CN220981610U - Crystal hot-fix rhinestone processing device with water cooling structure - Google Patents

Abstract

The utility model discloses a crystal hot-fix rhinestone processing device with a water cooling structure, which comprises a base (1), a hot-fix rhinestone die (2) and a squeeze roll (3), wherein two symmetrically distributed mounting plates (4) are arranged on the base (1), and a rotating shaft (5) is arranged between the two mounting plates (4); two symmetrically distributed fixed shafts (6) are arranged on the rotating shaft (5), and the end surface of each fixed shaft (6) facing the other fixed shaft (6) is fixedly connected with the hot-stamping die (2); one side of each fixed shaft (6) far away from the other fixed shaft (6) is provided with a cooling pipe (7) wound on the rotating shaft (5), and the end part of each cooling pipe (7) is connected with a water storage tank (8) arranged on the base (1). The utility model not only can prolong the service life, but also has the advantages of good cooling effect, better structural strength, convenient disassembly and assembly and high structural stability.

Description

Crystal hot-fix rhinestone processing device with water cooling structure

Technical Field

The utility model relates to crystal processing equipment, in particular to a crystal hot-dip drill processing device with a water cooling structure.

Background

The production of current quartzy hot-fix rhinestone product is generally all through pressing out of hot-fix rhinestone mould, need adopt outside drive arrangement to drive the hot-fix rhinestone mould at the in-process that hot-fix rhinestone mould pressed and rotate, general drive arrangement is mostly the structure of motor and pivot, it can produce a large amount of heats to drive the hot-fix rhinestone mould to carry out pivoted in-process to rotate at the pivot for a long time, and transmit the hot-fix rhinestone mould through the pivot, in case hot-fix rhinestone mould and pivot epaxial heat is higher and not in time dispel and will cause the damage of hot-fix rhinestone mould and pivot, influence the life of whole equipment. Therefore, the existing crystal hot-fix rhinestone production equipment has the problem of short service life.

Disclosure of utility model

The utility model aims to provide a crystal hot-dip drill processing device with a water cooling structure. The utility model has the advantage of long service life.

The technical scheme of the utility model is as follows: the crystal hot-dip drill processing device with the water-cooling structure comprises a base, a hot-dip drill die and a squeeze roller arranged above the hot-dip drill die, wherein two symmetrically distributed mounting plates are arranged on the base, and a rotating shaft is arranged between the two mounting plates; the rotating shaft is provided with two symmetrically distributed fixed shafts, and the end surface of each fixed shaft facing the other fixed shaft is fixedly connected with the hot-stamping die; a cooling pipe wound on the rotating shaft is arranged on one side, far away from the other fixed shaft, of each fixed shaft, and the end part of each cooling pipe is connected with a water storage tank arranged on the base; the cooling pipes on the two sides can be used for directly cooling the rotating shaft, so that high temperature generated by continuous rotation of the rotating shaft is prevented from being transmitted to the hot-stamping die, and certain indirect cooling work can be performed on the hot-stamping die from the two sides, so that damage to the hot-stamping die due to high temperature is avoided, and the service life is prolonged; the fixed shaft is used for connecting the hot-stamping die and the rotating shaft, so that the phenomenon that the rotating shaft is broken due to the fact that the rotating shaft is directly transmitted to the hot-stamping die is avoided, the structural strength is improved, and the service life is further prolonged.

In the crystal hot-dip drill processing device with the water-cooling structure, the outer side surface of each cooling pipe is sleeved with a dust cover, and the bottom end of the dust cover is provided with an opening; semicircular through holes for passing through the cooling pipes are formed in the positions, corresponding to the two end parts of the cooling pipes, on the two side surfaces of the opening; the cooling pipe is prevented from being broken by the aid of the dust cover, so that the service life is prolonged; the influence of external dust, impurities and the like on the cooling pipe on the cooling effect can be avoided; simultaneously, the upper opening of the cooling pipe and the arrangement of the through holes can facilitate the work of disassembling and assembling the dust cover from the cooling pipe.

In the crystal hot-fix rhinestone processing device with the water-cooling structure, the dust cover is made of soft materials such as rubber; the inner side surface of the dust cover is coated with a heat insulation layer; the heat exchange generated before the cooling pipe and the dust cover can be avoided by utilizing the heat insulation layer, and the cooling effect is ensured.

In the crystal hot-dip drill processing device with the water cooling structure, the water storage tank is internally provided with the heat dissipation plates, each heat dissipation plate is provided with a plurality of uniformly distributed heat dissipation fins, and the end part of each heat dissipation fin is fixedly connected with the inner side wall of the water storage tank; the top end of each side face of the water storage tank is provided with a ventilation channel.

In the crystal hot-dip drill processing device with the water cooling structure, the inner side wall of the water storage tank is provided with a plurality of semiconductor refrigerating sheets which are uniformly distributed; utilize fin and heating panel can be quick with the heat transfer of middle part water in the storage water tank to the inside wall of storage water tank on, the setting of semiconductor refrigeration piece in the storage water tank is gone up in the cooperation again, the cooling effect of cooling water in the storage water tank can be accelerated to the promotion cooling effect that can be better.

In the crystal hot-dip drill processing device with the water-cooling structure, two symmetrically distributed supporting pieces are arranged on the base at positions corresponding to the positions right below each cooling pipe, and the top surface of each supporting piece is provided with an inwards concave arc-shaped groove; the support piece is utilized to support the cooling pipe below the cooling pipe, so that the stability of the structure is improved.

Compared with the prior art, the utility model improves the existing processing device for the crystal hot-fix rhinestone, and by sleeving the cooling pipes at the two ends of the rotating shaft, the cooling pipes at the two sides can be used for directly cooling the rotating shaft, so that the high temperature generated by continuous rotation of the rotating shaft is prevented from being transmitted to the hot-fix rhinestone die, and the hot-fix rhinestone die can be cooled indirectly from the two sides to a certain extent, thereby avoiding the damage of the hot-fix rhinestone die caused by the high temperature and prolonging the service life; the water storage tanks are connected to each cooling pipe, so that the replacement rate of cooling water can be increased by utilizing the independent water storage tanks, and the cooling effect is ensured; meanwhile, the fixed shaft is arranged at the end part of the rotating shaft to connect the hot-stamping die, so that the phenomenon that the rotating shaft is broken due to the fact that the rotating shaft is directly transmitted to the hot-stamping die is avoided, the structural strength is improved, and the service life is further prolonged. In addition, the cooling pipe is sleeved with the dust cover, so that the cooling pipe can be protected from being damaged by external impact, and the service life of the cooling pipe is prolonged; the influence of external dust, impurities and the like on the cooling pipe on the cooling effect can be avoided; meanwhile, the upper opening of the cooling pipe and the arrangement of the through holes can facilitate the work of disassembling and assembling the dust cover from the cooling pipe; the heat insulation layer is stuck on the inner side surface of the dust cover, so that heat exchange between the cooling pipe and the dust cover can be avoided by utilizing the heat insulation layer, and the cooling effect is ensured; the heat dissipation plate is arranged in the water storage tank, the plurality of evenly distributed heat dissipation plates are arranged on the heat dissipation plate, heat of water in the middle of the water storage tank can be quickly transferred to the inner side wall of the water storage tank by the heat dissipation plates and the heat dissipation plate, and the cooling effect of cooling water in the water storage tank can be accelerated by matching with the arrangement of the semiconductor refrigerating sheets in the water storage tank, so that the cooling effect can be better improved; through being provided with support piece on the base, utilize support piece to support the cooling tube in the below of cooling tube, promoted the stability of structure. Therefore, the utility model not only can prolong the service life, but also has the advantages of good cooling effect, better structural strength, convenient disassembly and assembly and high structural stability.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic view of the internal structure of the water storage tank;

fig. 3 is a partial enlarged view at a in fig. 1.

The marks in the drawings are: the device comprises a base, a 2-hot-stamping die, a 3-extrusion roller, a 4-mounting plate, a 5-rotating shaft, a 6-fixing shaft, a 7-cooling pipe, an 8-water storage tank, a 9-dust cover, an 11-heat insulation layer, a 12-heat dissipation plate, 13-heat dissipation plates, 14-semiconductor refrigerating plates and 15-supporting pieces.

Detailed Description

The utility model is further illustrated by the following figures and examples, which are not intended to be limiting.

Examples. The crystal hot-dip drill processing device with the water-cooling structure is shown in figures 1 to 3, and comprises a base 1, a hot-dip drill die 2 and a squeeze roller 3 arranged above the hot-dip drill die 2, wherein two symmetrically distributed mounting plates 4 are arranged on the base 1, and a rotating shaft 5 is arranged between the two mounting plates 4; two symmetrically distributed fixed shafts 6 are arranged on the rotating shaft 5, and the end surface of each fixed shaft 6 facing the other fixed shaft 6 is fixedly connected with the hot-stamping die 2; a cooling pipe 7 wound on the rotating shaft 5 is arranged on one side, away from the other fixed shaft 6, of each fixed shaft 6, and the end part of each cooling pipe 7 is connected with a water storage tank 8 arranged on the base 1.

A dust cover 9 is sleeved on the outer side surface of each cooling pipe 7, and an opening is formed in the bottom end of each dust cover 9; semicircular through holes for passing through the cooling pipes 7 are arranged on the two side surfaces of the opening at positions corresponding to the two end parts of the cooling pipes 7; the dust cover 9 is made of soft materials such as rubber; the inner side surface of the dust cover 9 is coated with a heat insulation layer 11; a heat dissipation plate 12 is arranged in the water storage tank 8, a plurality of heat dissipation plates 13 which are uniformly distributed are arranged on each heat dissipation plate 12, and the end part of each heat dissipation plate 13 is fixedly connected with the inner side wall of the water storage tank 8; the top end part of each side surface of the water storage tank 8 is provided with a ventilation channel; a plurality of semiconductor refrigerating sheets 14 which are uniformly distributed are arranged on the inner side wall of the water storage tank 8; two symmetrically distributed supporting pieces 15 are arranged on the base 1 at positions corresponding to the positions right below each cooling pipe 7, and the top surface of each supporting piece 15 is provided with an inwards concave arc-shaped groove.

Working principle: when the device is specifically used, the whole device is connected with external safe commercial power, and is electrified to wait for work; then placing the crystal hot-fix rhinestone raw material to be processed on a hot-fix rhinestone die 2, controlling the crystal hot-fix rhinestone die 2 to be started by a driving motor connected with a rotating shaft 5, driving the rotating shaft 5 to rotate after the driving motor is started, driving a fixed shaft 6 to rotate after the rotating shaft 5 rotates, and driving the hot-fix rhinestone die 2 to rotate after the fixed shaft 6 rotates, so that the hot-fix rhinestone die 2 drives the crystal hot-fix rhinestone raw material to rotate and interact with an extrusion roller 3 above to finish extrusion processing work of the crystal hot-fix rhinestone raw material; in the whole processing process, in order to avoid the phenomenon that the temperature of the hot-fix rhinestone die 2 and the rotating shaft 5 is higher, a water suction pump connected to the cooling pipe 7 and a semiconductor refrigerating sheet 14 in the water storage tank 8 are required to be controlled to be electrified and started, wherein the water suction pump is started to transmit cooling water in the water storage tank 8 to the cooling pipe 7, the cooling water flows in the cooling pipe 7 and flows from one end part of the cooling pipe 7 to the other end part and returns to the water storage tank 8, the cooling pipe 7 is sleeved on the outer side of the rotating shaft 5, heat exchange is generated between the cooling water and the rotating shaft 5 in the cooling water flowing process, so that the cooling work of the rotating shaft 5 is realized, the phenomenon that the temperature of the rotating shaft 5 is transmitted to the hot-fix rhinestone die 2 is increased due to the temperature increase can be avoided, and the phenomenon that part of the cooling water is transmitted to the hot-fix rhinestone die 2 is damaged due to the temperature increase can be well solved, and the service life is prolonged; the semiconductor refrigerating sheet 14 can also perform certain cooling work on the cooling water in the water storage tank 8 after being electrified and started, so that the cooling rate of the cooling water in the water storage tank 8 can be increased, the continuous stability of the cooling effect on the hot-stamping die 2 can be ensured by increasing the cooling water cooling rate of the water storage tank 8, and the cooling effect is further ensured; meanwhile, because the heat radiation plate 12 is arranged in the water storage tank 8, and the plurality of heat radiation fins 13 are arranged on the heat radiation plate 12, the temperature of cooling water flowing back from the water storage tank 8 at a certain temperature can be quickly transferred to the side wall of the water storage tank 8 by using the heat radiation plate 12 and the heat radiation fins 13, and the ventilation channel on the top surface of the water storage tank 8 is matched at the moment, so that the top surface of the water storage tank 8 can perform certain air flow, and the cooling work of the cooling water in the water storage tank 8 can be quickened.

Claims (6)

1. A crystal hot-fix rhinestone processing device with a water-cooling structure, including base (1), scalding drill jig (2) and setting squeeze roll (3) in scalding drill jig (2) top, its characterized in that: two symmetrically distributed mounting plates (4) are arranged on the base (1), and a rotating shaft (5) is arranged between the two mounting plates (4); two symmetrically distributed fixed shafts (6) are arranged on the rotating shaft (5), and the end surface of each fixed shaft (6) facing the other fixed shaft (6) is fixedly connected with the hot-stamping die (2); one side of each fixed shaft (6) far away from the other fixed shaft (6) is provided with a cooling pipe (7) wound on the rotating shaft (5), and the end part of each cooling pipe (7) is connected with a water storage tank (8) arranged on the base (1).

2. The crystal hot-dip drill processing device with a water cooling structure according to claim 1, wherein: a dust cover (9) is sleeved on the outer side surface of each cooling pipe (7), and an opening is formed in the bottom end part of each dust cover (9); semi-circular through holes for passing through the cooling pipes (7) are arranged on the two side surfaces of the opening at positions corresponding to the two ends of the cooling pipes (7).

3. The crystal hot-dip drill processing device with a water cooling structure according to claim 2, wherein: the dust cover (9) is made of rubber soft materials; the inner side surface of the dust cover (9) is coated with a heat insulation layer (11).

4. The crystal hot-dip drill processing device with a water cooling structure according to claim 1, wherein: a heat dissipation plate (12) is arranged in the water storage tank (8), a plurality of heat dissipation fins (13) which are uniformly distributed are arranged on each heat dissipation plate (12), and the end part of each heat dissipation fin (13) is fixedly connected with the inner side wall of the water storage tank (8); the top end of each side face of the water storage tank (8) is provided with a ventilation channel.

5. The crystal hot-dip drill processing device with a water cooling structure according to claim 1, wherein: the inner side wall of the water storage tank (8) is provided with a plurality of semiconductor refrigerating sheets (14) which are uniformly distributed.

6. A crystal hot-dip drill processing apparatus having a water-cooling structure according to any one of claims 1 to 5, wherein: two symmetrically distributed supporting pieces (15) are arranged on the base (1) at positions corresponding to the positions right below each cooling pipe (7), and the top surface of each supporting piece (15) is provided with an inwards concave arc-shaped groove.