CN212030011U - Circulating water cooling mechanism for producing hantian crystal balls - Google Patents

Abstract

The utility model belongs to the technical field of the quartzy ball production of han tian, a production crystalline substance ball of han tian is with circulating water cooling mechanism is related to, the circulating water cooling subassembly includes the outer bucket of fixed connection's cooling and the interior bucket of cooling, the last edge of bucket in being higher than the cooling on the outer bucket of cooling, form overflow area and cooling zone, bucket bottom is equipped with interior barrel discharging pipe in the cooling, the bottom of the outer bucket of cooling is equipped with the feed liquor pipe, the cooling coil is including setting up and entering and setting up the export on the coil pipe on cooling coil pipe upper portion under the coil pipe of cooling coil pipe lower part, entry and interior barrel discharging pipe intercommunication under the coil pipe, export on the coil pipe through arranging the material pipe and discharging the quartzy ball of han tian to the material. Utility model discloses a production hantian brilliant ball is with circulating water cooling mechanism, fall into the interior bucket of cooling when hantian brilliant ball, sink to interior bucket bottom of cooling, along with rivers to material collecting pit, fall into the hantian brilliant ball in the interior bucket of cooling at every turn and all direct and cooling water contact and cooling, the cooling effect is good, and the finished product is not adhesive.

Description

Circulating water cooling mechanism for producing hantian crystal balls

Technical Field

The utility model belongs to the technical field of the quartzy ball production technique of hantian and specifically relates to a production is circulating water cooling mechanism for quartzy ball of hantian.

Background

The production of the cold celestial sphere needs to stir the raw materials firstly, the stirred semi-finished product is a sticky object, and if the temperature is lower than 50 ℃, the coagulation phenomenon can occur. Therefore, the semi-finished products are always above 50 ℃ before cutting, crystal balls fall into cooling water to be cooled and flow out along with water flow after cutting, and a plurality of crystal ball forming heads need to be arranged in a straight line due to the requirement of yield, so that the water temperature difference of the cooling water around the water flow direction and the cooling time of the crystal balls are inconsistent, the consistency of the finished products is influenced, and the finished products are possibly bonded together due to the fact that the crystal balls cannot be cooled in time.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a production is cold day is circulating water cooling mechanism for crystalline sphere is because of can not in time cooling down when crystalline sphere production is solved to take place the problem that the finished product bonded together mutually, and guarantee crystalline sphere cooling time's uniformity.

The utility model provides a production hantian crystal ball is with circulating water cooling mechanism, include:

circulating water cooling assembly and cooling coil

The circulating water cooling assembly comprises a cooling outer barrel and a cooling inner barrel which are coaxially nested and fixedly connected, the upper edge of the cooling outer barrel is higher than the upper edge of the cooling inner barrel, an overflow area is formed between the cooling inner barrel and the cooling outer barrel, a cooling area is formed in the cooling inner barrel, an inner barrel discharging pipe which penetrates through the cooling outer barrel and is communicated with the outside is arranged at the bottom of the cooling inner barrel, and a liquid inlet pipe communicated with the overflow area is arranged at the bottom of the cooling outer barrel.

The cooling coil comprises a coil lower inlet arranged at the lower part of the cooling coil and a coil upper outlet arranged at the upper part of the cooling coil.

The inlet is linked together with interior bucket discharging pipe under the coil pipe, and export is discharged the cold day crystal ball to the material collecting pit through arranging the material pipe on the coil pipe, export and row material pipe on the coil pipe are all less than the upper edge of interior bucket of cooling.

Preferably, the bottom of the cooling inner barrel is conical.

Preferably, the outer side wall of the cooling outer barrel is provided with an overflow pipe communicated with the overflow area, and the overflow pipe is higher than the upper edge of the cooling inner barrel.

Preferably, the cooling coil is arranged on the outer side wall of the cooling outer barrel.

Preferably, the overflow area is provided with a plurality of connecting brackets fixedly connecting the cooling outer barrel and the cooling inner barrel.

The beneficial effects of the utility model reside in that:

(1) the utility model relates to a circulating water cooling mechanism for producing a cold celestial crystal ball, which conveys cooling water to an overflow area of a cooling outer barrel through a liquid inlet pipe, the water quantity in the overflow area is gradually increased, when the water level exceeds the upper edge of the cooling inner barrel, the water overflows into the cooling inner barrel and passes through the discharge pipe and the cooling coil pipe, when the water level in the cooling inner barrel is higher than the upper outlet of the coil pipe and the discharge pipe, the water finally flows to the material collecting tank by adopting the liquid level difference principle, when the skyscraper balls fall into the cooling inner barrel, the skyscraper balls are sunk to the bottom of the cooling inner barrel and flow to the material collecting pool along with water, the skyscraper balls falling into the cooling inner barrel each time are directly contacted with cooling water and cooled, the cooling effect is good, and finished products are not adhered; but also follows the first-in-first-out principle, the water temperature of the cooling water before and after the water flow direction is not different, so that the consistency of the cooling time of the crystal balls is ensured, and the consistency of finished products is obtained.

(2) The utility model discloses a production is cold day crystal ball and is used circulating water cooling mechanism, after cold day crystal ball comes out from the cooling inner barrel, through the coil pipe cooling, only reach the material collecting pit finally, the use of cooling coil pipe has prolonged the time of material and cooling water contact, makes the material can fully cool off, fundamentally has solved the problem of cold day crystal ball adhesion, and the use of coil pipe has saved a large amount of spaces simultaneously;

(3) the utility model discloses a production hantian brilliant ball is with circulating water cooling mechanism, cooling coil pipe dish are established at outer bucket lateral wall of cooling, can be under the refrigerated prerequisite of completion hantian brilliant ball, furthest's saving equipment occupation of land space.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the technical solutions in the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic perspective view of the present invention;

fig. 2 is a schematic perspective view of the present invention;

fig. 3 is a plan view of the present invention;

FIG. 4 is a schematic perspective view of the forming mechanism;

FIG. 5 is a plan view of the forming mechanism;

FIG. 6 is a perspective view of the cutting mechanism;

FIG. 7 is a partially exploded view of the cutting mechanism;

FIG. 8 is a partially exploded view of the forming mechanism;

FIG. 9 is a partial top view of the forming mechanism;

FIG. 10 is a cross-sectional view taken along line B-B of FIG. 9;

FIG. 11 is an enlarged view at C of FIG. 10;

FIG. 12 is a first partial schematic view of a circulating water cooling mechanism;

fig. 13 is a partial schematic view of a circulating water cooling mechanism.

Reference numerals: 1. mounting bracket, 2, feeding mechanism, 5, material collecting tank, 31, screw pump, 32, forming die head, 33, guide rod, 34, guide seat, 35, cutting mechanism, 36, driving part, 41, cooling unit, 42, discharging pipe, 43, circulating water cooling component, 44, cooling coil, 51, solid-liquid separation baffle, 52, material collecting tank body, 321, upper shell cover, 322, extrusion disc, 323, lower shell cover, 324, cooling water channel, 325, water inlet pipe, 351, cutter seat, 352, cutting through groove, 353, cutter, 361, driving motor, 362, eccentric connecting disc, 431, cooling outer barrel, 433, connecting bracket, 434, mesh plate, 435, overflow pipe, 436, cooling inner barrel, 441, lower inlet of coil, 442, upper outlet of coil, 3211, feed inlet, 3221, extrusion through hole, 3222, extrusion pipe, 3231, cooling, 3241 cooling gap, 3212 outer shell, 3213 inner shell, 3214 water inlet gap, 3223 extruding disc flange, 3224 communicating hole, 4313 overflow area, 4312 cooling area, 4314 inner barrel discharging pipe, 4315 liquid inlet pipe.

Detailed Description

The technical solution of the present invention will be described clearly and completely with reference to the accompanying drawings, and obviously, the described embodiments are some, but not all embodiments of the present invention.

As shown in fig. 1-3,12 and 13, a circulating water cooling mechanism for producing a skyscraper ball comprises:

a circulating water cooling unit 43 and a cooling coil 44,

the circulating water cooling assembly 43 comprises a cooling outer barrel 431 and a cooling inner barrel 436 which are coaxially nested and fixedly connected, the upper edge of the cooling outer barrel 431 is higher than the upper edge of the cooling inner barrel 436, an overflow area 4313 is formed between the cooling inner barrel 436 and the cooling outer barrel 431, a cooling area 4312 is formed in the cooling inner barrel 436, an inner barrel discharging pipe 4314 which penetrates through the cooling outer barrel 431 and is communicated with the outside is arranged at the bottom of the cooling inner barrel 436, a liquid inlet pipe 4315 which is communicated with the overflow area 4313 is arranged at the bottom of the cooling outer barrel 431,

the cooling coil 44 includes a lower coil inlet 441 disposed at a lower portion of the cooling coil 44 and an upper coil outlet 442 disposed at an upper portion of the cooling coil 44,

the lower coil inlet 441 is communicated with an inner barrel discharge pipe 4314, the upper coil outlet 442 discharges the skynet balls to a material collection pool through a discharge pipe 42, and both the upper coil outlet 442 and the discharge pipe 42 are lower than the upper edge of the inner cooling barrel 436.

The cooling coil 44 may be a separate plate disposed beside the circulating water cooling assembly, and may be in a shape of a Chinese character 'hui', a zigzag shape, or other irregular shapes, and the main purpose is to prolong the cooling time of the product.

Preferably, the bottom of the cooling inner barrel 436 is tapered.

Preferably, an overflow pipe 435 communicating with the overflow region 4313 is provided on an outer sidewall of the cooling outer tub 431, and the overflow pipe 435 is higher than an upper edge of the cooling inner tub 436.

Preferably, the cooling coil 44 is coiled on the outer side wall of the cooling tub 431.

Preferably, the overflow zone 4313 is provided with a plurality of connection brackets 433 fixedly connecting the cooling outer tub 431 and the cooling inner tub 436.

Preferably, a plurality of connection brackets 433 are uniformly distributed between the cooling outer tub 431 and the cooling inner tub 436.

Preferably, a mesh plate 434 for blocking the crystal balls from entering the overflow area 4313 is arranged between the cooling outer barrel 431 and the cooling inner barrel 436.

As shown in fig. 1-3, a molding system for producing a skyscraper ball comprises a mounting bracket 1 and a plurality of molding devices, wherein each molding device comprises a molding mechanism and a circulating water cooling mechanism, the circulating water cooling mechanism is used for cooling a product produced by the molding mechanism, a material collecting pool 5 and a cooling unit 41, and the cooling unit 41 is used for filtering and cooling water in the material collecting pool 5 and supplying cooling water to the molding mechanism and the circulating water cooling mechanism.

In this embodiment, two sets of molding devices are provided, and the number of the molding devices can be adjusted according to the capacity or the size of the production field.

In one embodiment, as shown in fig. 4-11, the forming mechanism structure may include:

the feed mechanism 2 and the forming die 32,

the molding die 32 includes an upper housing 321, an extrusion disc 322, and a lower housing 323,

the top of the upper casing 321 is provided with a feed inlet 3211,

a plurality of extrusion through holes 3221 are arranged on the extrusion disc 322, extrusion pipes 3222 communicated with the extrusion through holes 3221 are arranged on the extrusion through holes 3221,

a plurality of cooling water holes 3231 are formed at the bottom of the lower housing cover 323,

the upper shell cover 321 is fixedly connected with the lower shell cover 323, the extrusion disc 322 is fixedly arranged between the upper shell cover 321 and the lower shell cover 323, a cooling water channel 324 communicated with external cooling water is formed between the extrusion disc 322 and the lower shell cover 323, the extrusion pipe 3222 is arranged in the cooling water hole 3231 in a penetrating manner, the cooling water in the cooling water channel 324 can conveniently pass through a cooling gap 3241 between the extrusion pipe 3222 and the cooling water hole 3231, the forming die head 32 is communicated with the feeding mechanism 2 through a feeding hole 3211 at the top of the upper shell cover 321, and the bottom of the forming die head 32 is further provided with a cutting mechanism 35 for cutting the cold celestial crystal balls.

Preferably, a screw pump 31 for stable feeding is arranged between the feeding mechanism 2 and the forming die head 32.

In a specific embodiment, the upper casing 321 may be a double-layer structure, including an outer casing 3212 and an inner casing 3213, a water inlet gap 3214 is formed between the outer casing 3212 and the inner casing 3213, a water inlet pipe 325 for introducing external cooling water into the water inlet gap 3214 is disposed outside the outer casing 3212, the pressing plate 322 has a pressing plate flange 3223, a plurality of communicating holes 3224 are uniformly distributed on the pressing plate flange 3223, and the water inlet gap 3214 is communicated with the cooling water passage 324 through the communicating holes 3224.

Preferably, the bottom of the extruded tube 3222 protrudes beyond the bottom of the lower housing shell 323.

In one embodiment, as shown in fig. 4-7, the cutting mechanism 35 includes a cutter seat 351 and a cutter 353, the cutter 353 is mounted on the cutter seat, the cutter seat 351 is provided with a cutting through groove 352 for facilitating the cutter 353 to cut the product, and the cutting mechanism further includes a driving member 36 for driving the cutter seat 351 to reciprocate.

In one embodiment, as shown in fig. 1-3, the material collecting tank 5 includes a material collecting tank body 52, and a solid-liquid separating partition plate 51 for separating cooling water and the eutectic balls is disposed on the top of the material collecting tank body 52.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention.

Claims (7)

1. The utility model provides a production is circulating water cooling mechanism for hantian crystal ball which characterized in that includes:

a circulating water cooling component (43) and a cooling coil (44)

The circulating water cooling assembly (43) comprises a cooling outer barrel (431) and a cooling inner barrel (436) which are coaxially nested and fixedly connected, the upper edge of the cooling outer barrel (431) is higher than the upper edge of the cooling inner barrel (436), an overflow area (4313) is formed between the cooling inner barrel (436) and the cooling outer barrel (431), a cooling area (4312) is formed in the cooling inner barrel (436), an inner barrel discharge pipe (4314) which penetrates through the cooling outer barrel (431) and is communicated with the outside is arranged at the bottom of the cooling inner barrel (436), a liquid inlet pipe (4315) communicated with the overflow area (4313) is arranged at the bottom of the cooling outer barrel (431),

the cooling coil (44) comprises a coil lower inlet (441) arranged at the lower part of the cooling coil (44) and a coil upper outlet (442) arranged at the upper part of the cooling coil (44),

the lower inlet (441) of the coil pipe is communicated with the discharge pipe (4314) of the inner barrel, the upper outlet (442) of the coil pipe discharges the skynet balls to the material collecting tank through the discharge pipe (42), and the upper outlet (442) of the coil pipe and the discharge pipe (42) are both lower than the upper edge of the cooling inner barrel (436).

2. The circulating water cooling mechanism for producing the hantian crystal ball as claimed in claim 1, wherein: the bottom of the cooling inner barrel (436) is conical.

3. The circulating water cooling mechanism for producing the hantian crystal ball as claimed in claim 1, wherein: the outer side wall of the cooling outer barrel (431) is provided with an overflow pipe (435) communicated with the overflow area (4313), and the overflow pipe (435) is higher than the upper edge of the cooling inner barrel (436).

4. The circulating water cooling mechanism for producing the hantian crystal ball as claimed in claim 1, wherein: the cooling coil (44) is coiled on the outer side wall of the cooling outer barrel (431).

5. The circulating water cooling mechanism for producing the hantian crystal ball as claimed in claim 1, wherein: the overflow area (4313) is provided with a plurality of connecting brackets (433) which are fixedly connected with the cooling outer barrel (431) and the cooling inner barrel (436).

6. The circulating water cooling mechanism for producing the hantian crystal ball as claimed in claim 5, wherein: the connecting brackets (433) are uniformly distributed between the cooling outer barrel (431) and the cooling inner barrel (436).

7. The circulating water cooling mechanism for producing the hantian crystal ball as claimed in claim 1, wherein: a mesh plate (434) for preventing the crystal balls from entering the overflow area (4313) is arranged between the cooling outer barrel (431) and the cooling inner barrel (436).

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