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CN-224231407-U - Civil engineering sample making device

CN224231407UCN 224231407 UCN224231407 UCN 224231407UCN-224231407-U

Abstract

The utility model relates to the field of civil engineering sample manufacturing, in particular to a device for manufacturing a civil engineering sample, which comprises a bearing plate, a collecting box and an inserting block, wherein a vibrating motor for vibrating to remove concrete filling gaps is arranged at the lower end of the bearing plate. According to the utility model, the steps of spraying the release agent and injecting the concrete are carried out in the discharge groove through normal manufacturing steps, then the vibration motor is started, the gap of the concrete filled in the discharge groove is eliminated in a vibration mode, then the upper end of the discharge groove is scraped by using the scraping plate, the scraped concrete can be collected through the fixed inclined block arranged on the die and the inclined surface arranged on the collecting box, after the concrete is formed, the insert block is taken out from the insert groove by pulling the carrying bent block at the outer side on the insert block, and then the small groove is formed on the concrete block by the carrying bent block at the inner side, so that the follow-up demoulding of the concrete is facilitated.

Inventors

  • WANG YUE
  • YANG JIANWEI
  • MA HUILONG
  • MA JUNHUI
  • ZHANG LIYUAN
  • Du Cuiyan
  • ZHANG CHAO
  • YANG ZHENWEI
  • WANG BO
  • LI SHENGXUAN
  • Jia Congfei
  • WANG PEIPEI
  • LU JIAXIANG
  • QI MINGMING
  • ZHANG XUCHEN
  • LIU HANQING

Assignees

  • 河北顺诚工程建设项目管理有限公司

Dates

Publication Date
20260512
Application Date
20250530

Claims (7)

  1. 1. The civil engineering sample manufacturing device comprises a bearing plate (1) and is characterized by further comprising a collecting box (3) and an inserting block (206), wherein a vibrating motor (404) for vibrating to remove a concrete filling gap is arranged at the lower end of the bearing plate (1), two collecting boxes (3) are arranged at the upper end of the bearing plate (1), the two collecting boxes (3) are distributed in a central symmetry mode, a die (2) is arranged at the upper end of the bearing plate (1) in a limiting mode, two discharging grooves (201) for subsequent solidification forming are formed in the upper end of the die (2), fixed inclined blocks (203) are fixedly connected at the left end and the right end of the die (2), a protruding inclined block (303) is fixedly connected at the upper end of the collecting box (3), the inclined upper end of the inclined face of the protruding inclined block (303) and the inclined face of the lower end of the fixed inclined block (203) are mutually attached, an inserting groove (204) is formed at the upper end of the die (2), the inserting block (206) is arranged in the inserting groove (204) in a magnetic attraction mode, and the front end and the rear end of the inserting block (206) is fixedly connected with a carrying bent block (207).
  2. 2. The civil engineering sample preparation device according to claim 1, wherein two support columns (401) are fixedly connected to the upper end of the vibrating base plate (4), two slide bars (402) are arranged on the support columns (401) in a sliding mode, a bearing frame (403) is fixedly connected to one end, close to each other, of each of the two groups of slide bars (402), a vibrating motor (404) is arranged on the bearing frame (403), a connecting plate (405) is fixedly connected to the upper end of the bearing frame (403), the upper end of the connecting plate (405) is fixedly connected to the lower end of the bearing plate (1), and springs (406) are sleeved on the outer walls of the slide bars (402) at one end, close to each other, of the bearing frame (403) and the support columns (401).
  3. 3. The civil engineering sample preparation device according to claim 1, wherein the upper end of the bearing plate (1) is fixedly connected with four first limit posts (101), the lower end of the die (2) is provided with four first limit grooves (202), and the first limit grooves (202) and the first limit posts (101) are in one-to-one correspondence and are matched.
  4. 4. The civil engineering sample preparation device according to claim 1, wherein two studs (102) are fixedly connected to the front end and the rear end of the bearing plate (1), and a clamping block (103) for clamping the collecting box (3) and a nut (104) for fixing the clamping block (103) are sequentially arranged on the outer wall of the stud (102) in a sliding manner.
  5. 5. The civil engineering sample preparation device according to claim 3, wherein the collection box (3) is a U-shaped object, one end is fixedly connected with two second limit posts (301), the other end is provided with two second limit grooves (302), the second limit grooves (302) are mutually matched with the second limit posts (301), and the two collection boxes (3) which are symmetrical in center are inserted into the second limit grooves (302) of each other through the second limit posts (301) for lamination placement.
  6. 6. The civil engineering sample preparation device according to claim 1, wherein the upper end of the collection box (3) is fixedly connected with a convex oblique block (303), the inner wall of the convex oblique block (303) is flush with the inner wall of the collection box (3), and the inner wall of the collection box (3) is mutually attached to the four outer walls of the die (2).
  7. 7. The apparatus for producing a civil engineering sample according to claim 1, wherein a first magnet (205) is provided at a lower end of the insertion groove (204), and a second magnet (208) is provided at a lower end of the insertion block (206), and the second magnet (208) and the first magnet (205) are magnetically attracted to each other.

Description

Civil engineering sample making device Technical Field The utility model belongs to the field of civil engineering sample preparation, and particularly relates to a device for preparing a civil engineering sample. Background Sample fabrication refers to the processing of raw materials (e.g., concrete, metal, plastic, soil, etc.) into samples of a shape, size, and performance according to specific standards, specifications, or experimental requirements for subsequent physical property testing, chemical analysis, mechanical testing, or other scientific experimental procedures. In the sample preparation process, when scraping the concrete of keeping flat silo upper end, unnecessary concrete often can spill subaerial, causes environmental pollution to the clearance is got up more hard, in the in-process of concrete filling the blowing silo, often has the space between the concrete, if do not eliminate these spaces, can influence quality and the intensity of sample, however, adopts manual stirring's mode to remove the bubble during current sample preparation, and efficiency is lower, and after the shaping of concrete sample, the drawing of patterns often is a more difficult process, if the drawing of patterns is improper, can lead to sample damage or deformation. Therefore, the existing civil engineering has the problems that the ground environment is polluted by redundant concrete, the concrete gap is inconvenient to eliminate and the demoulding is difficult in the process of manufacturing the sample. Disclosure of utility model In order to solve the problems that the ground environment is polluted by redundant concrete, the concrete gap is inconvenient to eliminate and the demoulding is difficult in the process of manufacturing samples in the prior civil engineering, the device for manufacturing the civil engineering samples is provided. The technical scheme of the utility model is that the civil engineering sample manufacturing device comprises a bearing plate, a collecting box and an inserting block, wherein the lower end of the bearing plate is provided with a vibrating motor for vibrating and removing concrete filling gaps, the upper end of the bearing plate is provided with two collecting boxes which are distributed in a central symmetry manner, the upper end of the bearing plate is provided with a die in a limiting manner, the upper end of the die is provided with two discharging grooves for subsequent solidification forming, the left end and the right end of the die are fixedly connected with fixed oblique blocks, the upper ends of the collecting boxes are fixedly connected with raised oblique blocks, the upper end of the inclined faces of the raised oblique blocks are mutually attached to the inclined faces of the lower ends of the fixed oblique blocks, the upper end of the die is provided with an inserting groove, the inserting groove is internally provided with the inserting block with the size being matched in a magnetic attraction manner, and the front end and the rear end of the inserting block are fixedly connected with lifting bent blocks Preferably, the upper end of the vibration bottom plate is fixedly connected with two support columns, two slide bars are arranged on the support columns in a sliding manner, one ends of the two groups of slide bars, which are close to each other, are fixedly connected with a bearing frame, the vibration motor is arranged on the bearing frame, the upper end of the bearing frame is fixedly connected with a connecting plate, the upper end of the connecting plate is fixedly connected with the lower end of the bearing plate, and the outer wall of one end of the slide bar, which is close to each other, of the bearing frame and the support column is sleeved with a spring. Preferably, the upper end of the bearing plate is fixedly connected with four first limit posts, the lower end of the die is provided with four first limit grooves, and the first limit grooves and the first limit posts are in one-to-one correspondence and are matched. Preferably, two studs are fixedly connected to the front end and the rear end of the bearing plate respectively, and a clamping block for clamping the collecting box and a nut for fixing the clamping block are sequentially arranged on the outer wall of each stud in a sliding mode. Preferably, the collecting box is a U-shaped object, one end is fixedly connected with two second limiting columns, the other end is provided with two second limiting grooves, the second limiting grooves and the second limiting columns are mutually matched, and the two collecting boxes which are centrosymmetric are inserted into the second limiting grooves of each other through the second limiting columns to be attached and placed. Preferably, the upper end of the collecting box is fixedly connected with a protruding inclined block, the inner wall of the protruding inclined block is flush with the inner wall of the collecting box, and the inner wall of the co