pivotable ring assembly 6 is suspended on a support branch 8 by coupling the ring gear 9 with a driven conical gear 10 on the end of a drive rod 11 driven by a motor 12 acting through a speed reducer 13, all mounted on the support. The rotation of the supply pipe 2 facilitates the proper mixing of the molten glass in the supply tank B, thereby ensuring the required homogeneity and temperature uniformity of the molten glass flowing through the openings O (Fig. 3).

The support branch 8 is supported along a vertical axis A which extends through a handle 14 which serves to lock the support branch in an unadjusted and non-rotatable position, as will be further described below. The support branch 8 is also adjustably mounted for precise movement along axis A on a vertically extending servo motor driven precision linear actuator 15 (Fig. 1), the cylindrical portion 15a (Fig. 5) of which is mounted on the frame 16 of the supply pipe device 1. is of the type available from Glastonbury E-Drive Design, Ine., Connecticut, Product Model EA2S-7.312-L / D-1836, which will be described in more detail later. The support branch 8 has an opening 17 (Fig. 5) extending concentric to the axis A and generally concentric to the longitudinal central axis of the linear actuator 15. A plurality of spaced bars 18 extend outwardly and upwardly from linear actuator 15 and are forced to move back and forth in unison along vertical axes by linear actuator 15. Rods 18 are pivotally mounted in block 19 by a composite adjusting mechanism 20 mounted on an inverted cup-shaped structure 21. , which is fixed to the upper surface of the support branch 8 (Fig. 5).

The adjusting mechanism 20 comprises a top plate 22 and the support branch 8 is movable with respect to the top plate 22 along a spaced groove 23 in the structure 21 which extends generally parallel to the longitudinal axis of the support branch 8 to accurately adjust the support branch 8 2 In the X direction. To make such an adjustment, the adjusting screw 24, which is threaded into the structure 21, has an inner edge which connects to the upper plate 22, and rotating the adjusting screw 24 pushes the support branch 8 there and back relative to the adjusting mechanism 20 advantages of attaching the linear actuator 15 to the frame 16 as described.

The adjusting mechanism 20 also includes the lower plate 25, and the support branch 8 is movable relative to the lower plate 25 along the spaced grooves 26 in the cup-shaped structure 21 extending across the longitudinal axis of the support branch 8 for precise adjustment of the support branch 8. feed tube with 2 Y pin. To effect such adjustment, the adjusting screw 27, which is threaded into the projection of the top plate 22, has an inner edge which connects to a projection 28 of the cup-shaped structure 21 and rotates the adjusting screw 27 in a Y direction relative to the adjusting mechanism. Of course, when the handle 14 is clamped downward against the projection 28, the abutment arms 8 will be prevented from moving relative to the adjusting mechanism 20 in both the X and Y directions due to friction.

Because of the high temperature environment in which the supply pipe 2 is used, it is important to cool the end of the support branch 8 on which the supply pipe 2 is suspended. The support branch 8 has an annular passage 29 (Fig. 2) surrounding and usually concentrically extending around the supply pipe 2. air or other cooling medium is forced to flow through channel 29 from inlet and outlet conduits 30, 31, respectively. In addition, a generally semi-cylindrical heat shield 32 is suspended from a support branch 8 at a location partially surrounding the upper end of linear actuator 15 and between linear actuator 15 and feed pipe 2 to stop heating of linear actuator 15 The heat emitted from feed tank B,

The flange 3 (Fig. 3) of the supply pipe 2 is securely but freely held coupled to the flange 7 by a plurality of circularly spaced locking mechanisms, each of which is usually identified by numerical reference 33 (Fig. 1), three such locking mechanisms being shown in Figs. 2. Each locking mechanism 33 has a lever 34 (Fig. 3) with a handle portion 34a at its rear end and an enlarged cam portion 34b at the opposite end. The lever 34 is pivotally connected to the support member 35 pivotally about the axis C and, when the lever is positioned vertically, the cam portion 34b is securely coupled to the upper surface of the clamp ring 36 which engages the flange 3 of the delivery tube 2. When the lever 34 is rotated to a horizontal position, the cam portion 34b is no longer coupled to the Ring 36 (Fig. 7). In this position, the feed pipe 2 can be pulled out of the feed tank B by a simple lifting motion using the lifting lugs 5 (Figs. 2 and 14). The locking mechanisms 33 can be displaced from centering with the feed tube 2 by rotation about axis D by connecting the support member 35 with the stationary structure 37. In this respect, the support element 35 slides towards the raised area 37a of the stationary structure 37 where it can then be rotated about axis D coupling with clamps 36. Before installing a new supply pipe 1, the support branch 8 must be raised so that the new supply pipe 1 does not touch the supply tank B.

The rotation of the support branch 8 about axis A is accomplished when it is decided to replace the supply reservoir B. After releasing the supply pipe 2 from the coupled position by releasing the locking mechanisms 33 and activating the linear actuator 15 to raise the support branch 8 so that the supply pipe 2 the bottom plate is released from the feed tank B, then the feed pipe 2 is lifted from the prefabricated unit 6. The upper plate 22 of the adjusting mechanism 20 is rotated with respect to the lower plate 25 by pulling a centering finger38 which circumferentially centers the upper plate 22, lower plate 25 and during supply pipe unit 1 operation.

₇ LT 5291 B

The linear actuator 15 is powered by an AC servo motor 39 which is coaxially coupled to the actuator 15, although it is believed that the connection must be parallel to the V-belt or other drive means between them. In any event, the device comprising the actuator 15 and the servo motor 39 is obtained from Glastonbury E-Drive Design, Ine., Connecticut, as previously described. As shown in Figs. 8, the motor 39 has a hollow output shaft 40. The hollow output shaft of the motor 39 is slidably slid onto the input shaft 41 (Figs. 8 and 11) of the linear drive 15, which has an internal ball gear 42, the ball gear 42 replaces the rotation of the shaft 40. moving in a linear forward or backward motion of the annular member 43, depending on the rotation protrusion of the shaft 40.

The annular member 43 can be manually inserted by rotating the lever 44 secured on the shaft 40. The shaft 40 extends to a level below the engine 39, actually below the level of the arched heat shield 45, which protects the engine 39 from thermal radiation from supply reservoir B. 44 extends outwardly from the shaft 40. The lever 44 has a handle 46 projecting downwardly radially outside the shaft 40 and the shaft 40 can be manually rotated by engaging the handle 46 and using it to rotate the lever 44.

The motor 39 has annular brakes 47 that rotate with the shaft 40, the brakes 47 being optionally coupled to a double clamping belt 48. The belt 48, when not tightened, does not engage the brakes 47 and does not produce a braking effect. Further, the band 48 may optionally be clamped by the action of the pneumatic cylinder 49 acting through the coupling system 50 and when the cylinder 49 is retracted as shown in FIG. 12, the belt 48 is clamped to engage the brakes 47, thereby preventing the shaft 40.41 from rotating, thereby locking the platform 8 to the required height.

The linear actuator 15 requires constant lubrication, so there are a plurality of grease inlet tubes 51, 52, 53, 54, 55, 56, and 57 (Fig. 4) to supply grease from a common source (not shown) to the various locations of the linear actuator 15. These locations include the inlets 58, 59 (Fig. 11) of the cylinder actuator 15a of the linear actuator 15 and each of the four rods 18 (Fig. 6) which exits. The grease is collected at the bottom of the cylinder 15a and returned to the source for recirculation by the return line 60 (Fig. 4), preferably once filtered and cooled, providing fresh additional grease as needed to compensate for any grease loss in the system. The lubrication system, as described, is a closed system that delivers sufficient lubricant on all moving surfaces while minimizing oil loss in a hot and relatively inaccessible environment and preserving the product from expensive and non-replaceable Sources.

₈ LT 5291 B

FIG. 13 and 14, which differ from the elements according to the embodiment of FIGS. 1 to 12 perform the same functions, identified by numerical references 100 in sequence, the last two digits of which correspond to the embodiment of FIG. 1-12 two-digit number of corresponding elements,

FIG. 13 illustrates a lock mechanism 133, three such lock mechanisms 133 illustrate FIG. 14, each locking mechanism 133 has a lever 134 with a handle portion 134a at its end and an enlarged cam portion 134b at the opposite end, the handle portion I34a extending from a position between the ends of the cam portion 134b, and an embodiment of FIG. . The handle portion 34a of the lever arm 33 is aligned with the end of the cam portion 34b. In this case, the cam portion 134b of the lever 134 has a profile that is much more versatile in use in various installations than the cam portion 34b of the lever 34 due to variations in the thickness of the flange portion 3 of the delivery pipe 2 in different devices. The lever 134 is pivotally connected to the support member 35 and, when the lever 134 extends vertically, the cam portion 134b securely engages the bottom of the clamping ring 136 in the cutout 136a which engages the flange of the delivery pipe by force pressing the flange 3 into the required working position. The use of a cutout 136a in the clamping ring 136 facilitates coupling of the clamping ring 136 to the cam 134b of the lever 134 and also facilitates the compression release action of the lever 133 when it is decided to replace the feed tube 2 with the lever 134 In this position, the clamping ring 136 may be raised from the position as shown in FIG. i4, thereby allowing the delivery tube to be lifted out, each locking mechanism 133 must first be pushed away from the resulting centering with the clamping ring 136 and the delivery tube 2. This is done by sliding the support member 35 into the raised area 37a of the stationary structure 37 axis D from collision with compression ring 136.

While the filing date illustrates and describes the best mode for carrying out the present invention as contemplated by the inventor, it will be apparent to those skilled in the art that appropriate modifications, departures, and equivalents may be made without departing from the scope of the invention.

Claims (21)

DEFINITION OF INVENTION 1. Glass melting furnace supply duct equipment, comprising a supply pipe arrangement for a supply tank, characterized in that the supply pipe arrangement comprises: a generally horizontally extending elongated support branch (8) having a pair of opposing ends, typically a vertically extending feed tube (2); means (33), considered as the said support branch, for detachably securing the supply pipe to the support branch, adjacent to its end; typically a vertically extending servo motor actuating a linear actuator (15) facing a support branch (8) at a position between its opposite ends, the servo motor having a linear actuator actuation means for adjusting the support arm elevation. 2. A supply pipe assembly comprising a glass melting furnace supply duct assembly according to claim 1, further comprising: means (9, 10,11, 12), held on a support branch (8) for rotating the supply pipe (2) with respect to the support branch around the longitudinal central axis of the supply pipe. 3. A supply pipe arrangement comprising a glass melting furnace supply channel assembly as claimed in claim 1, wherein the support branch (8) has an opening (17) disposed between its opposite ends, the opening being vertically centered with the longitudinal central axis of the linear drive. the ability to rotate with respect to the linear drive about the longitudinal central axis of the linear drive. 4. Glass melting furnace supply duct equipment comprising a supply pipe assembly according to Item 3, characterized in that he further has: means (20, 24) for adjusting the position of the support branch (8) with respect to the linear actuator (15), along an axis extending along the support branch. 5. Glass melting furnace supply duct equipment comprising a supply pipe assembly according to Item 4, characterized in that it still has: means (20, 26) for adjusting the position of the support branch (8) with respect to the linear drive (15), along an axis extending transversely of the support branch. 6, A glass melting furnace supply duct assembly comprising a supply pipe assembly according to claim 1, characterized in that the typically vertically extending servo motor actuated by a linear actuator (15) is comprised of a rotary movement of the output shaft of the servo motor. change to linear motion. 7, A glass melting furnace supply channel assembly comprising a supply pipe assembly according to claim 6, characterized in that the typically vertically extending servo motor actuating the linear actuator (15) further comprises means (47,48) for disconnecting the servo motor (39). from rotation. 8, A glass melting furnace supply duct assembly comprising a supply pipe assembly according to claim 1, characterized in that the support branch (8) has a second opening, the second opening of the support branch being vertically centered with the delivery pipe, and further comprising: means (29, 30, 31) for cooling the support arms (8) in the annular shell adjacent the second opening. 9, A glass melting furnace supply duct assembly comprising a supply pipe assembly as claimed in claim 6 wherein the linear actuator (15) comprises a housing (15a) and an element at least partially housed within the housing and capable of rotating relative to the housing between first and second positions. the result of rotary movement of the output shaft of the servo motor (39) and the equipment must also: a fixed support structure (16), the housing (15a) being fixedly attached to the fixed support structure (16). 10, A glass melting furnace supply duct assembly comprising a supply pipe assembly according to claim 9, wherein the linear actuator (15) further comprises: a block (19); a plurality of spaced rods (18) extending from a specified member of the linear actuator (15) to the block (19); and means for clamping the support branch (8) relative to the block (19) to prevent the support branch from rotating relative to the linear drive. 11. A glass melting furnace supply duct assembly comprising a supply pipe assembly according to claim 9, characterized in that the linear drive (15) has an input shaft (41), the linear drive input shaft is integral with the output shaft of the servo motor (39), and still have: means (44, 46) for rotating the linear drive input shaft (41) and the output shaft (40) of the servo motor (39) independently of the operation of the servo motor (39). 12. A glass melting furnace feed duct assembly comprising a feed pipe assembly according to claim 1 wherein the means for rotating the feed pipe comprises: an annular gear assembly (6), generally concentrically disposed with respect to the delivery tube (2), the annular gear (9) being constructed with respect to the delivery tube; a conical gear (10) connected to a circular gear (9); and means (11,12) for transmitting the rotational motion to the conical gear. 13. A glass melting furnace feed duct assembly comprising a feed pipe assembly, further characterized by: lubricating continuously the lubricating circulation means (51 - 57) for the actuator actuating the linear actuator (15). A glass melting furnace supply channel assembly according to one of claims 1 to 13, characterized in that it comprises a locking mechanism (33,133) for releasably securing the clamping ring (36, 136) to the flange (3) of the supply pipe (2). : a lever (34, 134) having a handle portion (34a 134a) and a cam portion (34b, 134b) with a rounded cam surface, the handle portion extending outwardly of the cam portion away from the rounded cam surface; a support member (8) and a lever (34, 134) pivotally connected to the support member near the end of that support member; and the stationary element (16) and the support element (8) pivotally connected to the stationary element near its opposite end; ₂ LT 5291 B of the support member (8) rotation of the fixed element (16), have the ability to rotate the lever (34, 134) of said collision contact clamps a ring (36, 134) to raise the compressing ring out of engagement with the supply tube (2) flange (3). 15. A glass melting furnace supply channel assembly comprising a locking mechanism according to claim 14, characterized in that the handle portion (34a) extends away from the end of the cam portion (34b). 16. A glass melting furnace supply duct assembly comprising a locking mechanism according to claim 14, characterized in that the handle portion (134a) extends outwardly from a position of the cam portion (134b) between the ends of the cam portion. 17. Glass melting furnace supply channel assembly in combination with a clamping ring used to clamp the flange of the supply pipe (2), characterized in that the clamping ring (36, 136) has an upper surface and the locking mechanism (33, 133) for the upper surface of the clamping ring. interlocking, this locking mechanism consists of: a lever (34, 134) having a handle portion (34a, 134a) and a cam portion (34b, 134b) with a rounded cam surface, the handle portion extending outwardly from the cam portion away from the rounded cam surface; a support member (8) and a lever (34, 134) pivotally connected to the support member near the end of that support member; and the stationary element (16) and the support element (8) pivotally connected to the stationary element near its opposite end; rotation of the support member (8) relative to the stationary member (16) has the ability to rotate the lever (34, 134) from the collision contact with the clamping ring (36, 134) to lift the clamping ring from its connection to the flange (3). Glass melting furnace 18. The feed equipment according to claim 17 characterized in that the squeeze ring (136) has a slot (136a) which engages the lever (134) rounded cam surface of the lever is connected to the compression clamps a ring (136) ₁₃ LT 5291 B 19. The glass melting furnace supply duct assembly of claim 18, wherein the handle portion (134a) extends outwardly from a position of the cam portion (134b) between the ends of the cam portion. 20. A glass melting furnace supply duct assembly according to claim 17, wherein the handle portion extends away from the end of the cam portion (34b). 21. A method of replacing a supply vessel (B) for a glass melting furnace supply channel, characterized in that the supply vessel has a mounting position in the equipment, the supply having a delivery tube assembly with a generally horizontally extending support branch (8) and a delivery tube (2) mounted on the end of the support branch and positioned normally with the lower end immersed in the supply tank, this method comprises the following steps: raising the support branch (8) so that the lower end (2) of the supply pipe is above the supply tank (B); rotating the support branch (8) about an axis spaced from the feed pipe (2) so that the feed pipe is not vertically centered with the feed tank (B); and then lifts the supply tank (B) out of its mounting position without otherwise removing the support branch (8).