CN112010541A - Annealing device for producing glass bottles for cosmetics - Google Patents

Abstract

The invention discloses an annealing device for producing glass bottles for cosmetics, which belongs to the technical field of glass production and comprises an annealing furnace, wherein an inflow opening and an outflow opening are respectively formed in the side surface of the annealing furnace, and the inflow opening and the outflow opening are arranged in an oblique diagonal manner. According to the invention, the transmission action of the glass bottles for cosmetics in the vertical direction can be carried out in the limited space of the annealing furnace under the mutual matching of the designed structures such as the first driving device, the second driving device, the first guiding device, the second guiding device, the transmission device, the combustor, the main pipe, the branch pipe, the second air pump, the first air pump, the negative pressure drainage pipe and the clamping groove, so that the floor area of the annealing furnace is effectively reduced, the temperature in the annealing furnace is reduced in a stepped manner from bottom to top, accidents such as cracks and the like caused by the large temperature difference of cold and heat of the glass bottles for cosmetics are effectively avoided, and the yield of the glass bottles for cosmetics is improved.

Description

Annealing device for producing glass bottles for cosmetics

Technical Field

The invention belongs to the technical field of glass production, and particularly relates to an annealing device for producing glass bottles for cosmetics.

Background

The cosmetic is chemical industry product or fine chemical product which is applied on any part of human body surface by smearing, spraying or other similar methods, such as skin, hair, nails, lips and teeth, to achieve the purpose of cleaning, caring, beautifying, modifying and changing appearance, or correcting human body odor and maintaining good state

Glass bottles exist in China from ancient times, the glass ware is considered to be rare in ancient times by the academic world in the past, so the glass ware can be owned and used only in few controlled levels, but the research in recent years considers that the production and the manufacture of the ancient glass ware are not difficult, and the glass ware is not easy to store and rare in the future, the glass bottles are traditional beverage packaging containers in China, the glass is historical packaging materials, and under the condition that a plurality of packaging materials are introduced into the market, the glass containers still occupy important positions in beverage packaging, and the packaging characteristics cannot be replaced by other packaging materials are not distinguished.

The production process of the cosmetic bottle is similar to that of other glass bottles, the high-temperature glass liquid in a molten state is blown and molded by using a model, the temperature of the glass bottle is about 1000 ℃ after the glass bottle is solidified, if air is directly fed, the cosmetic bottle is cracked due to rapid cooling, an annealing device is required to be used for annealing, the cosmetic bottle is smaller in size, complex in shape, more in bulges, more in appearance and more exquisite in appearance and does not contain lead, therefore, the annealing time of the cosmetic bottle is longer, at present, the annealing device used for producing the glass bottle for the cosmetic still has some defects, in order to prolong the annealing time of the glass bottle in an annealing furnace, the span of a transmission mechanism used in the annealing device is longer, the occupied area of the annealing furnace is larger, certain contradiction exists, and the glass bottle is easy to shake and topple in the transmission process, in addition, most of the heat energy released by the heating mechanism arranged in the annealing furnace is directly lost from the two openings, which causes waste of resources, and therefore, an annealing device used for producing glass bottles for cosmetics is urgently needed in the market at the present stage to solve the problems.

Disclosure of Invention

The invention aims to: the annealing device for producing the glass bottles for cosmetics is provided for solving the problems that the existing annealing device for producing the glass bottles for cosmetics still has some defects, the annealing time of the glass bottles in an annealing furnace is prolonged, the span of a transmission mechanism used in the annealing furnace is long, the occupied area of the annealing furnace is large, certain contradictions exist, the glass bottles are easy to tip due to vibration in the transmission process, more heat energy released by a heating mechanism arranged in the annealing furnace is directly lost from two openings, and the resource waste is caused.

In order to achieve the purpose, the invention adopts the following technical scheme:

an annealing device used for producing glass bottles for cosmetics comprises an annealing furnace, wherein the side surface of the annealing furnace is respectively provided with an inflow opening and an outflow opening, the inflow opening and the outflow opening are arranged in diagonal angles, the positions of the side directions of the annealing furnace corresponding to the outflow opening and the inflow opening are respectively and fixedly connected with a first driving device and a second driving device, the second driving device is in transmission connection with the first driving device through a transmission device, the transmission device is internally and respectively in transmission connection with a first guiding device and a second guiding device, the side end surfaces of the second guiding device and the first guiding device are fixedly connected with the inner side wall of the annealing furnace, the position of the inner side wall of the annealing furnace corresponding to the transmission device is provided with a burner, the positions of the side wall of the annealing furnace corresponding to the burner and the transmission device are respectively clamped with a branch pipe, and the end part of the branch pipe is communicated with an, the surface of the transmission device is provided with a clamping groove, a probe is arranged on the inner side wall of the transmission device at a position corresponding to the clamping groove, and an electromagnetic valve tube is arranged in a port of the probe.

As a further description of the above technical solution:

first drive arrangement and second drive arrangement's structure is the same, second drive arrangement includes the drive roller, the drive roller passes through the transmission and connects, the tip joint of drive roller has first bearing, cup jointed first pivot in the first bearing, the one end of first pivot and the inside wall fixed connection of outer frame, the side surface of outer frame and the inside wall fixed connection of annealing stove.

As a further description of the above technical solution:

the one end of first pivot and the tip fixed connection of first motor output shaft, the inside wall fixed connection of fixing base and drive roller is passed through on the surface of first motor fuselage.

As a further description of the above technical solution:

first guider includes first guide roll, first guide roll passes through the transmission and connects, the tip joint of first guide roll has the second bearing, the second pivot has been cup jointed in the second bearing, the first link of fixed surface of second pivot is connected with, the side tip of first link and the inside wall fixed connection of annealing stove.

As a further description of the above technical solution:

the second guiding device comprises a second guiding roller, the second guiding roller is connected through transmission of a transmission device, a third bearing is connected to the end portion of the second guiding roller in a clamped mode, a third rotating shaft is sleeved in the third bearing, a second connecting frame is fixedly connected to the surface of the third rotating shaft, and the side end portion of the second connecting frame is fixedly connected with the inner side wall of the annealing furnace.

As a further description of the above technical solution:

the transmission device comprises an outer side transmission belt, wherein an inner side transmission belt is sleeved on the inner side of the outer side transmission belt, and the end faces of the inner side transmission belt and the inner side transmission belt are fixedly connected through wrapping.

As a further description of the above technical solution:

the drive roller passes through the transmission of transmission device and connects, first guide roller passes through inboard transmission band transmission and connects, the second guide roller passes through inboard transmission band transmission and connects.

As a further description of the above technical solution:

the bottom of outside transmission band passes through the top fixed connection of shock mount and second air pump fuselage, the input port of second air pump is linked together through the surface of negative pressure drainage tube with the outside transmission band.

As a further description of the above technical solution:

the input port of the first air pump is communicated with one end close to the drainage tube, and the port of the drainage tube is positioned at the outflow opening.

As a further description of the above technical solution:

the input of first air pump, second air pump, combustor and motor all is through the output electric connection of wire with the switch, the input of switch passes through the output electric connection of wire and power, switch and power all set up the surface at the annealing stove, the solenoid valve pipe has solenoid valve and pipeline combination to form to be provided with pressure sensors in the probe, just solenoid valve and pressure sensors all with host computer electric connection to host computer and time-recorder electric connection.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

1. according to the invention, the transmission action of the glass bottles for cosmetics in the vertical direction can be carried out in the limited space of the annealing furnace under the mutual matching of the designed structures such as the first driving device, the second driving device, the first guiding device, the second guiding device, the transmission device, the combustor, the main pipe, the branch pipe, the second air pump, the first air pump, the negative pressure drainage pipe and the clamping groove, so that the floor area of the annealing furnace is effectively reduced, the temperature in the annealing furnace is reduced in a stepped manner from bottom to top, accidents such as cracks and the like caused by the large temperature difference of cold and heat of the glass bottles for cosmetics are effectively avoided, and the yield of the glass bottles for cosmetics is improved.

2. In the invention, the first driving device and the second driving device are operated by the designed first driving device and the second driving device, and the motor can directly act the torsion on the driving roller in the working process of the first driving device and the second driving device, so that the transmission device can be driven to carry out transmission work.

3. According to the invention, through the designed first guide device, in the process of transmission work of the transmission device, the first guide roller is positioned between the outer side transmission belt and the inner side transmission belt, and the connecting part between the first connecting frame and the second rotating shaft is positioned in the gap between the two inner side transmission belts, so that the transmission device can be positioned and guided without influencing the transmission work of the outer side transmission belt.

4. According to the invention, through the designed second guide device, in the process of transmission work of the transmission device, the second guide roller is positioned on the inner side of the inner side transmission belt, the connecting part between the second connecting frame and the third rotating shaft is positioned in the gap between the two inner side transmission belts, the positioning and guiding effects on the transmission device can be realized, the transmission and guiding work of the outer side transmission belt cannot be influenced, and the transmission action of the glass bottles for cosmetics in the vertical direction can be carried out in the limited space of the annealing furnace under the mutual cooperation of the first guide device and the second guide device, so that the floor area of the annealing furnace can be effectively reduced.

5. According to the invention, through the designed transmission device, the transmission device is formed by combining a group of outer transmission belts, two groups of inner transmission belts and two groups of covered edges, the covered edges are used as connecting media between the outer transmission belts and the inner transmission belts, so that the outer transmission belts can drive the inner transmission belts to carry out synchronous transmission action in the transmission process, the inner transmission belts can change the transmission tracks of the outer transmission belts in the positioning and guiding processes of the first guide device and the second guide device, and the normal transmission work of the outer transmission belts cannot be influenced.

6. In the invention, the first air pump and the burner work by the designed burner, the branch pipe, the main pipe, the drainage pipe and the first air pump, the switch is operated to ensure that the burner can heat the glass bottle for cosmetics which just enters the annealing furnace through the inflow opening, the input port of the first air pump can utilize the drainage pipe to introduce the low-temperature air positioned at the outflow opening into the main pipe through the output port of the first air pump in the working process, the low-temperature air in the main pipe is converged into the annealing furnace again through the branch pipe, and under the action of the negative pressure generated by the first air pump, the high-temperature air released by the burner at the bottom of the annealing furnace flows upwards and is mixed with the low-temperature air released by the branch pipe, so that the temperature in the annealing furnace is reduced in a step form from bottom to top, and accidents such as cracks of cosmetics and the like caused by the large difference of the cold and heat temperature of the glass bottle are, the yield of the glass bottles for cosmetics is improved.

7. According to the cosmetic glass bottle collecting device, the second air pump, the negative pressure drainage tube, the clamping groove, the probe and the electromagnetic valve tube are designed, the switch is operated to enable the second air pump to run, the pressure sensor is arranged in the clamping groove, after the pressure sensor senses that a cosmetic glass bottle is put in the clamping groove, the electromagnetic valve on the electromagnetic valve tube is controlled to be opened in a variable mode through the upper computer, suction force towards the interior of an outer transmission belt is enabled to be arranged in the clamping groove, after the cosmetic glass bottle is conveyed to the top, the timer counts time, the upper computer sends out a corresponding control instruction to the electromagnetic valve again, the electromagnetic valve is closed, the glass bottle is separated from the action of the suction force, the glass bottle flowing out through the outflow opening can be collected rapidly, and the glass bottle cannot be toppled over easily due to vibration in the conveying process.

Drawings

FIG. 1 is a schematic sectional view of a front view of an annealing device for producing cosmetic glass bottles, which is provided by the invention;

FIG. 2 is a schematic perspective view of a second driving device of an annealing device for producing cosmetic glass bottles according to the present invention;

FIG. 3 is a schematic cross-sectional view of the second driving device in the annealing device for producing cosmetic glass bottles according to the present invention;

FIG. 4 is a schematic perspective view of a first guiding device of an annealing device for producing cosmetic glass bottles according to the present invention;

FIG. 5 is a schematic perspective view of a second guiding device of the annealing device for producing cosmetic glass bottles according to the present invention;

FIG. 6 is an exploded view of an annealing device transfer device used for producing cosmetic glass bottles according to the present invention;

FIG. 7 is an enlarged schematic structural view of the part A of the annealing device for producing the glass bottle for cosmetics.

Illustration of the drawings:

1. an annealing furnace; 2. flows into the opening; 3. the outflow opening is opened; 4. a first driving device; 5. a second driving device; 51. a drive roller; 52. a first bearing; 53. a first rotating shaft; 54. an outer frame; 55. a motor; 56. a fixed seat; 6. a first guide means; 61. a first guide roller; 62. a second bearing; 63. a second rotating shaft; 64. a first connecting frame; 7. a second guide means; 71. a second guide roller; 72. a third bearing; 73. a third rotating shaft; 74. a second link frame; 8. a transmission device; 81. an outer conveyor belt; 82. an inner conveyor belt; 83. edge covering; 9. a burner; 10. a main pipe; 11. a branch pipe; 12. a drainage tube; 13. a first air pump; 14. a second air pump; 15. a negative pressure drainage tube; 16. a card slot; 17. a probe; 18. a solenoid valve tube; 19. a power source; 20. and (4) switching.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-7, the present invention provides a technical solution: an annealing device used for producing glass bottles for cosmetics comprises an annealing furnace 1, the side surface of the annealing furnace 1 is respectively provided with an inflow opening 2 and an outflow opening 3, the inflow opening 2 and the outflow opening 3 are arranged diagonally, the positions of the side of the annealing furnace 1 corresponding to the outflow opening 3 and the inflow opening 2 are respectively and fixedly connected with a first driving device 4 and a second driving device 5, the second driving device 5 is in transmission connection with the first driving device 4 through a transmission device 8, the transmission device 8 is respectively and fixedly connected with a first guiding device 6 and a second guiding device 7, the side end surfaces of the second guiding device 7 and the first guiding device 6 are fixedly connected with the inner side wall of the annealing furnace 1, the position of the inner side wall of the annealing furnace 1 corresponding to the transmission device 8 is provided with a burner 9, and the positions of the side wall of the annealing furnace 1 corresponding to the burner 9 and the transmission device 8 are respectively clamped with a branch, the end part of the branch pipe 11 is communicated with an output port of a first air pump 13 through a main pipe 10, a clamping groove 16 is formed in the surface of the transmission device 8, a probe 17 is arranged on the inner side wall of the transmission device 8 corresponding to the position of the clamping groove 16, and an electromagnetic valve pipe 18 is arranged in a port of the probe 17.

Specifically, as shown in fig. 1, the first driving device 4 and the second driving device 5 have the same structure, the second driving device 5 includes a driving roller 51, the driving roller 51 is in transmission connection with the transmission device 8, a first bearing 52 is clamped at an end of the driving roller 51, a first rotating shaft 53 is sleeved in the first bearing 52, one end of the first rotating shaft 53 is fixedly connected with an inner side wall of an outer frame 54, a side surface of the outer frame 54 is fixedly connected with the inner side wall of the annealing furnace 1, the first driving device 4 and the second driving device 5 are operated by operating the switch 20, the first driving device 4 and the second driving device 5 operate simultaneously, and the motor 55 can directly apply torque to the driving roller 51 during operation of the first driving device 4 and the second driving device 5, so as to drive the transmission device 8 to perform transmission operation.

Specifically, as shown in fig. 3, one end of the first rotating shaft 53 is fixedly connected to an end of an output shaft of the first motor 55, and a surface of a body of the first motor 55 is fixedly connected to an inner sidewall of the driving roller 51 through a fixing seat 56.

Specifically, as shown in fig. 4, the first guiding device 6 includes a first guiding roller 61, the first guiding roller 61 is in transmission connection with the conveying device 8, a second bearing 62 is clamped at an end of the first guiding roller 61, a second rotating shaft 63 is sleeved in the second bearing 62, a first connecting frame 64 is fixedly connected to a surface of the second rotating shaft 63, a side end of the first connecting frame 64 is fixedly connected with an inner side wall of the annealing furnace 1, the first guiding device 6 is designed, during the conveying operation of the conveying device 8, the first guiding roller 61 is located between the outer conveying belt 81 and the inner conveying belt 82, and a connecting portion between the first connecting frame 64 and the second rotating shaft 63 is located in a gap between the two inner conveying belts 82, so that the conveying device 8 can be positioned and guided without affecting the conveying operation of the outer conveying belt 81.

Specifically, as shown in fig. 5, the second guiding device 7 includes a second guiding roller 71, the second guiding roller 71 is in transmission connection with the conveying device 8, a third bearing 72 is clamped at an end of the second guiding roller 71, a third rotating shaft 73 is sleeved in the third bearing 72, a second connecting frame 74 is fixedly connected to a surface of the third rotating shaft 73, a side end of the second connecting frame 74 is fixedly connected with an inner side wall of the annealing furnace 1, by designing the second guiding device 7, during the conveying operation of the conveying device 8, the second guiding roller 71 is located at an inner side of the inner side conveying belt 82, and a connecting portion between the second connecting frame 74 and the third rotating shaft 73 is located in a gap between the two inner side conveying belts 82, so as to be able to perform positioning and guiding functions on the conveying device 8 without affecting the conveying and guiding operation of the outer side conveying belt 81, under the mutual cooperation of the first guiding device 6 and the second guiding device 7, the glass bottles for cosmetics can be conveyed in the vertical direction in a limited space of the annealing furnace 1, and the floor area of the annealing furnace 1 can be effectively reduced.

Specifically, as shown in fig. 6, the transmission device 8 includes an outer transmission belt 81, an inner transmission belt 82 is sleeved on an inner side of the outer transmission belt 81, and end surfaces of the inner transmission belt 82 and the inner transmission belt 82 are fixedly connected through an edge 83, the transmission device 8 is designed to be composed of a set of outer transmission belt 81, two sets of inner transmission belts 82 and two sets of edge 83, the edge 83 is used as a connection medium between the outer transmission belt 81 and the inner transmission belt 82, so that the outer transmission belt 81 can drive the inner transmission belt 82 to perform synchronous transmission in the transmission process, and the inner transmission belt 82 can change a transmission track of the outer transmission device 8 in the positioning and guiding processes of the first guiding device 6 and the second guiding device 7, and normal transmission work of the outer transmission belt 81 is not affected.

Specifically, as shown in fig. 1, the driving roller 51 is drivingly connected to the conveying device 8, the first guide roller 61 is drivingly connected to the inner conveying belt 82, and the second guide roller 71 is drivingly connected to the inner conveying belt 82.

Specifically, as shown in fig. 1, the bottom of the outer conveyor belt 81 is fixedly connected with the top of the body of the second air pump 14 through a shock absorption seat, the input port of the second air pump 14 is communicated with the surface of the outer conveyor belt 81 through the negative pressure drainage tube 15, the second air pump 14, the negative pressure drainage tube 15, the clamping groove 16, the probe 17 and the solenoid valve tube 18 are designed, the switch 20 is operated to operate the second air pump 14, the pressure sensor is arranged in the clamping groove 16, after the pressure sensor senses that the glass bottle for cosmetics is put in the clamping groove 16, the upper computer variably controls the opening of the solenoid valve on the solenoid valve tube 18 to enable the suction force in the clamping groove 16 to be directed to the inside of the outer conveyor belt 81, when the glass bottle for cosmetics is conveyed to the top, the timer counts time, the upper computer sends a corresponding control instruction to the solenoid valve again, the solenoid valve is closed, and the glass bottle is, so that the glass bottles flowing out through the outflow opening 3 can be rapidly collected, and the glass bottles cannot be easily toppled over due to vibration in the process of being conveyed.

Specifically, as shown in fig. 1, the input port of the first air pump 13 communicates with one end of the draft tube 12 adjacent thereto, and the port of the draft tube 12 is located at the outflow opening 3.

Specifically, as shown in fig. 1, the input ends of the first air pump 13, the second air pump 14, the burner 9 and the motor 55 are electrically connected with the output end of the switch 20 through wires, the input end of the switch 20 is electrically connected with the output end of the power supply 10 through wires, the switch 20 and the power supply 10 are both arranged on the surface of the annealing furnace 1, the electromagnetic valve tube 18 is formed by combining an electromagnetic valve and a pipeline, a pressure sensor is arranged in the probe 17, the electromagnetic valve and the pressure sensor are electrically connected with an upper computer, the upper computer is electrically connected with the timer, the first air pump 13 and the burner 9 are operated by the designed burner 9, the branch tube 11, the main tube 10, the drainage tube 12 and the first air pump 13, the burner 9 can heat the glass bottle for cosmetics which just enters the annealing furnace 1 through the inflow opening 2, and during the operation of the first air pump 13, the low-temperature air at the position of the outflow opening 3 can be introduced into the main pipe 10 through the input port by utilizing the drainage pipe 12, the low-temperature air in the main pipe 10 can be remitted into the annealing furnace 1 through the branch pipe 11, and under the action of the negative pressure generated by the first air pump 13, the high-temperature air released by the burner 9 at the bottom of the annealing furnace 1 flows upwards and is mixed with the low-temperature air released by the branch pipe 11, so that the temperature in the annealing furnace 1 is reduced in a stepped manner from bottom to top, accidents such as cracks and the like caused by the large difference of cold and hot temperatures of the glass bottles for cosmetics are effectively avoided, and the yield of the glass bottles for cosmetics is improved.

The working principle is as follows: when in use, the switch 20 is operated to enable the first driving device 4 and the second driving device 5 to operate simultaneously, the motor 55 can directly act on the driving roller 51 to drive the transmission device 8 to perform transmission work when the first driving device 4 and the second driving device 5 operate, the second guide roller 71 is positioned at the inner side of the inner side transmission belt 82 in the transmission work process of the transmission device 8, and the connecting part between the second connecting frame 74 and the third rotating shaft 73 is positioned in the gap between the two inner side transmission belts 82, so that the transmission device 8 can be positioned and guided, the transmission and guiding work of the outer side transmission belt 81 cannot be influenced, the glass bottles for cosmetics can be vertically transmitted in the limited space of the annealing furnace 1 under the mutual cooperation of the first guide device 6 and the second guide device 7, so that the floor area of the annealing furnace 1 can be effectively reduced, in the process of the transmission work of the transmission device 8, the first guide roller 61 is positioned between the outer transmission belt 81 and the inner transmission belt 82, the connecting part between the first connecting frame 64 and the second rotating shaft 63 is positioned in the gap between the two inner transmission belts 82, the transmission device 8 can play a role of positioning and guiding the transmission device 8 without influencing the transmission work of the outer transmission belt 81, the transmission device 8 is formed by combining a group of outer transmission belts 81, two groups of inner transmission belts 82 and two groups of covered edges 83, the covered edges 83 are used as connecting media between the outer transmission belts 81 and the inner transmission belts 82, so that the outer transmission belts 81 can drive the inner transmission belts 82 to carry out synchronous transmission action in the transmission process, and the inner transmission belts 82 can change the transmission track of the outer transmission device 8 in the positioning and guiding processes of the first guide device 6 and the second guide device 7, and will not influence the normal transmission work of the outside conveyor belt 81, in the above-mentioned process, the operation switch 20 makes the first air pump 13 and the burner 9 work, the burner 9 can heat the glass bottle for cosmetics which just enters into the annealing furnace 1 through the inflow opening 2, and in the working process of the first air pump 13, its input port can utilize the draft tube 12 to introduce the low temperature air which is located at the outflow opening 3 and into the main tube 10 from its output port, the low temperature air in the main tube 10 is remitted into the annealing furnace 1 through the branch tube 11, and under the effect of the negative pressure produced by the first air pump 13, the high temperature air released by the burner 9 located at the bottom of the annealing furnace 1 flows upwards and mixes with the low temperature air released by the branch tube 11, so that the temperature inside the annealing furnace 1 is reduced stepwise from bottom to top, thereby effectively avoiding the unexpected accidents such as cracks of the glass bottle for cosmetics due to the large difference of the cold and heat temperature, the finished product ratio of the glass bottles for cosmetics is improved, the second air pump 14 is operated by the operating switch 20, a pressure sensor is arranged in the clamping groove 16, after the pressure sensor senses that the glass bottles for cosmetics are put into the clamping groove 16, the electromagnetic valve on the upper computer change control electromagnetic valve pipe 18 is opened, suction force towards the inside of the outer side transmission band 81 is formed in the clamping groove 16, when the glass bottles for cosmetics are transmitted to the top, timing is carried out by the timer, the upper computer sends out a corresponding control instruction to the electromagnetic valve again, the electromagnetic valve is closed, the glass bottles are separated from the suction force, glass bottles flowing out through the outflow opening 3 can be collected quickly, and the glass bottles cannot be toppled over easily due to vibration in the process of being transmitted.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical scope of the present invention and the equivalent alternatives or modifications according to the technical solution and the inventive concept of the present invention within the technical scope of the present invention.

Claims (10)

1. The annealing device for producing the glass bottles for cosmetics comprises an annealing furnace (1) and is characterized in that an inflow opening (2) and an outflow opening (3) are respectively formed in the side surface of the annealing furnace (1), the inflow opening (2) and the outflow opening (3) are diagonally arranged, a first driving device (4) and a second driving device (5) are respectively and fixedly connected to the positions of the side part of the annealing furnace (1) corresponding to the outflow opening (3) and the inflow opening (2), the second driving device (5) is in transmission connection with the first driving device (4) through a transmission device (8), a first guide device (6) and a second guide device (7) are respectively in transmission connection with the transmission device (8), and the side end surfaces of the second guide device (7) and the first guide device (6) are fixedly connected with the inner side wall of the annealing furnace (1), the position that annealing stove (1) inside wall corresponds transmission device (8) is provided with combustor (9) to the position that annealing stove (1) lateral wall corresponds combustor (9) and transmission device (8) is the joint respectively has branch pipe (11), the tip of branch pipe (11) is linked together through the delivery outlet of being responsible for (10) and first air pump (13), draw-in groove (16) have been seted up on the surface of transmission device (8), and the position that transmission device (8) inside wall corresponds draw-in groove (16) is provided with probe (17), be provided with solenoid valve pipe (18) in the port of probe (17).

2. The annealing device for producing the glass bottles for cosmetics according to claim 1, wherein the first driving device (4) and the second driving device (5) are identical in structure, the second driving device (5) comprises a driving roller (51), the driving roller (51) is in transmission connection with a transmission device (8), a first bearing (52) is clamped at the end part of the driving roller (51), a first rotating shaft (53) is sleeved in the first bearing (52), one end of the first rotating shaft (53) is fixedly connected with the inner side wall of an outer frame (54), and the side surface of the outer frame (54) is fixedly connected with the inner side wall of the annealing furnace (1).

3. An annealing device for producing glass bottle for cosmetics according to claim 2, characterized in that one end of the first rotating shaft (53) is fixedly connected with the end of the output shaft of the first motor (55), and the surface of the body of the first motor (55) is fixedly connected with the inner side wall of the driving roller (51) through the fixing seat (56).

4. The annealing device for producing glass bottles for cosmetics according to claim 3, characterized in that the first guiding device (6) comprises a first guiding roller (61), the first guiding roller (61) is in transmission connection with a transmission device (8), a second bearing (62) is clamped at the end of the first guiding roller (61), a second rotating shaft (63) is sleeved in the second bearing (62), a first connecting frame (64) is fixedly connected to the surface of the second rotating shaft (63), and the side end of the first connecting frame (64) is fixedly connected with the inner side wall of the annealing furnace (1).

5. The annealing device for producing glass bottles for cosmetics according to claim 4, wherein the second guiding device (7) comprises a second guiding roller (71), the second guiding roller (71) is in transmission connection with the transmission device (8), a third bearing (72) is clamped at the end part of the second guiding roller (71), a third rotating shaft (73) is sleeved in the third bearing (72), a second connecting frame (74) is fixedly connected to the surface of the third rotating shaft (73), and the side end part of the second connecting frame (74) is fixedly connected with the inner side wall of the annealing furnace (1).

6. An annealing device for producing glass bottle for cosmetics according to claim 5, characterized in that the said conveying device (8) comprises an outer conveying belt (81), the inner side of the said outer conveying belt (81) is sleeved with an inner conveying belt (82), and the end faces of the inner conveying belt (82) and the inner conveying belt (82) are fixedly connected by a covered edge (83).

7. An annealing device for the production of glass bottles for cosmetics according to claim 6 characterized in that said driving roller (51) is drivingly connected by a transmission means (8), said first guiding roller (61) is drivingly connected by an inner transmission belt (82), and said second guiding roller (71) is drivingly connected by an inner transmission belt (82).

8. The annealing device for producing glass bottles for cosmetics according to claim 7, wherein the bottom of the outer conveyor belt (81) is fixedly connected with the top of the body of the second air pump (14) through a shock absorption seat, and the input port of the second air pump (14) is communicated with the surface of the outer conveyor belt (81) through a negative pressure drainage tube (15).

9. An annealing device for the production of cosmetic glass bottles according to claim 8 characterized in that the input port of said first air pump (13) communicates with the end near the drain tube (12) and the port of the drain tube (12) is located at the outflow opening (3).

10. The annealing device for producing glass bottles for cosmetics according to claim 9, wherein the input ends of the first air pump (13), the second air pump (14), the burner (9) and the motor (55) are electrically connected with the output end of the switch (20) through wires, the input end of the switch (20) is electrically connected with the output end of the power supply (10) through wires, the switch (20) and the power supply (10) are both arranged on the surface of the annealing furnace (1), the electromagnetic valve tube (18) is formed by combining an electromagnetic valve and a pipeline, a pressure sensor is arranged in the probe (17), the electromagnetic valve and the pressure sensor are both electrically connected with an upper computer, and the upper computer is electrically connected with a timer.

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