Multi-column mechanism material line horizontal rotating vertical mechanism
By introducing a belt conveyor structure, a bale-blocking mechanism, and a bale-scraping mechanism, the problems of low bale conversion efficiency and disorder in the horizontal-to-vertical conversion mechanism of multi-line material production lines are solved, achieving efficient bale conversion and neat operation.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 上海欧朔智能包装科技有限公司
- Filing Date
- 2025-06-19
- Publication Date
- 2026-06-12
AI Technical Summary
In traditional multi-row material production line flat-to-vertical mechanisms, the process of changing the strip from a lying state to an upright state is inefficient, and the strip is prone to becoming messy.
It adopts a belt conveyor structure, a packing stop mechanism, and a packing scraper mechanism. The packing stop mechanism limits and tidies up the packs, while the packing scraper mechanism keeps the packs neat at the work station, eliminating the need for the traditional flow channel plate pretreatment mechanism.
It improves the efficiency of changing the strip package from a flat to an upright position, avoids the strip package being messy, and ensures that the strip package remains neat in different workstations.
Smart Images

Figure CN224349209U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of packaging equipment, specifically to a multi-row material line horizontal-to-vertical mechanism. Background Technology
[0002] In traditional multi-row material conveyor systems, the process of changing the strip from a lying to an upright position is inefficient. This is because the traditional structure uses a pre-treatment mechanism with a flow channel plate. This mechanism aims to ensure the stability and accuracy of the strip's transition from a lying to an upright position. This includes functions such as angle adjustment, friction reduction, direction guidance, buffering, and speed control. While these functions do provide stability, the process is clearly cumbersome and lengthy, significantly reducing efficiency.
[0003] To address the aforementioned issues, we have made a series of improvements. Utility Model Content
[0004] The purpose of this invention is to provide a multi-column material line horizontal-to-vertical mechanism to overcome the above-mentioned shortcomings and deficiencies of the prior art.
[0005] A multi-row material conveyor system for horizontal to vertical operation includes: a material chute mechanism, a belt conveyor structure, a flow channel mechanism, a scraping mechanism, and a baffle mechanism. The front ends of the material chute mechanism and the flow channel mechanism are connected. The belt conveyor structure is located below the outlet of the material chute mechanism. The baffle mechanism is located at the front end of the flow channel mechanism. The scraping mechanism is connected to both sides of the flow channel mechanism.
[0006] The baffle mechanism includes a baffle plate, a cylinder, and a cylinder seat. The baffle plate is connected to the cylinder, the cylinder is fixed on the cylinder seat, the cylinder seat is located on the back of the flow channel mechanism, and the extended baffle of the baffle plate is located below the gap between the flow channel mechanisms.
[0007] Furthermore, the material chute mechanism includes: a horizontal-to-vertical material chute, a transition material chute, and left and right stops. One end of the horizontal-to-vertical material chute is connected to the feeding system, the other end of the horizontal-to-vertical material chute is connected to one end of the transition material chute, and the other end of the transition material chute is connected to the left and right stops. The left and right stops are located above the belt conveyor structure.
[0008] Furthermore, the scraping mechanism includes: a scraping conveying system, a scraper, a scraper cylinder, and a drive shaft. The scraping conveying system is equipped with a scraper cylinder, which is connected to the scraper via the drive shaft.
[0009] The beneficial effects of this utility model are:
[0010] Compared with traditional technology, this utility model adds a belt conveyor structure, which greatly improves the efficiency of the entire equipment; the packing mechanism avoids the problem of packs being messy due to excessive power of the belt conveyor structure; and the packing scraping mechanism keeps the packs neat at different work stations. Attached image description:
[0011] Figure 1 This is a schematic diagram of the structure of this utility model.
[0012] Figure 2 This is a schematic diagram of the material chute mechanism.
[0013] Figure 3 This is a schematic diagram of the baggage mechanism.
[0014] Figure 4 This is a schematic diagram of the baffle plate.
[0015] Figure label:
[0016] The material chute mechanism 100, the horizontal-to-vertical material chute 110, the transition material chute 120, and the left and right stops 130.
[0017] The belt conveyor structure 200, the flow channel mechanism 300, the scraping mechanism 400, the scraping conveyor system 410, the scraper 420, the scraper cylinder 430, and the drive shaft 440.
[0018] The bag-blocking mechanism 500, the bag-blocking plate 510, the extended baffle 511, the cylinder 520, and the cylinder seat 530. Detailed Implementation
[0019] The present invention will be further described below with reference to specific embodiments. It should be understood that the following embodiments are for illustrative purposes only and are not intended to limit the scope of the present invention.
[0020] Example 1
[0021] Figure 1 This is a schematic diagram of the structure of this utility model. Figure 2 This is a schematic diagram of the material chute mechanism. Figure 3 This is a schematic diagram of the baggage mechanism. Figure 4 This is a schematic diagram of the baffle plate.
[0022] like Figure 1-4 As shown, a multi-column material line horizontal-to-vertical mechanism includes: a material chute mechanism 100, a belt conveyor structure 200, a flow channel mechanism 300, a scraping mechanism 400, and a baffle mechanism 500. The front ends of the material chute mechanism 100 and the flow channel mechanism 300 are connected. The belt conveyor structure 200 is located below the outlet of the material chute mechanism 100. The baffle mechanism 500 is located at the front end of the flow channel mechanism 300. The scraping mechanism 400 is connected to both sides of the flow channel mechanism 300.
[0023] The baffle mechanism 500 includes a baffle plate 510, a cylinder 520, and a cylinder seat 530. The baffle plate 510 is connected to the cylinder 520, the cylinder 520 is fixed on the cylinder seat 530, the cylinder seat 530 is located on the back of the flow channel mechanism 300, and the extended baffle 511 of the baffle plate 510 is located below the gap between the flow channel mechanisms 300.
[0024] The material chute mechanism 100 includes: a horizontal-to-vertical material chute 110, a transition material chute 120, and left and right stops 130. One end of the horizontal-to-vertical material chute 110 is connected to the feeding system, and the other end of the horizontal-to-vertical material chute 110 is connected to one end of the transition material chute 120. The other end of the transition material chute 120 is connected to the left and right stops 130. The left and right stops 130 are located above the belt conveyor structure 200.
[0025] The scraping mechanism 400 includes: a scraping conveying system 410, a scraper 420, a scraper cylinder 430, and a drive shaft 440. The scraper conveying system 410 is equipped with a scraper cylinder 430, which is connected to the scraper 420 via the drive shaft 440.
[0026] The innovation of this invention lies in abandoning the pre-treatment mechanism via the flow channel plate and introducing a high-efficiency conveying mechanism: a belt conveyor structure is adopted to improve the conversion efficiency of the strip package from a flat to an upright state. The principle is that the belt conveyor structure, as a power-driven structure, provides a driving force when the strip package enters the flow channel mechanism 300 from the chute mechanism 100 through the high-speed rotation of the belt, causing the strip package to enter the flow channel mechanism 300 at an extremely high speed. However, problems arise: First, the strip package itself needs to be adjusted in position and angle, but the pre-setting mechanism is abandoned; second, the belt conveyor structure is too fast, and the driving method is uncontrollable, resulting in different forces on the strip package, different speeds to the preset location, and different times. The final result of these two problems is disorder.
[0027] To address this new issue, we added a packing stop mechanism 500. This mechanism counts packs together. Think of it this way: each batch of packs, in a "column," enters the flow channel mechanism 300. At the front end of the flow channel mechanism 300, before reaching the preset station, a cylinder 520 is activated. The cylinder 520 lifts the packing stop plate 510, creating a sudden obstruction on the previously unobstructed flow channel mechanism 300. The packs are then briefly stopped neatly at the stop plate 510. Logically, this structure serves as a limit switch, restricting the packs in this batch from the same starting point. Then, the cylinder 520 retracts the stop plate 510, and the packs are driven by a new force—the scraper mechanism 400. The scraper 420 of the scraper mechanism 400 neatly pushes the packs forward.
[0028] Finally, regarding the principle of the scraping mechanism 400, its structure and principle are similar to traditional mechanisms. The scraping conveyor system 410 is a classic belt-driven system, including a motor, bearings, connecting shaft, and belt drive structure. The specific structure is very traditional and common, so it will not be elaborated here. The scraping mechanism 400 adopts a cross-design. The scraper cylinder 430 drives the scraper 420 to move up and down via the drive shaft 440. This drives the entire scraper 420, scraper cylinder 430, and drive shaft 440 to move on the flow channel mechanism 300. During this process, the scraper cylinder 430 causes the scraper 420 to flip up and down. When it flips up, it does not contact the package; when it flips down, it contacts the package and pushes it. The flipping time of two adjacent scraping mechanisms 400 is exactly the same, i.e., cross-pushing. This allows the package to remain at the workstation during these intervals, facilitating other operations.
[0029] Compared with traditional technology, this utility model adds a belt conveyor structure, which greatly improves the efficiency of the entire equipment; the packing mechanism avoids the problem of packs being messy due to excessive power of the belt conveyor structure; and the packing scraping mechanism keeps the packs neat at different work stations.
[0030] The specific embodiments of this utility model have been described above, but this utility model is not limited thereto. Various changes can be made to this utility model as long as they do not depart from its spirit.
Claims
1. A multi-column material conveyor horizontal-to-vertical mechanism, characterized in that, include: The system comprises a material chute mechanism (100), a belt conveyor structure (200), a flow channel mechanism (300), a scraping mechanism (400), and a baffle mechanism (500). The front ends of the material chute mechanism (100) and the flow channel mechanism (300) are connected. The belt conveyor structure (200) is located below the outlet of the material chute mechanism (100). The baffle mechanism (500) is located at the front end of the flow channel mechanism (300). The scraping mechanism (400) is connected to both sides of the flow channel mechanism (300). The baffle mechanism (500) includes a baffle plate (510), a cylinder (520), and a cylinder seat (530). The baffle plate (510) is connected to the cylinder (520), the cylinder (520) is fixed on the cylinder seat (530), the cylinder seat (530) is located on the back of the flow channel mechanism (300), and the protruding baffle (511) of the baffle plate (510) is located below the gap between the flow channel mechanisms (300).
2. The multi-column material line horizontal-to-vertical mechanism according to claim 1, characterized in that, The material chute mechanism (100) includes: a horizontal-to-vertical material chute (110), a transition material chute (120), and left and right stops (130). One end of the horizontal-to-vertical material chute (110) is connected to the feeding system, and the other end of the horizontal-to-vertical material chute (110) is connected to one end of the transition material chute (120). The other end of the transition material chute (120) is connected to the left and right stops (130). The left and right stops (130) are located above the belt conveyor structure (200).
3. The multi-column material line horizontal-to-vertical mechanism according to claim 1, characterized in that, The scraping mechanism (400) includes: a scraping conveying system (410), a scraper (420), a scraper cylinder (430), and a drive shaft (440). The scraping conveying system (410) is equipped with a scraper cylinder (430), which is connected to the scraper (420) through the drive shaft (440).