CN218146323U - Structure for cooling electrode - Google Patents

Abstract

The utility model relates to a be used for electrode cooling's structure belongs to support plate glass preceding processing technology field. A structure for electrode cooling, including passing the electrode that the kiln oven got into glass liquid, the oven end along the electrode adds and is equipped with the water-cooling jacket, the water-cooling jacket includes following structure: the water inlet is arranged above the water cooling jacket and is connected with the straight channel; the straight channel is transversely arranged on the upper half part of the water cooling jacket and is in contact with the lower half part; the partition plates are vertically arranged at the lower half part of the water cooling jacket at intervals, and a wave-shaped cavity is formed in the water cooling jacket through the partition plates; the water outlet is arranged below the water cooling jacket; the cooling water enters the water cooling jacket through the water inlet, circulates along the water cooling jacket attached to the outer wall of the electrode and flows out along the water inlet. The utility model discloses can realize when electrode heating glass liquid, under kiln high temperature environment, lead to failing to appear no longer to the terminal preferential refrigerated phenomenon of electrode oven, effectively avoid producing the problem that electrode life is short from this.

Description

Structure for cooling electrode

Technical Field

The utility model relates to a be used for electrode cooling's structure belongs to support plate glass preceding processing technology field.

Background

In the carrier plate glass processing industry, an electrode directly enters glass liquid of a kiln to finish heating, cooling water of an electrode water cooling jacket flows from the head end outside the kiln to the tail end of the kiln wall to cool, and the tail end of the kiln wall of the electrode cannot be cooled preferentially in the high-temperature environment of the kiln. In order to prolong the service life of the electrode, a structure for solving the problem is needed. Chinese patent ZL 202221099786.3 discloses a cooling structure for a spiral feeder, which can cool an electrode at a high temperature, but has a dead space for cooling, and thus, the electrode cannot be cooled in all directions.

SUMMERY OF THE UTILITY MODEL

To the above defect that prior art exists, the utility model provides a be used for electrode refrigerated structure when electrode heating glass liquid, under kiln high temperature environment, fail the terminal preferential refrigerated problem of electrode oven to and produce the short problem of electrode life from this.

A water-cooling jacket includes following structure for electrode refrigerated structure, including passing the electrode that the kiln wall got into glass liquid, be equipped with additional along the oven end of electrode:

the water inlet is arranged above the water cooling jacket and is connected with the straight channel;

the straight channel is transversely arranged on the upper half part of the water cooling jacket and is in contact with the lower half part;

the partition plates are vertically arranged on the lower half portion of the water cooling jacket at intervals, and a wave-shaped cavity is formed in the water cooling jacket through the partition plates;

the water outlet is arranged below the water cooling jacket;

the cooling water enters the water cooling jacket through the water inlet, circulates along the water cooling jacket attached to the outer wall of the electrode and flows out along the water inlet.

The utility model provides a water-cooling jacket is used for electrode oven end to cool off specially, and the cooling effect is good, effectively prolongs the life of electrode. The structure of the water cooling jacket is improved, except for a common straight channel, the straight channel is changed into a wave-shaped pipe body specially for prolonging the contact time of cooling water and an electrode, and a partition plate is additionally arranged in the water cooling jacket; and the structure of the whole water cooling jacket is optimized, so that the covering area of the electrode is cooled without dead angles, and the electrode is cooled in all directions.

Preferably, a kiln wall is arranged between the water cooling jacket and the molten glass at an interval, and the water cooling jacket is not in direct contact with the molten glass.

Preferably, the longitudinal section of the water cooling jacket is rectangular, and the straight channel is positioned in the middle of the upper side and extends from the water inlet to the innermost part of the water cooling jacket; then the straight way extends downwards to the bottommost part of the lower half part of the water cooling jacket, then the straight way is divided into two parts which are respectively arranged into a front part and a rear part, and a partition plate is vertically arranged in each cooling pipeline in a direction perpendicular to the electrode direction, so that cooling liquid in the front part and the rear part advances in a wave shape, and the upper part and the lower part are finally converged to a water outlet.

Preferably, the area where the separator is located covers the sides and the bottom of the electrode.

The beneficial effects of the utility model are that: a structure for electrode cooling, can realize when electrode heating glass liquid, under kiln high temperature environment, lead to failing to appear no longer to the terminal preferential refrigerated phenomenon of electrode oven, effectively avoid producing the problem that electrode life is short from this.

Drawings

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

FIG. 2 is a front view of an electrode water jacket.

FIG. 3 is a side view of an electrode water jacket.

In the figure: 1. an electrode; 2. water cooling jacket; 3. a kiln wall; 4. glass liquid; 5. a water inlet; 6. a water outlet; 7. straight path; 8. A separator.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Example (b):

a problem that is used for electrode cooling's structure, solve when electrode 1 heating glass liquid 4, under kiln high temperature environment, fail the terminal preferential refrigerated problem of 1 oven of counter electrode to and produce electrode 1 life weak point from this.

As shown in figure 1, a molten glass 4 heating electrode 1 is provided with a water jacket 2, and the electrode 1 penetrates through a kiln wall 3 and enters the molten glass 4. Cooling water enters the water cooling jacket 2 from the water inlet 5, directly reaches the tail end of the furnace wall of the water cooling jacket 2 through the straight channel 7, preferentially cools the tail end of the furnace wall of the electrode 1 along the plurality of groups of partition plates 8, then flows back to the head end of the furnace wall of the water cooling jacket 2 along the plurality of groups of partition plates 8 to dissipate heat of the whole electrode 1, and finally the cooling water flows out of the water cooling jacket 2 from the water outlet 6. The water cooling jacket 2 with the new structure preferentially cools the tail end of the furnace wall of the molten glass 4 heating electrode 1, has good cooling effect, and effectively prolongs the service life of the electrode 1.

A structure for electrode cooling, including passing 3 electrode 1 that get into molten glass 4 of kiln oven, be equipped with water-cooling jacket 2 additional along electrode 1's oven end.

As shown in fig. 2 and 3, the water cooling jacket 2 includes the following structure:

the water inlet 5 is arranged above the water cooling jacket 2 and is connected with the straight channel 7;

the straight channel 7 is transversely arranged on the upper half part of the water cooling jacket 2 and is in contact with the lower half part;

the partition plates 8 are vertically arranged at the lower half part of the water cooling jacket 2 at intervals, and a wave-shaped cavity is formed in the water cooling jacket 2 through the partition plates 8;

the water outlet 6 is arranged below the water cooling jacket 2;

the cooling water enters the water cooling jacket 2 through the water inlet 5, circulates along the water cooling jacket 2 attached to the outer wall of the electrode 1 and flows out along the water inlet 5.

The utility model provides a water cooling jacket 2 is used for electrode 1 oven end to cool off specially, and the cooling effect is good, effectively prolongs electrode 1's life. The structure of the water cooling jacket 2 is improved, except for a common straight channel 7, in order to specially increase the contact time of cooling water and the electrode 1, the straight channel 7 is changed into a wave-shaped pipe body, and a partition plate 8 is additionally arranged in the water cooling jacket 2; and the structure of the whole water cooling jacket 2 is optimized, so that the covering area of the electrode 1 is cooled without dead angles, and the electrode is cooled in all directions. The kiln wall 3 is arranged between the water cooling jacket 2 and the molten glass 4 at intervals, and the water cooling jacket 2 is not in direct contact with the molten glass 4. The longitudinal section of the water cooling jacket 2 is rectangular, and the straight channel 7 is positioned in the middle of the upper edge and extends from the water inlet 5 to the innermost part of the water cooling jacket 2; then the straight channel 7 extends downwards to the bottommost part of the lower half part of the water cooling jacket 2, the straight channel 7 is divided into two parts, namely a front part and a rear part, a partition plate 8 is vertically arranged in each cooling pipeline in a direction perpendicular to the electrode 1, therefore, cooling liquid in the front part and the rear part advances in a wavy mode, and the upper part and the lower part are finally converged to the water outlet 6. The separator 8 covers the sides and bottom of the electrode 1.

The utility model discloses electrode 1 water-cooling jacket 2's characteristics are: a cooling water inlet 5 is arranged above the outer front end of the water cooling jacket 2, cooling water directly reaches the tail end of the furnace wall of the water cooling jacket 2 through a straight channel 7 and then flows back to the outer front end of the water cooling jacket 2 along a partition plate 8, and a cooling water outlet 6 is arranged below the outer front end of the water cooling jacket 2. Additionally, the utility model discloses can fundamentally solve prior art problem, preferentially cool off 1 oven end of electrode, the cooling effect is good, effectively prolongs electrode 1's life.

The utility model discloses a use as follows: be used for electrode cooling's structure, cooling water gets into 2 outer head end tops water inlets 5 of water-cooling jacket, directly reachs 2 oven ends of water-cooling jacket through straight way 7, cools off the oven end of 4 heating electrode 1 of glass liquid preferentially, then flows back to 2 outer head ends of water-cooling jacket along multiunit baffle 8, dispels the heat to 4 heating electrode 1 of whole glass liquid, cooling water goes out 2 outer head end below delivery ports 6 of water-cooling jacket at last. The water cooling jacket 2 with the new structure preferentially cools the tail end of the furnace wall of the molten glass 4 heating electrode 1, the cooling effect is good, and the service life of the electrode 1 is effectively prolonged.

A structure for electrode cooling, can realize when electrode 1 heating glass liquid 4, under kiln high temperature environment, lead to failing to appear no longer to the terminal preferential refrigerated phenomenon of electrode 1 oven, effectively avoid producing the problem that electrode 1 life is short from this. The utility model discloses can extensively apply to the processing occasion before the support plate glass.

The above-mentioned matters which are not mentioned are common technical means in the art, and are most typically described in the textbook "single chip microcomputer principle and its application" published by the university press of Qinghua, 2012, so that the above description and the accompanying drawings sufficiently illustrate the embodiments of the present invention to enable those skilled in the art to practice them.

Claims (4)

1. A structure for electrode cooling, includes passing electrode (1) that kiln wall (3) got into glass liquid (4), its characterized in that along the terminal water-cooling jacket (2) of installing additional of the oven wall of electrode (1), water-cooling jacket (2) include following structure:

the water inlet (5) is arranged above the water cooling jacket (2) and is connected with the straight channel (7);

the straight channel (7) is transversely arranged on the upper half part of the water cooling jacket (2) and is in contact with the lower half part;

the partition plates (8) are vertically arranged at the lower half part of the water cooling jacket (2) at intervals, and a wave-shaped cavity is formed in the water cooling jacket (2) through the partition plates (8);

the water outlet (6) is arranged below the water cooling jacket (2);

the cooling water enters the water cooling jacket (2) through the water inlet (5), circulates along the water cooling jacket (2) attached to the outer wall of the electrode (1) and flows out along the water inlet (5).

2. The structure for electrode cooling according to claim 1, characterized in that a kiln wall (3) is provided at an interval between the water-cooling jacket (2) and the molten glass (4), and the water-cooling jacket (2) is not in direct contact with the molten glass (4).

3. The structure for electrode cooling according to claim 1 or 2, characterized in that the water cooling jacket (2) has a rectangular longitudinal cross-section, and the straight channel (7) is located in the middle of the upper side and extends from the water inlet (5) to the innermost part of the water cooling jacket (2); then the straight channel (7) extends downwards to the bottommost part of the lower half part of the water cooling jacket (2), then the straight channel (7) is divided into two parts which are respectively arranged into a front part and a rear part, a partition plate (8) is vertically arranged in each cooling pipeline in a direction perpendicular to the electrode (1), therefore, cooling liquid in the front part and the rear part advances in a wave shape, and the upper part and the lower part are finally converged to a water outlet (6).

4. The structure for electrode cooling according to claim 3, characterized in that the area where the separator (8) is located covers the sides and the bottom of the electrode (1).

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