High-density oxidized polyethylene wax drying and dewatering integrated processing equipment

By designing an integrated dehydration tank and drying chamber, combined with motor drive and hydraulic control, the problem of step-by-step operation of the equipment during the drying and dehydration process of high-density oxidized polyethylene wax was solved, improving production efficiency and reducing the equipment footprint.

CN224327477UActive Publication Date: 2026-06-05LIANYUNGANG YOUDAO NEW MATERIAL TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
LIANYUNGANG YOUDAO NEW MATERIAL TECH CO LTD
Filing Date
2025-05-29
Publication Date
2026-06-05

AI Technical Summary

Technical Problem

The existing drying and dehydration process for high-density oxidized polyethylene wax requires multiple equipment steps, resulting in low production efficiency and large equipment footprint.

Method used

Design an integrated processing equipment, including a dehydration tank and a drying chamber. The dehydration tank is driven to rotate by a gear disc and a motor. Dehydration and drying are carried out by a heating structure and a fan. Rapid material feeding is achieved by a hydraulically controlled pump and a telescopic rod.

Benefits of technology

The integration of dehydration and drying processes reduces equipment relocation and waiting time, improves production efficiency, and reduces equipment footprint.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model provides a kind of high-density oxidized polyethylene wax drying dehydration integrated processing equipment, it is related to oxidized polyethylene wax processing technical field, including integrated processing component, the integrated processing component is provided with blanking assembly, the integrated processing component includes dehydration tank and drying oven, the outside of dehydration tank is provided with gear ring.The utility model is rotated by motor electric drive gear disc, gear disc is engaged with gear ring, and then it is favorable to drive dehydration tank to rotate, so as to be favorable to the dehydration treatment of raw material inside dehydration tank, work by heating structure generates heat, cooperate fan to work, it is favorable to hot air blowing into the inside of drying oven, so as to be favorable to the drying treatment of raw material inside dehydration tank, it is favorable to integrate dehydration and drying procedure as a whole, raw material need not be transferred between multiple equipment, reduce intermediate waiting and handling time, improve production efficiency.
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Description

Technical Field

[0001] This utility model relates to the field of oxidized polyethylene wax processing technology, and in particular to an integrated processing equipment for drying and dehydrating high-density oxidized polyethylene wax. Background Technology

[0002] High-density polyethylene (HDPE) wax is an important chemical raw material with wide applications in plastics processing, coatings, and inks. Drying and dehydration are crucial steps in the production of HDPE wax, as their effectiveness directly impacts the product's quality and performance.

[0003] Existing high-density oxidized polyethylene wax typically requires preliminary dehydration using centrifugal equipment to reduce the material's moisture content to a certain level before further drying using a hot air dryer. This process involves multiple steps using various equipment and manual transfer of materials between these devices, leading to reduced production efficiency. Utility Model Content

[0004] The purpose of this invention is to solve the problem that in the existing technology, when drying and dehydrating high-density oxidized polyethylene wax, it is usually necessary to use centrifugal equipment for preliminary dehydration to reduce the moisture content of the material to a certain level, and then use a hot air dryer for further drying. This requires the use of multiple equipment for step-by-step operation and manual transfer of materials between multiple equipment, which leads to a decrease in production efficiency. Therefore, this invention proposes an integrated processing equipment for drying and dehydrating high-density oxidized polyethylene wax.

[0005] To achieve the above objectives, the present invention adopts the following technical solution: an integrated processing equipment for drying and dehydrating high-density oxidized polyethylene wax, comprising an integrated processing component, a feeding component on the integrated processing component, the integrated processing component including a dehydration tank and a drying chamber, a gear ring on the outer side of the dehydration tank, a gear disk meshing with the outer side of the gear ring, a motor installed inside the gear disk, an installation box installed on the top of the drying chamber, a heating structure and a fan installed inside the installation box, the fan being positioned above the heating structure.

[0006] Preferably, the feeding assembly includes a rotating shaft, which is disposed on both sides of the drying chamber. A telescopic rod is connected to the bottom of each rotating shaft, a hydraulic control pump is connected to the side of each telescopic rod, and a rotating seat is connected to the bottom of each telescopic rod.

[0007] Preferably, one end of the dehydration tank is rotatably connected to a feed pipe, and the other end of the dehydration tank is rotatably connected to a discharge pipe.

[0008] Preferably, one end of the drying oven is connected to a support base, and a base plate is installed at the bottom of the support base.

[0009] Preferably, a filter element is installed inside the mounting box, and a protective frame is provided on the outside of the fan.

[0010] Preferably, the bottom of the drying oven is connected to a drain pipe, and the drying oven is provided with an observation window.

[0011] Compared with the prior art, the advantages and positive effects of this utility model are as follows:

[0012] 1. In this utility model, the gear disk is driven by an electric motor to rotate. The gear disk meshes with the gear ring, which in turn drives the dehydration tank to rotate, thus facilitating the dehydration of the raw materials inside the dehydration tank. The heating structure generates heat, which, in conjunction with the fan, blows hot air into the drying chamber, thereby drying the raw materials inside the dehydration tank. This integrates the dehydration and drying processes into one unit, eliminating the need to transfer raw materials between multiple machines, reducing intermediate waiting and handling time, improving production efficiency, and reducing the footprint of the equipment by eliminating the need for multiple machines to operate.

[0013] 2. In this utility model, the extension rod is extended synchronously by the hydraulic control pump, which helps to push the rotating shaft to rise and rotate in conjunction with the rotating seat. This helps to tilt one end of the drying box, and the use of gravity helps to facilitate the discharge of raw materials inside the dehydration tank through the discharge pipe, shortening the discharge time, increasing the discharge speed of materials, and thus improving the discharge efficiency. The support seat helps to provide stable support for the drying box. Attached Figure Description

[0014] Figure 1 This utility model provides a three-dimensional structural schematic diagram of an integrated processing equipment for drying and dehydrating high-density oxidized polyethylene wax;

[0015] Figure 2 This utility model presents another structural schematic diagram of an integrated processing equipment for drying and dehydrating high-density oxidized polyethylene wax;

[0016] Figure 3 This utility model provides an internal cross-sectional view of an integrated processing equipment for drying and dehydrating high-density oxidized polyethylene wax.

[0017] Figure 4 This utility model presents a partially exploded structural diagram of an integrated processing equipment for drying and dehydrating high-density oxidized polyethylene wax;

[0018] Figure 5 This invention presents a partially exploded structural diagram of an integrated processing equipment for drying and dehydrating high-density oxidized polyethylene wax.

[0019] Legend: 1. Integrated processing component; 101. Dehydration tank; 102. Drying box; 103. Gear ring; 104. Gear disk; 105. Motor; 106. Feed pipe; 107. Discharge pipe; 108. Drain pipe; 109. Mounting box; 110. Filter element; 111. Heating structure; 112. Fan; 113. Protective frame; 2. Discharge component; 201. Rotating shaft; 202. Telescopic rod; 203. Rotating seat; 204. Base plate; 205. Support seat; 206. Hydraulic control pump. Detailed Implementation

[0020] To better understand the above-mentioned objectives, features, and advantages of this utility model, the present utility model will be further described below with reference to the accompanying drawings and embodiments. It should be noted that, unless otherwise specified, the embodiments and features described in these embodiments can be combined with each other.

[0021] Many specific details are set forth in the following description in order to provide a full understanding of the present invention. However, the present invention may also be implemented in other ways different from those described herein. Therefore, the present invention is not limited to the specific embodiments disclosed in the following specification.

[0022] Example 1, as Figures 1-5 As shown, this utility model provides a technical solution: an integrated processing equipment for drying and dehydrating high-density oxidized polyethylene wax, including an integrated processing component 1, a feeding component 2 on the integrated processing component 1, the integrated processing component 1 including a dehydration tank 101 and a drying chamber 102, a gear ring 103 on the outside of the dehydration tank 101, a gear disk 104 meshing with the outside of the gear ring 103, a motor 105 installed inside the gear disk 104, an installation box 109 installed on the top of the drying chamber 102, a heating structure 111 and a fan 112 installed inside the installation box 109, the fan 112 being positioned above the heating structure 111, a feed pipe 106 rotatably connected to one end of the dehydration tank 101, a discharge pipe 107 rotatably connected to the other end of the dehydration tank 101, a filter element 110 installed inside the installation box 109, and a protective frame 113 on the outside of the fan 112.

[0023] In this embodiment, the raw material is placed into the dehydration tank 101 through the feed pipe 106. The gear disk 104 is electrically driven by the motor 105 to rotate. The gear disk 104 meshes with the gear ring 103, which facilitates the rotation of the dehydration tank 101, thereby facilitating the dehydration of the raw material inside the dehydration tank 101. The heating structure 111 generates heat, which, together with the fan 112, blows hot air into the drying chamber 102, thereby facilitating the drying of the raw material inside the dehydration tank 101. This integrates the dehydration and drying processes into one unit, eliminating the need to transfer the raw material between multiple devices, reducing intermediate waiting and handling time, improving production efficiency, and reducing the footprint of the equipment by eliminating the need for multiple devices to operate.

[0024] Example 2, as Figures 1-5 As shown, the feeding assembly 2 includes a rotating shaft 201, which is arranged on both sides of the drying chamber 102. The bottom of the rotating shaft 201 is connected to a telescopic rod 202. The side of the telescopic rod 202 is connected to a hydraulic control pump 206. The bottom of the telescopic rod 202 is connected to a rotating seat 203. One end of the drying chamber 102 is connected to a support seat 205. The bottom of the support seat 205 is equipped with a base plate 204. The bottom of the drying chamber 102 is connected to a drain pipe 108. An observation window is provided on the drying chamber 102.

[0025] In this embodiment, after processing is completed, the telescopic rod 202 is extended synchronously by the hydraulic control pump 206, which helps to push the rotating shaft 201 to rise and rotate in conjunction with the rotating seat 203. This helps to tilt one end of the drying box 102, and the raw materials inside the dehydration tank 101 are discharged through the feeding pipe 107 by gravity, which shortens the feeding time, increases the feeding speed of the material, and thus improves the feeding efficiency. The support seat 205 helps to provide stable support for the drying box 102.

[0026] The working principle of this embodiment is as follows: In use, the raw material is first put into the dehydration tank 101 through the feed pipe 106. The gear disk 104 is driven by the motor 105 to rotate. The gear disk 104 meshes with the gear ring 103, which helps to drive the dehydration tank 101 to rotate, thereby facilitating the dehydration of the raw material inside the dehydration tank 101. The heating structure 111 generates heat, which, together with the fan 112, blows hot air into the drying chamber 102, thereby facilitating the drying of the raw material inside the dehydration tank 101. This integrates the dehydration and drying processes. After processing, the extension rod 202 is extended synchronously by the hydraulic control pump 206, which helps to push the rotating shaft 201 to rise. Together with the rotating seat 203, it rotates, which helps to tilt one end of the drying chamber 102. The use of gravity helps to discharge the raw material inside the dehydration tank 101 through the discharge pipe 107, shortening the discharge time. The support seat 205 provides stable support for the drying chamber 102.

[0027] The gear ring 103, gear disk 104, motor 105, heating structure 111, telescopic rod 202, and hydraulic control pump 206 in this utility model are common knowledge in the field, and their working principles are known technologies. The appropriate model is selected according to actual use, so the gear ring 103, gear disk 104, motor 105, heating structure 111, telescopic rod 202, and hydraulic control pump 206 will not be explained in detail.

[0028] The above description is merely a preferred embodiment of the present utility model and is not intended to limit the present utility model in any other way. Any person skilled in the art may make changes or modifications to the above-disclosed technical content to create equivalent embodiments for application in other fields. However, any simple modifications, equivalent changes, and modifications made to the above embodiments based on the technical essence of the present utility model without departing from the technical solution of the present utility model shall still fall within the protection scope of the present utility model.

Claims

1. An integrated processing equipment for drying and dehydrating high-density oxidized polyethylene wax, characterized in that: The assembly includes an integrated processing component (1), on which a feeding component (2) is provided. The integrated processing component (1) includes a dehydration tank (101) and a drying chamber (102). A gear ring (103) is provided on the outside of the dehydration tank (101). A gear disk (104) is meshed on the outside of the gear ring (103). A motor (105) is installed inside the gear disk (104). An installation box (109) is installed on the top of the drying chamber (102). A heating structure (111) and a fan (112) are installed inside the installation box (109). The fan (112) is located above the heating structure (111).

2. The integrated drying and dehydration processing equipment for high-density oxidized polyethylene wax according to claim 1, characterized in that: The feeding assembly (2) includes a rotating shaft (201), which is arranged on both sides of the drying box (102). The bottom of the rotating shaft (201) is connected to a telescopic rod (202), the side of the telescopic rod (202) is connected to a hydraulic control pump (206), and the bottom of the telescopic rod (202) is connected to a rotating seat (203).

3. The integrated drying and dehydration processing equipment for high-density oxidized polyethylene wax according to claim 1, characterized in that: One end of the dehydration tank (101) is rotatably connected to a feed pipe (106), and the other end of the dehydration tank (101) is rotatably connected to a discharge pipe (107).

4. The integrated drying and dehydration processing equipment for high-density oxidized polyethylene wax according to claim 1, characterized in that: One end of the drying box (102) is connected to a support base (205), and a base plate (204) is installed at the bottom of the support base (205).

5. The integrated drying and dehydration processing equipment for high-density oxidized polyethylene wax according to claim 1, characterized in that: The installation box (109) is equipped with a filter element (110), and the fan (112) is equipped with a protective frame (113) on the outside.

6. The integrated drying and dehydration processing equipment for high-density oxidized polyethylene wax according to claim 1, characterized in that: The bottom of the drying box (102) is connected to a drain pipe (108), and an observation window is provided on the drying box (102).