CN216639290U - Efficient cooling device based on glass production - Google Patents

Abstract

The utility model discloses a high-efficiency cooling device used in glass production. Above-mentioned high-efficient cooling device based on use in glass production includes conveyor and coolant tank, energy-absorbing structure, fan housing subassembly, drive assembly, cooling structure. The energy absorption structure comprises a driving device fixedly arranged on the lower surface of the cooling water tank, a rotating stand column arranged at the output end of the driving device and a stirring sheet set fixedly arranged on the outer circumferential wall of the rotating stand column; the rotary upright column extends into the cooling water tank; the fan cover component comprises an air inlet cylinder arranged between the cooling water tank and the conveying device. The efficient cooling device used in glass production can continuously carry out heat exchange and heat exchange quantity integration on the bottle-shaped glass products in the transmission process, effectively reduce the annealing temperature of the glass products in the transmission process and the environmental temperature of a transmission area, remarkably improve the cooling effect of the glass products, and reduce the cooling cost, so that the flow operation speed of the glass products can be improved.

Description

Efficient cooling device based on glass production

Technical Field

The utility model relates to the technical field of glass processing, in particular to an efficient cooling device used in glass production.

Background

The glass bottle is generally designed according to an inward convex bottom structure, the center of the bottle bottom does not touch the bottom and protrudes inwards as much as possible, so that the stability of the bottle is facilitated, scratches and burst are prevented, and the internal pressure resistance is improved. Glass packaging materials and containers glass bottles are the main packaging containers in the food, medicine and chemical industries. They have good chemical stability; easy sealing, good air tightness, transparency and the like. In the glass bottle production process, after annealing treatment, the temperature of the glass bottle is higher at the moment, and the glass bottle can be conveniently packed and collected only by cooling treatment.

The cooling mode for glass production in the prior art usually adopts natural cooling or the mode that the mechanical arm lock singly presss from both sides the soaking cooling water to cool off, and two kinds of modes cooling efficiency are low, and man-hour is high, has influenced the speed of line production.

SUMMERY OF THE UTILITY MODEL

Therefore, the cooling device for glass production is required to solve the problems that the cooling mode for glass production usually adopts natural cooling or a mode that a mechanical clamping arm is soaked in cooling water, the cooling efficiency of the two modes is low, the working hours are high, and the flow production rate is influenced.

Based on high-efficient cooling device who uses in glass production includes:

a conveying device;

a cooling water tank provided at a position below the conveyor;

the energy absorption structure is fixedly arranged on the cooling water tank and comprises a driving device fixedly arranged on the lower surface of the cooling water tank, a rotating stand column arranged at the output end of the driving device and a stirring sheet set fixedly arranged on the outer circumferential wall of the rotating stand column; the rotary upright post extends into the cooling water tank;

the fan cover assembly is erected on the cooling water tank and comprises an air inlet cylinder arranged between the cooling water tank and the conveying device;

the transmission assembly is fixedly connected to the rotating stand column; and

the cooling structure is arranged on the transmission assembly and arranged in the air inlet cylinder.

Above-mentioned high-efficient cooling device based on use in glass production, can the continuity carry out heat transfer and the synthesis of heat transfer volume to the bottle-shaped glass article of transmission process, the effectual annealing temperature that reduces the transmission process glass article and the regional ambient temperature of transmission, the cooling effect of glass article is showing and is promoting, and the cooling cost is low, so can improve the speed of glass article flow operation.

In one embodiment, the set of agitating blades is formed by a plurality of agitating blades.

In one embodiment, the fan cover assembly further includes a support arm fixedly installed between the air inlet drum and the cooling water tank.

In one embodiment, the transmission assembly comprises a torsion column fixedly arranged at the top end of the rotary upright column, a first support piece rotatably connected to the outer circumferential wall of the torsion column, a main gear fixedly arranged at the top end of the torsion column and a pinion gear in meshing connection with the outer tooth surface of the main gear; the first supporting piece fixing frame is arranged on the inner wall of the air inlet cylinder.

In one embodiment, the diameter of the primary gear is larger than the diameter of the secondary gear.

In one embodiment, the cooling structure comprises a transmission rod coaxially and fixedly connected to the pinion, a second supporting piece rotatably connected to the outer circumferential wall of the transmission rod, and fan blades fixedly arranged at the bottom end of the transmission rod; the second supporting piece fixing frame is arranged on the inner wall of the air inlet cylinder.

In one embodiment, the cooling device further comprises a refrigeration control mechanism, wherein the refrigeration control mechanism comprises a refrigerator, a temperature sensor and a controller, wherein the refrigerator is arranged on the outer side surface of the cooling water tank; the refrigerating end of the refrigerator is communicated with the inner cavity of the cooling water tank; and the detection end of the temperature sensor extends into the inner cavity of the cooling water tank.

In one embodiment, the output end of the temperature sensor is electrically connected with the input end of the controller, and the output end of the controller is electrically connected with the input end of the refrigerator.

Compared with the prior art, the utility model has the beneficial effects that:

1. according to the utility model, under the synergistic effect of the cooling water tank, the energy absorption structure and the cooling structure, heat exchange and heat exchange amount integration can be continuously carried out on the bottle-shaped glass product in the transmission process, the annealing temperature of the glass product in the transmission process and the ambient temperature of the transmission area are effectively reduced, and the real-time heat exchange cooling efficiency is high.

2. According to the utility model, the cooling structure and the energy absorption structure share the same driving equipment under the action of connecting the transmission assembly and the energy absorption structure, so that the energy-saving and environment-friendly effects are achieved; meanwhile, under the matching of the meshing transmission of the main gear and the auxiliary gear, the speed-increasing transmission is realized, the rotating speed of heat suction of the cooling structure is effectively improved, and the cooling effect is obviously improved.

Of course, it is not necessary for any product in which the utility model is practiced to achieve all of the above-described advantages at the same time.

Drawings

FIG. 1 is a schematic view showing the structure of a high-efficiency cooling apparatus used in glass production according to the present invention.

Fig. 2 is a schematic view showing a connection structure of the cooling water tank of fig. 1.

FIG. 3 is a schematic view of the connection of the energy absorbing structure, the drive assembly and the cooling structure of FIG. 2.

Description of the main elements

In the figure: 1. a conveying device; 2. a cooling water tank; 3. an energy absorbing structure; 31. a drive device; 32. rotating the upright post; 33. stirring sheet group; 4. a fan housing assembly; 41. an air inlet cylinder; 42. a support arm; 5. a transmission assembly; 51. twisting the column; 52. a first support member; 53. a main gear; 54. a pinion gear; 6. a cooling structure; 61. a transmission rod; 62. a second support member; 63. a fan blade; 7. a refrigeration control mechanism; 71. a refrigerator; 72. a temperature sensor; 73. and a controller.

The present invention is described in further detail with reference to the drawings and the detailed description.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings.

Referring to fig. 1-3, the present embodiment provides a high-efficiency cooling device used in glass production, which includes a conveying device 1; the conveying device 1 adopts a chain conveyor to carry out the conveying use for cooling the bottle-shaped convex-bottom glass, and the conveying surface of the chain conveyor is a sieve hole surface so as to achieve the ventilation property.

The efficient cooling device based on glass production further comprises a cooling water tank 2, an energy absorption structure 3, a fan cover assembly 4, a transmission assembly 5, a cooling structure 6 and a refrigeration control mechanism 7.

Wherein the cooling water tank 2 is provided at a position below the conveyor 1.

The cooling medium in the cooling water tank 2 can be used for heat exchange.

Wherein, the energy absorption structure 3 is fixedly arranged on the cooling water tank 2; the energy absorption structure 3 comprises a driving device 31 fixedly arranged on the lower surface of the cooling water tank 2, a rotating upright post 32 arranged at the output end of the driving device 31 and a stirring sheet group 33 fixedly arranged on the outer circumferential wall of the rotating upright post 32; the rotary stand 32 extends into the cooling water tank 2. The driving device 31 in the present embodiment employs a rotating electric machine.

The stirring blade group 33 is composed of a plurality of stirring blades; the stirring sheet set 33 can provide the mixing degree of the water body stirring.

Specifically, start drive arrangement 31 and drive rotatory stand 32 and carry out axial rotation, rotatory stand 32 drives stirring piece group 33 and stirs the action in coolant tank 2, and when paving on the cooling water surface in coolant tank 2 and come the heat, the cooling water of stirring state can fully carry out comprehensive heat transfer to the heat that the shop was come, and thermal energy-absorbing is efficient to can reduce glass article temperature and transmission ambient temperature on the conveyor 1 through the mode of cooling water energy-absorbing.

Wherein, the fan cover component 4 is arranged on the cooling water tank 2; the fan cover assembly 4 comprises an air inlet cylinder 41 arranged between the cooling water tank 2 and the conveying device 1; the fan housing assembly 4 further includes a support arm 42 fixedly installed between the air inlet drum 41 and the cooling water tank 2.

The supporting arm 42 is used to provide stability for the air inlet cylinder 41 between the conveying device 1 and the cooling water tank 2, and the air inlet cylinder 41 can provide an air inlet channel for heat exchange of the cooling water tank 2.

Referring to fig. 3, the transmission assembly 5 is fixedly connected to the rotating column 32; the transmission assembly 5 comprises a torsion column 51 fixedly arranged at the top end of the rotary upright post 32, a first support 52 rotatably connected with the outer circumferential wall of the torsion column 51, a main gear 53 fixedly arranged at the top end of the torsion column 51 and a secondary gear 54 engaged with the outer tooth surface of the main gear 53; the first supporting piece 52 is fixed on the inner wall of the air inlet cylinder 41; the first support 52 can improve the stability of the torsion bar 51 in a rotated state.

The tooth diameter of the main gear 53 is larger than that of the pinion 54; the effect of the speed increasing transmission of the pinion 54 can be achieved.

Wherein, the cooling structure 6 is arranged on the transmission component 5; the cooling structure 6 is arranged in the air inlet cylinder 41; the cooling structure 6 comprises a transmission rod 61 coaxially connected to the pinion 54, a second supporting member 62 rotatably connected to the outer circumferential wall of the transmission rod 61, and fan blades 63 fixedly mounted at the bottom end of the transmission rod 61; the second supporting piece 62 is fixed on the inner wall of the air inlet cylinder 41; the second support 62 may improve the stability of the driving lever 61 in a rotated state.

Specifically, during the rotation of the rotating column 32, the rotating column 51 is driven to rotate synchronously, and in cooperation with the transmission of the accelerating meshing between the main gear 53 and the pinion gear 54, the pinion gear 54 can be linked with the fan blade 63 on the transmission rod 61 to perform a rotating air suction action, so that the fan blade 63 can suck the heat of the glass products transmitted on the conveying device 1 through the conveying device 1, the air inlet cylinder 41 provides an air supply channel, the heat can spread on the surface of the glass products to the cooling water tank 2, and the cooling water in the cooling water tank 2 performs heat exchange.

Wherein, the refrigeration control mechanism 7 comprises a refrigerator 71 arranged on the outer side surface of the cooling water tank 2, a temperature sensor 72 and a controller 73; the refrigerating end of the refrigerator 71 is communicated with the inner cavity of the cooling water tank 2; the detection end of the temperature sensor 72 extends into the inner cavity of the cooling water tank 2.

The output end of the temperature sensor 72 is electrically connected with the input end of the controller 73, and the output end of the controller 73 is electrically connected with the input end of the refrigerator 71.

Specifically, when the refrigeration control mechanism 7 is used, when the cooling water in the cooling water tank 2 cannot meet the heat energy absorption treatment, the temperature sensor 72 detects the water temperature in the cooling water tank 2, and transmits the detection data to the controller 73 in real time, and when the cooling water temperature cannot meet the energy absorption use, the controller 73 can control the refrigerator 71 to refrigerate the cooling water in the cooling water tank 2, so as to meet the use of the continuous energy absorption of the cooling water tank 2.

In summary, the high-efficiency cooling device used in the glass production of the present embodiment has the following advantages compared with the current cooling device: the high-efficient cooling device based on use in glass production of this embodiment, but the bottle glass article of continuity to transmission course carries out heat transfer and heat transfer volume's synthesis, the effectual annealing temperature that reduces transmission course glass article and the regional ambient temperature of transmission, and the cooling effect of glass article is showing and is promoting, and the cooling cost is low, so can improve the speed of glass article pipelining.

The foregoing is illustrative of the preferred embodiments of this invention, and it is to be understood that the utility model is not limited to the precise form disclosed herein and that various other combinations, modifications, and environments may be resorted to, falling within the scope of the concept as disclosed herein, either as described above or as apparent to those skilled in the relevant art. And that modifications and variations may be effected by those skilled in the art without departing from the spirit and scope of the utility model as defined by the appended claims.

Claims (8)

1. High-efficient cooling device based on use in glass production, including conveyor (1), its characterized in that:

a cooling water tank (2) disposed at a position below the conveyor (1);

the energy absorption structure (3) is fixedly arranged on the cooling water tank (2), and the energy absorption structure (3) comprises a driving device (31) fixedly arranged on the lower surface of the cooling water tank (2), a rotating upright post (32) arranged at the output end of the driving device (31) and a stirring sheet group (33) fixedly arranged on the outer circumferential wall of the rotating upright post (32); the rotating stand (32) extends into the cooling water tank (2);

the fan cover assembly (4) is erected on the cooling water tank (2), and the fan cover assembly (4) comprises an air inlet cylinder (41) arranged between the cooling water tank (2) and the conveying device (1);

the transmission assembly (5) is fixedly connected to the rotating upright post (32); and

and the cooling structure (6) is arranged on the transmission assembly (5) and is arranged in the air inlet cylinder (41).

2. The efficient cooling device used in glass production according to claim 1, characterized in that the stirring sheet group (33) is composed of a plurality of stirring sheets.

3. The high-efficiency cooling device used in glass production is characterized in that the fan cover component (4) further comprises a supporting arm (42) fixedly installed between the air inlet cylinder (41) and the cooling water tank (2).

4. The efficient cooling device used in glass production according to claim 1, wherein the transmission assembly (5) comprises a torsion column (51) fixedly mounted at the top end of the rotating column (32), a first support member (52) rotatably connected to the outer circumferential wall of the torsion column (51), a main gear (53) fixedly mounted at the top end of the torsion column (51), and a secondary gear (54) engaged with the outer tooth surface of the main gear (53); the first supporting piece (52) is fixedly arranged on the inner wall of the air inlet cylinder (41).

5. The efficient cooling device used in glass production according to claim 4, characterized in that the tooth diameter of the main gear (53) is larger than the tooth diameter of the secondary gear (54).

6. The cooling device for glass production according to claim 4, wherein the cooling structure (6) comprises a transmission rod (61) coaxially connected to the pinion (54), a second support member (62) rotatably connected to the outer circumferential wall of the transmission rod (61), and a fan blade (63) fixedly installed at the bottom end of the transmission rod (61); the second supporting piece (62) is fixedly arranged on the inner wall of the air inlet cylinder (41).

7. The high-efficiency cooling device used in glass production is characterized in that the cooling device further comprises a refrigeration control mechanism (7), wherein the refrigeration control mechanism (7) comprises a refrigerator (71) arranged on the outer side surface of the cooling water tank (2), a temperature sensor (72) and a controller (73);

the refrigerating end of the refrigerator (71) is communicated with the inner cavity of the cooling water tank (2); the detection end of the temperature sensor (72) extends into the inner cavity of the cooling water tank (2).

8. The efficient cooling device used in glass production according to claim 7, wherein the output of the temperature sensor (72) is electrically connected to the input of the controller (73), and the output of the controller (73) is electrically connected to the input of the refrigerator (71).

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