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CN-224198544-U - Multi-layer conveying mechanism for plate purification and drying cabin

CN224198544UCN 224198544 UCN224198544 UCN 224198544UCN-224198544-U

Abstract

The invention discloses a multi-layer conveying mechanism for purifying plates and a drying cabin, relates to the technical field of plate purification, and can solve the problems that the number of plates in the purifying drying cabin is small and the purifying efficiency is low due to the conventional conveying mechanism. The multi-layer conveying mechanism for purifying the plates comprises two groups of annular rail mechanisms which are arranged on the front side and the rear side of a cabin body respectively, wherein each annular rail mechanism comprises an upper annular rail assembly and a lower annular rail assembly which are arranged on the top and the bottom of the cabin body respectively, a transverse passing gap for accommodating the plate main body is formed between the two groups of annular rail mechanisms which are arranged in parallel with each other, a plurality of bearing plates which are vertically arranged on the two groups of annular rail mechanisms and a plurality of bearing assemblies which are arranged on the bearing plates at intervals along a plurality of height setting planes and used for bearing the plate main body, and the top and the bottom of each bearing plate are respectively fixed on the upper annular rail assembly and the lower annular rail assembly of each annular rail mechanism.

Inventors

  • ZHANG GUANGYU
  • YE CHANGHAI

Assignees

  • 成都市美康三杉木业有限公司

Dates

Publication Date
20260505
Application Date
20250428

Claims (10)

  1. 1. The multi-layer type transportation mechanism for purifying the plates is characterized by comprising two groups of annular rail mechanisms which are respectively arranged on the front side and the rear side of a cabin body (9), wherein each annular rail mechanism comprises an upper annular rail assembly (4) and a lower annular rail assembly (5) which are respectively arranged on the top and the bottom of the cabin body (9), and the upper annular rail assembly (4) and the lower annular rail assembly (5) are mutually parallel; a transverse passing gap for accommodating the plate main body (8) is arranged between the two groups of annular rail mechanisms; The device also comprises a plurality of bearing plates (6) vertically arranged on the two groups of annular rail mechanisms, and a plurality of bearing assemblies (7) which are distributed on the bearing plates (6) at intervals along a plurality of height setting planes and are used for bearing the plate main body (8); The top and the bottom of the bearing plate (6) are respectively fixed on an upper annular rail assembly (4) and a lower annular rail assembly (5) of the annular rail mechanism.
  2. 2. A multi-layer transport mechanism for panel decontamination according to claim 1, further comprising a synchronous transmission mechanism (2) and a chain transmission assembly (3) for driving the lower endless track assembly (5) of the two sets of endless track mechanisms to rotate synchronously, and a drive mechanism (1); the lower annular rail assembly (5) comprises a lower annular rail main body (51) and a plurality of lower sliding sleeves (52) which are connected to the lower annular rail main body (51) in a sliding manner, and the bottom of the bearing plate (6) is fixed at the top of the lower sliding sleeves (52); The power output end of the driving mechanism (1) is in transmission connection with the power input end of the synchronous transmission mechanism (2), the two power output ends of the synchronous transmission mechanism (2) are respectively in transmission connection with the power input ends of the two groups of chain transmission assemblies (3), and the power output ends of the two groups of chain transmission assemblies (3) are fixedly connected with the lower sliding sleeve (52).
  3. 3. A multi-layer transport mechanism for purifying a sheet material according to claim 2, wherein the synchronous transmission mechanism (2) comprises a synchronous transmission shaft (21) and driven gears (22) arranged on the synchronous transmission shaft (21), and two synchronous bevel gears (23) arranged on both sides of the driven gears (22); The driving mechanism (1) comprises a driving motor (11) and a driving gear (12) arranged on an output shaft of the driving motor (11), wherein the driving gear (12) is meshed with a driven gear (22); The power input end of the chain transmission assembly (3) is a driven bevel gear (32), and the driven bevel gear (32) is meshed with the synchronous bevel gear (23).
  4. 4. A multi-layer transport mechanism for purifying a sheet material according to claim 2, wherein the chain transmission assembly (3) comprises at least two vertically arranged rotating shafts (31) and two transmission sprockets (33) arranged on the rotating shafts (31), and a driven chain (34) arranged on the transmission sprockets (33); The driving chain wheel (33) and the driven chain (34) are both positioned on the inner side of the lower circular rail main body (51); The chain transmission assembly (3) further comprises a plurality of L-shaped connecting plates (35) which are arranged on the driven chain (34), and the other sides of the L-shaped connecting plates (35) are fixedly connected with the lower sliding sleeve (52).
  5. 5. A multi-layer transport mechanism for panel decontamination according to claim 4, wherein the chain drive assembly (3) further comprises two bearings (36), the shaft (31) being vertically arranged by means of the two bearings (36); The power input end of the chain transmission component (3) is a driven bevel gear (32) sleeved and fixed on the rotating shaft (31).
  6. 6. A multi-layer transport mechanism for purifying a sheet material according to claim 1, wherein the support assembly (7) comprises a support bracket (71) and an elastic support block (72), the elastic support block (72) being fixed to the support bracket (71), the support bracket (71) being detachably and fixedly connected to the support plate (6).
  7. 7. A multi-layer transport mechanism for panel decontamination according to claim 6, wherein the top of the resilient support block (72) has an inclined surface for supporting the edges of the panel body (8); The longitudinal section of the elastic supporting block (72) is any one of right trapezoid and right triangle.
  8. 8. A multi-layer transport mechanism for purifying a sheet material according to claim 6, wherein the bearing plate (6) is vertically provided with a plurality of adjusting holes (61), and the bearing assembly (7) is detachably fixed to the bearing plate (6) through the adjusting holes (61).
  9. 9. The multi-layer transport mechanism for purifying plates according to claim 1, wherein the upper annular rail assembly (4) comprises an upper annular rail main body (41) and a plurality of upper sliding sleeves (42), the upper sliding sleeves (42) are slidably connected to the upper annular rail main body (41), and the top of the pressure bearing plate (6) is fixedly connected to the bottom of the upper sliding sleeves (42).
  10. 10. A panel purification baking chamber comprising a panel purification multi-layer transport mechanism according to any of claims 1-9, characterized by further comprising a chamber body (9); The two groups of ring rail mechanisms are respectively arranged at the front side and the rear side of the cabin body (9); The left side and the right side of the cabin body (9) are also provided with a plurality of feeding holes and discharging holes (91) which are positioned at two sides of the transverse passing gap along the conveying direction of the plate main body (8); the setting height of the feed inlet and the discharge outlet (91) is matched with the height setting plane of the bearing assembly (7).

Description

Multi-layer conveying mechanism for plate purification and drying cabin Technical Field The utility model relates to the technical field of plate purification, in particular to a multi-layer conveying mechanism for plate purification and a drying cabin. Background The synthetic board has the advantages of wide application, good stability, easy mass production and manufacture and the like compared with the board directly processed by raw wood, and the formaldehyde-containing glue such as trialdehyde glue is required to be used for bonding in the manufacturing process of the synthetic board, so that a large amount of formaldehyde is contained in the synthetic board, and formaldehyde removal treatment is required before delivery. In the prior art, when aldehyde removal treatment is carried out on artificially synthesized plates, the plates are generally sent into a high-temperature purification baking cabin, so that formaldehyde is quickly released under a high-temperature environment, but in order to ensure production efficiency, the plates are generally horizontally placed into the cabin for high-temperature purification treatment in the prior art, but the treatment mode has the defects of low purification efficiency, different purification degrees of plates in each batch and the like, and therefore, the prior art designs a conveying mechanism capable of sending the plates into and out of the purification baking cabin in a beat mode to form continuous purification operation. The existing conveying mechanism of the continuous plate purifying and drying cabin is characterized in that the plates are horizontally suspended, so that the plates are uniformly heated on two sides, the problems that the plates warp and are adhered to the conveying mechanism due to uneven heating are avoided, the width of the plates is wider in general, gaps are needed between the plates, and a plurality of plates are sequentially paved along the conveying direction of the conveying mechanism during conveying, so that the existing conveying mechanism is low in number of plates in the purifying and drying cabin at the same time, and the purifying efficiency is low. Based on the above background, the inventors devised a multi-layered transport mechanism and a drying chamber for panel purification, solving at least one of the above problems, and thus, the present application was made. Disclosure of utility model The application aims to provide a multi-layer conveying mechanism for purifying plates and a drying cabin, which solve the problems that the number of plates in the purifying drying cabin is small and the purifying efficiency is low due to the conventional conveying mechanism. In order to solve the technical problems, the utility model adopts the following scheme: on the one hand, the application provides a multi-layer transport mechanism for purifying plates, which comprises two groups of annular rail mechanisms, wherein the annular rail mechanisms are respectively arranged on the front side and the rear side of a cabin body, each annular rail mechanism comprises an upper annular rail assembly and a lower annular rail assembly which are respectively arranged on the top and the bottom of the cabin body, and the upper annular rail assembly and the lower annular rail assembly are mutually parallel; A transverse passing gap for accommodating the plate main body is arranged between the two groups of annular rail mechanisms; The device also comprises a plurality of bearing plates vertically arranged on the two groups of annular rail mechanisms, and a plurality of bearing assemblies which are distributed on the bearing plates at intervals along a plurality of height setting planes and are used for bearing the plate main body; the top and the bottom of the bearing plate are respectively fixed on an upper annular rail assembly and a lower annular rail assembly of the annular rail mechanism. Optionally, the device further comprises a synchronous transmission mechanism and a chain transmission assembly for driving the lower annular rail assemblies of the two annular rail mechanisms to synchronously rotate, and a driving mechanism; The lower annular rail assembly comprises a lower annular rail main body and a plurality of lower sliding sleeves which are connected to the lower annular rail main body in a sliding manner, and the bottom of the bearing plate is fixed at the top of the lower sliding sleeves; The power output end of the driving mechanism is in transmission connection with the power input end of the synchronous transmission mechanism, the two power output ends of the synchronous transmission mechanism are respectively in transmission connection with the power input ends of the two groups of chain transmission assemblies, and the power output ends of the two groups of chain transmission assemblies are fixedly connected with the lower sliding sleeve. Optionally, the synchronous transmission mechanism comprises a synchronous transmis