CN110667081B

CN110667081B - Flask blow molding flash device of injection mold

Info

Publication number: CN110667081B
Application number: CN201910953602.1A
Authority: CN
Inventors: 王换军
Original assignee: Foshan Shunde Darong Mould Industrial Co ltd
Current assignee: FOSHAN SHUNDE DARONG MOULD INDUSTRIAL Co.,Ltd.
Priority date: 2019-10-09
Filing date: 2019-10-09
Publication date: 2021-08-17
Anticipated expiration: 2039-10-09
Also published as: CN110667081A

Abstract

The invention relates to the field of injection molds, in particular to a flask blow molding flash device of an injection mold, and aims to provide a flask blow molding flash device of an injection mold, which comprises a support frame, a water tank, a water pump, a processing cabin, a double-line guide rail, a control display, a stepping motor, a poking-in separating mechanism, a first mold pushing mechanism, a first bevel gear, a first transmission rod, a second bevel gear and a second mold pushing mechanism; the left side of the top end of the support frame is connected with the water tank through a bolt; the left side of the top end of the support frame is connected with the water pump through the bolt, and the invention achieves the effects of firstly processing the product and then cooling and demoulding, improving the production efficiency through mechanized production and being used for actual production.

Description

Flask blow molding flash device of injection mold

Technical Field

The invention relates to the field of injection molds, in particular to a flask blow mold flash device of an injection mold.

Background

The injection molding method has the advantages of high production speed, high efficiency, automation operation, various colors, shapes from simple to complex, sizes from large to small, precise product size, easy product replacement, capability of forming products with complex shapes, and suitability for the molding processing fields of mass production, products with complex shapes and the like.

In order to solve the problems of uneven mixing, low mixing efficiency and easy generation of inferior products of plastic master batches and additives in the prior art during processing, Chinese patent CN108556174A discloses a device for an injection mold, which overcomes the problems of uneven mixing, low mixing efficiency and easy generation of inferior products of the plastic master batches and the additives during processing by stirring a mixing cabin.

In the prior art, chinese patent CN107791452A discloses an invention demolding device for an injection mold, which solves the problems of low cost and low cooling efficiency of the existing natural cooling method, and overcomes the problems of low cost and low cooling efficiency of the natural cooling method by adding a circulating liquid cooling method outside the mold, but the injection-molded product usually needs to be reprocessed to obtain a finished product, which results in increased cost and increased processing difficulty.

To sum up, need to develop a direct injection molding and form complete product at present, process the product earlier simultaneously and cool off the drawing of patterns, mechanized production improves production efficiency to can be used to the flask blowing mould flash device of actual production's an injection mold, overcome the device that lacks the direct injection molding of flask and form the product among the prior art and be used for the actual production in-process, excessively rely on the manual work, can't reach the required stable production and the accuracy of processing finished product, carry out secondary operation after earlier cooling simultaneously, require the degree of difficulty to processing high, and the secondary operation easily produces the shortcoming of defective goods.

Disclosure of Invention

The invention aims to overcome the defects that in the prior art, a device for directly injecting and molding a flask to form a product is lacked and is used in the actual production process, the manual work is excessively relied, the stable production and the accuracy required by the processing of a finished product cannot be achieved, meanwhile, the secondary processing is carried out after the cooling, the processing requirement is high in difficulty, and defective goods are easily produced in the secondary processing.

The invention is achieved by the following specific technical means:

a flask blow molding flash device of an injection mold comprises a support frame, a water tank, a water pump, a processing cabin, a double-line guide rail, a control display, a stepping motor, a poking-in separating mechanism, a first mold pushing mechanism, a first bevel gear, a first transmission rod, a second bevel gear and a second mold pushing mechanism; the left side of the top end of the support frame is connected with the water tank through a bolt; the left side of the top end of the support frame is connected with a water pump through a bolt, and the left end of the water pump is connected with a water tank through a water pipe; the right part of the top end of the support frame is welded with the processing cabin; the left middle part of the front end of the support frame is welded with the double-line guide rail, and the outer surface of the right upper part of the double-line guide rail is connected with the processing cabin; the top of the left end of the processing cabin is connected with a control display through a bolt; the left side of the bottom end in the processing cabin is connected with a stepping motor through a bolt; the middle part in the processing cabin is provided with a poking-in separation mechanism, and the bottom end of the poking-in separation mechanism is connected with a stepping motor; the left end in the processing cabin is rotationally connected with the first die pushing mechanism through the mounting seat; a first bevel gear is arranged at the lower left part in the processing cabin, and the top of the left end of the first bevel gear is connected with a first mold pushing mechanism; the right end in the processing cabin is rotationally connected with the second die pushing mechanism through a mounting seat; the middle part of the right end of the first bevel gear is inserted into the first transmission rod, and the outer surface of the first transmission rod is connected with the processing cabin through the mounting seat; the right end of the first transmission rod is spliced with the second bevel gear, and the top of the right end of the second bevel gear is connected with the second die pushing mechanism;

the poking-in separation mechanism comprises a third bevel gear, a fourth bevel gear, a first cylindrical gear, a second cylindrical gear, a first special-shaped transmission wheel, a second special-shaped transmission wheel, a third cylindrical gear, a second transmission rod, a first transmission wheel, a second transmission wheel, a fourth cylindrical gear, a first annular gear ring, a first bearing seat, an atomizing nozzle, a first cutting knife, a blow molding gun and a poking plate; the top of the front end of the third bevel gear is meshed with the fourth bevel gear; the middle part of the top end of the fourth bevel gear is spliced with the first cylindrical gear through a round rod; the left end of the first cylindrical gear is meshed with the second cylindrical gear; the top end of the first cylindrical gear is connected with a second transmission rod in an inserting mode through a round rod; the middle part of the top end of the second cylindrical gear is inserted with the first special-shaped transmission wheel; the left end of the first special-shaped transmission wheel is in transmission connection with the second special-shaped transmission wheel; the middle part of the bottom end of the second special-shaped transmission wheel is inserted with the third cylindrical gear; the middle part of the top end of the second transmission rod is inserted into the first transmission wheel; the right side of the first driving wheel is in transmission connection with a second driving wheel through a belt; the middle part of the bottom end of the second transmission wheel is spliced with the fourth cylindrical gear through a round rod; the left end of the fourth cylindrical gear is meshed with the first annular gear ring; the outer circle of the bottom end of the first annular gear ring is welded with the first bearing seat; the left end of the first bearing block is connected with the atomizing nozzle through a bolt; the left side of the bottom end of the first bearing seat is welded with a first cutting knife; the inner surface of the first bearing seat is welded with the blow molding gun; the middle part of the rear end of the third bevel gear is connected with a stepping motor; the bottom end of the second cylindrical gear is connected with the processing cabin through a round rod; the middle part of the bottom end of the third cylindrical gear is connected with the processing cabin; the top of the outer surface of the blow molding gun is connected with the processing cabin;

the first mold pushing mechanism comprises a fifth bevel gear, a fifth cylindrical gear, a sixth bevel gear, a seventh bevel gear, a first transmission disc, a third transmission rod, a fourth transmission rod, a first sliding sleeve and a first partial mold; the middle part of the top end of the fifth bevel gear is spliced with the fifth cylindrical gear through a round rod; the middle part of the top end of the fifth cylindrical gear is inserted with the sixth bevel gear through a round rod; the rear part of the top end of the sixth bevel gear is meshed with the seventh bevel gear; a first transmission disc is inserted in the middle of the rear end of the seventh bevel gear; the middle upper part of the rear end of the first transmission disc is in transmission connection with a third transmission rod; the right end of the third transmission rod is in transmission connection with the fourth transmission rod; the right end of the fourth transmission rod is in transmission connection with the first sliding rod; the middle part of the outer surface of the first sliding rod is in sliding connection with the first sliding sleeve; the right end of the first sliding rod is welded with the first part of the die; the rear part of the bottom end of the fifth bevel gear is connected with the first bevel gear; the middle part of the rear end of the first transmission disc is connected with the processing cabin through a mounting seat; the top end of the first sliding sleeve is connected with the processing cabin through the mounting seat;

the second mold pushing mechanism comprises an eighth bevel gear, a ninth bevel gear, a tenth bevel gear, a second transmission disc, a fifth transmission rod, a sixth transmission rod, a second sliding sleeve, a second partial mold, a first worm gear, a seventh cylindrical gear, an eighth cylindrical gear, a first cam, an opening cut-through group, an eleventh bevel gear, a twelfth bevel gear, a third transmission disc, a seventh transmission rod, an eighth transmission rod, a third sliding sleeve and a third partial mold; the middle part of the top end of the eighth bevel gear is spliced with the ninth bevel gear through a round rod; the rear part of the top end of the ninth bevel gear is meshed with the tenth bevel gear; the middle part of the top end of the ninth bevel gear is inserted into the first worm; the middle part of the rear end of the tenth bevel gear is inserted into the second transmission disc; the middle upper part of the rear end of the second transmission disc is in transmission connection with a fifth transmission rod; the left end of the fifth transmission rod is in transmission connection with the sixth transmission rod; the left end of the sixth transmission rod is in transmission connection with the second sliding rod; the middle part of the outer surface of the second sliding rod is in sliding connection with the second sliding sleeve; the left end of the second sliding rod is welded with the second part of the die; the middle part of the left end of the first worm is meshed with the first worm wheel; the top end of the first worm is inserted with the eleventh bevel gear; the middle part of the rear end of the first worm wheel is meshed with the seventh cylindrical gear; the middle part of the left end of the seventh cylindrical gear is meshed with the eighth cylindrical gear; the front end of the eighth cylindrical gear is spliced with the first cam; the left end of the first cam is connected with the opening cut-through group; the rear part of the top end of the eleventh bevel gear is spliced with the twelfth bevel gear; the middle part of the rear end of the twelfth bevel gear is inserted with the third transmission disc; the middle lower part of the rear end of the third transmission disc is in transmission connection with a seventh transmission rod; the left end of the seventh transmission rod is in transmission connection with the eighth transmission rod; the left end of the eighth transmission rod is in transmission connection with the third sliding rod; the middle part of the outer surface of the third sliding rod is in sliding connection with the third sliding sleeve; the left end of the third sliding rod is welded with the third part module; the left part of the bottom end of the eighth bevel gear is meshed with the second bevel gear; the middle part of the rear end of the second transmission disc is connected with the processing cabin through a mounting seat; the middle part of the bottom end of the second sliding sleeve is connected with the processing cabin through a mounting seat; the middle part of the bottom end of the opening cut-through group is connected with the processing cabin through a mounting seat; the middle part of the rear end of the third transmission disc is connected with the processing cabin through a mounting seat; the middle part of the top end of the third sliding sleeve is connected with the processing cabin through a mounting seat;

the opening cut-through group comprises a first telescopic rod, a sleeve, a limiting spring, a second telescopic rod, a toothed bar, a ninth cylindrical gear, a thirteenth bevel gear, a fourteenth bevel gear, a tenth cylindrical gear, a second annular gear ring, a second bearing seat, a fixed rod, a second cutting knife and a thimble; the left side of the outer surface of the first telescopic rod is sleeved with the sleeve; the left end of the first telescopic rod is welded with the limiting spring; the left end of the limiting spring is welded with the second telescopic rod, and the right side of the outer surface of the second telescopic rod is connected with the sleeve; the top end of the sleeve is welded with the toothed bar; the left end of the second telescopic rod is welded with the fixed rod; the left side of the bottom end of the toothed bar is meshed with a ninth cylindrical gear; the middle part of the front end of the ninth cylindrical gear is spliced with the thirteenth bevel gear; the left side of the front end of the thirteenth bevel gear is meshed with the fourteenth bevel gear; the middle part of the left end of the fourteenth bevel gear is spliced with the tenth cylindrical gear through a round rod; the top end of the tenth cylindrical gear is meshed with the second annular gear ring; the outer circle of the left end of the second annular gear ring is welded with the second bearing seat, and the inner surface of the second bearing seat is connected with the fixed rod; the top of the left end of the second bearing block is welded with the second cutting knife; the middle part of the left end of the fixed rod is welded with the thimble; the right end of the first telescopic rod is connected with the second transmission disc; the middle part of the bottom end of the sleeve is connected with the processing cabin.

Furthermore, the shifting plate is arranged into an arc shape which is concave backwards, and a convex baffle is arranged at the middle right part of the top end of the shifting plate.

Furthermore, a cylindrical deflector rod is arranged at the left upper part of the bottom end of the first special-shaped driving wheel.

Furthermore, the left side of the outer surface of the first telescopic rod and the right side of the outer surface of the second telescopic rod are both provided with limiting blocks, and the left side of the inner surface of the sleeve and the right side of the inner surface of the sleeve are both provided with limiting blocks.

Compared with the prior art, the invention has the following beneficial effects:

(1) in order to solve the defects that a device for directly injecting and molding a flask to form a product is lacked in the prior art and is used in the actual production process, the manual work is excessively relied, the stable production and the accuracy required by the finished product cannot be achieved, meanwhile, secondary processing is carried out after cooling, the processing requirement difficulty is high, and defective goods are easily generated in the secondary processing, a support frame, a water tank, a water pump, a processing cabin, a double-line guide rail, a control display, a stepping motor, a poking-in separating mechanism, a first mold pushing mechanism, a first bevel gear, a first transmission rod, a second bevel gear and a second mold pushing mechanism are designed, molten raw materials are blown into smaller balls through the poking-in separating mechanism, then the molds on the first mold pushing mechanism and the second mold pushing mechanism are closed through intermittent linkage, the smaller balls are wrapped through the molds, and finally, the semi-finished product matched with the molds is obtained through blow molding, and then the second mould pushing mechanism is used for cutting the branch pipe of the overflow part of the branch pipe of the flask to perform opening operation to obtain the opening of the branch pipe with smooth opening, then the semi-finished product and the blow mould residue are cut and separated by the poking-in separating mechanism, and then water mist is sprayed on the outer surface of the mould to separate the mould from the intact finished product, so that the obtained complete flask is collected at the tail end of the double-line guide rail, thereby achieving the effects of firstly processing the product and then cooling and demoulding, improving the production efficiency in mechanized production and being used for actual production.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural view of a poking-in and separating mechanism of the present invention;

FIG. 3 is a schematic view of a combination structure of a first special-shaped transmission wheel and a second special-shaped transmission wheel according to the present invention;

FIG. 4 is a schematic structural view of a first mold pushing mechanism of the present invention;

FIG. 5 is a schematic structural view of a second mold pushing mechanism of the present invention;

FIG. 6 is a schematic view of the structure of the opening cut-through set of the present invention;

FIG. 7 is an enlarged view of the region X of the present invention;

fig. 8 is an enlarged view of the Y region of the present invention.

The labels in the figures are: 1-a support frame, 2-a water tank, 3-a water pump, 4-a processing cabin, 5-a two-wire guide rail, 6-a control display, 7-a stepping motor, 8-a poking-in separating mechanism, 9-a first mold pushing mechanism, 10-a first bevel gear, 11-a first transmission rod, 12-a second bevel gear, 13-a second mold pushing mechanism, 801-a third bevel gear, 802-a fourth bevel gear, 803-a first cylindrical gear, 804-a second cylindrical gear, 805-a first special-shaped transmission wheel, 806-a second special-shaped transmission wheel, 807-a third cylindrical gear, 808-a second transmission rod, 809-a first transmission wheel, 8010-a second transmission wheel, 1-a fourth cylindrical gear, 8012-a first annular gear ring and 8013-a first bearing seat, 8014-atomizer, 8015-first cutting blade, 8016-blow molding gun, 8017-paddle, 901-fifth bevel gear, 902-fifth cylindrical gear, 903-sixth bevel gear, 904-seventh bevel gear, 905-first drive disk, 906-third drive rod, 907-fourth drive rod, 908-first slide bar, 909-first slide bushing, 9010-first partial mold, 1301-eighth bevel gear, 1302-ninth bevel gear, 1303-tenth bevel gear, 1304-second drive disk, 1305-fifth drive rod, 1306-sixth drive rod, 1307-second slide bar, 1308-second slide bushing, 1309-second partial mold, 13010-first worm, 13011-first worm gear, 13012-seventh cylindrical gear, 13013-eighth cylindrical gear, 13014-first cam, 13015-opening cut-through group, 13016-eleventh bevel gear, 13017-twelfth bevel gear, 13018-third transmission disk, 13019-seventh transmission rod, 13020-eighth transmission rod, 13021-third sliding rod, 13022-third sliding sleeve, 13023-third part module, 1301501-first telescopic rod, 1301502-sleeve, 1301503-limit spring, 1301504-second telescopic rod, 1301505-toothed rod, 1301506-ninth cylindrical gear, 1301507-thirteenth bevel gear, 1301508-fourteenth bevel gear, 1301509-tenth cylindrical gear, 13015010-second annular gear ring, 13015011-second bearing seat, 13015012-fixed rod, 13015013-second cutting knife and 13015014-thimble.

Detailed Description

The invention is further described below with reference to the figures and examples.

Examples

A flask blow molding flash device of an injection mold is shown in figures 1-8 and comprises a support frame 1, a water tank 2, a water pump 3, a processing cabin 4, a double-line guide rail 5, a control display 6, a stepping motor 7, a poking-in separating mechanism 8, a first mold pushing mechanism 9, a first bevel gear 10, a first transmission rod 11, a second bevel gear 12 and a second mold pushing mechanism 13; the left side of the top end of the support frame 1 is connected with the water tank 2 through a bolt; the left side of the top end of the support frame 1 is connected with a water pump 3 through a bolt, and the left end of the water pump 3 is connected with a water tank 2 through a water pipe; the right part of the top end of the support frame 1 is welded with the processing cabin 4; the left middle part of the front end of the support frame 1 is welded with the double-line guide rail 5, and the outer surface of the right upper part of the double-line guide rail 5 is connected with the processing cabin 4; the top of the left end of the processing cabin 4 is connected with a control display 6 through a bolt; the left side of the bottom end in the processing cabin 4 is connected with a stepping motor 7 through a bolt; a poking-in separation mechanism 8 is arranged in the middle of the processing cabin 4, and the bottom end of the poking-in separation mechanism 8 is connected with a stepping motor 7; the left end in the processing cabin 4 is rotationally connected with a first mould pushing mechanism 9 through a mounting seat; a first bevel gear 10 is arranged at the lower left part in the processing cabin 4, and the top of the left end of the first bevel gear 10 is connected with a first mold pushing mechanism 9; the right end in the processing cabin 4 is rotationally connected with a second mould pushing mechanism 13 through a mounting seat; the middle part of the right end of the first bevel gear 10 is inserted into the first transmission rod 11, and the outer surface of the first transmission rod 11 is connected with the processing cabin 4 through a mounting seat; the right end of the first transmission rod 11 is inserted into the second bevel gear 12, and the top of the right end of the second bevel gear 12 is connected with the second mold pushing mechanism 13.

The poking-in and separating mechanism 8 comprises a third bevel gear 801, a fourth bevel gear 802, a first cylindrical gear 803, a second cylindrical gear 804, a first special-shaped driving wheel 805, a second special-shaped driving wheel 806, a third cylindrical gear 807, a second driving rod 808, a first driving wheel 809, a second driving wheel 8010, a fourth cylindrical gear 8011, a first annular gear ring 8012, a first bearing seat 8013, an atomizing nozzle 8014, a first cutting knife 8015, a blow molding gun 8016 and a poking plate 8017; the top of the front end of the third bevel gear 801 is meshed with the fourth bevel gear 802; the middle part of the top end of the fourth bevel gear 802 is inserted into the first cylindrical gear 803 through a round rod; the left end of the first cylindrical gear 803 is meshed with the second cylindrical gear 804; the top end of the first cylindrical gear 803 is spliced with a second transmission rod 808 through a round rod; the middle part of the top end of the second cylindrical gear 804 is inserted into the first special-shaped transmission wheel 805; the left end of the first special-shaped driving wheel 805 is in transmission connection with a second special-shaped driving wheel 806; the middle part of the bottom end of the second special-shaped driving wheel 806 is inserted into the third cylindrical gear 807; the middle part of the top end of the second transmission rod 808 is inserted into the first transmission wheel 809; the right side of the first driving wheel 809 is in driving connection with a second driving wheel 8010 through a belt; the middle part of the bottom end of the second driving wheel 8010 is spliced with the fourth cylindrical gear 8011 through a round rod; the left end of the fourth cylindrical gear 8011 is engaged with the first ring-shaped gear ring 8012; the outer circle of the bottom end of the first annular gear ring 8012 is welded with the first bearing seat 8013; the left end of the first bearing block 8013 is in bolted connection with the atomizing nozzle 8014; the left side of the bottom end of the first bearing block 8013 is welded with the first cutting blade 8015; the inner surface of the first bearing block 8013 is welded to the blow molding gun 8016; the middle part of the rear end of the third bevel gear 801 is connected with a stepping motor 7; the bottom end of the second cylindrical gear 804 is connected with the processing cabin 4 through a round bar; the middle part of the bottom end of the third cylindrical gear 807 is connected with the processing cabin 4; the blow molding gun 8016 is attached to the process chamber 4 at the top of its outer surface.

The first mold pushing mechanism 9 comprises a fifth bevel gear 901, a fifth cylindrical gear 902, a sixth bevel gear 903, a seventh bevel gear 904, a first transmission disc 905, a third transmission rod 906, a fourth transmission rod 907, a first sliding rod 908, a first sliding sleeve 909 and a first partial mold 9010; the middle part of the top end of the fifth bevel gear 901 is inserted into the fifth cylindrical gear 902 through a round rod; the middle part of the top end of the fifth cylindrical gear 902 is spliced with a sixth bevel gear 903 through a round rod; the rear part of the top end of the sixth bevel gear 903 is meshed with a seventh bevel gear 904; a first transmission disc 905 is inserted in the middle of the rear end of the seventh bevel gear 904; the middle upper part of the rear end of the first transmission disc 905 is in transmission connection with a third transmission rod 906; the right end of the third transmission rod 906 is in transmission connection with a fourth transmission rod 907; the right end of a fourth transmission rod 907 is in transmission connection with the first sliding rod 908; the middle part of the outer surface of the first sliding rod 908 is in sliding connection with a first sliding sleeve 909; the right end of the first sliding rod 908 is welded with a first part mold 9010; the rear part of the bottom end of the fifth bevel gear 901 is connected with the first bevel gear 10; the middle part of the rear end of the first transmission disc 905 is connected with the processing cabin 4 through a mounting seat; the top end of the first sliding sleeve 909 is connected with the processing chamber 4 through the mounting seat.

The second mold pushing mechanism 13 comprises an eighth bevel gear 1301, a ninth bevel gear 1302, a tenth bevel gear 1303, a second transmission disc 1304, a fifth transmission rod 1305, a sixth transmission rod 1306, a second sliding rod 1307, a second sliding sleeve 1308, a second partial mold 1309, a first worm 13010, a first worm gear 13011, a seventh cylindrical gear 13012, an eighth cylindrical gear 13013, a first cam 13014, an opening cut-through group 13015, an eleventh bevel gear 13016, a twelfth bevel gear 13017, a third transmission disc 13018, a seventh transmission rod 13019, an eighth transmission rod 13020, a third sliding rod 13021, a third sliding sleeve 13022 and a third partial mold 13023; the middle part of the top end of the eighth bevel gear 1301 is inserted into the ninth bevel gear 1302 through a round rod; the rear part of the top end of the ninth bevel gear 1302 is meshed with a tenth bevel gear 1303; the middle part of the top end of the ninth bevel gear 1302 is inserted with the first worm 13010; the middle part of the rear end of the tenth bevel gear 1303 is inserted into the second transmission disc 1304; the middle upper part of the rear end of the second transmission disc 1304 is in transmission connection with a fifth transmission rod 1305; the left end of the fifth transmission rod 1305 is in transmission connection with a sixth transmission rod 1306; the left end of the sixth transmission rod 1306 is in transmission connection with a second sliding rod 1307; the middle part of the outer surface of the second sliding bar 1307 is in sliding connection with the second sliding sleeve 1308; the left end of the second slide bar 1307 is welded with a second partial mould 1309; the middle part of the left end of the first worm 13010 is meshed with a first worm gear 13011; the top end of the first worm 13010 is spliced with an eleventh bevel gear 13016; the middle part of the rear end of the first worm gear 13011 is meshed with a seventh cylindrical gear 13012; the middle part of the left end of the seventh cylindrical gear 13012 is meshed with the eighth cylindrical gear 13013; the front end of the eighth cylindrical gear 13013 is spliced with the first cam 13014; the left end of the first cam 13014 is connected with an opening cut-through group 13015; the rear part of the top end of the eleventh bevel gear 13016 is spliced with a twelfth bevel gear 13017; the middle part of the rear end of the twelfth bevel gear 13017 is spliced with a third transmission disc 13018; the middle lower part of the rear end of the third transmission disc 13018 is in transmission connection with a seventh transmission rod 13019; the left end of the seventh transmission rod 13019 is in transmission connection with the eighth transmission rod 13020; the left end of the eighth transmission rod 13020 is in transmission connection with a third sliding rod 13021; the middle part of the outer surface of the third sliding rod 13021 is in sliding connection with a third sliding sleeve 13022; the left end of the third sliding rod 13021 is welded with a third partial module 13023; the left part of the bottom end of the eighth bevel gear 1301 is meshed with the second bevel gear 12; the middle part of the rear end of the second transmission disc 1304 is connected with the processing cabin 4 through a mounting seat; the middle part of the bottom end of the second sliding sleeve 1308 is connected with the processing cabin 4 through a mounting seat; the middle part of the bottom end of the opening cut-through group 13015 is connected with the processing cabin 4 through a mounting seat; the middle part of the rear end of the third transmission disc 13018 is connected with the processing cabin 4 through a mounting seat; the middle of the top end of the third sliding sleeve 13022 is connected with the processing cabin 4 through a mounting seat.

The opening cut-through group 13015 comprises a first telescopic rod 1301501, a sleeve 1301502, a limit spring 1301503, a second telescopic rod 1301504, a toothed bar 1301505, a ninth cylindrical gear 1301506, a thirteenth bevel gear 1301507, a fourteenth bevel gear 1301508, a tenth cylindrical gear 1301509, a second annular gear ring 13015010, a second bearing seat 13015011, a fixed rod 13015012, a second cutting knife 13015013 and a thimble 13015014; the left side of the outer surface of the first telescopic rod 1301501 is sleeved with the sleeve 1301502; the left end of the first telescopic rod 1301501 is welded with a limit spring 1301503; the left end of the limit spring 1301503 is welded with the second telescopic rod 1301504, and the right side of the outer surface of the second telescopic rod 1301504 is connected with the sleeve 1301502; the top end of the sleeve 1301502 is welded with the toothed bar 1301505; the left end of the second telescopic rod 1301504 is welded with the fixed rod 13015012; the left side of the bottom end of the toothed bar 1301505 is meshed with a ninth cylindrical gear 1301506; the middle part of the front end of the ninth cylindrical gear 1301506 is spliced with a thirteenth bevel gear 1301507; the left side of the front end of the thirteenth bevel gear 1301507 is meshed with the fourteenth bevel gear 1301508; the middle part of the left end of the fourteenth bevel gear 1301508 is spliced with the tenth cylindrical gear 1301509 through a round rod; the top end of the tenth cylindrical gear 1301509 is meshed with the second ring-shaped gear 13015010; the outer circle of the left end of the second annular gear ring 13015010 is welded with the second bearing seat 13015011, and the inner surface of the second bearing seat 13015011 is connected with the fixed rod 13015012; the top of the left end of the second bearing seat 13015011 is welded with a second cutting blade 13015013; the middle part of the left end of the fixed rod 13015012 is welded with the thimble 13015014; the right end of the first telescopic rod 1301501 is connected with the second transmission disc 1304; the bottom end of the sleeve 1301502 is connected to the process chamber 4 at its middle.

The toggle plate 8017 is provided in an arc shape recessed rearward, and a convex baffle is provided in the right portion in the top end of the toggle plate 8017.

A cylindrical shifting lever is arranged at the left upper part of the bottom end of the first special-shaped driving wheel 805.

The left side of the outer surface of the first telescopic rod 1301501 and the right side of the outer surface of the second telescopic rod 1301504 are both provided with a limiting block, and the left side of the inner surface of the sleeve 1301502 and the right side of the inner surface of the sleeve are both provided with a limiting block.

The working principle is as follows: when the device for blow molding flash of the flask of the injection mold is used, the device is firstly placed on the horizontal plane of a workshop, whether the water tank 2 has a leakage phenomenon is checked and replaced in time, then the blow molding gun 8016 is respectively connected with molten processing raw materials and hot steam through a round pipe, a power supply is switched on, the stepping motor 7 is started through the control display 6, the molten raw materials are blown into smaller spheres through the pulling separation mechanism 8, then the first mold pushing mechanism 9 and the molds on the second mold pushing mechanism 13 are closed through intermittent linkage, after the smaller spheres are wrapped by the molds, blow molding is continuously carried out, finally, semi-finished products matched with the molds are obtained, then the second mold pushing mechanism 13 is used for cutting branch pipes for opening the overflow part of the flask branch pipes, branch pipe openings with smooth openings are obtained, and then the semi-finished products and the blow molding residual materials are cut and separated through the pulling separation mechanism 8, the mold is then separated from the finished product by spraying water mist onto the outer surface of the mold to obtain a complete flask which is collected at the end of the two-wire guide 5.

The third bevel gear 801 is driven to rotate by the stepping motor 7, so that the third bevel gear 801 is meshed with the fourth bevel gear 802 to rotate, the first cylindrical gear 803 and the first transmission wheel 809 are driven to rotate, meanwhile, the first cylindrical gear 803 drives the second cylindrical gear 804 by meshing, the first special-shaped transmission wheel 805 drives the second special-shaped transmission wheel 806 to rotate, then the third cylindrical gear 807 is driven to rotate, the third cylindrical gear 807 is meshed with the fifth cylindrical gear 902 to drive the fifth cylindrical gear 902 to rotate, the first transmission wheel 809 rotates by driving the second transmission wheel 8010 by a belt, the fourth cylindrical gear 8011 is meshed with the first annular gear ring 8012, due to the action of the first bearing seat 8013, the first annular gear ring 8012 rotates, meanwhile, the first cutting knife 8015 realizes cutting separation of a semi-finished product and blow mold residue, and finally, after the molded finished product is pulled into the two-wire guide rail 5 by the rotation of the pull plate 8017, collection is performed at the end of the two-wire guide 5.

The fifth cylindrical gear 902 drives the fifth bevel gear 901 to rotate, then the fifth bevel gear 901 is meshed with and drives the first bevel gear 10 to rotate, meanwhile, the fifth cylindrical gear 902 upwards drives the sixth bevel gear 903 to rotate, the sixth bevel gear 903 is meshed with and drives the seventh bevel gear 904 to rotate, and further drives the first transmission disc 905 to transmit, the first transmission disc 905 transmits the third transmission rod 906, and then the fourth transmission rod 907 is transmitted, so that the first sliding rod 908 slides in the first sliding sleeve 909, and the first part of the mold 9010 is spliced with other molds. Due to the poking action of the first special-shaped driving wheel 805 on the second special-shaped driving wheel 806, the first part of the mold 9010 can stop at the end of the action, and therefore the injection molding stage can be achieved.

The second bevel gear 12 is meshed with and drives the eighth bevel gear 1301 to rotate, the eighth bevel gear 1301 drives the ninth bevel gear 1302 to rotate upwards, the tenth bevel gear 1303 is meshed and drives the second transmission disc 1304 to rotate, the fifth transmission rod 1305 is driven by the rotation of the second transmission disc 1304 and then drives the sixth transmission rod 1306, so that the second sliding rod 1307 reciprocates in the second sliding sleeve 1308, meanwhile, the second sliding sleeve 1308 pushes the second partial mould 1309 to be spliced with other moulds, the ninth bevel gear 1302 drives the first worm 13010 to rotate, the first worm 13010 is meshed and driven to rotate by the rotation of the first worm 13011, the first worm 13011 drives the seventh cylindrical gear 13012 to rotate, the seventh cylindrical gear 13012 rotates by meshing with the eighth cylindrical gear 13013 and drives the first cam 13014 to rotate, and the branch pipe is cut and opened after the injection molding is finished through the buffering effect of the opening cutting group 13015, the opening is rounded, meanwhile, the first worm 13010 drives an eleventh bevel gear 13016 to rotate, meanwhile, the eleventh bevel gear 13016 is meshed with a twelfth bevel gear 13017 to rotate, meanwhile, the twelfth bevel gear 13017 drives a third transmission disc 13018 to rotate, a seventh transmission rod 13019 is driven by the transmission of the third transmission disc 13018 to rotate in a transmission manner, the seventh transmission rod 13019 drives an eighth transmission rod 13020 to move, so that a third sliding rod 13021 slides in a third sliding sleeve 13022, meanwhile, the third sliding rod 13021 pushes a third partial module 13023 to move, so that the third partial module 13023 is spliced with other molds, then, the third partial module 13023 is matched with a pulling-in separation mechanism 8 to complete an injection molding process, and meanwhile, the quality of a product formed at one time is guaranteed.

Through the rotation of the first cam 13014, the first telescopic rod 1301501 is driven to slide in the sleeve 1301502, and meanwhile, the limit spring 1301503 is compressed, then the delay action of the limit spring 1301503 is used for pushing the second telescopic rod 1301504 to push the fixing rod 13015012 leftward after the injection molding is completed, so that the ninth cylindrical gear 1301506 rotates leftward along the toothed bar 1301505, and thus the ninth cylindrical gear 1301506 is driven to rotate, the thirteenth bevel gear 1301507 is driven to rotate through meshing, the fourteenth bevel gear 1301508 is driven to rotate, meanwhile, the tenth cylindrical gear 1301509 is driven to rotate, the tenth cylindrical gear 1301509 drives the second annular gear 13015010 to rotate, meanwhile, the second annular gear 13015010 drives the second cutting knife 13015013 to rotate through the second bearing seat 13015011, the thimble 13015014 punctures the branch pipe to form an opening when contacting a semi-finished product, and meanwhile, the branch pipe wall is supported, and the cutting is convenient to perform.

The poking plate 8017 is arranged in an arc shape which is concave backwards, a convex baffle plate is arranged at the middle right part of the top end of the poking plate 8017, the poking plate 8017 pokes a processed die into the double-line guide rail 5 through rotation, and the phenomenon that the center of gravity is overturned backwards due to poking is prevented.

The upper left part of the bottom end of the first special-shaped driving wheel 805 is provided with a cylindrical shifting lever, so that the first special-shaped driving wheel 805 can rotate, the second special-shaped driving wheel 806 can be shifted to perform intermittent motion, and the intermittent stop time provides time for injection molding.

The left side of the outer surface of the first telescopic rod 1301501 and the right side of the outer surface of the second telescopic rod 1301504 are provided with limit blocks, the left side of the inner surface of the sleeve 1301502 and the right side of the inner surface of the sleeve are provided with limit blocks, shaking in the cutting process is prevented, and meanwhile the spring is prevented from pushing the first telescopic rod 1301501 and the second telescopic rod 1301504 out to be separated from the sleeve 1301502.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention to achieve the above technical effects.

Claims

1. The utility model provides an injection mold's flask blowing mould flash device, includes the support frame, the water tank, the water pump, the processing cabin, double-line guide and control display, its characterized in that: the device comprises a stepping motor, a poking-in separating mechanism, a first die pushing mechanism, a first bevel gear, a first transmission rod, a second bevel gear and a second die pushing mechanism; the left side of the top end of the support frame is connected with the water tank through a bolt; the left side of the top end of the support frame is connected with a water pump through a bolt, and the left end of the water pump is connected with a water tank through a water pipe; the right part of the top end of the support frame is welded with the processing cabin; the left middle part of the front end of the support frame is welded with the double-line guide rail, and the outer surface of the right upper part of the double-line guide rail is connected with the processing cabin; the top of the left end of the processing cabin is connected with a control display through a bolt; the left side of the bottom end in the processing cabin is connected with a stepping motor through a bolt; the middle part in the processing cabin is provided with a poking-in separation mechanism, and the bottom end of the poking-in separation mechanism is connected with a stepping motor; the left end in the processing cabin is rotationally connected with the first die pushing mechanism through the mounting seat; a first bevel gear is arranged at the lower left part in the processing cabin, and the top of the left end of the first bevel gear is connected with a first mold pushing mechanism; the right end in the processing cabin is rotationally connected with the second die pushing mechanism through a mounting seat; the middle part of the right end of the first bevel gear is inserted into the first transmission rod, and the outer surface of the first transmission rod is connected with the processing cabin through the mounting seat; the right end of the first transmission rod is spliced with the second bevel gear, and the top of the right end of the second bevel gear is connected with the second die pushing mechanism;

2. A blow mold flash unit for a flask of an injection mold as in claim 1, wherein the paddle is configured in a rearwardly concave arc shape and the right-hand portion of the top end of the paddle is configured with a convex baffle.

3. A device for blowing flash onto a flask in an injection mold as in claim 2, wherein a cylindrical driver is provided on the left upper portion of the bottom end of the first profile wheel.

4. A flask blow molding flash device of an injection mold according to claim 3, wherein the left side of the outer surface of the first telescopic rod and the right side of the outer surface of the second telescopic rod are both provided with a limiting block, and the left side of the inner surface of the sleeve and the right side of the inner surface of the sleeve are both provided with a limiting block.