DE2426297A1 - Outlet channel contg. heaters, coolers, and a stirrer - for homogenising molten glass leaving a glass melting furnace - Google Patents

Abstract

Feeder channel, for homogenising molten glass continuously from a melting furnace, is fitted with electrodes, for heating the stream of glass, and an oulet which, if necessary can be periodically closed by a plunger. The low furnace outlet is connected to a rising section of the channel, contg. hollow electrodes through which cooling water may be circulated, followed by a horizontal covered channel for homogenisation and then a vertical channel, with a round cross-section contg. a rotating stirrer; the ends of the blades of the stirrer are close to the wall of the channel and the leading edges of the blades are on top. Better thermal and chemical homogeneity of the glass leaving the outlet is obtd.

Description

Feeder channel for homogenizing continuously from a melting tank peeled glass The invention relates to a feed channel for homogenizing Glass continuously withdrawn from a melting tank with electrodes for heating of the glass stream and with a feeder outlet, which is optionally periodically from a Plunger is closed and opened.

There are already feeder channels for the homogenization of continuous Known from a melting tank peeled glass, which consists of shallow channels of various There are widths and depths, and which are created by burners or by radiating elements heated from above or

cooled in other places by exposing the glass surface will.

It is disadvantageous and obvious to the person skilled in the art that in such a channel result in considerable temperature differences between the glass, which flows on the surface or the ground. The required quality Homogenization for the later formation of glass gobs of the same size or for further processing is therefore not given.

It is also known through the additional installation of electrodes and direct heating of the glass to achieve improved homogeneity. As per experience but even these additional funds are not suitable, a sufficiently large or to set even complete temperature homogeneity.

It is also disadvantageous in the known feeder ducts that the large glass surfaces lead to evaporation losses, especially with glasses easily evaporating components lead, so that in addition to thermal inhomogeneity a chemical inhomogenitrate is generated.

It is known that even great technical effort in the known Feeder ducts only lead to an imperfect solution in terms of the desired uniformity Has led to temperature distribution in the outflowing glass.

It is accordingly the object of the invention to provide an economical one and to create short risers that are much better thermal and chemical homogeneity enabled and even for practical purposes and within the usual measuring accuracy can set a perfect homogeneity.

The feeder channel according to the invention should continue to be only short in length have little space requirement and process a high glass throughput can.

This object is achieved in that the initially called feeder channel in the ascending channel part following the low-lying one Furnace outlet - a number of electrodes arranged for the flow of cooling water, then in the direction of flow of the glass a horizontal duct section without a free surface for homogenization and then a vertically ascending duct section with a round one Has cross-section in which a stirrer rotates, the blade ends of which close to the duct wall extends and its leading blade edges at the top, i.e. in the direction of flow of the glass are at the back.

The feeder duct according to the invention can advantageously be used for easy control and control a arranged behind the electrodes in the flow direction of the glass and thermocouple immersed in the glass and depending on control signals movable insulating elements have in the ascending canal part.

To reduce the homogeneity of the already homogenized glass can be avoided over the free glass surfaces in the direction of flow of the glass be mounted behind the stirrer a number of radiation elements and around the A heating coil can be laid around the feeder outlet.

The electrodes are within the feeder channel according to the invention advantageously hollow cylinders through which cooling water flows from an electrode tube Mitteilbohrung exist, with a sleeve on both sides on the end faces wear high-temperature, stainless steel, to which a power supply cable and a cooling water supply and drainage can be connected.

In order to prevent air from entering the when the cooling water is shut off To avoid electrodes and thus an oxidation of the electrodes from the inside, can a SIagnetic Rickschlag valve must be installed in the cooling water supply line and a Uniform and low-resistance transmission of electrical energy from the sleeves to enable the electrodes, between the sleeve base and the end faces A ring made of plastic sealing metal is inserted into the electrodes be and to allow easy replacement of the electrodes, one of the Sleeve ends to be attached to a replacement sleeve.

For precise temperature setting and equalization of the Drops emerging from the feed opening are advantageous with additional heating provided with the support of the drip ring as an electrode.

In detail, the drip ring is outwardly supported by a support ring held, on which a power supply line is attached and wherein the drip ring is radial and optionally has circumferential bores extending obliquely upward, which have a Form the current path from the ring to the exiting drop, the ring in turn electrically interconnected with other electrodes installed in the feeder head is.

In this way a supply of heating current is created on the surface of the emerging droplet that has cooled down the most brought. The drop is heated where its temperature has dropped the most can be and there is thereby a temperature homogenization also of the already formed, escaping drop reached.

The prerequisite is that the holes in the head ring from Glass are filled, which has such a high temperature that it is already conductive is. Surprisingly this is the case and it has been shown that the power line through the holes works without difficulty.

To avoid oxidation of the ring, it is in the area of the Boreholes advantageously platinum-plated or with a different, conductive and non-oxidizing material Surface coating provided.

The temperature of the exiting drops is advantageous by a Thermocouple measured that a drip ring or above the drip ring for contact is inserted with the emerging droplet and it can be due to the temperature signal This 4AHs thermocouple can be used to regulate the drop temperature. It has been shown that due to the direct measurement and direct influence the drop temperature this kept constant to a previously unknown extent can be.

The ring serving as an electrode is used to avoid heat loss to the outside additionally protected by an insulation layer, which in turn is protected by a Retaining ring is held.

It is surprising to the person skilled in the art that by in and of itself simple elements of the device, especially through their combination the effect according to the invention of homogenization which is perfect for practical purposes of the glass flow is achievable.

In the following an embodiment of the invention is based on Drawings described in more detail. They show: FIG. 1 a schematic section through a feeder channel according to the invention, FIG. 2 shows a schematic section through one of the electrodes arranged transversely in the feeder channel and FIG. 3 shows a schematic Cross section through the feeder opening.

According to FIG. 1, the feeder channel according to the invention closes at a flow 1, which connects to a melting tank 2 or a deep distribution channel creates. The feeder channel according to the invention then leads to the throughflow 1 obliquely or vertically upwards and has a rectangular cross-section.

In the ascending channel part 3 are combined heating and Sühlelemente or electrodes a, b, c, and d with internal cooling are used. The electrodes exist made of molybdenum and have a training as will be discussed later in connection with Fig. 2 will be described in more detail.

A horizontal channel part 4 also connects to the channel part 3 round cross-section, which is so deep that the apex line of the channel below the deepest glass level of the glass melting tank. The channel part 4 is always completely filled with glass.

In order to achieve improved regulation, the walls of the duct part are 3 shielded with movable insulating elements 10, which, if the glass temperature is too high, removed and reapplied if the glass temperature is too low.

The horizontal channel part 4 is so strongly insulated that practically none Heat losses occur. This horizontal channel part 4 is followed by a vertical one Channel part 5 with a round cross-section, in which a ceramic agitator 6 with inclined blades or paddles from above through the free glass surface immersed.

The blade length of the stirrer 6 is so missing that the entire glass flow until close to the walls of the channel part 5 is swept and the direction of rotation is For the inclined paddles, select the one that is at the front in the direction of rotation Blade edge is on top, so a reaction is exerted on the glass flow that counteracts the direction of flow.

Because of this setting, the stirrer 6 performs a complete cycle Mixing of the rising glass stream.

A horizontal short channel part closes at the ascending channel part 5 7, which opens into a normal feeder bowl 8. The channel part 7 and 8 are covered as much as possible so that only as much free surface remains as there is required for the rotary tube, the plunger and to replace the ceramic stirrer is.

To simplify the illustration, both for the rotary kiln as also only the passages are shown for the plunger. The heat losses of the short horizontal piece and above the feeder bowl 8 are heated by heating elements 11 covered in the form of Silitstäben, which by means of radiation on the glass surface hold at the desired temperature. The heating elements 11 are on attached to the edges of the free surfaces.

There is also a heating coil 12 around the feeder bowl, which covers the heat losses at the lower edge of the feeder bowl.

Regarding the regulation of the inventive feeder channel is still in the horizontal channel part Lt uses a thermocouple 9, which is inserted into the glass melt immersed and continuously determines the temperature, which is already largely uniform and reports to suitable regulatory bodies known to those skilled in the art.

All parts of the feeder channel with the exception of section 3 are with well-known, permanently installed insulation provided, the heat losses and thus Avoid inhomogeneities in the glass stream.

The feeder duct according to the invention now works as follows: That out the passage 1 coming glass is in the channel part 3 depending on requirements due accordingly the measured value of the thermocouple 9 heated or cooled.

Since the combined heating and cooling elements a, b, c, and d with water are flowed through, they can be used as heating elements in the usual way and when switched off of Stromes serve as cooling elements. The current flows between The electrodes are transferred from the electrodes through the glass bath and heat the hot State of conductive glass by resistance heating.

The amount of water is set using control valves (not shown). It is obvious to those skilled in the art that instead of those shown in the drawing four electrodes through which water flows, any other number depending on the dimensions of the feeder duct can be used.

The cooling effect in the channel part 3 can be achieved by opening the movable insulating elements 10 can be intensified, accordingly, the heating effect can be achieved by closing the movable insulating elements are also reinforced.

The voltage on electrodes a, b, c and d is also not over Shown organs adjustable, so that any desired energy value through the glass to Heating of the same can be conducted. The dimensioning of the individual elements is to be done so that at the end of section 3 of the feeder channel the glass has on average a temperature as in the feeder head or in the feeder bowl is required for drop formation.

A further homogenization occurs in the section Lt of the feeder channel of the glass in that neither heat is added nor removed and the temperature of the individual glass flow filaments through heat dissipation or heat absorption among each other is balanced.

The length and the diameter of the channel part 4 is the desired one Adjust performance.

A further homogenization of the glass takes place in the channel part 5 the ceramic stirrer 6, which swirls the entire amount of glass, because its Paddles extend to the edge of the channel part 5.

It can be seen that the heat losses are set in the short term Pieces 7 and the feeder head 8 extremely small and are also due to the heating elements 11 and the heating coil 12 are balanced.

It is particularly advantageous that the length of the invention Feeder channel compared to conventional feeders of the same power is lower because the flow velocity in the individual duct parts because of the larger cross-section can be lower.

In FIG. 2, electrodes a, b, c and d are denoted by the reference numeral 23 marked. The electrodes 23 are tubular and have a water flow through them Inner bore 24. Sleeves 25 are made of a heat-resistant one on both end faces and stainless steel, which cover the electrodes almost as far as the electrodes extend within the channel wall 21 made of refractory material.

To ensure an even supply of current to the front sides of the electrodes -to achieve is between the sleeve base and the end faces of the electrodes 23 each a flat ring made of a slightly under the prevailing temperatures plastic metal, e.g. B. silver solder, inserted.

The outer ends of the sleeves go over an intermediate piece made of water glass to the electrode to prevent the liquid ends from being attacked by liquid glass.

In the end faces of the sleeves 25 are the inlet and outlet lines for the cooling water is used, the supply line 28 being a magnetic check valve 30 wears, which closes immediately if the cooling water is switched off or fails and prevents air from entering.

In this way, oxidation of the inside of the electrode is also prevented, because the remaining cooling water still evaporates well above the oxidation temperature thus creating an inert atmosphere.

The power supply line 31 for the alternating current used for heating is applied. Furthermore, one of the End faces of the sleeves 25 an exchange sleeve 29 can be attached, the z. B. over the cooling water drain 27 attacks. When pulling out an electrode rod so that the next electrode can be drawn in immediately.

Obviously, the regulation is very inert because the thermocouple 9 the temperature of the glass flowing through directly behind the heating or cooling zone determined in the channel part 3. Due to the large control options - strong cooling and Strong heating - can also regulate the glass temperature and homogenization can then be achieved when the inflowing glass is strongly opposed in temperature the desired value slightly or extremely unevenly in the temperature cross-section is.

Overall, it can be said that the feeder channel according to the invention represents a superior solution to the problems at hand.

According to Fig. 3, the feeder outflow is in addition to heating the outflow or droplets ejected from the plunger. The drip ring 35 has a Number of holes 34 in which there is hot and molten glass and forms a conductive bridge to the support ring 36 which is the drip ring 35 holds from the outside. A power supply line 37 is attached to the support ring 36, over which electrical current is supplied. The support ring 36 is opposite connected to other electrodes, not shown, in the feeder head and the current flows So through the glass in the holes 34 through the exiting drops in the feeder head.

In order to prevent heat flow to the outside, the temperature inhomogeneities as well would produce, an insulation layer is on the outside of the support or electrode ring 36 33 attached, which in turn is held by a retaining ring 32.

Above the head ring 35 is a thermocouple 38 which sets one is carried out to the edge of the emerging droplets and what the temperature the drop measures directly. About the signal of the thermocouple 38 is an exact one Regulation of the drop temperature possible, since the current flow from the ring 36 accordingly can be adjusted.

The heating through the bores 34 is particularly advantageous at the points where there is increased cooling of the drop, namely at Drop surface.

In order to prevent oxidation or corrosion of the support member 36 in the area of the To prevent holes 34, the ring is there or on its entire surface platinum-plated or with another conductive and non-oxidizing surface coating Mistake.

To prevent corrosion in the electrodes 23 in the feeder channel it is also provided that in this an inner tube made of stainless steel, E.g. made of Inconel or Nimonic. It is prevented in this way that within the electrodes 23 even in the presence of oxidizing media a Oxidation or even embrittlement of the molybdenum of the actual electrode takes place.

Claims (12)

Patent claims: 1. Feeder channel for homogenizing continuously from a melting tank stripped glass with electrodes for heating the glass flow and with a feeder outlet, which, if necessary, is periodically closed and opened by a plunger, characterized in that it is in the ascending channel part (3) following the deep furnace outlet (1) a number of set up for the flow of cooling water Electrodes (a, b, c, d), then a horizontal channel part in the direction of flow of the glass (4) without a free surface for homogenization and then a vertically rising surface Has channel part (5) with a round cross-section, in which a stirrer (6) rotates, whose The blade ends reach close to the channel wall and its leading blade edges at the top, i.e. at the back in the direction of flow of the glass. 2. Feeder duct according to claim 1, characterized by one in the direction of flow of the glass behind the electrodes (a, b, c, d) and immersed in the glass Thermocouple (9). 3. Feeder channel according to claim 1 to 2, characterized by as a function of control signals movable insulating elements (10) in the ascending duct part (3). 4. feeder duct according to claim 1 to 3, characterized in that over the free glass surfaces in the direction of flow of the glass behind the stirrer (6) Radiant elements (11) are attached and a heating coil around the feeder outlet (12) is lying around. 5. feeder duct according to claim 1 to Lt, characterized in that the electrodes (a, b, c, d) are hollow cylinders consisting of an electrode tube (23) with a central bore (24) through which cooling water flows, on both sides on the end faces wear a sleeve (25) made of high temperature resistant, stainless steel to which a Power supply cable (31) and a cooling water supply line (27) and drainage line (28) connected. 6. feeder duct according to claim 4 and 5, characterized in that a solenoid check valve (30) is built into the cooling water supply line (28). 7. feeder duct according to claim 4 to 6, characterized in that a ring (26) between the sleeve base and the end faces of the electrodes (23) made of plastic sealing metal is inserted. 8. feeder duct according to claim 4 to 7, characterized in that an exchange sleeve (29) is attached to one of the sleeves (25) 9. Outflow opening for a feeder channel according to claim 1 to 8 ,, with a conical, ceramic drip ring and a plunger that moves concentrically up and down, characterized in that the head ring (35) extends outwardly from a support ring (36) is held, on which a power supply line (37) is attached and that the drip ring (35) circumferential bores running radially and, if necessary, obliquely upwards (34) which form a current path from the ring (36) to the exiting drops, the ring (36) being electrically connected to other electrodes mounted in the feeder head is switched together. 10. Outflow opening according to claim 9, characterized in that the Ring (36) in the area of the bores (34) platinum-plated or with another conductive one and non-oxidizing surface coating is provided. 11. Outflow opening according to claim 9 and 1Q, characterized in that that a thermocouple (38) for measuring the drop temperature in or above of the drip ring (35) is used for contact with the exiting drop. 12. Outflow opening according to claim 9 to 11, characterized in that that the ring (36) has an insulating layer (33) with a retaining ring (32) on the outside having. Blank page