CN210635888U - High-temperature-resistant dropping pipe for producing glassware - Google Patents

Abstract

The utility model relates to a production glassware is with high temperature resistant material pipe that drips, annular plate A upper surface is placed graphite pipe A, pipe A is established to the outside cover of graphite pipe A, graphite pipe A and pipe A clearance fit, pipe B is established to the outside cover of pipe A, pipe B is located annular plate A top, pipe A, pipe B is fixed with annular plate A respectively, annular plate B is established to graphite pipe A upper portion cover, pipe A upper end and annular plate B lower fixed surface, annular plate B's lateral wall and pipe B inside wall upper end are fixed, pipe A, pipe B, annular plate A, enclose the cavity between the annular plate B, the ring flange is established to the fixed cover in pipe B lateral wall upper portion, the fixed pipe C in pipe B lateral wall upper portion, pipe C and cavity intercommunication, the fixed pipe D in pipe B lateral wall lower part, pipe D and cavity intercommunication. The utility model discloses beneficial effect: the molten glass liquid is not easy to solidify on the inner side wall of the dropping pipe, the dropping pipe is convenient to maintain, and the dropping pipe can be recycled.

Description

High-temperature-resistant dropping pipe for producing glassware

Technical Field

The utility model relates to a drip pipe, in particular to a high temperature resistant drip pipe for producing glassware.

Background

The material dropping pipe is an important guide pipe on equipment for producing glassware, at present, the existing material dropping pipe is a stainless steel guide pipe, in order to prevent the material dropping pipe from being heated in the guide process, the temperature of the wall of the material dropping pipe rises, the existing material dropping pipe adopts circulating water to cool the material dropping pipe, the cooling of the material dropping pipe is uneven, molten glass liquid is easy to solidify on the inner side wall of the material dropping pipe, the material dropping pipe can only be scrapped, and the production cost is increased.

SUMMERY OF THE UTILITY MODEL

The utility model discloses the technical problem that will solve is: the utility model provides a production glassware is with high temperature resistant material dropping pipe, has solved current material dropping pipe cooling inhomogeneous, and molten form glass liquid solidifies easily on the intraductal lateral wall of material dropping, and the material dropping pipe can only scrap the processing, has increased manufacturing cost's problem.

The utility model discloses a solve the technical scheme that the problem that the aforesaid provided adopted and be:

a high-temperature resistant dripping pipe for producing glassware comprises a round pipe A1, a round pipe B2, an annular plate A3, a through hole A301, an annular plate B4, a through hole B401, a graphite pipe A5, a flange plate 6, a cavity 7, a round pipe C8 and a round pipe D9, wherein a graphite pipe A5 is placed on the upper surface of the annular plate A3, the round pipe A5 is sleeved outside the graphite pipe A5, the graphite pipe A5 is in clearance fit with the round pipe A5, the inner diameter of the graphite pipe A5 is smaller than the diameter of the through hole A301 on the annular plate A5, the round pipe B5 is sleeved outside the round pipe A5, the round pipe B5 is positioned above the annular plate A5, the round pipe A5 and the round pipe B5 are respectively and fixedly connected with the annular plate A5, the annular plate B5 is sleeved on the upper part of the graphite pipe A5, the annular plate A5 is fixedly connected with the inner side wall of the upper end of the annular plate B5, the inner side wall of the annular plate B5 is fixedly connected with the inner side wall of the annular plate B5, a cavity 7 is defined among the round tube A1, the round tube B2, the annular plate A3 and the annular plate B4, a flange plate 6 is fixedly sleeved on the upper portion of the outer side wall of the round tube B2, a round tube C8 is fixedly arranged on the upper portion of the outer side wall of the round tube B2, the round tube C8 is communicated with the cavity 7, a round tube D9 is fixedly arranged on the lower portion of the outer side wall of the round tube B2, and the round tube D9 is communicated with the cavity 7.

The lower end of the outer side wall of the graphite tube A5 is provided with a notch 501, the notch 501 at the lower end of the graphite tube A5 is positioned at the inner side of the through hole A301 on the annular plate A3, and molten glass in a molten state is prevented from being adhered to the annular plate A3.

The lower surface of the annular plate A3 is fixedly provided with a round tube E10, and the inner diameter of the round tube E10 is larger than that of the graphite tube A5, so that the glass liquid falling off from the lower end of the graphite tube A5 is guided.

The upper end of the round tube B2 is fixedly provided with a round tube F11, an internal thread 1101 is formed in the round tube F11, an external thread 1201 is formed in the round tube G12, the external thread 1201 formed in the round tube G12 is matched with the internal thread 1101 formed in the round tube F11, the lower portion of the inner side wall of the round tube G12 is provided with a conical structure A1202, the lower portion of the graphite tube B13 is provided with a conical structure B1301, the graphite tube B13 is located inside the round tube G12, the minimum diameter of the graphite tube B13 is the same as the inner diameter of the graphite tube A5, and the falling molten glass is guided.

The upper surface of the round tube G12 is provided with a threaded counter bore 14, the upper part of the hexagon socket head cap screw 15 is sleeved with a gasket 16, the hexagon socket head cap screw 15 is matched with the threaded counter bore 14, the right edge of the gasket 16 is positioned above the left of the upper surface of the graphite tube B13, and the graphite tube B13 is prevented from falling out of the round tube G12.

The utility model discloses a theory of operation: fixing a high-temperature resistant dripping pipe for producing glassware at a required position of production equipment through a flange plate, introducing water into a round pipe C, discharging the water from a round pipe D after passing through a cavity, discharging molten glass liquid falling after shearing into a graphite pipe B, discharging the glass liquid into the graphite pipe A through the graphite pipe B, transferring the temperature of the glass liquid to the graphite pipe A, transferring the temperature of the graphite pipe A to the round pipe A, transferring the overhigh temperature of the round pipe A through the water in the cavity, discharging the glass liquid through the lower end of the graphite pipe A, limiting the glass liquid falling from the graphite pipe A and deviating from the required position by the round pipe E, feeding the glass liquid into the next process, controlling the glass liquid to fall to other positions through the production equipment if the dripping pipe is blocked, detaching the dripping pipe connected through the flange plate, detaching an inner hexagonal bolt gasket, inverting the dripping pipe, sequentially pouring the graphite pipe B and the graphite pipe A, and overturning the dripping pipe, and (3) loading a new graphite tube A and a new graphite tube B in sequence, re-fastening the hexagon socket head cap screw and the gasket in the threaded counter bore, re-fixing the material dripping tube through the flange plate, and controlling the molten glass to fall to the original position again through production equipment.

The beneficial effects of the utility model reside in that: 1. the cooling of the dropping pipe is not uniform, the molten glass liquid is not easy to solidify on the inner side wall of the dropping pipe, the maintenance of the dropping pipe is convenient, the dropping pipe can be recycled, and the production cost is reduced. 2. The lower end of the outer side wall of the graphite tube A is provided with a notch, and the notch at the lower end of the graphite tube A is positioned on the inner side of the through hole A on the annular plate A to prevent molten glass from being adhered to the annular plate A. 3. The lower surface of the annular plate A is fixedly provided with a circular tube E, and the inner diameter of the circular tube E is larger than that of the graphite tube A, so that the lower end of the graphite tube A is guided by the inclined glass liquid. 4. The fixed pipe F that sets up in pipe B upper end, set up the internal thread on the pipe F, set up the external screw thread on the pipe G, the external screw thread of seting up on the pipe G with the internal thread that sets up on the pipe F cooperatees, pipe G inside wall lower part sets up to conical structure A, and graphite tube B lower part is conical structure B, graphite tube B is located inside the pipe G, graphite tube B's minimum diameter with graphite tube A's internal diameter is the same, gives the glass liquid direction of whereabouts. 5. The upper surface of the round tube G is provided with a threaded counter bore, the upper part of the hexagon socket head cap is provided with a gasket, the hexagon socket head cap bolt is matched with the threaded counter bore, and the right edge of the gasket is positioned above the left upper surface of the graphite tube B to prevent the graphite tube B from falling out of the round tube G.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural view of the round tube E of the present invention.

The device comprises a 1-round pipe A, a 2-round pipe B, a 3-annular plate A, a 301-through hole A, a 4-annular plate B, a 401-through hole B, a 5-graphite pipe A, 501-notches, a 6-flange plate, a 7-cavity, an 8-round pipe C, a 9-round pipe D, a 10-round pipe E, an 11-round pipe F, an 1101-internal thread, a 12-round pipe G, a 1201-external thread, a 1202-conical structure A, a 13-graphite pipe B, a 1301-conical structure B, a 14-thread counter bore, a 15-hexagon socket head cap screw and a 16-gasket.

Detailed Description

The embodiments of the present invention will be further explained with reference to the drawings.

The first embodiment is as follows:

referring to fig. 1, a high temperature resistant dropping tube for producing glassware according to this embodiment includes a circular tube a1, a circular tube B2, an annular plate A3, a through hole a301, an annular plate B4, a through hole B401, a graphite tube A5, a flange 6, a cavity 7, a circular tube C8, and a circular tube D9, a graphite tube A5 is placed on an upper surface of an annular plate A3, a circular tube a1 is sleeved outside the graphite tube A5, the graphite tube A5 is in clearance fit with the circular tube a1, an inner diameter of the graphite tube A5 is smaller than a diameter of the through hole a301 on the annular plate A3, a circular tube B1 is sleeved outside the circular tube a1, the circular tube B1 is located above the annular plate a1, the circular tubes a1 and B1 are respectively fixedly connected with the annular plate a1, a1 is sleeved on an upper portion of the annular plate a1, an outer diameter of the graphite tube a1 is smaller than an inner diameter of the annular plate B1, and an upper end of the circular tube a1 is fixedly connected with a1, the outer side wall of the annular plate B4 is fixedly connected with the upper end of the inner side wall of the circular tube B2, a cavity 7 is defined among the circular tube A1, the circular tube B2, the annular plate A3 and the annular plate B4, the upper portion of the outer side wall of the circular tube B2 is fixedly sleeved with the flange 6, the upper portion of the outer side wall of the circular tube B2 is fixedly provided with a circular tube C8, the circular tube C8 is communicated with the cavity 7, the lower portion of the outer side wall of the circular tube B2 is fixedly provided with a circular tube D9, and the circular tube D9 is.

The working principle of the specific embodiment is as follows: fixing a high-temperature resistant dripping pipe for producing glassware at a required position of production equipment through a flange plate, introducing water into a circular pipe C, flowing out of a circular pipe D after the water passes through a cavity, dropping molten glass liquid after shearing into a graphite pipe A,

the temperature on the glass liquid is transmitted to a graphite pipe A, the temperature on the graphite pipe A is transmitted to a round pipe A, the excessive temperature on the round pipe A is transmitted out through water in a cavity, the glass liquid enters the next process through the glass liquid after the glass liquid falls from the lower end of the graphite pipe A, if the dripping pipe is blocked, the glass liquid falls to other positions through production equipment control, the dripping pipe connected through a flange plate is detached, the dripping pipe is inverted, the graphite pipe A is poured out, the dripping pipe is turned over, a new graphite pipe A is installed again, the dripping pipe is fixed again through the flange plate, and the glass liquid falls to the original position through the production equipment control again.

The beneficial effects of the embodiment are as follows: the cooling of the dropping pipe is not uniform, the molten glass liquid is not easy to solidify on the inner side wall of the dropping pipe, the maintenance of the dropping pipe is convenient, the dropping pipe can be recycled, and the production cost is reduced.

Example two:

referring to fig. 2, the high temperature resistant dropping pipe for producing glassware according to this embodiment includes a circular pipe a1, a circular pipe B2, an annular plate A3, a through hole a301, an annular plate B4, a through hole B401, a graphite pipe A5, a flange 6, a cavity 7, a circular pipe C8, and a circular pipe D9, where a graphite pipe A5 is placed on an upper surface of an annular plate A3, a circular pipe a1 is sleeved outside the graphite pipe A5, the graphite pipe A5 is in clearance fit with the circular pipe a1, an inner diameter of the graphite pipe A5 is smaller than a diameter of the through hole a301 on the annular plate A3, a circular pipe B1 is sleeved outside the circular pipe a1, the circular pipe B1 is located above the annular plate a1, the circular pipes a1 and B1 are respectively fixedly connected with the annular plate a1, a1 is sleeved on an upper portion of the annular plate a1, an outer diameter of the graphite pipe a1 is smaller than an inner diameter of the annular plate B1, and an upper end of the circular pipe B1 is fixedly connected with a1, the outer side wall of the annular plate B4 is fixedly connected with the upper end of the inner side wall of the circular tube B2, a cavity 7 is defined among the circular tube A1, the circular tube B2, the annular plate A3 and the annular plate B4, the upper portion of the outer side wall of the circular tube B2 is fixedly sleeved with the flange 6, the upper portion of the outer side wall of the circular tube B2 is fixedly provided with a circular tube C8, the circular tube C8 is communicated with the cavity 7, the lower portion of the outer side wall of the circular tube B2 is fixedly provided with a circular tube D9, and the circular tube D9 is.

The lower end of the outer side wall of the graphite tube A5 is provided with a notch 501, the notch 501 at the lower end of the graphite tube A5 is positioned at the inner side of the through hole A301 on the annular plate A3, and molten glass in a molten state is prevented from being adhered to the annular plate A3.

The lower surface of the annular plate A3 is fixedly provided with a round tube E10, and the inner diameter of the round tube E10 is larger than that of the graphite tube A5, so that the glass liquid falling off from the lower end of the graphite tube A5 is guided.

The upper end of the round tube B2 is fixedly provided with a round tube F11, an internal thread 1101 is formed in the round tube F11, an external thread 1201 is formed in the round tube G12, the external thread 1201 formed in the round tube G12 is matched with the internal thread 1101 formed in the round tube F11, the lower portion of the inner side wall of the round tube G12 is provided with a conical structure A1202, the lower portion of the graphite tube B13 is provided with a conical structure B1301, the graphite tube B13 is located inside the round tube G12, the minimum diameter of the graphite tube B13 is the same as the inner diameter of the graphite tube A5, and the falling molten glass is guided.

The upper surface of the round tube G12 is provided with a threaded counter bore 14, the upper part of the hexagon socket head cap screw 15 is sleeved with a gasket 16, the hexagon socket head cap screw 15 is matched with the threaded counter bore 14, the right edge of the gasket 16 is positioned above the left of the upper surface of the graphite tube B13, and the graphite tube B13 is prevented from falling out of the round tube G12.

The working principle of the specific embodiment is as follows: fixing a high-temperature resistant dripping pipe for producing glassware at a required position of production equipment through a flange plate, introducing water into a round pipe C, discharging the water from a round pipe D after passing through a cavity, discharging molten glass liquid falling after shearing into a graphite pipe B, discharging the glass liquid into the graphite pipe A through the graphite pipe B, transferring the temperature of the glass liquid to the graphite pipe A, transferring the temperature of the graphite pipe A to the round pipe A, transferring the overhigh temperature of the round pipe A through the water in the cavity, discharging the glass liquid through the lower end of the graphite pipe A, limiting the glass liquid falling from the graphite pipe A and deviating from the required position by the round pipe E, feeding the glass liquid into the next process, controlling the glass liquid to fall to other positions through the production equipment if the dripping pipe is blocked, detaching the dripping pipe connected through the flange plate, detaching an inner hexagonal bolt gasket, inverting the dripping pipe, sequentially pouring the graphite pipe B and the graphite pipe A, and overturning the dripping pipe, and (3) loading a new graphite tube A and a new graphite tube B in sequence, re-fastening the hexagon socket head cap screw and the gasket in the threaded counter bore, re-fixing the material dripping tube through the flange plate, and controlling the molten glass to fall to the original position again through production equipment.

The beneficial effects of the embodiment are as follows: 1. the cooling of the dropping pipe is not uniform, the molten glass liquid is not easy to solidify on the inner side wall of the dropping pipe, the maintenance of the dropping pipe is convenient, the dropping pipe can be recycled, and the production cost is reduced. 2. The lower end of the outer side wall of the graphite tube A is provided with a notch, and the notch at the lower end of the graphite tube A is positioned on the inner side of the through hole A on the annular plate A to prevent molten glass from being adhered to the annular plate A. 3. The lower surface of the annular plate A is fixedly provided with a circular tube E, and the inner diameter of the circular tube E is larger than that of the graphite tube A, so that the lower end of the graphite tube A is guided by the inclined glass liquid. 4. The fixed pipe F that sets up in pipe B upper end, set up the internal thread on the pipe F, set up the external screw thread on the pipe G, the external screw thread of seting up on the pipe G with the internal thread that sets up on the pipe F cooperatees, pipe G inside wall lower part sets up to conical structure A, and graphite tube B lower part is conical structure B, graphite tube B is located inside the pipe G, graphite tube B's minimum diameter with graphite tube A's internal diameter is the same, gives the glass liquid direction of whereabouts. 5. The upper surface of the round tube G is provided with a threaded counter bore, the upper part of the hexagon socket head cap is provided with a gasket, the hexagon socket head cap bolt is matched with the threaded counter bore, and the right edge of the gasket is positioned above the left upper surface of the graphite tube B to prevent the graphite tube B from falling out of the round tube G.

The utility model discloses a concrete embodiment does not constitute the pair the utility model discloses a restriction, all adopt the utility model discloses a similar structure and change are all in the utility model discloses a within the protection scope.

Claims (5)

1. The utility model provides a production glassware is with high temperature resistant dropping pipe which characterized in that: comprises a circular tube A (1), a circular tube B (2), an annular plate A (3), a through hole A (301), an annular plate B (4), a through hole B (401), a graphite tube A (5), a flange plate (6), a cavity (7), a circular tube C (8) and a circular tube D (9), wherein the graphite tube A (5) is placed on the upper surface of the annular plate A (3), the circular tube A (1) is sleeved outside the graphite tube A (5), the graphite tube A (5) is in clearance fit with the circular tube A (1), the inner diameter of the graphite tube A (5) is smaller than the diameter of the through hole A (301) on the annular plate A (3), the circular tube B (2) is sleeved outside the circular tube A (1), the circular tube B (2) is positioned above the annular plate A (3), the circular tube A (1) and the circular tube B (2) are respectively and fixedly connected with the annular plate A (3), and the annular plate B (4) is sleeved on the upper part of the graphite tube A (5), graphite pipe A (5) external diameter is less than the internal diameter of through-hole B (401) is gone up in annular slab B (4), pipe A (1) upper end with annular slab B (4) lower fixed surface is connected, the lateral wall of annular slab B (4) with pipe B (2) inside wall upper end fixed connection, enclose out cavity (7) between pipe A (1), pipe B (2), annular slab A (3), the annular slab B (4), pipe B (2) lateral wall upper portion is fixed to be overlapped and is established ring flange (6), pipe B (2) lateral wall upper portion is fixed and is set up pipe C (8), pipe C (8) with cavity (7) intercommunication, pipe B (2) lateral wall lower part is fixed and is set up pipe D (9), pipe D (9) with cavity (7) intercommunication.

2. The high temperature resistant dispensing tube for glassware manufacture of claim 1, wherein: the lower end of the outer side wall of the graphite tube A (5) is provided with a notch (501), and the notch (501) at the lower end of the graphite tube A (5) is located on the inner side of the through hole A (301) on the annular plate A (3).

3. The high temperature resistant dispensing tube for glassware manufacture of claim 1, wherein: the lower surface of the annular plate A (3) is fixedly provided with a circular tube E (10), and the inner diameter of the circular tube E (10) is larger than that of the graphite tube A (5).

4. The high temperature resistant dispensing tube for glassware manufacture of claim 1, wherein: the fixed pipe F (11) that sets up in pipe B (2) upper end, set up internal thread (1101) on pipe F (11), set up external screw thread (1201) on pipe G (12), external screw thread (1201) of seting up on pipe G (12) with internal thread (1101) of seting up on pipe F (11) cooperate, pipe G (12) inside wall lower part sets up to conical structure A (1202), and graphite tube B (13) lower part is conical structure B (1301), graphite tube B (13) are located inside pipe G (12), the minimum diameter of graphite tube B (13) with the internal diameter of graphite tube A (5) is the same.

5. The high temperature resistant dispensing tube for glassware manufacture of claim 4, wherein: the upper surface of the round tube G (12) is provided with a threaded counter bore (14), the upper part of the inner hexagon bolt (15) is sleeved with a gasket (16), the inner hexagon bolt (15) is matched with the threaded counter bore (14), and the right edge of the gasket (16) is positioned above the left side of the upper surface of the graphite tube B (13).

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