阅读说明：本技术 一种高效环保玻璃瓶吹制工艺 (Efficient environment-friendly glass bottle blowing process ) 是由 许民诚 于 2020-07-13 设计创作，主要内容包括：本发明属于玻璃瓶技术领域,具体的说是一种高效环保玻璃瓶吹制工艺,该工艺中使用的吹瓶模具包括本体,本体有两个左右对称布置的分体组成,分体相邻的一侧开设有用于控制玻璃瓶成型的型腔,型腔顶部开设有用于固定瓶坯的环形槽,环形槽上部设有瓶口孔,瓶口孔内设有螺旋形的瓶口螺纹槽；瓶口孔处设有薄壁的加热环,圆环设置于瓶口孔内与加热环对应位置；圆环内径略大于瓶坯外径,且圆环为铁质材料；加热环通过控制器与电源连接,本发明加热环通过高频加热圆环,增加圆环和加强丝与瓶坯的融合效率,增加玻璃瓶强度。(The invention belongs to the technical field of glass bottles, and particularly relates to a high-efficiency environment-friendly glass bottle blowing process.A bottle blowing mold used in the process comprises a body, wherein the body consists of two split bodies which are arranged in bilateral symmetry, one adjacent side of each split body is provided with a cavity for controlling the forming of a glass bottle, the top of each cavity is provided with an annular groove for fixing a bottle blank, the upper part of each annular groove is provided with a bottle mouth hole, and a spiral bottle mouth thread groove is arranged in each bottle mouth hole; a thin-wall heating ring is arranged at the position of the bottleneck hole, and a circular ring is arranged in the bottleneck hole and corresponds to the heating ring; the inner diameter of the circular ring is slightly larger than the outer diameter of the bottle blank, and the circular ring is made of iron material; the heating ring is connected with a power supply through a controller, and the heating ring heats the ring through high frequency, so that the fusion efficiency of the ring, the reinforcing wire and the bottle blank is improved, and the strength of the glass bottle is improved.)

1. A blowing process of a high-efficiency environment-friendly glass bottle is characterized by comprising the following steps: the method comprises the following steps:

s1, crushing colorless and transparent recovered glass, then washing the glass in a water washing tank for one time, fishing out the glass after the water washing is finished, putting the glass in a pickling tank for pickling, preparing hydrochloric acid water solution with the concentration of twenty percent in the pickling tank, soaking the glass in the pickling tank for 30-60S, fishing out the glass through a filter screen, and vibrating the glass at high frequency after the filter screen is separated from the liquid level to reduce acid liquor residue on the glass;

s2, washing the acid-washed glass in the step S1 for the second time, fishing out the glass through a filter screen, spraying purified water, removing acid liquor adhered to the glass, drying and crushing the glass, and grinding the glass through a grinder to form powder with the granularity of more than 2000 meshes;

s3, weighing the powder ground in the S2, weighing 50-60 parts of glass powder, 20-30 parts of calcite, 3-5 parts of soda ash and 0.6-1.5 parts of iron oxide powder, putting the raw materials into a stirrer, fully and uniformly stirring, then sending into a furnace, heating to 1200-1400 ℃, preserving heat for more than 5 hours, and blowing oxygen into the furnace in the heating process until stable molten glass is formed in the furnace;

s4, taking out the molten glass in the step S3, putting the molten glass into a mold to prepare a bottle blank, and cooling the bottle blank for later use;

s5, reheating the bottle blank to 650-750 ℃, then installing the bottle blank in a bottle blowing mold, meanwhile, sleeving a circular ring (16) with a reinforcing wire (17) made of metal material uniformly distributed on the circumference of the bottom on the periphery of the bottle blank, blowing high-pressure air into the bottle blank, so that the bottle blank is expanded and then is tightly pressed against the inner surface of the bottle blowing mold, meanwhile, the reinforcing wire (17) is embedded into the bottle body, the strength of the bottle body is improved, the phenomenon that people are injured by splashing during crushing is reduced, then introducing cold water into the mold for cooling, opening the mold after the bottle body is cooled, taking out, and completing the blowing of the glass bottle.

2. The process of claim 1, wherein the blowing step comprises: the circular ring (16) is sleeved into the bottle blank from bottom to top and then fixed in the bottle blowing mold together with the bottle blank, so that the winding of the reinforcing wire (17) is reduced.

3. A process of blowing high efficiency environmentally friendly glass bottles as claimed in claim 2 wherein: glass powder with the particle size of 20000 meshes is adhered to the surfaces of the circular ring (16) and the reinforcing wire (17), so that the compatibility of the reinforcing wire (17) and the bottle body is improved, and the strength of the bottle body is further improved;

the bottle blowing mold used in the S5 comprises a body (1), wherein the body (1) is composed of two split bodies (11) which are arranged in a bilateral symmetry manner, a cavity (12) used for controlling the forming of a glass bottle is formed at one adjacent side of the split bodies (11), an annular groove (13) used for fixing a bottle blank is formed at the top of the cavity (12), a bottle mouth hole (14) is formed in the upper part of the annular groove (13), and a spiral bottle mouth thread groove is formed in the bottle mouth hole (14); a thin-wall heating ring (15) is arranged at the bottleneck hole (14), and a circular ring (16) is arranged in the bottleneck hole (14) at a position corresponding to the heating ring (15); the inner diameter of the circular ring (16) is slightly larger than the outer diameter of the bottle blank, and the circular ring (16) is made of iron material; the heating ring (15) is connected with a power supply through a controller, the heating ring (15) heats the circular ring (16) through high frequency, the fusion efficiency of the circular ring (16), the reinforcing wire (17) and the bottle blank is increased, and the strength of the glass bottle is increased.

4. A process of blowing high efficiency environmentally friendly glass bottles as claimed in claim 3 wherein: the inner periphery of the heating ring (15) is provided with a magnetic ring, and the magnetic ring adsorbs the circular ring (16), so that the positioning precision of the circular ring (16) is further ensured, and the strength of the glass bottle is increased.

5. The blowing process of high-efficiency environmental-friendly glass bottles as claimed in claim 4, wherein: the reinforcing wire (17) is pre-magnetized; the periphery of the cavity (12) is provided with an electromagnet (2), and the electromagnet (2) applies repulsive force to the reinforcing wire (17) to further increase the quality of the reinforcing wire (17) embedded in the bottle body; a group of fins (21) are arranged on the periphery of the heating ring (15), spiral cooling holes (22) formed in the heating ring (15) are communicated with cooling water, heat dissipation of the heating ring (15) is accelerated by matching the cooling holes (22) with the fins (21), and overheating deformation of bottle blanks at the bottle mouth holes (14) is reduced.

6. The blowing process of high-efficiency environmental-friendly glass bottles as claimed in claim 5, wherein: an annular groove (23) is formed in the bottom of the cavity (12), and a breathable film (24) is fixedly connected to the top of the groove (23); a group of fins (26) are uniformly distributed in the first hole (25) formed in the split body (11) in the circumferential direction, and one side of the bottom of the first hole (25) is communicated with high-pressure water through a water inlet hole (27); a first hole (25) at the lower part of the water inlet hole (27) is communicated with the bottom of the groove (23) through a second hole (30); the cooling efficiency of the split body (11) is increased by spraying water and atomizing to the first hole (25); an arc-shaped baffle (28) is arranged on one side, away from the bottle opening, of the top of the first hole (25), and the baffle (28) is used for guiding water mist to the fins (21); a group of third holes (29) are uniformly distributed on the circumference of the fin (21), and the cooling efficiency of the bottle blank is further improved by enabling water mist to flow through the third holes (29).

Technical Field

The invention belongs to the technical field of glass bottles, and particularly relates to a high-efficiency environment-friendly glass bottle blowing process.

Background

Glass bottles are packaging containers for food, beverage and many products, are widely used, and glass is a historical packaging material. In the case of the emergence of a large variety of packaging materials, glass containers still occupy an important position in the packaging of beverages. Glass bottles are typically manufactured through four steps of compounding, melting, forming and annealing. In the forming process, the molten glass stock solution is required to be injected into a forming die with a water cooling system, and the forming die is rapidly cooled and formed, so that most of energy is stored in the glass bottle body to form internal stress, and if the internal stress is too large, the bottle body is easy to crack. In order to eliminate the internal stress, the glass bottle needs to be annealed to release the internal stress in the bottle body of the glass bottle.

Disclosure of Invention

In order to make up the defects of the prior art and solve the problems that in the prior art, in the process of blowing the glass bottle by a mold, the mold needs to be rapidly cooled to enable the bottle blank to be rapidly solidified and formed after being expanded, but due to the fact that the distribution of cooling water channels is not uniform, the cooling speed of the bottle body is not uniform, the bottle body needs to be cooled to a preset temperature for a long time, the production efficiency of the glass bottle is influenced, meanwhile, the glass bottle is low in strength and high in brittleness, and people are easily burst and hurt due to local shock cooling and sudden heating after forming.

The technical scheme adopted by the invention for solving the technical problems is as follows: the invention relates to a high-efficiency environment-friendly glass bottle blowing process, which comprises the following steps:

s1, crushing colorless and transparent recovered glass, then washing the glass in a water washing tank for one time, fishing out the glass after the water washing is finished, putting the glass in a pickling tank for pickling, preparing hydrochloric acid water solution with the concentration of twenty percent in the pickling tank, soaking the glass in the pickling tank for 30-60S, fishing out the glass through a filter screen, and vibrating the glass at high frequency after the filter screen is separated from the liquid level to reduce acid liquor residue on the glass;

s2, washing the acid-washed glass in the step S1 for the second time, fishing out the glass through a filter screen, spraying purified water, removing acid liquor adhered to the glass, drying and crushing the glass, and grinding the glass through a grinder to form powder with the granularity of more than 2000 meshes;

s3, weighing the powder ground in the S2, weighing 50-60 parts of glass powder, 20-30 parts of calcite, 3-5 parts of soda ash and 0.6-1.5 parts of iron oxide powder, putting the raw materials into a stirrer, fully and uniformly stirring, then sending into a furnace, heating to 1200-1400 ℃, preserving heat for more than 5 hours, and blowing oxygen into the furnace in the heating process until stable molten glass is formed in the furnace;

s4, taking out the molten glass in the step S3, putting the molten glass into a mold to prepare a bottle blank, and cooling the bottle blank for later use;

s5, heating the bottle blank to 650 plus 750 ℃ again, then installing the bottle blank in a bottle blowing mold, simultaneously sleeving a circular ring with reinforcing wires made of metal materials uniformly distributed on the circumference of the bottom on the periphery of the bottle blank, blowing high-pressure air into the bottle blank, enabling the bottle blank to be tightly pressed against the inner surface of the bottle blowing mold after being expanded, enabling the reinforcing wires to be embedded into the bottle body, increasing the strength of the bottle body, reducing the splash injury during crushing, then introducing cold water into the mold for cooling, opening the mold after the bottle body is cooled, and taking out the bottle blank to finish the blowing of the glass bottle; in the prior art, when the blowing process of the glass bottle is completed through a mold, the mold needs to be rapidly cooled, so that the bottle blank is rapidly solidified and molded after being expanded, but due to the fact that the distribution of cooling water channels is not uniform, the cooling speed of the bottle body is not uniform, the bottle body needs to be cooled to a preset temperature for a long time, the production efficiency of the glass bottle is influenced, meanwhile, the glass bottle is low in strength and high in brittleness, and people are easily burst and hurt when the glass bottle is suddenly heated due to local shock cooling after being molded; imbed the reinforcing wire in the glass bottle this moment, make the quick even cooling of body through the better heat conductivity of metal, reduce the cool time of body, increase the intensity of body simultaneously, make the body pass through the reinforcing wire with the heat easily when meeting with the quench suddenly hot to conduct on every side, and then reduce local temperature periphery, the fragmentation that expend with heat and contract with cold arouses, the reinforcing wire produces the adhesion effect after the body is broken simultaneously, it hurts the people to reduce the glass disintegrating slag to splash, the security of increase glass bottle.

Preferably, the circular ring is sleeved into the bottle blank from bottom to top and then fixed in the bottle blowing mold together with the bottle blank, so that the winding of the reinforcing wire is reduced; through the ring of emboliaing by supreme down for the reinforcing wire is in the natural state of droing all the time, reduces the bending and the winding of reinforcing wire, and then further increases the quality that the reinforcing wire imbeds the body, improves the intensity of glass bottle.

Preferably, the surfaces of the circular ring and the reinforcing wire are adhered with glass powder of more than 20000 meshes, so that the compatibility of the reinforcing wire and the bottle body is improved, and the strength of the bottle body is further improved; through the glass powder of reinforcing wire surface adhesion for during the reinforcing wire melts into the bottle base fast when the bottle base of contact high temperature, and then guarantee the quality of reinforcing wire embedding body, further improve body strength.

The bottle blowing mold used in the S5 comprises a body, wherein the body is composed of two split bodies which are arranged symmetrically left and right, one adjacent sides of the split bodies are provided with a cavity for controlling the forming of a glass bottle, the top of the cavity is provided with an annular groove for fixing a bottle blank, the upper part of the annular groove is provided with a bottle mouth hole, and a spiral bottle mouth thread groove is arranged in the bottle mouth hole; a thin-wall heating ring is arranged at the position of the bottleneck hole, and a circular ring is arranged in the bottleneck hole and corresponds to the heating ring; the inner diameter of the circular ring is slightly larger than the outer diameter of the bottle blank, and the circular ring is made of iron material; the heating ring is connected with a power supply through a controller, and the heating ring heats the ring through high frequency, so that the fusion efficiency of the ring and the reinforcing wire with the bottle blank is increased, and the strength of the glass bottle is increased; installing the heated bottle blank in a cavity through a clamping device, embedding the shoulder part of the bottle blank into an annular groove, then closing the two split bodies and keeping a certain pressure, propping against the top of the bottle blank through an air nozzle and charging high-pressure air into the bottle blank, enabling the bottle blank to be attached to the inner wall of the cavity after being expanded, driving a reinforcing wire to be opened along with the bottle blank and propping against the inner wall of the cavity by the expanded bottle blank, embedding the reinforcing wire into the bottle body in the continuous pressure maintaining process of the air nozzle, further enhancing the strength of the bottle body, then cooling the bottle body through charging cooling water into the body, opening the mold and taking the bottle after the bottle body is solidified, performing high-frequency heating on a ring through a heating ring after the ring is installed in the cavity along with the bottle blank, enabling the temperature of the ring to rise and be rapidly fused into the corresponding position of the bottle blank, further avoiding the corrosion of the ring due to the exposure, enhancing the strength of the upper part close to the glass bottle, further increasing the strength of the glass bottle.

Preferably, the magnetic ring is arranged on the inner periphery of the heating ring, and the magnetic ring adsorbs the circular ring, so that the positioning precision of the circular ring is further ensured, and the strength of the glass bottle is increased; attract the ring through the magnetic ring, and then carry out preliminary fixed to the ring, later make it permanent fixed with the bottle base through the heating ring to the ring heating, further reduce the positioning error of ring, magnetism reduces after the magnetic ring is heated simultaneously, reduces the appeal to the ring, and then makes the ring take out fast along with the glass bottle after the solidification, increases the blowing efficiency of glass bottle.

Preferably, the reinforcing wires are pre-magnetized; electromagnets are arranged on the periphery of the cavity, and repulsive force is applied to the reinforcing wires through the electromagnets, so that the quality of the reinforcing wires embedded into the bottle body is further improved; a group of fins are arranged on the periphery of the heating ring, spiral cooling holes formed in the heating ring are communicated with cooling water, heat dissipation of the heating ring is accelerated by matching the cooling holes with the fins, and overheating deformation of bottle blanks at positions of bottle opening holes is reduced; the reinforcing wire has certain magnetism after being pre-magnetized, so that when the reinforcing wire props against the inner wall of the cavity along with the expanded bottle blank, a magnetic field is formed after the electromagnet is electrified, the electromagnet has the same magnetic pole with one side adjacent to the reinforcing wire, the repelling force is formed on the reinforcing wire, the depth of the reinforcing wire embedded into the bottle body is increased, and the strength of the glass bottle is further increased; accelerate the heat radiating area of heating ring through the fin, the cooling water that the cooperation cooling hole let in by supreme spiral down further accelerates the cooling of heating ring, avoids overheated heating ring to make behind the ring embedding bottle base continuation softening deformation, reduces the vertical quality of body.

Preferably, the bottom of the cavity is provided with an annular groove, and the top of the groove is fixedly connected with a breathable film; a group of fins are uniformly distributed on the periphery of a first hole formed in the sub-body, and one side of the bottom of the first hole is communicated with high-pressure water through a water inlet; the first hole at the lower part of the water inlet hole is communicated with the bottom of the groove through the second hole; the cooling efficiency of the split body is increased by spraying water and atomizing to the first hole; an arc-shaped baffle is arranged on one side, away from the bottle mouth, of the top of the first hole and used for guiding water mist to the fins; a group of third holes are uniformly distributed on the circumference of the fin, and the cooling efficiency of the bottle blank is further improved by allowing water mist to flow through the third holes; when the bottle blank expands in the closed cavity, air in the cavity passes through the breathable film and the groove after being compressed and then is blown into the first hole through the second hole, meanwhile, cooling water is sprayed into the water inlet hole, the atomized cooling water rises along the first hole after being atomized due to lack of cold water, the atomized cooling water continuously absorbs heat of the fins in the rising process of the fins, and meanwhile, the cooling water is evaporated and absorbed quickly, so that the heat dissipation efficiency of the fins is accelerated, the cooling efficiency of the split body is increased finally, the bottle body is cooled and solidified quickly, the production efficiency of the glass bottle is increased, water mist at the top of the first hole is blown to the fins after being guided by the baffle, the air flow efficiency of the fins is increased by matching with the third hole, the temperatures of the fins and the heating ring are further reduced, the positioning accuracy of the ring is guaranteed, and the abnormal deformation of the bottle.

The invention has the following beneficial effects:

1. according to the efficient environment-friendly glass bottle blowing process, the reinforcing wires are embedded into the glass bottle, the bottle body is rapidly and uniformly cooled through the good heat conductivity of metal, the cooling time of the bottle body is shortened, the strength of the bottle body is increased, the bottle body is easy to conduct heat to the periphery through the reinforcing wires when being suddenly heated by shock cooling, the local temperature periphery is further reduced, the breakage caused by expansion and contraction is caused by heat, the reinforcing wires generate an adhesion effect after the bottle body is broken, the broken glass slag is reduced from splashing to hurt people, and the safety of the glass bottle is improved.

2. According to the efficient environment-friendly glass bottle blowing process, the ring is attracted by the magnetic ring to be preliminarily fixed, and then the ring is heated by the heating ring to be permanently fixed with a bottle blank, so that the positioning error of the ring is further reduced, meanwhile, the magnetism of the magnetic ring is reduced after the magnetic ring is heated, the attraction force to the ring is reduced, and further the ring is quickly taken out along with the glass bottle after being solidified and formed, and the glass bottle blowing efficiency is improved.

Drawings

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

FIG. 1 is a process flow diagram of the present invention;

FIG. 2 is a perspective view of a bottle blowing mold according to the present invention;

FIG. 3 is a front view of the bottle blowing mold of the present invention;

FIG. 4 is an enlarged view of a portion of FIG. 2 at A;

FIG. 5 is an enlarged view of a portion of FIG. 2 at B;

FIG. 6 is a cross-sectional view taken at C-C of FIG. 3;

in the figure: the device comprises a body 1, a split body 11, a cavity 12, an annular groove 13, a bottleneck hole 14, a heating ring 15, a circular ring 16, a reinforcing wire 17, an electromagnet 2, fins 21, a cooling hole 22, a groove 23, a breathable film 24, a first hole 25, fins 26, a water inlet hole 27, a baffle 28, a third hole 29 and a second hole 30.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

As shown in fig. 1 to 6, the process for blowing a high-efficiency environment-friendly glass bottle according to the present invention comprises the following steps:

s1, crushing colorless and transparent recovered glass, then washing the glass in a water washing tank for one time, fishing out the glass after the water washing is finished, putting the glass in a pickling tank for pickling, preparing hydrochloric acid water solution with the concentration of twenty percent in the pickling tank, soaking the glass in the pickling tank for 30-60S, fishing out the glass through a filter screen, and vibrating the glass at high frequency after the filter screen is separated from the liquid level to reduce acid liquor residue on the glass;

s2, washing the acid-washed glass in the step S1 for the second time, fishing out the glass through a filter screen, spraying purified water, removing acid liquor adhered to the glass, drying and crushing the glass, and grinding the glass through a grinder to form powder with the granularity of more than 2000 meshes;

s3, weighing the powder ground in the S2, weighing 50-60 parts of glass powder, 20-30 parts of calcite, 3-5 parts of soda ash and 0.6-1.5 parts of iron oxide powder, putting the raw materials into a stirrer, fully and uniformly stirring, then sending into a furnace, heating to 1200-1400 ℃, preserving heat for more than 5 hours, and blowing oxygen into the furnace in the heating process until stable molten glass is formed in the furnace;

s4, taking out the molten glass in the step S3, putting the molten glass into a mold to prepare a bottle blank, and cooling the bottle blank for later use;

s5, reheating the bottle blank to 650 plus 750 ℃, then installing the bottle blank in a bottle blowing mold, meanwhile, sleeving a circular ring 16 with a reinforcing wire 17 which is made of metal material and is uniformly distributed on the circumference of the bottom on the periphery of the bottle blank, blowing high-pressure air into the bottle blank, so that the bottle blank is expanded and then is tightly pressed against the inner surface of the bottle blowing mold, meanwhile, the reinforcing wire 17 is embedded into the bottle body, the strength of the bottle body is increased, the phenomenon that people are injured by splashing during crushing is reduced, then, introducing cold water into the mold for cooling, opening the mold after the bottle body is cooled, taking out, and completing the blowing of a glass; in the prior art, when the blowing process of the glass bottle is completed through a mold, the mold needs to be rapidly cooled, so that the bottle blank is rapidly solidified and molded after being expanded, but due to the fact that the distribution of cooling water channels is not uniform, the cooling speed of the bottle body is not uniform, the bottle body needs to be cooled to a preset temperature for a long time, the production efficiency of the glass bottle is influenced, meanwhile, the glass bottle is low in strength and high in brittleness, and people are easily burst and hurt when the glass bottle is suddenly heated due to local shock cooling after being molded; imbed the reinforcing wire 17 in the glass bottle this moment, make the quick even cooling of body through the better heat conductivity of metal, reduce the cool time of body, increase the intensity of body simultaneously, make the body pass through the reinforcing wire 17 with the heat easily when meeting with the quench suddenly hot to conduct on every side, and then reduce local temperature periphery, the fragmentation that expend with heat and contract with cold arouses, reinforcing wire 17 produces the adhesion effect after the body is broken simultaneously, reduce the broken glass slag and splash and injure the people, increase the security of glass bottle.

As an embodiment of the invention, the circular ring 16 is sleeved into the bottle blank from bottom to top, and then fixed in the bottle blowing mold together with the bottle blank, so as to reduce the winding of the reinforcing wire 17; through the lower supreme ring 16 that embolias for the reinforcing wire 17 is in the natural state of droing all the time, reduces the crooked and the winding of reinforcing wire 17, and then further increases the quality that reinforcing wire 17 imbeds the body, improves the intensity of glass bottle.

In one embodiment of the present invention, 20000 mesh or more glass powder is adhered to the surfaces of the ring 16 and the reinforcing wire 17, so as to increase the compatibility between the reinforcing wire 17 and the bottle body and further improve the strength of the bottle body; through the glass powder of reinforcing wire 17 surface adhesion for reinforcing wire 17 melts into the bottle base fast when the bottle base of contact high temperature, and then guarantees the quality of reinforcing wire 17 embedding body, further improves body strength.

The bottle blowing mold used in the S5 comprises a body 1, wherein the body 1 consists of two split bodies 11 which are symmetrically arranged left and right, a cavity 12 used for controlling the forming of a glass bottle is arranged on one adjacent side of each split body 11, an annular groove 13 used for fixing a bottle blank is arranged at the top of each cavity 12, a bottle mouth hole 14 is arranged at the upper part of each annular groove 13, and a spiral bottle mouth thread groove is arranged in each bottle mouth hole 14; a thin-wall heating ring 15 is arranged at the bottleneck hole 14, and a circular ring 16 is arranged in the bottleneck hole 14 and corresponds to the heating ring 15; the inner diameter of the circular ring 16 is slightly larger than the outer diameter of the bottle blank, and the circular ring 16 is made of iron materials; the heating ring 15 is connected with a power supply through a controller, the heating ring 15 heats the circular ring 16 through high frequency, the fusion efficiency of the circular ring 16 and the reinforcing wire 17 with the bottle blank is increased, and the strength of the glass bottle is increased; installing the heated bottle blank in a cavity 12 through a clamping device, enabling the shoulder part of the bottle blank to be embedded into an annular groove 13, then closing the two split bodies 11 and keeping a certain pressure, propping against the top of the bottle blank through an air nozzle and filling high-pressure air into the bottle blank, enabling the bottle blank to be attached to the inner wall of the cavity 12 after being expanded, enabling the expanded bottle blank to drive a reinforcing wire 17 to be opened along with the bottle blank and propping against the inner wall of the cavity 12, then embedding the reinforcing wire 17 into the bottle body in the continuous pressure maintaining process of the air nozzle so as to further enhance the strength of the bottle body, then cooling the bottle body through filling cooling water into the body 1 so as to open the mold and take out the bottle after the bottle body is solidified, after the ring 16 is installed in the cavity 12 along with the bottle blank, carrying out high-frequency heating on the ring 16 through a heating ring 15 so as to enable the temperature of the ring 16 to be raised and rapidly fused into the corresponding position of the bottle blank, the circular ring 16 and the reinforcing wire 17 are reduced, so that the positioning error is increased due to the downward sliding, and the strength of the glass bottle is further increased.

As an embodiment of the invention, the inner circumference of the heating ring 15 is provided with a magnetic ring, and the magnetic ring adsorbs the circular ring 16, so that the positioning precision of the circular ring 16 is further ensured, and the strength of the glass bottle is increased; attract ring 16 through the magnetic ring, and then carry out preliminary fixed to ring 16, later heat ring 16 through heating ring 15 and make it permanent fixed with the bottle base, further reduce the positioning error of ring 16, the magnetism reduces after the magnetic ring is heated simultaneously, reduces the appeal to ring 16, and then makes ring 16 take out fast along with the glass bottle after the solidification shaping, increases the blowing efficiency of glass bottle.

As an embodiment of the present invention, the reinforcing wire 17 is magnetized in advance; the periphery of the cavity 12 is provided with the electromagnet 2, and the electromagnet 2 applies repulsive force to the reinforcing wire 17 to further increase the quality of the reinforcing wire 17 embedded in the bottle body; a group of fins 21 are arranged on the periphery of the heating ring 15, spiral cooling holes 22 formed in the heating ring 15 are communicated with cooling water, the cooling holes 22 are matched with the fins 21 to accelerate the heat dissipation of the heating ring 15, and the overheating deformation of the bottle blank at the position of the bottleneck hole 14 is reduced; because the reinforcing wire 17 has certain magnetism after being pre-magnetized, when the reinforcing wire 17 props against the inner wall of the cavity 12 along with the expanded bottle blank, a magnetic field is formed after the electromagnet 2 is electrified, the magnetic poles of the electromagnet 2 and the adjacent side of the reinforcing wire 17 are the same, so that repulsive force is formed on the reinforcing wire 17, the depth of the reinforcing wire 17 embedded into the bottle body is increased, and the strength of the glass bottle is further increased; the heat dissipation area of the heating ring 15 is increased through the fins 21, the cooling water is introduced from bottom to top in a spiral manner through the cooling holes 22, cooling of the heating ring 15 is further accelerated, the phenomenon that the overheated heating ring 15 enables the circular ring 16 to be embedded into the bottle blank and then the bottle blank is continuously softened and deformed is avoided, and the vertical quality of the bottle body is reduced.

As an embodiment of the invention, the bottom of the cavity 12 is provided with an annular groove 23, and the top of the groove 23 is fixedly connected with a breathable film 24; a group of fins 26 are uniformly distributed on the periphery of a first hole 25 formed in the split body 11, and one side of the bottom of the first hole 25 is communicated with high-pressure water through a water inlet 27; the first hole 25 at the lower part of the water inlet hole 27 is communicated with the bottom of the groove 23 through the second hole 30; the cooling efficiency of the split body 11 is increased by spraying water and atomizing to the first hole 25; an arc-shaped baffle 28 is arranged on one side of the top of the first hole 25, which is far away from the bottle mouth, and the baffle 28 is used for guiding water mist to the fins 21; a group of third holes 29 are uniformly distributed on the circumference of the fin 21, and the cooling efficiency of the bottle blank is further improved by allowing water mist to flow through the third holes 29; when the bottle blank expands in the closed cavity 12, air in the cavity 12 passes through the air-permeable film 24 and the groove 23 after being compressed and then is blown into the first hole 25 through the second hole 30, meanwhile, cooling water is sprayed into the water inlet hole 27, so that cold water is atomized and then ascends along the first hole 25, the atomized cooling water continuously absorbs heat of the fins 26 in the ascending process along the fins 26, and meanwhile, the heat is quickly evaporated and absorbed, so that the heat dissipation efficiency of the fins 26 is improved, the cooling efficiency of the split body 11 is finally improved, the bottle body is quickly cooled and solidified, the production efficiency of the glass bottle is improved, water mist at the top of the first hole 25 is blown to the fins 21 after being guided by the baffle 28, the air flow efficiency of the fins 21 is improved by matching with the third hole 29, the temperature of the fins 21 and the heating ring 15 is further reduced, the positioning precision of the circular ring 16 is ensured, and abnormal deformation of the bottle blank is further reduced.

When the glass bottle blowing mold is used, in the prior art, in the process of blowing a glass bottle through the mold, the mold needs to be rapidly cooled, so that a bottle blank is rapidly solidified and molded after being expanded, but due to the fact that the distribution of cooling water channels is not uniform, the cooling speed of a bottle body is not uniform, the requirement for cooling the bottle body for a long time is reduced, all positions of the bottle body can be cooled to a preset temperature, the production efficiency of the glass bottle is influenced, meanwhile, the glass bottle is low in strength and large in brittleness, and people are easily burst and injured when local shock cooling and sudden heating occur after molding; at the moment, the reinforcing wire 17 is embedded into the glass bottle, the bottle body is rapidly and uniformly cooled through the good heat conductivity of metal, the cooling time of the bottle body is shortened, the strength of the bottle body is increased, the bottle body is easy to conduct heat to the periphery through the reinforcing wire 17 when suffering from shock cooling and sudden heating, further the local temperature periphery and the fragmentation caused by thermal expansion and cold contraction are reduced, meanwhile, the reinforcing wire 17 generates an adhesion effect after the bottle body is crushed, the splashing of broken glass slag to hurt people is reduced, and the safety of the glass bottle is improved; the reinforcing wire 17 is always in a natural sagging state by sleeving the circular ring 16 from bottom to top, so that the bending and winding of the reinforcing wire 17 are reduced, the quality of embedding the reinforcing wire 17 into the bottle body is further improved, and the strength of the glass bottle is improved; the glass powder adhered to the surface of the reinforcing wire 17 enables the reinforcing wire 17 to be rapidly fused into the bottle blank when contacting the high-temperature bottle blank, so that the quality of embedding the reinforcing wire 17 into the bottle body is ensured, and the strength of the bottle body is further improved; installing the heated bottle blank in a cavity 12 through a clamping device, enabling the shoulder part of the bottle blank to be embedded into an annular groove 13, then closing the two split bodies 11 and keeping a certain pressure, propping against the top of the bottle blank through an air nozzle and filling high-pressure air into the bottle blank, enabling the bottle blank to be attached to the inner wall of the cavity 12 after being expanded, enabling the expanded bottle blank to drive a reinforcing wire 17 to be opened along with the bottle blank and propping against the inner wall of the cavity 12, then embedding the reinforcing wire 17 into the bottle body in the continuous pressure maintaining process of the air nozzle so as to further enhance the strength of the bottle body, then cooling the bottle body through filling cooling water into the body 1 so as to open the mold and take out the bottle after the bottle body is solidified, after the ring 16 is installed in the cavity 12 along with the bottle blank, carrying out high-frequency heating on the ring 16 through a heating ring 15 so as to enable the temperature of the ring 16 to be raised and rapidly fused into the corresponding position of the bottle blank, the positioning error caused by the downward sliding of the circular ring 16 and the reinforcing wire 17 is reduced, so that the strength of the glass bottle is further improved; the ring 16 is attracted through the magnetic ring, so that the ring 16 is preliminarily fixed, and then the ring 16 is heated through the heating ring 15 to be permanently fixed with the bottle blank, so that the positioning error of the ring 16 is further reduced, meanwhile, the magnetism of the heated magnetic ring is reduced, the attraction to the ring 16 is reduced, so that the ring 16 is quickly taken out along with the glass bottle after being cured and formed, and the blowing efficiency of the glass bottle is improved; because the reinforcing wire 17 has certain magnetism after being pre-magnetized, when the reinforcing wire 17 props against the inner wall of the cavity 12 along with the expanded bottle blank, a magnetic field is formed after the electromagnet 2 is electrified, the magnetic poles of the electromagnet 2 and the adjacent side of the reinforcing wire 17 are the same, so that repulsive force is formed on the reinforcing wire 17, the depth of the reinforcing wire 17 embedded into the bottle body is increased, and the strength of the glass bottle is further increased; the heat dissipation area of the heating ring 15 is increased through the fins 21, and the cooling water is spirally introduced from bottom to top through the cooling holes 22, so that the cooling of the heating ring 15 is further accelerated, the phenomenon that the overheated heating ring 15 enables the circular ring 16 to be embedded into the bottle blank and then the bottle blank is continuously softened and deformed is avoided, and the vertical quality of the bottle body is reduced; when the bottle blank expands in the closed cavity 12, air in the cavity 12 passes through the air-permeable film 24 and the groove 23 after being compressed and then is blown into the first hole 25 through the second hole 30, meanwhile, cooling water is sprayed into the water inlet hole 27, so that cold water is atomized and then ascends along the first hole 25, the atomized cooling water continuously absorbs heat of the fins 26 in the ascending process along the fins 26, and meanwhile, the heat is quickly evaporated and absorbed, so that the heat dissipation efficiency of the fins 26 is improved, the cooling efficiency of the split body 11 is finally improved, the bottle body is quickly cooled and solidified, the production efficiency of the glass bottle is improved, water mist at the top of the first hole 25 is blown to the fins 21 after being guided by the baffle 28, the air flow efficiency of the fins 21 is improved by matching with the third hole 29, the temperature of the fins 21 and the heating ring 15 is further reduced, the positioning precision of the circular ring 16 is ensured, and abnormal deformation of the bottle blank is further reduced.

The front, the back, the left, the right, the upper and the lower are all based on the figure 2 in the attached drawings of the specification, according to the standard of the observation angle of a person, the side of the device facing an observer is defined as the front, the left side of the observer is defined as the left, and the like.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc., indicate orientations or positional relationships based on those shown in the drawings, and are used merely for convenience in describing the present invention and for simplifying the description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the scope of the present invention.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.