CN113003923B - Material mixing device for manufacturing wine bottles - Google Patents

Abstract

The invention discloses a material mixing device for manufacturing wine bottles, which comprises a device main body, a heating plate, a driving and stirring assembly, a first driven assembly and a second driven assembly, wherein the heating plate is arranged on the side surface of the shell, the driving and stirring assembly is arranged above the shell, and the first driven assembly and the second driven assembly are arranged on two sides of the driving and stirring assembly and are matched with the driving and stirring assembly. The glass stirring device has the beneficial effects that the glass stirring device is improved, the glass material in the device is fully stirred, the phenomenon that the glass forming quality is influenced due to uneven heating temperature caused by excessive raw materials is avoided, and the production quality is improved.

Description

Material mixing device for manufacturing wine bottles

Technical Field

The invention relates to the technical field of wine bottle manufacturing, in particular to a material mixing device for wine bottle manufacturing.

Background

Glass is an amorphous inorganic non-metallic material, and is generally prepared by using various inorganic minerals as main raw materials and adding a small amount of auxiliary raw materials. Its main components are silicon dioxide and other oxides. The chemical composition of the common glass is Na2SiO3, caSiO3, siO2 or Na 2O. CaO.6SiO 2, etc., the main component is a silicate double salt, and the common glass is an amorphous solid with a random structure. The light-transmitting composite material is widely applied to buildings, is used for isolating wind and transmitting light, and belongs to a mixture. Colored glass in which an oxide or salt of a certain metal is mixed to develop a color, tempered glass produced by a physical or chemical method, and the like are also available. Some transparent plastics are sometimes called organic glass, and glass wine bottles are usually processed in a material dropping mode in the production process, wherein the material dropping mode is to make the glass liquid in a tank furnace flow out to reach the forming temperature, and the material dropping machine is used for making material drops with certain mass and shape and sending the material drops into a forming machine mold at certain time intervals. The material mixing device for producing and processing the existing glass wine bottle can not stir and heat glass liquid, so that the glass liquid is heated unevenly, and the production quality of the product is influenced.

Disclosure of Invention

This section is for the purpose of summarizing some aspects of embodiments of the invention and to briefly introduce some preferred embodiments. In this section, as well as in the abstract and the title of the invention of this application, simplifications or omissions may be made to avoid obscuring the purpose of the section, the abstract and the title, and such simplifications or omissions are not intended to limit the scope of the invention.

The present invention has been made keeping in mind the above and/or other problems occurring in the prior art.

Therefore, one of the objects of the present invention is to provide a stirring device for manufacturing wine bottles, which can sufficiently stir glass frit for molding so as to heat the glass frit uniformly.

In order to solve the technical problems, the invention provides the following technical scheme: the utility model provides a material device of mixing of beverage bottle manufacturing usefulness, its includes the device main part, including the casing, set up in the hot plate of casing side, set up in the drive stirring subassembly of casing top, set up in drive stirring subassembly both sides to rather than the first driven subassembly of complex and the driven subassembly of second.

As a preferable aspect of the material mixing device for manufacturing the wine bottle of the present invention, wherein: the driving stirring assembly comprises a driving motor arranged above the shell, a first transmission shaft connected with the driving motor, a stirring plate connected with the bottom of the first transmission shaft, and a driving gear connected with the first transmission shaft.

As a preferable scheme of the material mixing device for manufacturing the wine bottle of the present invention, wherein: the first driven assembly and the second driven assembly are symmetrically arranged; the first driven assembly comprises a transfer gear engaged with the driving gear, a driven gear engaged with the transfer gear, a second transmission shaft connected with the center of the bottom of the driven gear, a sleeve part arranged at the bottom of the second transmission shaft, a third transmission shaft connected with the bottom of the sleeve part, a blade plate arranged on the side face of the third transmission shaft, and a liquid lifting part connected with the bottom of the third transmission shaft.

As a preferable scheme of the material mixing device for manufacturing the wine bottle of the present invention, wherein: the sleeve part comprises an outer sleeve, a rotating cylinder arranged in the outer sleeve and connected with the tail end of the second transmission shaft, a matching groove arranged on the side surface of the rotating cylinder, an inner sleeve arranged on the side surface of the rotating cylinder, and sliding columns symmetrically arranged on two sides of the inner sleeve and one end of each sliding column is matched with the matching groove; the top of the third transmission shaft is connected with the center of the bottom of the inner sleeve, and the third transmission shaft and the second transmission shaft extend out of the outer sleeve.

As a preferable scheme of the material mixing device for manufacturing the wine bottle of the present invention, wherein: the liquid lifting piece comprises a support fixedly connected with the bottom of the third transmission shaft, and a first liquid dividing piece and a second liquid dividing piece which are respectively connected with the two sides of the support; the first liquid dividing part and the second liquid dividing part are consistent in structure.

As a preferable scheme of the material mixing device for manufacturing the wine bottle of the present invention, wherein: first minute liquid spare includes the first articulated slab articulated with support one end, with the articulated second articulated slab of first articulated slab, set up the fixing base in the casing, set up on the fixing base, the axis of rotation that one end is connected with the second articulated slab, the rotating gear who is connected with the axis of rotation other end, set up in the rotating gear top to rather than the meshing gear of increaseing, with the drive shaft of increaseing gear central connection, the cylinder of being connected with drive shaft one end, and the array sets up the stirring flabellum in the cylinder side.

As a preferable aspect of the material mixing device for manufacturing the wine bottle of the present invention, wherein: the shell comprises a feeding nozzle arranged on the side surface of the shell, a dripping port arranged at the bottom of the shell and four groups of cylinders.

As a preferable aspect of the material mixing device for manufacturing the wine bottle of the present invention, wherein: the outer sleeve also comprises a fixing ring arranged in the middle of the outer sleeve and a sealing ring arranged at the bottom of the outer sleeve, and the sealing ring is movably connected with the third transmission shaft.

As a preferable aspect of the material mixing device for manufacturing the wine bottle of the present invention, wherein: the outer sleeve further comprises sliding limiting grooves symmetrically arranged on the inner wall of the outer sleeve, and the sliding column comprises limiting blocks arranged at the outer end of the sliding limiting grooves and matched with the sliding limiting grooves.

As a preferable scheme of the material mixing device for manufacturing the wine bottle of the present invention, wherein: the matching grooves are communicated broken line grooves, and one ends of the two groups of sliding columns are symmetrically arranged in the grooves; the length of the first hinge plate is far greater than that of the second hinge plate.

The invention has the beneficial effects that: according to the device, the glass stirring device is improved, so that the glass in the device is fully stirred, the phenomenon that the glass forming quality is influenced due to uneven heating temperature caused by excessive raw materials is avoided, and the production quality is improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the description below are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without inventive labor. Wherein:

fig. 1 is an external configuration diagram of a stirring device for manufacturing wine bottles.

Fig. 2 is an internal structure diagram of a stirring device for manufacturing wine bottles.

Fig. 3 is a structural view of a first driven assembly of the stirring device for manufacturing wine bottles.

Fig. 4 is an exploded view of a sleeve member of a material mixing device for wine bottle manufacturing.

Fig. 5 is another perspective view of the sleeve member of the stirring device for wine bottle manufacture shown disassembled.

Fig. 6 is a structural view of a liquid lifting member of the stirring device for manufacturing wine bottles.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways than those specifically described and will be readily apparent to those of ordinary skill in the art without departing from the spirit of the present invention, and therefore the present invention is not limited to the specific embodiments disclosed below.

Furthermore, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one implementation of the invention. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

Example 1

Referring to fig. 1 to 6, a first embodiment of the present invention provides a material stirring device for manufacturing a wine bottle, which is used for fully stirring a molten glass material, and uniformly heating the molten glass material in the device to reach a temperature required for molding, thereby improving product quality.

Specifically, the device main body 100 includes a housing 101, a heating plate 102 disposed on a side surface of the housing 101, a driving and stirring assembly 103 disposed above the housing 101, and a first driven assembly 104 and a second driven assembly 105 disposed on two sides of the driving and stirring assembly 103 and engaged therewith. Heating plates 102 are provided at the bottom and both sides of the casing 101 to heat the molten glass inside the apparatus. The stirring assembly 103 is driven to move, so that the first driven assembly 104 and the second driven assembly 105 can fully stir the raw materials in the device.

Further, the driving stirring assembly 103 includes a driving motor 103a disposed above the housing 101, a first transmission shaft 103b connected to the driving motor 103a, a stirring plate 103c connected to a bottom of the first transmission shaft 103b, and a driving gear 103d connected to the first transmission shaft 103 b. When the drive motor 103a is started, the stirring plate 103c at the bottom of the first transmission shaft 103b is rotated to stir the molten glass raw material. The stirring plate 103c is a heating rod and heats while stirring.

Further, the first driven assembly 104 and the second driven assembly 105 are symmetrically arranged; the first driven assembly 104 comprises a transfer gear 104a engaged with the driving gear 103d, a driven gear 104b engaged with the transfer gear 104a, a second transmission shaft 104c connected with the center of the bottom of the driven gear 104b, a sleeve part 104d arranged at the bottom of the second transmission shaft 104c, a third transmission shaft 104e connected with the bottom of the sleeve part 104d, a fan blade plate 104f arranged on the side surface of the third transmission shaft 104e, and a liquid lifting part 104g connected with the bottom of the third transmission shaft 104 e. The transfer gear 104a is provided to drive the stirring assembly 103 to drive the first driven assembly 104 and the second driven assembly 105 on both sides thereof to start. The third transmission shaft 104e is provided with a plurality of sets of fan blades 104f. The transfer gear 104a is engaged with the driving gear 103d, and the transfer gear 104a is engaged with the driven gear 104b, so that the stirring assembly 103 is driven to drive the first driven assembly 104 and the second driven assembly 105 to move.

Further, the sleeve member 104d comprises an outer sleeve 104d-1, a rotating cylinder 104d-2 disposed in the outer sleeve 104d-1 and connected to the end of the second transmission shaft 104c, a fitting groove 104d-3 disposed on the side of the rotating cylinder 104d-2, an inner sleeve 104d-4 disposed on the side of the rotating cylinder 104d-2, and a sliding column 104d-5 symmetrically disposed on both sides of the inner sleeve 104d-4 and having one end fitting with the fitting groove 104 d-3; the top of the third transmission shaft 104e is connected to the bottom center of the inner sleeve 104d-4, and the third transmission shaft 104e and the second transmission shaft 104c extend out of the outer sleeve 104d-1.

Further, the liquid lifting piece 104g comprises a bracket 104g-1 fixedly connected with the bottom of the third transmission shaft 104c, and a first liquid dividing piece 104g-2 and a second liquid dividing piece 104g-3 respectively connected with two sides of the bracket 104 g-1; the first dispensing member 104g-2 and the second dispensing member 104g-3 are identical in structure. The bracket 104g-1 is fixedly connected to the third transmission shaft 104c and follows the movement of the third transmission shaft 104 c.

Further, the first liquid dividing member 104g-2 comprises a first hinge plate 104g-21 hinged with one end of the support 104g-1, a second hinge plate 104g-22 hinged with the first hinge plate 104g-21, a fixed seat 104g-23 arranged in the housing 101, a rotating shaft 104g-24 arranged on the fixed seat 104g-23 and having one end connected with the second hinge plate 104g-22, a rotating gear 104g-25 connected with the other end of the rotating shaft 104g-24, an elevation gear 104g-26 arranged above and meshed with the rotating gear 104g-25, a driving shaft 104g-27 connected with the center of the elevation gear 104g-26, a cylinder 104g-28 connected with one end of the driving shaft 104g-27, and stirring fan blades 104g-29 arranged on the side of the cylinder 104g-28 in an array manner. The height-adjusting gears 104g-26 are arranged to adjust the height positions of the stirring fan blades 104g-29, so that the glass liquid raw materials at the bottom can be better lifted.

Further, the housing 101 includes a feeding nozzle 101a disposed on a side thereof, and a dropping port 101b and four sets of cylinders 101c disposed on a bottom thereof. Through setting up cylinder 101c in the four corners of casing 101, can controlling means's lift, the drip of being convenient for.

Further, the outer sleeve 104d-1 further includes sliding position-limiting grooves 104d-13 symmetrically disposed on the inner wall thereof, and the sliding column 104d-5 includes position-limiting blocks 104d-51 disposed on the outer end thereof and engaged with the sliding position-limiting grooves 104 d-13. The sliding limiting groove 104d-13 is arranged inside the outer sleeve 104d-1, so that the glass liquid raw material is effectively prevented from entering the sleeve part 104d and affecting normal operation. The top end of the stop block 104d-51 is disposed within the slide stop slot 104d-13 and functions to stabilize the outer sleeve 104d-1 and limit the direction of movement of the outer sleeve 104d-1.

Furthermore, the matching grooves 104d-3 are communicated broken line grooves, and one ends of the two groups of sliding columns 104d-5 are symmetrically arranged in the grooves; the first hinge plate 104g-21 has a length substantially greater than the second hinge plate 104 g-22. The sliding columns 104d-5 are matched with the matching grooves 104d-3, and the motion tracks of the two groups of sliding columns 104d-5 in the grooves of the upper broken line and the lower broken line are consistent.

In use, by activating the driving motor 103a, the first driven assembly 104 and the second driven assembly 105 on both sides of the stirring assembly 103 are driven to move, and the first driven assembly 104 and the second driven assembly 105 move in unison. The driving gear 103d drives the transfer gear 104a to rotate, the driven gear 104b engaged with the transfer gear 104a also rotates, even if the second transmission shaft 104c starts to rotate, because the rotating cylinder 104d-2 is fixedly connected with the second transmission shaft 104c, the rotating cylinder 104d-2 finally rotates in the inner sleeve 104d-4, because the two sides of the inner sleeve 104d-4 are provided with the sliding column 104d-5 matched with the matching groove 104d-3 on the rotating cylinder 104d-2, the sliding column 104d-5 moves up and down at one end of the matching groove 104d-3 according to the up and down track of the broken line groove under the rotation of the rotating cylinder 104d-2, the inner sleeve 104d-4 fixedly connected with the sliding column 104d-5 moves in the outer sleeve 104d-1, and because the other end of the sliding column 104d-5 is the limiting block 104d-51 matched with the sliding limiting groove 104d-13 on the inner wall of the outer sleeve 104d-1, the inner sleeve 104d-4 can only do linear reciprocating motion along the length direction of the sliding limiting groove 104 d-13. The third transmission shaft 104e is fixedly connected with the bottom of the inner sleeve 104d-4 and linearly reciprocates along with the inner sleeve 104d-4, so that the fan blade plate 104f vertically shakes on the middle upper layer of the molten glass raw material, the middle upper layer of the molten glass raw material can rapidly flow under the action of the fan blade plate 104f, interaction is performed, and the middle upper layer temperature and material mixing are more uniform. Meanwhile, the third transmission shaft 104e moves up and down along the linear direction to drive the bracket 104g-1 to move downwards, so that the first liquid separating piece 104g-2 and the second liquid separating piece 104g-3 on two sides of the bracket 104g-1 move, and the first liquid separating piece 104g-2 and the second liquid separating piece 104g-3 have the same structure, so that only the movement process of the first liquid separating piece 104g-2 is described: the first hinge plate 104g-21 pushes the second hinge plate 104g-22 to move downwards during the downward movement of the bracket 104g-1, and since the second hinge plate 104g-22 is connected to the rotating shaft 104g-24 provided on the fixing base 104g-23, the second hinge plate 104g-22 rotates half a turn downwards around the rotating shaft 104-24 during the downward movement, and when the third transmission shaft 104e is lifted upwards, the first hinge plate 104g-21 pulls the second hinge plate 104g-22 to move upwards, so that the second hinge plate 104g-22 rotates half a turn again around the rotating shaft 104-24 according to the rotating direction of the previous half turn during the upward movement, and reciprocates in sequence, and the rotating shaft 104g-24 keeps rotating continuously. The cylinder 104g-28 is finally rotated by the heightening gear 104g-26 engaged with the rotary gear 104g-25 fixedly connected to one end of the rotary shaft 104g-24, thereby realizing the continuous rotation of the agitating fan blades 104g-29. The glass liquid raw material after the bottom layer of the glass liquid raw material is heated by the heating plate 102 is pushed by the stirring fan blades 104g-29 to be pushed to the middle layer by the stirring fan blades 104g-29 to be mixed with the glass liquid raw material with poor heating effect of the middle layer, and the glass liquid raw material pushed to the periphery by the continuous stirring of the middle stirring plate 103c is returned to the middle part again to be stirred and heated under the rotation of the stirring fan blades 104g-29, so that the full stirring and the uniform temperature are realized. It should be noted that the first liquid separator 104g-2 and the second liquid separator 104g-3 are disposed on the bottom layer, the vane plate 104f is disposed above the liquid separator, the vane plate 104f is disposed in the middle of the device, and a plurality of sets of vane plates 104f are disposed.

In summary, the first driven assembly 104 and the second driven assembly 105 are driven by the driving stirring assembly 103, and the glass liquid raw material in the middle is heated and stirred, the glass liquid raw material in the bottom layer is lifted to the middle layer by the first driven assembly 104 and the second driven assembly 105, and is mixed and heated with the glass liquid raw material with poor heating effect in the middle layer, so that the heating efficiency and the uniform heating effect are improved, the glass liquid raw material in the middle and upper layers can flow rapidly by the stirring blades 104g-29 which stir up and down, the stirring and heating efficiency of the middle stirring plate 103c is improved while the glass liquid raw material is mixed and heated, and in addition, the glass liquid raw material which is rotated by the middle stirring plate 103c and pushed to the two sides is pushed back to the middle part under the action of the first liquid separating piece 104g-2 and the second liquid separating piece 104g-3, so that the stirring is more sufficient.

Example 2

Referring to fig. 1 and 3, a second embodiment of the present invention, which is different from the first embodiment, is: also included are retaining rings 104d-11 and sealing rings 104d-12. In the last embodiment, the material mixing device for manufacturing the wine bottle comprises the device for fully mixing the glass liquid raw material, and the glass liquid raw material in the device is uniformly heated to reach the temperature required by forming, so that the product quality is improved.

Specifically, the device main body 100 includes a housing 101, a heating plate 102 disposed on a side surface of the housing 101, a driving and stirring assembly 103 disposed above the housing 101, and a first driven assembly 104 and a second driven assembly 105 disposed on two sides of the driving and stirring assembly 103 and engaged therewith. Heating plates 102 are provided at the bottom and both sides of the casing 101 to heat the molten glass inside the apparatus. The stirring assembly 103 is driven to move, so that the first driven assembly 104 and the second driven assembly 105 can fully stir the raw materials in the device.

Further, the driving stirring assembly 103 includes a driving motor 103a disposed above the housing 101, a first transmission shaft 103b connected to the driving motor 103a, a stirring plate 103c connected to a bottom of the first transmission shaft 103b, and a driving gear 103d connected to the first transmission shaft 103 b. When the drive motor 103a is started, the stirring plate 103c at the bottom of the first transmission shaft 103b is rotated to stir the molten glass raw material. The stirring plate 103c is a heating rod, and is heated while stirring.

Further, the first driven assembly 104 and the second driven assembly 105 are symmetrically arranged; the first driven assembly 104 comprises a transfer gear 104a engaged with the driving gear 103d, a driven gear 104b engaged with the transfer gear 104a, a second transmission shaft 104c connected with the center of the bottom of the driven gear 104b, a sleeve member 104d arranged at the bottom of the second transmission shaft 104c, a third transmission shaft 104e connected with the bottom of the sleeve member 104d, a fan blade plate 104f arranged on the side surface of the third transmission shaft 104e, and a liquid lifting member 104g connected with the bottom of the third transmission shaft 104 e. The transfer gear 104a is provided to drive the stirring assembly 103 to drive the first driven assembly 104 and the second driven assembly 105 on both sides thereof to start. The third transmission shaft 104e is provided with a plurality of sets of fan blades 104f. The transfer gear 104a is engaged with the driving gear 103d, and the transfer gear 104a is engaged with the driven gear 104b, so that the stirring assembly 103 is driven to drive the first driven assembly 104 and the second driven assembly 105 to move.

Further, the sleeve member 104d includes an outer sleeve 104d-1, a rotating cylinder 104d-2 disposed in the outer sleeve 104d-1 and connected to the end of the second transmission shaft 104c, a fitting groove 104d-3 disposed at the side of the rotating cylinder 104d-2, an inner sleeve 104d-4 disposed at the side of the rotating cylinder 104d-2, and a sliding column 104d-5 symmetrically disposed at both sides of the inner sleeve 104d-4 and having one end fitted with the fitting groove 104 d-3; the top of the third transmission shaft 104e is connected to the bottom center of the inner sleeve 104d-4, and the third transmission shaft 104e and the second transmission shaft 104c extend out of the outer sleeve 104d-1. The inner sleeve 104d-4 is a shell with an open top and sleeved outside the rotating cylinder 104d-2, the outer sleeve 104d-1 is a closed shell with transmission shaft openings at two ends, and the bottom of the closed shell is provided with a sealing ring 104d-12 for sealing to prevent molten glass from entering the sleeve 104d and affecting the operation of the device.

Further, the liquid lifting piece 104g comprises a bracket 104g-1 fixedly connected with the bottom of the third transmission shaft 104c, and a first liquid dividing piece 104g-2 and a second liquid dividing piece 104g-3 respectively connected with two sides of the bracket 104 g-1; the first dispensing member 104g-2 and the second dispensing member 104g-3 are identical in structure. The bracket 104g-1 is fixedly connected to the third transmission shaft 104c and follows the movement of the third transmission shaft 104 c.

Further, the first liquid dividing member 104g-2 comprises a first hinge plate 104g-21 hinged with one end of the support 104g-1, a second hinge plate 104g-22 hinged with the first hinge plate 104g-21, a fixed seat 104g-23 arranged in the housing 101, a rotating shaft 104g-24 arranged on the fixed seat 104g-23 and having one end connected with the second hinge plate 104g-22, a rotating gear 104g-25 connected with the other end of the rotating shaft 104g-24, an elevation gear 104g-26 arranged above and meshed with the rotating gear 104g-25, a driving shaft 104g-27 connected with the center of the elevation gear 104g-26, a cylinder 104g-28 connected with one end of the driving shaft 104g-27, and stirring fan blades 104g-29 arranged on the side of the cylinder 104g-28 in an array manner. The height-adjusting gears 104g-26 are arranged to adjust the height positions of the stirring fan blades 104g-29, so that the glass liquid raw materials at the bottom can be better lifted.

Further, the housing 101 includes a feeding nozzle 101a disposed on a side surface thereof, and a dropping port 101b and four sets of cylinders 101c disposed on a bottom portion thereof. Through setting up cylinder 101c in casing 101 four corners, can controlling means's lift, the drip of being convenient for.

Further, the outer sleeve 104d-1 further includes sliding position-limiting grooves 104d-13 symmetrically disposed on the inner wall thereof, and the sliding column 104d-5 includes position-limiting blocks 104d-51 disposed on the outer end thereof and engaged with the sliding position-limiting grooves 104 d-13. The sliding limiting groove 104d-13 is arranged inside the outer sleeve 104d-1, so that the glass liquid raw material is effectively prevented from entering the sleeve part 104d and affecting normal operation. The top end of the stop block 104d-51 is disposed within the slide stop slot 104d-13 and functions to stabilize the outer sleeve 104d-1 and limit the direction of movement of the outer sleeve 104d-1.

Furthermore, the matching grooves 104d-3 are communicated broken line grooves, and one ends of the two groups of sliding columns 104d-5 are symmetrically arranged in the grooves; the first hinge plate 104g-21 has a length substantially greater than the second hinge plate 104 g-22. The sliding columns 104d-5 are matched with the matching grooves 104d-3, and the motion tracks of the two groups of sliding columns 104d-5 in the grooves of the upper broken line and the lower broken line are consistent.

Preferably, the outer sleeve 104d-1 further comprises a fixing ring 104d-11 disposed at a middle portion thereof, and a sealing ring 104d-12 disposed at a bottom portion thereof, wherein the sealing ring 104d-12 is movably connected to the third transmission shaft 104 e. The outer sleeve 104d-1 is fixed by the fixing ring 104 d-11. The sealing ring 104d-12 is provided to prevent molten glass material from entering the sleeve member 104d.

In use, by activating the driving motor 103a, the first driven assembly 104 and the second driven assembly 105 on both sides of the stirring assembly 103 are driven to move, and the first driven assembly 104 and the second driven assembly 105 move in unison. The driving gear 103d drives the transfer gear 104a to rotate, the driven gear 104b engaged with the transfer gear 104a also rotates, even if the second transmission shaft 104c starts to rotate, because the rotating cylinder 104d-2 is fixedly connected with the second transmission shaft 104c, the rotating cylinder 104d-2 finally rotates in the inner sleeve 104d-4, because the two sides of the inner sleeve 104d-4 are provided with the sliding column 104d-5 matched with the matching groove 104d-3 on the rotating cylinder 104d-2, the sliding column 104d-5 moves up and down at one end of the matching groove 104d-3 according to the up and down track of the broken line groove under the rotation of the rotating cylinder 104d-2, the inner sleeve 104d-4 fixedly connected with the sliding column 104d-5 moves in the outer sleeve 104d-1, and because the other end of the sliding column 104d-5 is the limiting block 104d-51 matched with the sliding limiting groove 104d-13 on the inner wall of the outer sleeve 104d-1, the inner sleeve 104d-4 can only do linear reciprocating motion along the length direction of the sliding limiting groove 104 d-13. The third transmission shaft 104e is fixedly connected with the bottom of the inner sleeve 104d-4 and linearly reciprocates along with the inner sleeve 104d-4, so that the fan blade plate 104f vertically shakes on the middle upper layer of the molten glass raw material, the middle upper layer of the molten glass raw material can rapidly flow under the action of the fan blade plate 104f, interaction is performed, and the middle upper layer temperature and material mixing are more uniform. Meanwhile, the third transmission shaft 104e moves up and down along the linear direction to drive the bracket 104g-1 to move downwards, so that the first liquid separating piece 104g-2 and the second liquid separating piece 104g-3 on two sides of the bracket 104g-1 move, and the first liquid separating piece 104g-2 and the second liquid separating piece 104g-3 have the same structure, so that the movement process of the first liquid separating piece 104g-2 is only described: the first hinge plate 104g-21 pushes the second hinge plate 104g-22 to move downwards during the downward movement of the bracket 104g-1, the second hinge plate 104g-22 rotates downwards for a half turn around the rotating shaft 104-24 during the downward movement due to the connection of the second hinge plate 104g-22 with the rotating shaft 104g-24 provided on the fixed seat 104g-23, and when the third transmission shaft 104e is lifted upwards, the first hinge plate 104g-21 pulls the second hinge plate 104g-22 to move upwards, so that the second hinge plate 104g-22 rotates again for a half turn around the rotating shaft 104-24 according to the rotating direction of the previous half turn during the upward movement, and the second hinge plate 104g-22 reciprocates in sequence to keep the rotating shaft 104g-24 rotating continuously. The cylinder 104g-28 is finally rotated by the heightening gear 104g-26 engaged with the rotary gear 104g-25 fixedly connected to one end of the rotary shaft 104g-24, thereby realizing the continuous rotation of the agitating fan blades 104g-29. The glass liquid raw material after the bottom layer of the glass liquid raw material is heated by the heating plate 102 is pushed by the stirring fan blades 104g-29 to be pushed to the middle layer by the stirring fan blades 104g-29 to be mixed with the glass liquid raw material with poor heating effect of the middle layer, and the glass liquid raw material pushed to the periphery by the continuous stirring of the middle stirring plate 103c is returned to the middle part again to be stirred and heated under the rotation of the stirring fan blades 104g-29, so that the full stirring and the uniform temperature are realized. It should be noted that the first liquid separator 104g-2 and the second liquid separator 104g-3 are disposed on the bottom layer, the vane plate 104f is disposed above the liquid separator, the vane plate 104f is disposed in the middle of the device, and a plurality of sets of vane plates 104f are disposed.

In summary, the first driven assembly 104 and the second driven assembly 105 are driven by the driving stirring assembly 103, and the glass liquid raw material in the middle is heated and stirred, the glass liquid raw material in the bottom layer is lifted to the middle layer by the first driven assembly 104 and the second driven assembly 105, and is mixed and heated with the glass liquid raw material with poor heating effect in the middle layer, so that the heating efficiency and the uniform heating effect are improved, the glass liquid raw material in the middle and upper layers can flow rapidly by the stirring blades 104g-29 which stir up and down, the stirring and heating efficiency of the middle stirring plate 103c is improved while the glass liquid raw material is mixed and heated, and in addition, the glass liquid raw material which is rotated by the middle stirring plate 103c and pushed to the two sides is pushed back to the middle part under the action of the first liquid separating piece 104g-2 and the second liquid separating piece 104g-3, so that the stirring is more sufficient.

It is important to note that the construction and arrangement of the present application as shown in the various exemplary embodiments is illustrative only. Although only a few embodiments have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters (e.g., temperatures, pressures, etc.), mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter recited in this application. For example, elements shown as integrally formed may be constructed of multiple parts or elements, the position of elements may be reversed or otherwise varied, and the nature or number of discrete elements or positions may be altered or varied. Accordingly, all such modifications are intended to be included within the scope of this invention. The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. In the claims, any means-plus-function clause is intended to cover the structures described herein as performing the recited function and not only structural equivalents but also equivalent structures. Other substitutions, modifications, changes and omissions may be made in the design, operating conditions and arrangement of the exemplary embodiments without departing from the scope of the present inventions. Therefore, the present invention is not limited to a particular embodiment, but extends to various modifications that nevertheless fall within the scope of the appended claims.

Moreover, in an effort to provide a concise description of the exemplary embodiments, all features of an actual implementation may not have been described (i.e., those unrelated to the presently contemplated best mode of carrying out the invention, or those unrelated to enabling the invention).

It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions may be made. Such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure, without undue experimentation.

It should be noted that the above-mentioned embodiments are only for illustrating the technical solutions of the present invention and not for limiting, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions may be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, which should be covered by the claims of the present invention.

Claims (5)

1. The utility model provides a material device is mixed in beverage bottle manufacturing usefulness which characterized in that: comprises the steps of (a) preparing a mixture of a plurality of raw materials,

the device comprises a device main body (100) and a control device, wherein the device main body comprises a shell (101), a heating plate (102) arranged on the side surface of the shell (101), a driving and stirring assembly (103) arranged above the shell (101), and a first driven assembly (104) and a second driven assembly (105) which are arranged on two sides of the driving and stirring assembly (103) and matched with the driving and stirring assembly;

the driving stirring assembly (103) comprises a driving motor (103 a) arranged above the shell (101), a first transmission shaft (103 b) connected with the driving motor (103 a), a stirring plate (103 c) connected with the bottom of the first transmission shaft (103 b), and a driving gear (103 d) connected with the first transmission shaft (103 b);

the first driven assembly (104) and the second driven assembly (105) are symmetrically arranged; the first driven assembly (104) comprises a transfer gear (104 a) meshed with the driving gear (103 d), a driven gear (104 b) meshed with the transfer gear (104 a), a second transmission shaft (104 c) connected with the center of the bottom of the driven gear (104 b), a sleeve part (104 d) arranged at the bottom of the second transmission shaft (104 c), a third transmission shaft (104 e) connected with the bottom of the sleeve part (104 d), a fan blade plate (104 f) arranged on the side face of the third transmission shaft (104 e), and a liquid lifting part (104 g) connected with the bottom of the third transmission shaft (104 e);

the sleeve part (104 d) comprises an outer sleeve (104 d-1), a rotating cylinder (104 d-2) which is arranged in the outer sleeve (104 d-1) and is connected with the tail end of the second transmission shaft (104 c), a matching groove (104 d-3) which is arranged on the side surface of the rotating cylinder (104 d-2), an inner sleeve (104 d-4) which is arranged on the side surface of the rotating cylinder (104 d-2), and sliding columns (104 d-5) which are symmetrically arranged on two sides of the inner sleeve (104 d-4) and one end of each sliding column is matched with the matching groove (104 d-3); the top of the third transmission shaft (104 e) is connected with the bottom center of the inner sleeve (104 d-4), and the third transmission shaft (104 e) and the second transmission shaft (104 c) extend out of the outer sleeve (104 d-1);

the liquid lifting piece (104 g) comprises a bracket (104 g-1) fixedly connected with the bottom of the third transmission shaft (104 e), and a first liquid dividing piece (104 g-2) and a second liquid dividing piece (104 g-3) which are respectively connected with two sides of the bracket (104 g-1); the first liquid dividing part (104 g-2) and the second liquid dividing part (104 g-3) are consistent in structure;

the first liquid separating piece (104 g-2) comprises a first hinge plate (104 g-21) hinged with one end of the support (104 g-1), a second hinge plate (104 g-22) hinged with the first hinge plate (104 g-21), a fixed seat (104 g-23) arranged in the shell (101), a rotating shaft (104 g-24) arranged on the fixed seat (104 g-23) and connected with the second hinge plate (104 g-22) at one end, a rotating gear (104 g-25) connected with the other end of the rotating shaft (104 g-24), an heightening gear (104 g-26) arranged above and meshed with the rotating gear (104 g-25), a driving shaft (104 g-27) connected with the center of the heightening gear (104 g-26), a cylinder (104 g-28) connected with one end of the driving shaft (104 g-27), and stirring fan blades (104 g-29) arranged on the side face of the cylinder (104 g-28) in an array manner;

the first liquid separating piece (104 g-2) and the second liquid separating piece (104 g-3) are arranged at the bottom layer, the fan blade plate (104 f) is arranged above the liquid separating pieces, and the fan blade plate (104 f) is arranged in the middle of the device and is provided with a plurality of groups of fan blade plates (104 f); the third transmission shaft (104 e) is fixedly connected with the bottom of the inner sleeve (104 d-4) and linearly reciprocates along with the inner sleeve (104 d-4), so that the leaf plates (104 f) vertically shake in the middle and upper layers of the molten glass raw materials, the middle and upper layers of the molten glass raw materials can rapidly flow under the action of the leaf plates (104 f) and are interacted, and the temperature of the middle and upper layers and the material mixing are more uniform; the stirring fan blades (104 g-29) push the glass liquid raw material heated by the heating plate (102) at the bottom layer of the glass liquid raw material to the middle layer under the pushing of the stirring fan blades (104 g-29) to be mixed with the glass liquid raw material with poor heating effect at the middle layer, and under the rotation of the stirring fan blades (104 g-29), the glass liquid raw material pushed to the periphery due to continuous stirring of the middle stirring plate (103 c) returns to the middle part again for stirring and heating, so that sufficient stirring and uniform temperature are realized.

2. The material mixing device for manufacturing the wine bottle according to claim 1, wherein: the shell (101) comprises a feeding nozzle (101 a) arranged on the side surface of the shell, a material dropping opening (101 b) arranged at the bottom of the shell and four groups of cylinders (101 c).

3. The material mixing device for manufacturing the wine bottle as claimed in claim 2, wherein: the outer sleeve (104 d-1) further comprises a fixing ring (104 d-11) arranged in the middle of the outer sleeve and a sealing ring (104 d-12) arranged at the bottom of the outer sleeve, and the sealing ring (104 d-12) is movably connected with the third transmission shaft (104 e).

4. A material mixing device for wine bottle manufacturing according to claim 3, characterized in that: the outer sleeve (104 d-1) further comprises sliding limiting grooves (104 d-13) symmetrically arranged on the inner wall of the outer sleeve, and the sliding column (104 d-5) comprises limiting blocks (104 d-51) arranged at the outer end of the sliding column and matched with the sliding limiting grooves (104 d-13).

5. The material mixing device for manufacturing the wine bottle according to claim 4, wherein: the matching grooves (104 d-3) are communicated broken line grooves, and one ends of the two groups of sliding columns (104 d-5) are symmetrically arranged in the grooves; the length of the first hinge plate (104 g-21) is larger than that of the second hinge plate (104 g-22).

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