CN118527617A - Hanging hanger die-casting device for clothing processing - Google Patents

Abstract

The invention relates to the technical field of die casting equipment, and discloses a die device, which comprises a lower die and an upper die, wherein a pushing rod is connected in a pushing hole in a sliding manner, a limiting ring is fixedly connected in the lower die, the limiting ring is arranged at one end of the pushing hole, one side of the pushing rod is fixedly connected with a connecting plate, one side of the connecting plate is fixedly connected with a driving spring, the other end of the driving spring is fixedly connected to the lower die, one side of the upper die is provided with a first sliding rod, the rotating device comprises a chassis fixedly connected to one side of the lower die, the other side of the chassis is fixedly connected with an output shaft of a driving motor, the first sliding rod is connected in a track groove in a sliding manner, the track groove is formed in an outer ring, a groove and a convex block are arranged on the outer ring, the outer ring is arranged at one end of the first sliding rod, and the die is provided with a plurality of processing dies.

Description

A die-casting device for hanging hangers for garment processing

Technical Field

The invention relates to the technical field of die-casting equipment, in particular to a die-casting device for a hanger used for garment processing and hanging.

Background Art

The die-casting device for hanging hangers for garment processing is a device specially used to produce hangers required in garment processing. This device can efficiently and accurately manufacture hangers that meet the requirements through the die-casting process.

Die casting device, also known as die casting machine, is an important equipment used to manufacture metal castings. Its working principle is to heat the metal material to a liquid or semi-liquid state, and then use the high pressure of the die casting machine to spray the molten metal into a pre-prepared mold, and then cool and solidify in the mold to obtain the desired casting.

The die-casting device in the prior art needs to take the material out of the mold through a material taker after the die-casting is completed, and spray a certain release agent into the mold through an external device to prevent the next die-casting from sticking to the mold. However, this processing procedure has many processes and a long working cycle, resulting in low production efficiency; therefore, it does not meet the existing needs. In this regard, we propose a die-casting casting device for a hanger for clothing processing and hanging.

Summary of the invention

The present invention provides a die-casting device for a hanger for garment processing and hanging, which has the beneficial effects of setting up multiple processing molds and realizing uninterrupted processing through the driving resistance of an outer ring, and having different functions when the mold moves to different positions of the outer ring, thereby solving the problem of low production efficiency caused by the large number of existing processing steps and long working cycle mentioned in the above background technology.

The present invention provides the following technical solution: a die-casting device for a hanger for garment processing and hanging, comprising a mold device, the mold device comprising a lower mold and an upper mold, one side of the lower mold is fixedly connected with a positioning pin, the upper mold is plugged on the positioning pin, an injection hole and a push port are provided in the lower mold, a push rod is slidably connected in the push port, a limiting ring is fixedly connected in the lower mold, the limiting ring is arranged at one end of the push port, one side of the push rod is fixedly connected with a connecting plate, one side of the connecting plate is fixedly connected with a driving spring, the other end of the driving spring is fixedly connected to the lower mold, one side of the upper mold is provided with a No. 1 slide bar, and the No. 1 slide bar is arranged in a rotating device;

The rotating device comprises a chassis fixedly connected to one side of the lower mold, the other side of the chassis is fixedly connected to the output shaft of the driving motor, the first slide bar is slidably connected in the track groove, the track groove is opened in the outer ring, the outer ring is provided with a groove and a convex block, and the outer ring is provided at one end of the first slide bar;

A pushing component is provided in the pushing rod, and the pushing component includes a hydraulic groove opened in the pushing rod, a hydraulic rod is slidably connected in the hydraulic groove, one end of the hydraulic rod abuts against the outer ring, one side of the hydraulic groove is connected with a pushing groove through a No. 1 hose and a hydraulic channel, an I-shaped pushing block is slidably connected in the pushing groove, a No. 2 spring is fixedly connected to one side of the I-shaped pushing block, and the other end of the No. 2 spring is fixedly connected in the pushing groove.

As an optional solution of the die-casting casting device of a hanger for garment processing and hanging described in the present invention, the sliding rod No. 1 includes an outer rod and an inner rod, one end of the inner rod is fixedly connected to one side of the upper mold, the inner rod is inserted in the outer rod, the outer rod is inserted in the track groove, one side of the inner rod is fixedly connected to a spring No. 1, the other end of the spring No. 1 is fixedly connected to the outer rod, a limiting groove is provided in the outer rod, a limiting block is slidably connected in the limiting groove, and the limiting block is fixedly connected to the inner rod.

As an optional solution of the die-casting casting device for a hanger for garment processing and hanging described in the present invention, one end of the hydraulic rod is fixedly connected to a hydraulic high-strength spring, the other end of the hydraulic high-strength spring is fixedly connected to the hydraulic groove, one side of the hydraulic groove is connected to the No. 1 hose, the other end of the No. 1 hose is connected to the hydraulic channel, the hydraulic channel is opened in the lower mold, and the other end of the hydraulic channel is connected to the top material groove.

As an optional scheme of the die-casting casting device of a hanger for garment processing and hanging described in the present invention, wherein: a spraying component is arranged on the I-shaped top material block, and the spraying component includes a slide groove opened in the I-shaped top material block, a spraying head is slidably connected in the slide groove, a spraying wedge is fixedly connected to one side of the spraying head, a No. 3 spring is fixedly connected to one side of the spraying wedge, and the other end of the No. 3 spring is fixedly connected to the spring groove, and the spring groove is opened on the I-shaped top material block, a blocking plate is arranged at one end of the spraying head, and the blocking plate is rotatably connected to a fixed shaft, the blocking plate and the fixed shaft are connected by a torsion spring, and the fixed shaft is fixedly connected to the I-shaped top material block at the slide groove.

As an optional scheme of the die-casting casting device of a hanger for garment processing and hanging described in the present invention, the sliding of the spray head in the slide groove is driven by a telescopic driving component, and the telescopic driving component includes a mounting groove opened in the I-shaped top material block, and a No. 2 transmission wedge block is slidably connected in the mounting groove, one end of the No. 2 transmission wedge block abuts against the spray wedge block, and the other end of the No. 2 transmission wedge block is fixedly connected to a transmission rod, and the other end of the transmission rod is fixedly connected to a No. 1 transmission wedge block, one side of the No. 1 transmission wedge block abuts against a driving wedge rod, and the driving wedge rod is slidably connected in the driving groove, and the driving groove is opened in the I-shaped top material block.

As an optional solution of the die-casting casting device for a hanger for garment processing and hanging described in the present invention, one end of the driving wedge rod is provided with a telescopic ring, the telescopic ring is slidably connected in the telescopic shell, the telescopic shell is fixedly connected in the lower mold, the telescopic shell is located in the top material trough, one end of the telescopic ring is fixedly connected to a No. 4 spring, and the other end of the No. 4 spring is fixedly connected in the telescopic shell.

As an optional solution of the die-casting casting device for a garment processing and hanging hanger described in the present invention, the sliding of the driving wedge rod in the driving groove is restricted by a limiting device, and the limiting device includes a limiting groove opened in the I-beam top block, and a limiting plate is slidably connected in the limiting groove, and the limiting plate is fixedly connected to the driving wedge rod, and a limiting spring is fixedly connected to one side of the limiting plate, and the other end of the limiting spring is fixedly connected in the limiting groove.

As an optional scheme of the die-casting casting device of a hanger for garment processing and hanging described in the present invention, wherein: a feeding component is arranged on one side of the spray head, and the feeding component includes a No. 2 hose arranged on one side of the spray head, and the No. 2 hose is arranged in a buffer groove, and the buffer groove is arranged in the I-shaped top material block, and the other end of the No. 2 hose is connected with a connecting channel, and the connecting channel is arranged on the I-shaped top material block, and the other end of the connecting channel is connected with a storage bin, and the storage bin is arranged in the I-shaped top material block, and the storage bin is connected with a feeding channel, and the feeding channel is arranged in the I-shaped top material block, and the other end of the feeding channel is connected with a feeding straight pipe, and the feeding straight pipe is fixedly connected to the bottom surface of the I-shaped top material block, and the feeding straight pipe is slidably connected in the sliding groove, and the sliding groove is arranged in the lower mold.

As an optional solution of the die-casting casting device of a hanger for garment processing and hanging described in the present invention, a spiral device is arranged between the top material groove and the I-shaped top material block, and the spiral device includes a straight groove and a spiral groove opened in the lower mold, and the straight groove is connected to the spiral groove, and a guide block is slidably connected between the straight groove and the spiral groove, and the guide block is fixedly connected to the I-shaped top material block.

The present invention has the following beneficial effects:

1. The die-casting device for hanging hangers for garment processing drives the chassis to rotate by driving a motor, so that the mold device on the chassis can rotate around the inner wall of the outer ring. When the mold device rotates to different positions, the inner wall of the outer ring and the height of the track groove change to enable the mold device to achieve different functions. When the mold device rotates to the groove, the injection hole is injected with material through an external device. When the mold device leaves the groove, the raw material can be pushed into the mold by sliding the push rod. When the mold device rotates to the convex block, the I-shaped ejector rod can be driven to separate the cooled and formed product from the mold by sliding the hydraulic rod.

2. The die-casting device for hanging hangers for garment processing can improve the spraying range of the inner wall of the lower mold by arranging multiple groups of water spray components on the I-shaped top material block. The spray head with telescopic design will not affect the normal sliding of the I-shaped top material block in the top material groove. The drive of the spray component by the telescopic driving component starts when the spray head on the I-shaped top material block extends out of the top material groove. After the I-shaped top material block rises a certain distance, the driving wedge rod at the bottom of the I-shaped top material block will contact one side of the telescopic ring, and the telescopic ring is driven by the No. 4 spring. Always apply a certain pressure downward, at this time the driving wedge rod will slide to the right and hit the No. 1 transmission wedge, thereby driving the No. 1 transmission wedge to slide up and down in the installation groove. Since the No. 1 transmission wedge is connected to the No. 2 transmission wedge through the transmission rod, and one side of the No. 2 transmission wedge hits the spray wedge fixedly connected to the spray head, through the above series of transmissions, it can be achieved that the spray head extends out of the slide slot only after the I-shaped top material block rises a distance from one end. This transmission method ensures that the extension of the spray head will not affect the sliding of the I-shaped top material block.

3. The die-casting device for the garment processing and hanging hanger, through the design of the spiral groove and the guide block, allows the I-shaped top block to rotate during the rising process. This rotation allows the spray head on the I-shaped top block to rotate and spray, thereby increasing the spraying range of the release agent. The design of the straight groove is to ensure that the rotation of the spray head is performed after the I-shaped top block is extended, so as to prevent the rotating spray head from causing the I-shaped top block to fail to rise normally.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic structural diagram of the present invention.

FIG. 2 is a schematic diagram of the structure of the present invention from above.

FIG. 3 is a schematic diagram of the outer ring structure of the present invention.

FIG. 4 is a schematic diagram of the structure of a slide bar No. 1 of the present invention.

FIG5 is a schematic diagram of the cross-sectional structure of line 1-1 in FIG4 of the present invention.

FIG. 6 is a schematic diagram of the structure of mold No. 1 of the present invention.

FIG. 7 is a schematic diagram of the structure of the lower mold viewed from above according to the present invention.

FIG8 is a schematic diagram of the three-dimensional structure of the section 2-2 in FIG7 of the present invention.

FIG9 is a schematic diagram of the planar structure of section 2-2 in FIG7 of the present invention.

FIG. 10 is a schematic diagram of the enlarged structure of point A in FIG. 9 of the present invention.

FIG. 11 is a schematic diagram of the enlarged structure of point B in FIG. 9 of the present invention.

FIG. 12 is a schematic diagram of the enlarged structure of point C in FIG. 11 of the present invention.

FIG. 13 is a schematic diagram of the enlarged structure of point E in FIG. 12 of the present invention.

FIG. 14 is a schematic diagram of the enlarged structure of point D in FIG. 11 of the present invention.

FIG. 15 is a schematic diagram of the structure of the I-shaped ejector rod of the present invention.

FIG. 16 is a schematic diagram of the cross-sectional structure of the lower mold of the present invention.

FIG17 is a schematic diagram of the cross-sectional structure taken along line 3-3 in FIG7 of the present invention.

FIG. 18 is a schematic diagram of the enlarged structure of point F in FIG. 17 of the present invention.

In the figure: 1. mold device; 101. lower mold; 102. upper mold; 103. positioning pin; 104. No. 1 slide bar; 1041. outer rod; 1042. inner rod; 1043. No. 1 spring; 1044. limit groove; 1045. limit block; 105. push rod; 106. injection hole; 107. push port; 108. limit ring; 109. connecting plate; 110. driving spring; 2. rotation device; 201, chassis; 202, drive motor; 203, outer ring; 204, groove; 205, convex block; 206, track groove; 3, ejector component; 301, hydraulic groove; 302, hydraulic rod; 303, hydraulic high-strength spring; 304, No. 1 hose; 305, hydraulic channel; 306, ejector groove; 307, I-shaped ejector block; 308, No. 2 spring; 4, spraying component; 401, slide groove ; 402, spray head; 403, spray wedge; 404, spring slot; 405, spring No. 3; 406, fixed shaft; 407, blocking plate; 408, torsion spring; 5, telescopic drive member; 501, mounting slot; 502, telescopic housing; 503, telescopic ring; 504, spring No. 4; 505, drive slot; 506, drive wedge rod; 507, transmission rod; 508, drive wedge No. 1; 509, Transmission wedge No. 2; 510, limiting device; 5101, limiting groove; 5102, limiting plate; 5103, limiting spring; 6, spiral device; 601, straight groove; 602, spiral groove; 603, guide block; 7, feeding component; 701, feeding straight pipe; 702, sliding groove; 703, feeding channel; 704, storage bin; 705, connecting channel; 706, No. 2 hose; 707, buffer tank.

DETAILED DESCRIPTION

The following will be combined with the drawings in the embodiments of the present invention to clearly and completely describe the technical solutions in the embodiments of the present invention. Obviously, the described embodiments are only part of the embodiments of the present invention, not all of the embodiments. Based on the embodiments of the present invention, all other embodiments obtained by ordinary technicians in this field without creative work are within the scope of protection of the present invention.

Embodiment 1: This embodiment is intended to promote the solution of the problem of low production efficiency caused by more processing steps and long working cycle, please refer to Figures 1-18, including a mold device 1, the mold device 1 includes a lower mold 101 and an upper mold 102, one side of the lower mold 101 is fixedly connected with a positioning pin 103, the upper mold 102 is plugged on the positioning pin 103, an injection hole 106 and a push port 107 are opened in the lower mold 101, a push rod 105 is slidably connected in the push port 107, a limit ring 108 is fixedly connected in the lower mold 101, the limit ring 108 is arranged at one end of the push port 107, one side of the push rod 105 is fixedly connected with a connecting plate 109, one side of the connecting plate 109 is fixedly connected with a driving spring 110, the other end of the driving spring 110 is fixedly connected to the lower mold 101, one side of the upper mold 102 is fixedly connected with a No. 1 slide bar 104, and the No. 1 slide bar 104 is arranged in the rotating device 2;

The rotating device 2 includes a chassis 201 fixedly connected to one side of the lower mold 101, and the output shaft of the driving motor 202 is fixedly connected to the other side of the chassis 201. The first slide bar 104 is slidably connected in the track groove 206, and the track groove 206 is opened in the outer ring 203. The outer ring 203 is provided with a groove 204 and a protrusion 205. The outer ring 203 is arranged at one end of the first slide bar 104;

A pushing member 3 is arranged in the pushing rod 105, and the pushing member 3 includes a hydraulic groove 301 opened in the pushing rod 105, a hydraulic rod 302 is slidably connected in the hydraulic groove 301, one end of the hydraulic rod 302 abuts against the outer ring 203, one side of the hydraulic groove 301 is connected with a pushing groove 306 through a No. 1 hose 304 and a hydraulic channel 305, an I-shaped pushing block 307 is slidably connected in the pushing groove 306, a No. 2 spring 308 is fixedly connected to one side of the I-shaped pushing block 307, and the other end of the No. 2 spring 308 is fixedly connected in the pushing groove 306.

One end of the hydraulic rod 302 is fixedly connected to a hydraulic high-strength spring 303, and the other end of the hydraulic high-strength spring 303 is fixedly connected to the hydraulic groove 301. One side of the hydraulic groove 301 is connected to a No. 1 hose 304, and the other end of the No. 1 hose 304 is connected to a hydraulic channel 305. The hydraulic channel 305 is opened in the lower mold 101, and the other end of the hydraulic channel 305 is connected to a top material groove 306.

The driving motor 202 drives the chassis 201 to rotate, so that the mold device 1 on the chassis 201 can rotate around the inner wall of the outer ring 203. When the mold device 1 rotates to different positions, the changes in the inner wall of the outer ring 203 and the height of the track groove 206 will enable the mold device 1 to achieve different functions.

When the mold device 1 rotates to the groove 204, material is injected into the injection hole 106 through an external device. At this time, the push rod 105 is driven by the connecting plate 109 and the driving spring 110 to contact the groove 204. When the driving motor 202 drives to rotate, due to the height change of the outer ring 203, the inner wall of the outer ring 203 will contact and drive the hydraulic rod 302 in the push rod 105. Since the hydraulic rod 302 is connected to the hydraulic groove 301 through the hydraulic high-strength spring 303, the outer ring 203 will push the hydraulic rod 302 and the push rod 105 to slide in the push port 107 at the same time. At this time, the raw material injected into the push port 107 through the injection hole 106 will enter the combined mold under the push of the push rod 105.

Under the continued drive of the driving motor 202, the mold device 1 rotates to the protrusion 205. At this time, the push rod 105 slides to one end of the push port 107 under the resistance of the protrusion 205, and one end of the push rod 105 resists on the limit ring 108 in the push port 107. The push rod 105 cannot continue to slide. At this time, the outer ring 203 can only drive the hydraulic rod 302 to slide in the hydraulic groove 301. Since the hydraulic groove 301 is connected to the ejection groove 306 through the No. 1 hose 304 and the hydraulic channel 305, and the ejection groove 306 is slidably connected with an I-shaped ejection block 307, the sliding of the hydraulic rod 302 will drive the I-shaped ejection block 307 to slide in the ejection groove 306. Through this transmission, the cooled and formed product can be separated from the mold.

During this process, the No. 1 slide bar 104 on one side of the upper mold 102 slides in the track groove 206, and the height of the track groove 206 at the protrusion 205 will rise a certain distance, and when it leaves the protrusion 205, it will return to its original position. Through this change of the track groove 206, the No. 1 slide bar 104 sliding in the track groove 206 will drive the upper mold 102 to slide upward. Through this sliding, the upper and lower molds can be opened, so that the I-shaped ejector block 307 can eject the processed material, and the material removal machine can also take out the material.

The No. 1 slide bar 104 includes an outer rod 1041 and an inner rod 1042. The inner rod 1042 is inserted into the outer rod 1041. One end of the inner rod 1042 is fixedly connected to one side of the upper mold 102. The outer rod 1041 is inserted into the track groove 206. One side of the inner rod 1042 is fixedly connected to a No. 1 spring 1043. The other end of the No. 1 spring 1043 is fixedly connected to the outer rod 1041. A limiting groove 1044 is provided in the outer rod 1041. A limiting block 1045 is slidably connected in the limiting groove 1044. The limiting block 1045 is fixedly connected to the inner rod 1042.

The No. 1 slide bar 104 is composed of an outer rod 1041 and an inner rod 1042, and the outer rod 1041 and the inner rod 1042 are connected by a No. 1 spring 1043 to ensure that the No. 1 spring 1043 always applies a certain elastic force to the inner rod 1042. This elastic force can effectively drive the upper mold 102 to always fit with the lower mold 101 to ensure the sealing during mold closing and liquid injection. The limitation of the limit groove 1044 and the limit block 1045 can effectively prevent the inner rod 1042 from shaking left and right in the outer rod 1041.

Embodiment 2: This embodiment is intended to facilitate solving the problem of driving the nozzle to extend and spray the stripping agent into the mold after die casting is completed. This embodiment is an explanation based on Embodiment 1. For details, please refer to FIGS. 1-18.

A spraying component 4 is provided on the I-shaped top material block 307, and the spraying component 4 includes a slide groove 401 opened in the I-shaped top material block 307, a spraying head 402 is slidably connected in the slide groove 401, a spraying wedge 403 is fixedly connected to one side of the spraying head 402, a No. 3 spring 405 is fixedly connected to one side of the spraying wedge 403, and the other end of the No. 3 spring 405 is fixedly connected in the spring groove 404, and the spring groove 404 is opened on the I-shaped top material block 307. A blocking plate 407 is provided at one end of the spraying head 402, and the blocking plate 407 is rotatably connected to the fixed shaft 406. The blocking plate 407 and the fixed shaft 406 are connected by a torsion spring 408, and the fixed shaft 406 is fixedly connected to the I-shaped top material block 307 at the slide groove 401.

The sliding of the spray head 402 in the slide groove 401 is driven by the telescopic driving component 5, and the telescopic driving component 5 includes a mounting groove 501 opened in the I-shaped top material block 307, and a No. 2 transmission wedge block 509 is slidably connected in the mounting groove 501, and one end of the No. 2 transmission wedge block 509 abuts against the spray wedge block 403, and the other end of the No. 2 transmission wedge block 509 is fixedly connected to a transmission rod 507, and the other end of the transmission rod 507 is fixedly connected to a No. 1 transmission wedge block 508, and one side of the No. 1 transmission wedge block 508 abuts against a driving wedge rod 506, and the driving wedge rod 506 is slidably connected in the driving groove 505, and the driving groove 505 is opened in the I-shaped top material block 307.

A telescopic ring 503 is provided at one end of the driving wedge rod 506, and the telescopic ring 503 is slidably connected in the telescopic shell 502, and the telescopic shell 502 is fixedly connected in the lower mold 101. The telescopic shell 502 is located in the top material groove 306, and one end of the telescopic ring 503 is fixedly connected to a No. 4 spring 504, and the other end of the No. 4 spring 504 is fixedly connected in the telescopic shell 502.

By arranging multiple groups of spraying components 4 on the I-shaped top material block 307, the spraying range of the inner wall of the lower mold 101 can be increased. The spraying head 402 with a telescopic design will not affect the normal sliding of the I-shaped top material block 307 in the top material groove 306. The driving of the spraying component 4 by the telescopic driving component 5 starts when the spraying head 402 on the I-shaped top material block 307 extends out of the top material groove 306. After the I-shaped top material block 307 rises a certain distance, the driving wedge rod 506 located at the bottom of the I-shaped top material block 307 will contact one side of the telescopic ring 503, and the telescopic ring 503 is driven by the No. 4 spring 504 to always exert a certain pressure downward. At this time, the driving wedge rod 506 at the bottom of the I-shaped top material block 307 will contact the telescopic ring 503. The movable wedge rod 506 will slide to the right (refer to Figure 14) and abut against the No. 1 transmission wedge block 508, thereby driving the No. 1 transmission wedge block 508 to slide up and down in the installation groove 501. Since the No. 1 transmission wedge block 508 is connected to the No. 2 transmission wedge block 509 through the transmission rod 507, and one side of the No. 2 transmission wedge block 509 abuts against the spray wedge block 403 fixedly connected to the spray head 402, through the above series of transmissions, it can be achieved that the process of the spray head 402 extending out of the slide groove 401 starts only after the I-shaped top material block 307 rises a distance at one end. This transmission method ensures that the extension of the spray head 402 will not affect the sliding of the I-shaped top material block 307.

Driven by the telescopic driving member 5, the spray head 402 slides in the slide groove 401. Before the spray head 402 is extended, one end of the spray head 402 is blocked by the blocking plate 407, which makes the spray head 402 unable to spray the demolding agent, thereby preventing liquid leakage. During the sliding of the spray head 402, the spray head 402 contacts the blocking plate 407 and drives the blocking plate 407 to rotate around the fixed shaft 406. At this time, the blocking plate 407 no longer blocks the spray head 402. At this time, the demolding agent can be sprayed into the lower mold 101 under the supply of the feeding member 7 to facilitate the material taking of the material taker. The fixed shaft 406 and the blocking plate 407 are connected by the torsion spring 408, which can effectively ensure that the blocking plate 407 has a blocking effect on the spray head 402 when it is not driven.

The sliding movement of the driving wedge rod 506 in the driving groove 505 is restricted by the limiting device 510, and the limiting device 510 includes a limiting groove 5101 opened in the I-shaped top block 307, and a limiting plate 5102 is slidably connected in the limiting groove 5101. The limiting plate 5102 is fixedly connected to the driving wedge rod 506, and a limiting spring 5103 is fixedly connected to one side of the limiting plate 5102, and the other end of the limiting spring 5103 is fixedly connected in the limiting groove 5101.

Through the design of the limiting groove 5101 and the limiting plate 5102, the sliding range of the driving wedge rod 506 is effectively limited to prevent the driving wedge rod 506 from sliding out of the driving groove 505. At the same time, the design of the limiting spring 5103 ensures that the driving wedge rod 506 is effectively reset when the telescopic ring 503 does not apply drive to the driving groove 505.

A feeding component 7 is provided on one side of the spray head 402, and the feeding component 7 includes a No. 2 hose 706 provided on one side of the spray head 402, the No. 2 hose 706 is provided in a buffer groove 707, the buffer groove 707 is opened in the I-shaped top material block 307, the other end of the No. 2 hose 706 is connected with a connecting channel 705, the connecting channel 705 is opened on the I-shaped top material block 307, the other end of the connecting channel 705 is connected with a storage bin 704, the storage bin 704 is opened in the I-shaped top material block 307, the storage bin 704 is connected with a feeding channel 703, the feeding channel 703 is opened in the I-shaped top material block 307, the other end of the feeding channel 703 is connected with a feeding straight pipe 701, the feeding straight pipe 701 is fixedly connected to the bottom surface of the I-shaped top material block 307, the feeding straight pipe 701 is slidably connected in the sliding groove 702, and the sliding groove 702 is opened in the lower mold 101.

The feeding component 7 is used to provide the required demoulding agent for the spray head 402. The demoulding agent enters the mold through the feeding straight pipe 701. The feeding straight pipe 701 is made of hard material. If a hose is used, the feeding straight pipe 701 may be bent and stuck when sliding in the sliding groove 702. The demoulding agent in the feeding straight pipe 701 enters the storage bin 704 through the feeding channel 703. The storage bin 704 serves as a transfer bin to provide raw materials for the spray head 402. The storage bin 704 is connected to multiple groups of connecting channels 705 and No. 2 hoses 706 to provide demoulding agents for multiple groups of spray heads 402.

Embodiment 3: This embodiment is intended to promote the solution of the problem that the nozzle can rotate to spray material by rotating the ejecting rod. This embodiment is an explanation based on Embodiment 2. For details, please refer to FIGS. 1-18.

A spiral device 6 is arranged between the ejection groove 306 and the I-shaped ejection block 307. The spiral device 6 includes a straight groove 601 and a spiral groove 602 opened in the lower mold 101. The straight groove 601 is connected to the spiral groove 602. A guide block 603 is slidably connected in the straight groove 601 and the spiral groove 602. The guide block 603 is fixedly connected to the I-shaped ejection block 307.

Through the design of the spiral groove 602 and the guide block 603, the I-shaped top material block 307 can rotate during the rising process. This rotation allows the spray head 402 on the I-shaped top material block 307 to rotate and spray, thereby increasing the spraying range of the release agent. The design of the straight groove 601 is to ensure that the rotation of the spray head 402 is performed after the I-shaped top material block 307 is extended, so as to prevent the rotating spray head 402 from causing the I-shaped top material block 307 to fail to rise normally.

It should be noted that, in this article, relational terms such as first and second, etc. are only used to distinguish one entity or operation from another entity or operation, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Moreover, the terms "include", "comprise" or any other variants thereof are intended to cover non-exclusive inclusion, so that a process, method, article or device including a series of elements includes not only those elements, but also other elements not explicitly listed, or also includes elements inherent to such process, method, article or device.

The above is only a preferred embodiment of the present invention. It should be pointed out that for ordinary technicians in this technical field, several improvements and modifications can be made without departing from the technical principles of the present invention. These improvements and modifications should also be regarded as the scope of protection of the present invention.

Claims (9)

1. The utility model provides a garment processing is hung and is used hoist die-casting device, includes mould device (1), its characterized in that: the die device (1) comprises a lower die (101) and an upper die (102), one side of the lower die (101) is fixedly connected with a positioning pin (103), the upper die (102) is inserted on the positioning pin (103), a material injection hole (106) and a material pushing opening (107) are formed in the lower die (101), a material pushing rod (105) is connected in the material pushing opening (107) in a sliding mode, a limiting ring (108) is fixedly connected in the lower die (101), the limiting ring (108) is arranged at one end of the material pushing opening (107), one side of the material pushing rod (105) is fixedly connected with a connecting plate (109), one side of the connecting plate (109) is fixedly connected with a driving spring (110), the other end of the driving spring (110) is fixedly connected with the lower die (101), one side of the upper die (102) is provided with a first sliding rod (104), and one end of the first sliding rod (104) is arranged in the rotating device (2);

The rotating device (2) comprises a chassis (201) fixedly connected to one side of the lower die (101), an output shaft of a driving motor (202) is fixedly connected to the other side of the chassis (201), a first sliding rod (104) is slidably connected in a track groove (206), the track groove (206) is formed in an outer ring (203), a groove (204) and a protruding block (205) are arranged on the outer ring (203), and the outer ring (203) is arranged at one end of the first sliding rod (104);

The novel hydraulic ejector is characterized in that a material ejection component (3) is arranged in the material pushing rod (105), the material ejection component (3) comprises a hydraulic groove (301) formed in the material pushing rod (105), a hydraulic rod (302) is connected in a sliding mode in the hydraulic groove (301), one end of the hydraulic rod (302) is abutted to the outer ring (203), one side of the hydraulic groove (301) is communicated with a material ejection groove (306) through a hose (304) and a hydraulic channel (305), an I-shaped material ejection block (307) is connected in the material ejection groove (306) in a sliding mode, a second spring (308) is fixedly connected to one side of the I-shaped material ejection block (307), and the other end of the second spring (308) is fixedly connected in the material ejection groove (306).

2. The die casting device for hanging tools for clothing processing according to claim 1, wherein: the first sliding rod (104) comprises an outer rod (1041) and an inner rod (1042), one end of the inner rod (1042) is fixedly connected to one side of the upper die (102), the inner rod (1042) is inserted into the outer rod (1041), the outer rod (1041) is inserted into the track groove (206), a first spring (1043) is fixedly connected to one side of the inner rod (1042), the other end of the first spring (1043) is fixedly connected to the inner rod (1041), a limiting groove (1044) is formed in the outer rod (1041), and a limiting block (1045) is connected to the inner rod (1042) in a sliding mode.

3. The die casting device for hanging tools for clothing processing according to claim 2, wherein: one end fixedly connected with hydraulic pressure high strength spring (303) of hydraulic pressure pole (302), the other end fixed connection of hydraulic pressure high strength spring (303) is in hydraulic pressure groove (301), one side intercommunication of hydraulic pressure groove (301) has hose (304) No. one, the other end intercommunication of hose (304) has hydraulic pressure passageway (305), hydraulic pressure passageway (305) are seted up in lower mould (101), the other end intercommunication of hydraulic pressure passageway (305) has liftout groove (306).

4. The die casting device for hanging tools for clothing processing according to claim 1, wherein: the novel material spraying device is characterized in that a material spraying component (4) is arranged on the I-shaped material pushing block (307), the material spraying component (4) comprises a chute (401) formed in the I-shaped material pushing block (307), a material spraying head (402) is connected in a sliding mode in the chute (401), a material spraying wedge block (403) is fixedly connected to one side of the material spraying head (402), a spring No. three (405) is fixedly connected to one side of the material spraying wedge block (403), the other end of the spring No. three (405) is fixedly connected in a spring groove (404), the spring groove (404) is formed in the I-shaped material pushing block (307), a blocking plate (407) is arranged at one end of the material spraying head (402), the blocking plate (407) is connected to a fixed shaft (406) in a rotating mode, the blocking plate (407) is connected with the fixed shaft (406) through a torsion spring (408), and the fixed shaft (406) is fixedly connected to the I-shaped material pushing block (307) and is located at the position of the chute (401).

5. The die casting device for hanging tools for clothing processing according to claim 4, wherein: the material spraying head (402) is driven by the telescopic driving component (5) in the sliding groove (401), the telescopic driving component (5) comprises a mounting groove (501) formed in the I-shaped jacking block (307), a second transmission wedge block (509) is connected in a sliding mode in the mounting groove (501), one end of the second transmission wedge block (509) is abutted to the material spraying wedge block (403), the other end of the second transmission wedge block (509) is fixedly connected with a transmission rod (507), the other end of the transmission rod (507) is fixedly connected with a first transmission wedge block (508), one side of the first transmission wedge block (508) is abutted to a driving wedge rod (506), the driving wedge rod (506) is connected in the driving groove (505) in a sliding mode, and the driving groove (505) is formed in the I-shaped jacking block (307).

6. The die casting device for hanging tools for clothing processing according to claim 5, wherein: one end of drive wedge pole (506) is provided with expansion ring (503), expansion ring (503) sliding connection is in flexible shell (502), flexible shell (502) fixed connection is in bed die (101), flexible shell (502) set up in top silo (306), the one end fixedly connected with spring (504) No. four of expansion ring (503), the other end fixed connection of spring (504) No. four is in flexible shell (502).

7. The die casting device for hanging tools for clothing processing according to claim 5, wherein: the sliding of the driving wedge rod (506) in the driving groove (505) is limited by a limiting device (510), the limiting device (510) comprises a limiting groove (5101) formed in the I-shaped ejector block (307), a limiting plate (5102) is connected in a sliding mode in the limiting groove (5101), one side of the limiting plate (5102) is fixedly connected to the driving wedge rod (506), a limiting spring (5103) is fixedly connected to one side of the limiting plate (5102), and the other end of the limiting spring (5103) is fixedly connected to the limiting groove (5101).

8. The die casting device for hanging tools for clothing processing according to claim 5, wherein: one side of the material spraying head (402) is provided with a feeding component (7), the feeding component (7) comprises a second hose (706) arranged on one side of the material spraying head (402), the second hose (706) is arranged in a buffer groove (707), the buffer groove (707) is formed in the I-shaped material spraying block (307), the other end of the second hose (706) is communicated with a connecting channel (705), the connecting channel (705) is formed in the I-shaped material spraying block (307), the other end of the connecting channel (705) is communicated with a storage bin (704), the storage bin (704) is formed in the I-shaped material spraying block (307), the storage bin (704) is communicated with a feeding channel (703), the feeding channel (703) is formed in the I-shaped material spraying block (307), the other end of the feeding channel (703) is communicated with a feeding straight pipe (701), the feeding pipe (701) is fixedly connected to the bottom surface of the I-shaped material spraying block (307), the feeding straight pipe (701) is connected to the sliding groove (702) in a sliding mode, and the feeding pipe (702) is formed in the sliding mode (702) and the sliding mode (101).

9. The die casting device for hanging tools for clothing processing according to claim 1, wherein: screw device (6) are arranged between the ejector groove (306) and the I-shaped ejector block (307), the screw device (6) comprises a straight groove (601) and a screw groove (602) which are arranged in the lower die (101), the straight groove (601) is communicated with the screw groove (602), a guide block (603) is connected in the straight groove (601) and the screw groove (602) in a sliding mode, and the guide block (603) is fixedly connected to the I-shaped ejector block (307).