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CN-224207863-U - Automatic chromosome stirrer

CN224207863UCN 224207863 UCN224207863 UCN 224207863UCN-224207863-U

Abstract

The application relates to the technical field of stirring equipment, in particular to an automatic chromosome stirrer, which comprises a stirrer body, wherein a fixing device is arranged on the stirrer body and comprises at least three clamping arms arranged on the stirrer body, clamping claws arranged on the clamping arms in a sliding manner and a driving mechanism for controlling the clamping claws to slide on the clamping arms in a synchronous control manner.

Inventors

  • LIANG LI
  • ZHU HUI
  • PAN XINHUI
  • HUANG KAI

Assignees

  • 浙江贝越绳业有限公司

Dates

Publication Date
20260508
Application Date
20250303

Claims (10)

  1. 1. The automatic chromosome stirrer comprises a stirrer body (100), and is characterized in that a fixing device (200) is arranged on the stirrer body (100), the fixing device (200) comprises at least three clamping arms (210) arranged on the stirrer body (100), clamping claws (220) arranged on the clamping arms (210) in a sliding manner, and a driving mechanism (230) used for controlling the clamping claws (220) to slide on the clamping arms (210) in a synchronous manner, and a plurality of clamping claws (220) slide around the axis of a stirring shaft of the stirrer body (100) in a synchronous manner.
  2. 2. The automatic chromosome mixer as set forth in claim 1, wherein the driving mechanism (230) comprises a worm wheel (231) rotatably mounted on the mixer body (100), a worm (232) engaged with the worm wheel (231), a hand wheel (233) mounted on the worm (232), a driving gear (234) coaxially connected with the worm wheel (231), and a transmission structure (235) for connecting the driving gear (234) and the claw (220).
  3. 3. The automatic chromosome mixer as set forth in claim 2, wherein the transmission structure (235) includes a driven wheel (2351) engaged with the driving gear (234), and a rack (2352) engaged with the driven wheel (2351), and the rack (2352) is connected to the claw (220).
  4. 4. The automatic chromosome mixer as set forth in claim 3, wherein the plurality of clamping arms (210) are integrally connected, the driving mechanism (230) is hollow, and the clamping arms (210) penetrate through the driving mechanism (230) to be connected with the mixer body (100).
  5. 5. The automatic chromosome mixer as set forth in claim 4, wherein the driving mechanism (230) is fastened to the mixer body (100) by a clamp arm (210).
  6. 6. The automatic chromosome mixer as set forth in claim 4, wherein the clamping arm (210) is provided with a sliding chute for the clamping jaw (220), and the rack (2352) and the clamping jaw (220) are respectively arranged at two ends of the clamping arm (210).
  7. 7. The automatic chromosome mixer as set forth in claim 6, wherein the clamping arm (210) and the driving gear (234) are disposed at a distance from each other for the rack (2352) to pass through.
  8. 8. The automatic chromosome stirrer according to claim 1, wherein a damping structure (300) is mounted on the clamping end surface of the jaw (220).
  9. 9. The automatic chromosome mixer as set forth in claim 8, wherein the damping structure (300) is an elastic block.
  10. 10. The automatic chromosome mixer as set forth in claim 9, wherein the end face of the elastic block is arranged in an obtuse triangle recess.

Description

Automatic chromosome stirrer Technical Field The application relates to the technical field of stirring equipment, in particular to an automatic chromosome stirrer. Background The high molecular polyethylene rope is used as an important fiber product in the industrial field, and the dyeing process directly influences the added value and the market competitiveness of the product. The dyeing process commonly adopted in the current industry still continues the traditional flow and is mainly divided into two links of dye pre-preparation and stirring color mixing. In a specific operation, the worker needs to pour the dyeing master batch into an open chromosome barrel according to the formula proportion, and then mix and stir the dyeing master batch by using a hand-held electric stirrer. Although this mode of operation can meet basic dyeing requirements, a number of technical drawbacks are exposed in the actual production process. Firstly, in the stirring process, the chromosome barrels are generally in a cylindrical open design, and the calibers of different chromosome barrels are different, so that operators have to carry out operations by using a stirrer with the whole process of hand-holding weight of 3-5 kg. The stirring shaft is difficult to keep in a vertical state due to physiological vibration of arms of a human body, dye splashing is easy to be caused, and the health of an operator is influenced. Secondly, the current stirring mode is difficult to realize uniform color mixing. Experimental data show that when the dyeing barrel is held for stirring, irregular vortex fields can be formed in the dyeing barrel due to radial eccentric motion caused by uneven force application. This turbulent flow condition results in the metal complex dye having a relatively high density being easily deposited on the bottom of the tub, while the organic dye tends to be suspended on the liquid surface, causing delamination of the dyeing mother liquor. Particularly, when high-concentration coloring agent is treated, the color difference qualification rate is generally lower than 85%, and the development of high-end products is seriously restricted. Disclosure of utility model In order to realize the through opening of the chromosome barrel which can be fixed to various calibers, the application provides a chromosome automatic stirrer. The application provides a chromosome automatic stirrer, which adopts the following technical scheme: The utility model provides an automatic stirrer of chromosome, includes the mixer body, be equipped with fixing device on the mixer body, fixing device includes at least three card arm of installing in the mixer body, slides the jack catch of installing on the card arm to and be used for controlling synchronous control jack catch and slide on the card arm actuating mechanism, a plurality of the jack catch slides around the axle center of the (mixing) shaft of mixer body in step. In one embodiment, the driving mechanism comprises a worm wheel rotatably arranged on the mixer body, a worm meshed with the worm wheel, a hand wheel arranged on the worm, a driving gear coaxially connected with the worm wheel, and a transmission structure for connecting the driving gear and the clamping jaw. In one embodiment, the transmission structure comprises a driven wheel meshed with the driving gear and a rack meshed with the driven wheel, wherein the rack is connected with the claw. In one embodiment, a plurality of clamping arms are integrally connected, the driving machine is in a hollow arrangement, and the clamping arms penetrate through the driving mechanism and are connected with the mixer body. In one embodiment, the driving mechanism is fixedly supported on the mixer body through the clamping arm. In one embodiment, the clamping arm is provided with a sliding chute for the clamping jaw, and the rack and the clamping jaw are respectively arranged at two ends of the clamping arm. In one embodiment, the clamping arm and the driving gear are arranged at intervals for the rack to pass through. In one embodiment, a damping structure is arranged on the clamping end face of the clamping jaw. In one embodiment, the damping structure is an elastomeric block. In one embodiment, the end face of the elastic block is arranged in an obtuse triangular concave manner. In summary, the application has the following beneficial effects: The clamping jaw is controlled to slide on the clamping arm through the driving mechanism, so that the fixed caliber of the clamping jaw is adjusted, and the clamping jaw can be suitable for the through holes of chromosome barrels with various calibers. Drawings FIG. 1 is a schematic diagram of the first embodiment; FIG. 2 is a schematic diagram of an explosive structure of the present embodiment; FIG. 3 is a second schematic structural view of the present embodiment; fig. 4 is a schematic view of the structure of the claw in the present embodiment. 100 Parts of a stirrer body, 200 parts of a