The present disclosure relates to feeders for delivering vertical runners of molten glass to a shear mechanism which severs the runners into discrete gobs for distribution to a glass container forming apparatus. The present disclosure more particularly relates to the refractory orifice ring for such apparatus which has one or a plurality of holes distributing a corresponding number of continuous runners of molten glass to the shear mechanism.
Glass feeders are shown in U.S. Pat. Nos. 4,554,000 and 4,999,040, the disclosures of which are herein incorporated by reference. Such feeders have a spout bowl which has a cylindrical vertical outlet at the bottom. This cylindrical outlet is closed by a circular orifice plate which has one, two, three or four in-line holes through which the glass passes. Plungers, corresponding in number and location to the holes in the orifice plate, are located within the cylindrical outlet and reciprocate vertically to form the runners as they are sheared into the gobs.
With specific to
The orifice ring 20 has a plurality of holes 32. The side wall 34 of the orifice plate extends from a top edge 36 to bottom outside edge 38 which intersects a bottom wall 40. The bottom wall 40 of the orifice plate has a uniform thickness where it joins the side wall, except where a pair of parallel strengthening ribs 42 are located. These strengthening ribs extend perpendicular to the array of holes 32 from one side of the orifice plate to the other, and merge with the sidewall 34 to define localized areas 33 at the periphery of the orifice plate. Grooves 44 are defined in these strengthening ribs to receive cooling tubes (not shown) which maintain constant temperature across each hole.
The present disclosure is particularly directed to an improved orifice ring construction that provides improved life and reduced variation in gob size.
The function of the orifice ring is to control the diameter of the molten glass gob and the number of gobs required for the particular glass operation. The orifice ring is typically circular or elliptical and contains the appropriate number of gob holes, normally from one to four holes, centrally located in the orifice ring. The orifice ring is installed in the bottom of a spout. The molten glass is forced through the holes in the orifice ring by means of mechanical force from plunger(s) located above the orifice ring.
Failure of the orifice ring can affect the glass in several significant ways. First, a fissure can score the surface of the glass and pass an imperfection on to the finished product. Second, a faulty orifice ring can allow the molten glass to leak from the feeder. Third, variation in gob weight delivered by the orifice ring can cause variation in the resultant product and potentially unacceptability. These are each serious problems that can be expensive if they remain undetected. Failure also, of course, causes production time to be lost while the orifice ring is replaced and the system returned to normal.
According to a first embodiment, a refractory orifice ring of a glass forming apparatus is provided. The orifice ring has an annular side wall, and a base wall. At least one discharge hole is formed in the base wall. The discharge hole has a top opening and a bottom opening, wherein the top opening includes a surface area which is larger than a surface area of the bottom opening.
According to a second embodiment, a refractory orifice ring of a glass forming apparatus is provided. The orifice ring includes an annular side wall and a base wall. At least one discharge hole is formed in the base wall. The discharge hole includes a top opening and a bottom opening, wherein the top opening has a width at its smallest dimension which is greater than a width of the bottom opening at its largest dimension.
The present inventive orifice ring has been found to improve operational longevity by providing a longer throat hole which wears top down. The present inventive orifice ring has also been found to reduce gob weight variation by between about 20 and about 50 percent.
A typical orifice ring will be constructed of a high purity refractory composition of alumina-zirconia-silica such as Pyroguard Wearshield Z200 available from Pyrotek Inc. Of course, alternative refractory materials known to the skilled artisan are equally suitable for use in the present orifice ring construction.
Referring now to
Each of the discharge holes 105 and 106 can have a top opening 107 and a bottom opening 109. The top opening 107 is configured to be of a larger dimension than the bottom opening 109. In this regard, although the depicted discharge hole is circular at both the top and bottom opening, it is envisioned that different geometric configurations could be employed. For example, a circular top opening could be employed with an elliptical bottom opening. Moreover, the specific shape of the openings is not intended to be limiting provided the surface area of the bottom opening is smaller than the surface area of the top opening (i.e. the discharge hole has a narrowing between top opening and bottom opening).
Although the holes can be configured in any shape desired by the skilled artisan, in the depicted design the top opening and bottom opening are each circular in cross-section. This configuration, in combination with the inwardly slanted side wall 111 combines to form a discharge hole 105 having a shape in the form of a truncated cone 113 (see
The orifice ring 100 can generally be formed by casting. The cast body, as shown in
With reference to
In the embodiment of
To provide a suitably robust orifice ring, it is contemplated that the base wall 103 will have a height BH greater than a height SH and width SW of the corresponding annular side wall (see
To further improve performance and longevity, it may be desirable to provide the inner surface 121 of the annular side wall 101 with an inward slope as it approaches the base wall 103. It may similarly be desirable to provide the corner forming the intersection between the inner surface 121 of the annular side wall 101 and base wall 103 with a filleted or chamfered shape. Similarly, it may be desirable to form the corner 131 between base wall 103 and wall 111 forming discharge hole 105 with one of a chamfered and/or radiused shape.
For ease of construction, the exterior surface 139 of the base wall 103 may be similarly constructed with a truncated cone configuration. It is also observed that longevity of the orifice ring may be improved by providing a neck 141 adjacent to the bottom opening 109 of the discharge hole 105.
With reference now to
The exemplary embodiment has been described with reference to the preferred embodiments. Obviously, modifications and alterations will occur to others upon reading and understanding the preceding detailed description. It is intended that the exemplary embodiment be construed as including all such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.
This application claims the benefit of U.S. Provisional Application No. 62/111,777, filed Feb. 4, 2015, the disclosure of which is hereby incorporated by reference.
Number | Date | Country | |
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62111777 | Feb 2015 | US |