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CN-224224368-U - Ladle installation positioning mechanism for rubber boot forming

CN224224368UCN 224224368 UCN224224368 UCN 224224368UCN-224224368-U

Abstract

The utility model discloses a steel ladle installation positioning mechanism for rubber boots, which relates to the technical field of rubber boots production and comprises a steel ladle installation mechanism, wherein the steel ladle installation mechanism comprises a first connecting frame, a second connecting frame is symmetrically connected to one end of the first connecting frame, two groups of second connecting frames are connected to the inner side surfaces of the second connecting frames, a rotary ladle clamping and bearing seat are arranged between the two groups of side frames, and steel ladles matched with the head of a lower core mold through the steel ladle installation mechanism are stably installed on the lower core mold, so that an integral structure of a boot body and the steel ladles is formed through integral injection molding during boot body injection molding.

Inventors

  • ZONG YONGJIANG
  • CHEN HUANGUANG
  • LI LIFENG

Assignees

  • 郎溪润祥橡胶新材料有限公司

Dates

Publication Date
20260512
Application Date
20250516

Claims (10)

  1. 1. The steel ladle installation positioning mechanism for rubber boot forming is characterized by comprising a steel ladle installation mechanism (8), wherein the steel ladle installation mechanism (8) comprises a first connecting frame (81), one end of the first connecting frame (81) is symmetrically connected with a second connecting frame (82), and the inner side surfaces of the two groups of the second connecting frames (82) are respectively connected with a side frame (83); A rotary clamping bag (84) and a bearing seat (85) are arranged between the two groups of side frames (83).
  2. 2. The steel ladle installation positioning mechanism for rubber boot molding according to claim 1, wherein two groups of the second connecting frames (82) are arranged at ninety degrees with the first connecting frames (81).
  3. 3. The ladle installation positioning mechanism for rubber boot molding according to claim 1, wherein the rotary ladle (84) is arranged above the bearing seat (85).
  4. 4. The ladle installation positioning mechanism for rubber boot molding according to claim 1, wherein the rotary clamp (84) is rotatably arranged between two sets of the side frames (83).
  5. 5. The steel ladle installation and positioning mechanism for rubber boot molding according to claim 4, wherein the rotary clamping bag (84) is rotatably connected with two groups of side frames (83) through connecting shafts at two sides, and a coil spring (86) is arranged between the connecting shaft at the outer side of the rotary clamping bag (84) and the inner side surface of the side frame (83) at the corresponding side.
  6. 6. The ladle installation positioning mechanism for rubber boot molding according to claim 5, wherein one end of the coil spring (86) is connected with the side frame (83), the other end of the coil spring (86) is connected with the corresponding side face of the rotary collet (84), and the coil spring (86) is sleeved on the corresponding connecting shaft.
  7. 7. The ladle installation positioning mechanism for rubber boot molding according to claim 1 or 6, wherein an adsorption assembly is arranged on one side of the bearing seat (85); The adsorption component is used for adsorbing the steel ladle during steel ladle clamping, and releasing the steel ladle after positioning and mounting the steel ladle.
  8. 8. The steel ladle installation positioning mechanism for rubber boot forming according to claim 7, wherein the adsorption assembly comprises a supporting frame (87), an air pipe (88) is horizontally arranged at the top of the supporting frame (87) in a sliding mode, a vacuum adsorption head is arranged at one end, close to the steel ladle (9), of the air pipe (88), and an external air source is communicated with the other end of the air pipe (88).
  9. 9. The steel ladle installation positioning mechanism for rubber boot molding according to claim 8, wherein a clamping table is arranged at one end of the air pipe (88), and a return spring (89) is arranged between the clamping table and the supporting frame (87).
  10. 10. The steel ladle installation positioning mechanism for rubber boot forming according to claim 1, wherein two groups of side frames (83) are connected and rotationally connected with the second connecting frame (82); The outer side surface of any group of the second connecting frames (82) is provided with a motor; The motor drives the side frame (83) to deflect, and the installation angle of the ladle (9) is adjusted.

Description

Ladle installation positioning mechanism for rubber boot forming Technical Field The utility model relates to the technical field of rubber boot production, in particular to a steel ladle installation positioning mechanism for rubber boot molding. Background Conventional rubber boots are a typical type of protective boot, and are usually manufactured by manually adhering various rubber sheets, liners, soles and the like of the rubber boot to a boot last on a simple production line by workers, and vulcanizing the rubber sheets, the liners, the soles and the like by a vulcanizing tank. However, with the improvement of industrial safety standards and the increase of demands of consumers on protective performance, the structural design and production process of the traditional rubber boots gradually expose the defect that the boots heads of the traditional rubber boots are generally integrally formed by pure rubber or composite materials, and although the requirements of basic water resistance and skid resistance can be met, the traditional rubber boots still have obvious potential safety hazards in high-risk operation scenes. For example, in special scenes such as construction sites, mining or fire fighting, operators may face risks such as falling of heavy objects, penetration of sharp objects or extrusion impact, and the pure rubber boots are difficult to effectively resist external impact force or penetration of sharp objects due to insufficient hardness of materials, so that foot injuries are easily caused. Although the integral injection molding die of the rubber boot is gradually introduced in the industry, the efficiency and quality defects of the traditional manual production are overcome, the existing die can only realize the molding of the rubber boot basic structure, and the protective components such as the steel ladle head and the like cannot be directly integrated. In the traditional process, the steel toe cap is fixed inside the boot head through secondary assembly (such as gluing or riveting), so that the production efficiency is low, the assembly precision is greatly influenced by the operation level of workers, the problems of shifting or falling off of the steel toe cap and the like are easily caused, and the protection reliability of products is further weakened. Disclosure of utility model The utility model aims to provide a ladle installation positioning mechanism for rubber boot molding, which solves the technical problems that the existing mold can only realize molding of a rubber boot foundation structure and cannot directly integrate protective components such as a ladle head and the like. The aim of the utility model can be achieved by the following technical scheme: The steel ladle installation positioning mechanism for rubber boot forming comprises a steel ladle installation mechanism, wherein the steel ladle installation mechanism comprises a first connecting frame, a second connecting frame is symmetrically connected to one end of the first connecting frame, and side frames are connected to the inner side surfaces of the two connecting frames; and a rotary clamping bag and a bearing seat are arranged between the two groups of side frames. As a further scheme of the utility model, the two groups of connecting frames II are arranged at ninety degrees with the connecting frame I. As a further scheme of the utility model, the rotary clamp is arranged above the bearing seat. As a further scheme of the utility model, the rotary clamp is rotatably arranged between two groups of side frames. As a further scheme of the utility model, the rotary clamp is rotationally connected with two groups of side frames through connecting shafts at two sides, and a coil spring is arranged between the connecting shaft at the outer side of the rotary clamp and the inner side surface of the side frame at the corresponding side. As a further proposal of the utility model, one end of the coil spring is connected with the side frame, the other end of the coil spring is connected with the corresponding side face of the rotary clamp packet, and the coil spring is sleeved on the corresponding connecting shaft. As a further scheme of the utility model, one side of the bearing seat is provided with an adsorption component; The adsorption component is used for adsorbing the steel ladle during steel ladle clamping, and releasing the steel ladle after positioning and mounting the steel ladle. As a further scheme of the utility model, the adsorption component comprises a support frame, an air pipe is horizontally arranged at the top of the support frame in a sliding manner, a vacuum adsorption head is arranged at one end of the air pipe, which is close to the steel ladle, and the other end of the air pipe is communicated with an external air source. As a further scheme of the utility model, one end of the air pipe is provided with a clamping table, and a return spring is arranged between the clamping table and the su