A tilting unloading dewaterer

By designing an inclined feeding dewatering machine, and utilizing telescopic cylinders and locking devices to achieve automated flipping and feeding of parts, the problems of low drying efficiency and risk of burns are solved, thus improving safety and efficiency.

CN224455152UActive Publication Date: 2026-07-03HONGYI MECHANICAL IND (ZHEJIANG) CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
HONGYI MECHANICAL IND (ZHEJIANG) CO LTD
Filing Date
2025-08-22
Publication Date
2026-07-03

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Abstract

A kind of slanting unloading dewatering machine, it includes centrifuge support and centrifugal device.The centrifuge support includes support, telescopic cylinder and locking device.The locking device includes locking cylinder and locking head.The centrifugal device includes mesa, rotating shaft, centrifuge and driving motor.The side of the mesa away from the centrifuge is provided with locking hook.By being provided with telescopic cylinder on the support, the centrifugal device is rotatably arranged on the support and movably connected with the movable end of the telescopic cylinder, and the unloading speed is improved by the telescopic function of the telescopic cylinder.A locking device is arranged on the support, a locking hook is arranged on the mesa, the mesa is fixed by being buckled with the locking hook through the locking device, so that the mesa is prevented from being turned over during use, and the locking or unhooking between the locking cylinder and the locking hook is controlled, so that manual adjustment is not needed, and the safety factor is high.
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Description

Technical Field

[0001] This utility model relates to the technical field of automated dewatering and feeding equipment, and in particular to an inclined feeding dewatering machine. Background Technology

[0002] During production, the parts require cooling and cleaning. During processing, moisture may remain on the surface of the chain links. Since the parts are typically polygonal or irregularly shaped, drying them in a drying oven is inefficient, leaving water stains in crevices and corners. Furthermore, all parts must be manually placed and removed by workers, which not only increases the risk of burns from high temperatures but also takes a significant amount of time.

[0003] Application CN202421565706.8 discloses a durable parts dehydration tank, including a tank body support base. The upper end of the support base has a cylindrical dehydration basket main body structure evenly distributed vertically. The dehydration basket main body structure is processed from steel sheet by bending. The interior of the dehydration basket main body structure is a hollow main body placement cavity. A central clearance mounting hole is formed at the center of the dehydration basket main body structure. Dehydration safety conveying holes are provided on both the inner and outer sides of the dehydration basket main body structure. A flipping connection hook is provided on one side of the support base. In use, it can cooperate with a centrifugal rotating component to achieve rapid dehydration of the chain links through centrifugal processing. Furthermore, the flipping mechanism enables automatic discharge, resulting in better overall dehydration performance. However, the flipping requires manual operation, and the overall structure still has room for improvement. Utility Model Content

[0004] In view of this, the present invention provides an inclined feeding dewatering machine to solve the above-mentioned technical problems.

[0005] A tilting feed dewatering machine includes a centrifuge support and a centrifugal device mounted on the centrifuge support. The centrifuge support includes a bracket, a telescopic cylinder with one end movably mounted on the bracket away from the centrifugal device, and a locking device movably mounted in the bracket. The locking device includes a locking cylinder and a locking head mounted on the movable end of the locking cylinder. The centrifugal device includes a platform, a rotating shaft located in the central region of both sides of the platform, a centrifuge mounted on the platform, and a drive motor mounted on the platform on one side of the centrifuge. A locking hook is provided on the side of the platform away from the centrifuge. The side of the platform near the drive motor is movably connected to the movable end of the telescopic cylinder.

[0006] Furthermore, one end of the telescopic cylinder is pivotally fixed to the bracket, and its telescopic end is movably connected to the centrifugal device through a movable component.

[0007] Furthermore, the locking head is movably mounted on the locking cylinder.

[0008] Furthermore, when the telescopic cylinder retracts to bring the centrifugal device to a horizontal position, the locking cylinder extends to engage and lock the locking head with the centrifugal device.

[0009] Furthermore, when the telescopic cylinder extends to its maximum length, the rotation angle of the centrifugal device is greater than or equal to 90 degrees.

[0010] Furthermore, the centrifuge and the drive motor are connected by a transmission belt.

[0011] Compared with existing technologies, the tilting feeding dewatering machine provided by this utility model has a telescopic cylinder installed on the support frame. The centrifugal device is rotatably mounted on the support frame and movably connected to the movable end of the telescopic cylinder. The telescopic movement allows the centrifugal device to tilt and feed materials, increasing the feeding speed. A locking device is installed on the support frame, and a locking hook is installed on the platform. The locking device and the locking hook are interlocked to fix the platform and prevent it from tilting during use. The locking cylinder controls the locking and unlocking of the device and the locking hook, eliminating the need for manual adjustment and ensuring a high safety factor. Attached Figure Description

[0012] Figure 1 This is a structural schematic diagram of an inclined feeding dewatering machine provided by this utility model.

[0013] Figure 2 for Figure 1 The top view of the inclined feeding dewatering machine is shown above, and the reverse view is shown below.

[0014] Figure 3 for Figure 1 A top view of the inclined feeding dewatering machine. Detailed Implementation

[0015] The specific embodiments of this utility model are described in further detail below. It should be understood that the description of the embodiments of this utility model herein is not intended to limit the scope of protection of this utility model.

[0016] like Figures 1 to 3The diagram shown is a structural schematic of an inclined feeding dewatering machine provided by this utility model. The inclined feeding dewatering machine includes a centrifuge support 10 and a centrifugal device 20 mounted on the centrifuge support 10. It is conceivable that the inclined feeding dewatering machine also includes other functional structures, such as fasteners, support components, etc., which are technologies known to those skilled in the art and will not be described in detail here.

[0017] The centrifuge support 10 includes a support 11, a telescopic cylinder 12 with one end movably disposed on the side of the support 11 away from the centrifuge device 20, and a locking device 13 movably disposed in the support 11.

[0018] The support frame 11 is fixed to the ground. One end of the telescopic cylinder 12 is pivotally fixed to the support frame 11, and its telescopic end is movably connected to the centrifuge device 20 via a movable member 14. By extending or retracting the telescopic end of the telescopic cylinder 12, the centrifuge device 20 connected to the movable end of the telescopic cylinder 12 is controlled to rotate, thereby emptying the material in the centrifuge device 20. The movable member 14 is rotatable to facilitate changes in the angle between the movable end of the telescopic cylinder 12 and the centrifuge device 20.

[0019] The locking device 13 includes a locking cylinder 131 and a locking head 132 disposed on the movable end of the locking cylinder 131. The locking head 132 is movably disposed on the locking cylinder 131. When the telescopic cylinder 12 retracts to bring the centrifugal device 20 to a horizontal position, the locking cylinder 131 extends to engage and lock the locking head 132 with the centrifugal device 20. The telescopic cylinder 12 and the locking device 13 can be controlled via a control panel after programming. When the telescopic cylinder 12 extends to its maximum length, the rotation angle of the centrifugal device 20 is greater than or equal to 90 degrees, ensuring that the parts can fall under their own weight.

[0020] The centrifuge device 20 includes a platform 21, a rotating shaft 22 disposed in the middle area on both sides of the platform 21, a centrifuge 23 disposed on the platform 21, and a drive motor 24 disposed on the platform 21 located on one side of the centrifuge 23.

[0021] A locking hook 25 is provided on the side of the platform 21 away from the centrifuge 23, which engages with the locking head 152 to lock the platform 21. The side of the platform 21 closest to the drive motor 24 is movably connected to the movable end of the telescopic cylinder 12. The telescopic cylinder 12 drives the platform 21 to rotate along the rotating shaft 22, thereby emptying the dehydrated parts from the centrifuge 23. The centrifuge 23 is a commercially available device, and its structure and function will not be described in detail here. The centrifuge 23 is connected to the drive motor 24 via a transmission belt. The drive motor 24 drives the centrifuge 23 to rotate, achieving the purpose of dehydrating the parts in the centrifuge 23. The speed of the drive motor 24 can be adjusted by a controller (not shown) or other devices to regulate the speed of the centrifuge 23.

[0022] In use, the operator places the parts to be dehydrated into the centrifuge 23, ensuring that the locking device 13 and the locking hook 25 are locked. The drive motor 24 is then started to rotate the centrifuge 23, causing the parts placed in the centrifuge 23 to be dehydrated by centrifugal force. After dehydration, the locking cylinder 151 retracts, disengaging the locking head 132 from the locking hook 25. The telescopic cylinder 12 extends, causing the table 21 to flip. The centrifuge 23 flips along with the table 21, allowing the parts to be poured out of the centrifuge 23.

[0023] Compared with the prior art, the tilting feeding dewatering machine provided by this utility model has a telescopic cylinder 12 installed on the support 11. The centrifugal device 20 is rotatably mounted on the support 11 and movably connected to the movable end of the telescopic cylinder 12. The telescopic cylinder 12 allows the centrifugal device 20 to tilt and feed material, increasing the feeding speed. A locking device 13 is installed on the support 11, and a locking hook 25 is installed on the table 21. The locking device 13 and the locking hook 25 are interlocked to fix the table 21, preventing it from tilting during use. The locking cylinder 131 controls the locking or unhooking of the locking hook 25, eliminating the need for manual adjustment and ensuring a high safety factor.

[0024] The above are merely preferred embodiments of the present utility model and are not intended to limit the scope of protection of the present utility model. Any modifications, equivalent substitutions or improvements within the spirit of the present utility model are covered within the scope of the claims of the present utility model.

Claims

1. A sloping down-draught dehydrator characterised in that: The inclined feeding dewatering machine includes a centrifuge support and a centrifugal device mounted on the centrifuge support. The centrifuge support includes a bracket, a telescopic cylinder with one end movably mounted on the side of the bracket away from the centrifugal device, and a locking device movably mounted in the bracket. The locking device includes a locking cylinder and a locking head mounted on the movable end of the locking cylinder. The centrifugal device includes a platform, a rotating shaft mounted in the middle area on both sides of the platform, a centrifuge mounted on the platform, and a drive motor mounted on the platform on one side of the centrifuge. A locking hook is provided on the side of the platform away from the centrifuge, and the side of the platform near the drive motor is movably connected to the movable end of the telescopic cylinder.

2. The inclined gravity dewaterer of claim 1, wherein: One end of the telescopic cylinder is pivotally fixed to the bracket, and its telescopic end is movably connected to the centrifugal device through a movable component.

3. The inclined gravity dewaterer of claim 1, wherein: The locking head is movably mounted on the locking cylinder.

4. The inclined gravity dewaterer of claim 1 wherein: When the telescopic cylinder retracts to bring the centrifuge device to a horizontal position, the locking cylinder extends to engage and lock the locking head with the centrifuge device.

5. The inclined feeding dewatering machine as described in claim 1, characterized in that: When the telescopic cylinder extends to its maximum length, the centrifugal device flips at an angle greater than or equal to 90 degrees.

6. The inclined gravity dewaterer of claim 1 wherein: The centrifuge and the drive motor are connected by a transmission belt.