阅读说明：本技术 一种搪玻璃设备烧成炉 (Glass lining equipment firing furnace ) 是由 常帅 于 2020-11-27 设计创作，主要内容包括：本发明公开了一种搪玻璃设备烧成炉,其结构包括焚烧炉、舱门、控制按钮、舱体,焚烧炉镶嵌设于舱体的内侧端面,舱门活动卡合安装在焚烧炉的外侧端,控制按钮位于焚烧炉的正下方,焚烧炉包括装载机构、滑槽、加热器,装载机构嵌固安装在滑槽的上端面,滑槽通过焊接安装在焚烧炉的内侧下端,加热器镶嵌设于滑槽的右侧上方,在变更二氧化硅浓度与清理时,可通过将均匀且活动卡合连接着联动机构的手柄向中间握紧聚拢,将联动机构从滑槽上取下后使其与焚化盒形成分离状进行清理,避免部分二氧化硅溶液在倾倒时附着在焚化盒的内壁角落而无法清理,导致二氧化硅浓度不准确。(The invention discloses a glass lining equipment firing furnace, which comprises a firing furnace, a cabin door, a control button and a cabin body, wherein the firing furnace is embedded in the inner side end surface of the cabin body, the cabin door is movably clamped and installed at the outer side end of the firing furnace, the control button is positioned right below the firing furnace, the firing furnace comprises a loading mechanism, a chute and a heater, the loading mechanism is embedded and installed at the upper end surface of the chute, the chute is installed at the lower end of the inner side of the firing furnace through welding, the heater is embedded and installed above the right side of the chute, when changing silica concentration and clearance, the accessible is held tightly to the centre with even and activity joint link gear's handle and is gathered together, takes off link gear from the spout after make it form the separation form with the box of burning and clear up, avoids partial silica solution to adhere to in the inner wall corner of burning the box when empting and can't clear up, leads to silica concentration inaccurate.)

1. A glass lining equipment firing furnace structurally comprises an incinerator (1), a cabin door (2), a control button (3) and a cabin body (4), wherein the incinerator (1) is embedded in the inner side end face of the cabin body (4), the cabin door (2) is movably clamped and installed at the outer side end of the incinerator (1), and the control button (3) is located right below the incinerator (1); the method is characterized in that:

the incinerator (1) comprises a loading mechanism (11), a sliding groove (12) and a heater (13), wherein the loading mechanism (11) is fixedly embedded in the upper end face of the sliding groove (12), the sliding groove (12) is installed at the lower end of the inner side of the incinerator (1) through welding, and the heater (13) is embedded above the right side of the sliding groove (12).

2. A glass-lined apparatus firing furnace as claimed in claim 1, wherein the loading mechanism (11) comprises a mosaic plate (111), a separation mechanism (112), an incineration box (113), a handle (114), the incineration box (113) is mounted on the upper end surface of the mosaic plate (111) in a built-in manner, the separation mechanism (112) is mounted directly above the incineration box (113) in a built-in manner, the handle (114) is mounted on the left end surface of the incineration box (113) in a built-in manner, and the handle (114) is located on the left upper side of the mosaic plate (111).

3. A glass-lined apparatus firing furnace as claimed in claim 2, wherein the separating mechanism (112) comprises a chute (121), a linkage mechanism (122), a bulkhead (123) and a handle (124), the chute (121) is embedded in the lower end surface of the bulkhead (123), the linkage mechanism (122) is uniformly embedded in the inner end surface of the bulkhead (123), the bulkhead (123) is attached to the handle (124), and the inner end surface of the handle (124) is movably connected to the linkage mechanism (122) in a clamping manner.

4. A glass-lined equipment firing furnace as claimed in claim 3, wherein the linkage mechanism (122) comprises a reverse shaft (221), a second chute (222), a closing mechanism (223), a connecting shaft (224), an expansion link (225) and a second connecting shaft (226), the reverse shaft (221) is embedded in the left end face of the closing mechanism (223), the inner end face of the second chute (222) is movably clamped and connected with the connecting shaft (224), the left end face of the closing mechanism (223) is attached and connected with the second connecting shaft (226), the connecting shaft (224) is embedded and arranged above the right side of the expansion link (225), the lower end face of the expansion link (225) is movably clamped and connected with the second connecting shaft (226), and the second connecting shaft (226) is embedded and arranged under the second chute (222).

5. A firing furnace of glass lining equipment as claimed in claim 4, wherein the reverse shaft (221) comprises an embedding block (211), an embedding disc (212), a gear ring (213) and a second gear ring (214), the embedding block (211) is embedded and installed on the outer end face of the embedding disc (212), the embedding disc (212) countermeasures are installed on the upper end and the lower end of the second gear ring (214), the gear ring (213) is embedded and clamped with the second gear ring (214), and the second gear ring (214) is movably clamped on the inner end face of the reverse shaft (221).

6. A glass-lined apparatus firing furnace as claimed in claim 4, wherein the closing mechanism (223) comprises a movable disc (231), an embedding strip (232) and a movable groove (233), the movable disc (231) is uniformly embedded and fixed on the inner side end surface of the closing mechanism (223), the embedding strip (232) is embedded and fixed on the inner side end surface of the movable disc (231), and the movable groove (233) is attached and wrapped on the outer side end surface of the embedding strip (232).

Technical Field

The invention belongs to the field of glass equipment, and particularly relates to a glass lining equipment firing furnace.

Background

The glass equipment firing furnace is characterized in that gravel is poured into a mold, silica in the gravel is melted into a viscous liquid state after continuous incineration and purification, and then the viscous liquid state is poured into the mold, and then the liquid glass is cooled and demoulded.

Based on the findings of the inventor, the following defects mainly exist in the prior art, such as: after the gravel is subjected to hot melting purification, the gravel is in a sticky state, a thin solution layer is left in a pouring flow path by a solution when viscous liquid is poured, and a hard block formed on the surface of a container after cooling cannot be completely cleaned, so that different silicon dioxide contents are caused when glass with different content standards is manufactured.

Therefore, a firing furnace for glass lining equipment needs to be provided.

Disclosure of Invention

In order to solve the problem that after the gravel is subjected to hot melting purification by the technology, the gravel is sticky, a thin solution layer is left on a pouring flow path when the viscous liquid is poured, and a hard block is formed on the surface of a container after cooling and cannot be completely cleaned, so that the content of silicon dioxide is different when glass with different content standards is manufactured.

The invention relates to a purpose and an effect of a glass lining equipment firing furnace, which are achieved by the following specific technical means: the structure of the incinerator comprises an incinerator, a cabin door, a control button and a cabin body, wherein the incinerator is embedded in the inner side end face of the cabin body, the cabin door is movably clamped and installed at the outer side end of the incinerator, and the control button is located right below the incinerator; the incinerator comprises a loading mechanism, a sliding groove and a heater, wherein the loading mechanism is fixedly embedded in the upper end face of the sliding groove, the sliding groove is installed at the lower end of the inner side of the incinerator through welding, and the heater is embedded above the right side of the sliding groove.

Wherein, loading mechanism includes mosaic plate, separating mechanism, burns box, handle, the mosaic plate upper end surface is inlaying and is being installed and is burning the box, separating mechanism inlays and locates directly over burning the box, burn box left side terminal surface and inlay and install the handle admittedly, the handle is located the left side top of mosaic plate, it is two-layer inside and outside the box is equipped with to burn, and the inlayer is the sectional type design.

The separating mechanism comprises a sliding groove, a linkage mechanism, a bulkhead and a handle, the sliding groove is embedded in the lower end surface of the bulkhead, the linkage mechanism is uniformly embedded in the inner side end surface of the bulkhead, the bulkhead is connected with the handle in a fitting mode, the inner side end surface of the handle is movably clamped and connected with the linkage mechanism, and the density of the inner side end surface of the linkage mechanism is higher than that of the outer wall.

Wherein, link gear includes reverse axle, second spout, closing mechanism, connecting axle, telescopic link, second connecting axle, the left side terminal surface of locating closing mechanism is inlayed to the reverse axle, the connecting axle is being connected to second spout medial surface activity block, the second connecting axle is being connected in the laminating of closing mechanism left side terminal surface, the right side top of locating the telescopic link is inlayed to the connecting axle, terminal surface activity block is being located the second connecting axle under the telescopic link, the second connecting axle is inlayed and is located the second spout under, the telescopic link is equipped with inside and outside two-layer.

The reverse shaft comprises an embedding block, an embedding disc, a gear ring and a second gear ring, the embedding block is fixedly installed on the end face of the outer side of the embedding disc, the embedding disc is installed at the upper end and the lower end of the second gear ring in a countermeasure mode, the gear ring is embedded and clamped with the second gear ring, the second gear ring is movably clamped on the end face of the inner side of the reverse shaft, the reverse shaft and the second sliding groove are both provided with two parts, and the embedding discs at the upper end and the lower end are respectively provided with the embedding block.

Wherein, closing mechanism includes activity dish, inlay strip, activity groove, the activity dish evenly inlays the medial surface at closing mechanism, inlay the strip and inlay the medial surface of solid installation at the activity dish, the outside terminal surface of activity groove laminating parcel inlay strip, closing mechanism is equipped with inside and outside two-layer, and the diameter of inlayer laminates with the terminal surface of inlaying the strip mutually.

Compared with the prior art, the invention has the following beneficial effects:

1. when changing silica concentration and clearance, the accessible is held tightly to the centre with even and activity joint link gear's handle and is gathered together, takes off link gear from the spout after make it form the separation form with the box of burning and clear up, avoids partial silica solution to adhere to in the inner wall corner of burning the box when empting and can't clear up, leads to silica concentration inaccurate.

2. The movable disc is utilized to enable the embedding strips embedded on the inner side end face of the closing mechanism to protrude outwards along the movable groove, so that the glass solid attached and solidified on the surface of the embedding strips is separated from the bonding state with the inner side end face of the closing mechanism.

Drawings

FIG. 1 is a schematic view showing the overall structure of a firing furnace of a glass lining apparatus according to the present invention.

FIG. 2 is a schematic view of the incinerator of the glass lining equipment firing furnace of the present invention.

FIG. 3 is a schematic structural view of a loading mechanism of a firing furnace of a glass lining apparatus according to the present invention.

FIG. 4 is a schematic structural view of a separating mechanism of a firing furnace of a glass lining apparatus according to the present invention.

FIG. 5 is a schematic structural view of a linkage mechanism of a firing furnace of a glass lining apparatus according to the present invention.

FIG. 6 is a schematic view showing the structure of a reverse shaft of a firing furnace of a glass lining apparatus according to the present invention.

FIG. 7 is a schematic structural view of a closing mechanism of a firing furnace of a glass lining apparatus according to the present invention.

In the figure: incinerator-1, cabin door-2, control button-3, cabin body-4, loading mechanism-11, chute-12, heater-13, mosaic plate-111, separating mechanism-112, incineration box-113, handle-114, chute-121, linkage mechanism-122, cabin wall-123, handle-124, reverse shaft-221, second chute-222, closing mechanism-223, connecting shaft-224, telescopic rod-225, second connecting shaft-226, mosaic block-211, mosaic disk-212, gear ring-213, second gear ring-214, movable disk-231, mosaic strip-232 and movable groove-233.

Detailed Description

The invention is further described below with reference to the accompanying drawings:

example 1:

as shown in figures 1 to 5:

the invention provides a glass lining equipment firing furnace, which structurally comprises a firing furnace 1, a cabin door 2, a control button 3 and a cabin body 4, wherein the firing furnace 1 is embedded in the inner side end surface of the cabin body 4, the cabin door 2 is movably clamped and installed at the outer side end of the firing furnace 1, and the control button 3 is positioned right below the firing furnace 1; the incinerator 1 comprises a loading mechanism 11, a sliding chute 12 and a heater 13, wherein the loading mechanism 11 is fixedly embedded in the upper end face of the sliding chute 12, the sliding chute 12 is installed at the lower end of the inner side of the incinerator 1 through welding, and the heater 13 is embedded in the upper portion of the right side of the sliding chute 12.

Wherein, loading mechanism 11 includes mosaic plate 111, separating mechanism 112, incineration box 113, handle 114, mosaic plate 111 upper end surface is inlaying and is installing incineration box 113, separating mechanism 112 inlays and locates directly over incineration box 113, incineration box 113 left side terminal surface is inlayed and is installing handle 114, handle 114 is located mosaic plate 111's left side top, incineration box 113 is equipped with two-layer inside and outside, and the inlayer is the sectional type design, and accessible control separating mechanism 112 will incinerate box 113 and separate.

The separating mechanism 112 comprises a chute 121, a linkage mechanism 122, a bulkhead 123 and a handle 124, wherein the chute 121 is embedded in the lower end surface of the bulkhead 123, the linkage mechanism 122 is uniformly embedded in the inner end surface of the bulkhead 123, the bulkhead 123 is connected with the handle 124 in a fitting manner, the inner end surface of the handle 124 is movably clamped and connected with the linkage mechanism 122, the density of the inner end surface of the linkage mechanism 122 is higher than that of the outer wall, the adhesion of a silica solution can be effectively avoided, and the linkage mechanism 122 is designed in a sectional manner.

The specific use mode and function of the embodiment are as follows:

when the invention is used, the gravel is placed in the loading mechanism 11 in the incinerator 1, the cabin body 4 and the heater 13 are controlled by the control button 3 to smelt the gravel in the loading mechanism 11, so that the silicon dioxide in the gravel is melted and condensed into solution and is presented at the inner end of the incineration box 113, impurities in the gravel are continuously discharged outwards, thus the concentration of the silicon dioxide in the gravel is purified, when the concentration of the silicon dioxide is changed and cleaned, the handle 124 which is uniformly and movably clamped and connected with the linkage mechanism 122 is held and gathered towards the middle, the linkage mechanism 122 is taken down from the chute 121 and then is separated from the incineration box 113 for cleaning, and the problem that part of silicon dioxide solution is attached to the inner wall corner of the incineration box 113 during pouring and cannot be cleaned, so that the concentration of the silicon dioxide is not accurate is avoided.

Example 2:

as shown in fig. 5 to 7:

wherein, the link gear 122 includes reverse axle 221, second spout 222, closing mechanism 223, connecting axle 224, telescopic link 225, second connecting axle 226, reverse axle 221 inlays and locates the left side terminal surface of closing mechanism 223, connecting axle 224 is connected to the movable block of second spout 222 medial surface, closing mechanism 223 left side terminal surface laminating is connected to second connecting axle 226, connecting axle 224 inlays and locates the right side top of telescopic link 225, the second connecting axle 226 is being blocked in the lower terminal surface activity of telescopic link 225, second connecting axle 226 inlays and locates under second spout 222, telescopic link 225 is equipped with inside and outside two-layer and second connecting axle 226 is mobile, and the rotation of accessible reverse axle 221 drives telescopic link 225 and promotes second connecting axle 226 and closing mechanism 223 removal forward.

The reverse shaft 221 includes an embedded block 211, an embedded disc 212, a gear ring 213 and a second gear ring 214, the embedded block 211 is embedded and fixedly installed on the outer end surface of the embedded disc 212, the embedded disc 212 is installed at the upper end and the lower end of the second gear ring 214 in a countermeasure manner, the gear ring 213 is embedded, clamped and connected with the second gear ring 214, the second gear ring 214 is movably clamped on the inner end surface of the reverse shaft 221, the reverse shaft 221 and the second chute 222 are both provided with two embedded blocks 211, the embedded discs 212 at the upper end and the lower end are respectively provided with one embedded block 211, and the embedded discs 212 at the upper end and the lower end can be driven to reversely rotate by the transmission of the second gear ring 214.

Wherein, closure mechanism 223 includes activity dish 231, inlay strip 232, activity groove 233, activity dish 231 evenly inlays the medial surface at closure mechanism 223, inlay strip 232 inlays the medial surface of installing at activity dish 231, the outside terminal surface of activity groove 233 laminating parcel inlay strip 232, closure mechanism 223 is equipped with inside and outside two-layer, and the diameter of inlayer laminates mutually with inlay strip 232's terminal surface and can effectively avoid silica solution to get into closure mechanism 223's medial surface along activity groove 233 and inlay strip 232's gap.

The specific use mode and function of the embodiment are as follows:

in the invention, when the handle 124 is gripped, the link mechanism 122 can drive the reverse shaft 221 to rotate, so that the reverse shaft 221 drives the embedding disc 212 to rotate by taking the center of the circle as the center point, and two embedding blocks 211 and two embedding discs 212 are arranged, when the upper end of the inlaying disk 212 is driven by the handle 124 to rotate, the inlaying disk 212 at the lower end is driven by the second gear ring 214 to rotate reversely, so that the inlaying blocks 211 inlaid on the inlaying disk 212 are gathered towards the middle, when the glass is gathered, the telescopic rod 225 and the second connecting shaft 226 which are installed below the telescopic rod are pushed, the closing mechanism 223 is enabled to be deflected outwards under the movable clamping of the connecting shaft 224 and the second sliding groove 222, the embedding strip 232 embedded in the inner side end face of the closing mechanism 223 is enabled to protrude outwards along the movable groove 233 through the movable disc 231, and the glass solid attached and solidified on the surface of the embedding strip is enabled to be separated from the bonding state with the inner side end face of the closing mechanism 223.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention to achieve the above technical effects.