A granulator with a fan structure
By introducing a fan structure into the granulator, air cooling and airflow distribution adjustment are achieved, solving the problem of heat dissipation difficulties during the rainy season and improving the production efficiency and granule quality of the granulator.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JIANGSU ZHUHUA NEW MATERIALS CO LTD
- Filing Date
- 2025-06-16
- Publication Date
- 2026-07-14
Smart Images

Figure CN224485880U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of granulator technology, specifically a granulator with a fan structure. Background Technology
[0002] In many industrial production fields such as chemical, food, pharmaceutical, and plastics, granulators occupy an indispensable position. As a mechanical device that can process powdery and lumpy materials into granules of specific shapes and specifications, it greatly improves the convenience of product storage and transportation as well as the adaptability of subsequent processing, thereby significantly improving production efficiency and product quality.
[0003] During operation, traditional granulators generate a significant amount of heat as materials pass through the granulation device. However, during the rainy season, air humidity increases dramatically. On one hand, humid air has poor thermal conductivity, hindering the rapid conduction and dissipation of heat, making it difficult to effectively reduce the heat inside the granulator and improve the high-temperature environment during granulation. On the other hand, when the hot air generated by the granulator comes into contact with humid air, condensation easily forms in the low-temperature areas inside the granulator, producing water droplets. Once these water droplets mix with the material, they will have a serious negative impact on the quality of the granules, affecting the normal operation of the granulator, reducing production efficiency, and increasing production costs. Utility Model Content
[0004] The purpose of this utility model is to provide a granulator with a fan structure to solve the problems mentioned in the background art. To solve the above technical problems, this utility model is achieved through the following technical solution:
[0005] This utility model is a granulator with a fan structure, comprising:
[0006] A granulation component, comprising a granulation frame and a granulation chamber, wherein the granulation chamber is disposed at one end of the top of the granulation frame;
[0007] The fan assembly includes a fan housing, a pipe body, an air outlet, a distribution plate, a rotating shaft, a rotating rod, a handle, and an air outlet ring. The fan housing is installed on both sides of the outer surface of the granulation chamber. The pipe body is located at one end of the outer surface of the fan housing. The air outlet ring is located at the bottom of the pipe body. The air outlet is fixed at the bottom of the air outlet ring. The distribution plate is located on the inner surface of the air outlet ring. The rotating rod passes through and rotates inside the air outlet ring. The rotating shaft is located on the outer surface of the rotating rod and fits against both sides of the outer surface of the air outlet ring. The handle is rotatably connected to one side of the rotating rod.
[0008] Furthermore, the fan component also includes an air inlet and a cooling chamber. The air inlet is located at one end of the outer surface of the fan housing, and the cooling chamber is located between the fan housing and the pipe body.
[0009] Furthermore, it also includes a fixing component, which includes a moving groove, a support ring, and a moving rod. The support ring is disposed at one end of the outer surface of the rotating rod, the moving groove is opened inside the support ring, and the moving rod is fixed to one side of the handle and movably connected inside the moving groove.
[0010] Furthermore, the two ends of the outer surface of the movable rod are threaded with nut rings, and the crossbar is fixed between the air outlet ring and the support ring.
[0011] Furthermore, a feed inlet is provided at one end of the top of the granulation chamber, and a base is welded to the bottom of the granulator frame.
[0012] Furthermore, it also includes a moving component, which includes a motor, a lead screw, a turntable, and an internal threaded ring. The turntable is located at the lower part of one side of the granulation chamber, the lead screw is rotatably connected between the two turntables, the motor is located at the top of the top turntable, one side of the internal threaded ring is fixed to one side of the fan housing, and the middle part is threaded to the outer surface of the lead screw.
[0013] Furthermore, grooves are provided on both sides of the outer surface of the granulation chamber, and a slider is provided on one side of the fan casing, with the slider movably connected inside the groove.
[0014] This utility model has the following beneficial effects:
[0015] This invention utilizes a fan component. When the fan casing is activated, its powerful suction quickly draws in outside air. This air first enters the air inlet pipe, which effectively guides the airflow smoothly towards the cooling chamber. In the cooling chamber, the air undergoes a precise temperature regulation process and is rapidly cooled to a suitable temperature. The distribution plate has a unique angle adjustment function, which can be flexibly adjusted according to actual usage needs. The operator only needs to hold the handle and turn it gently to drive the distribution plate to make precise angle changes through the rotation of the rotating rod. It can flexibly adjust the airflow distribution according to different material characteristics and granulation process requirements, so that the cold air can fully contact the material, improve cooling efficiency, shorten granulation time, and thus improve the efficiency of the entire granulation production. Attached Figure Description
[0016] To more clearly illustrate the technical solutions of the embodiments of this utility model, the accompanying drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0017] Figure 1 This is a schematic diagram of the overall granulator frame of this utility model;
[0018] Figure 2This is a schematic diagram of the tube body of this utility model;
[0019] Figure 3 This is a schematic diagram of the flow divider of this utility model.
[0020] The attached diagram lists the components represented by each number as follows:
[0021] 100. Granulator frame; 101. Granulation chamber; 102. Feed inlet; 103. Base;
[0022] 200. Fan housing; 201. Air inlet; 202. Cooling chamber; 203. Pipe body; 205. Air outlet; 206. Diverter plate; 207. Rotating shaft; 208. Rotating rod; 209. Handle; 210. Air outlet ring;
[0023] 300. Nut ring; 301. Moving groove; 302. Support ring; 303. Crossbar; 304. Moving rod;
[0024] 400. Motor; 401. Lead screw; 402. Slide groove; 403. Turntable; 404. Internal threaded ring; 405. Slider. Detailed Implementation
[0025] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0026] To make the objectives, technical solutions, and advantages of this utility model clearer, the embodiments of this utility model will be described in further detail below with reference to the accompanying drawings.
[0027] Please see Figure 1-3 As shown, this utility model is a granulator with a fan structure, comprising:
[0028] The granulation component includes a granulator frame 100 and a granulation chamber 101, wherein the granulation chamber 101 is disposed at one end of the top of the granulator frame 100;
[0029] The fan assembly includes a fan housing 200, a pipe body 203, an air outlet 205, a distribution plate 206, a rotating shaft 207, a rotating rod 208, a handle 209, and an air outlet ring 210. The fan housing 200 is installed on both sides of the outer surface of the granulation chamber 101. The pipe body 203 is located at one end of the outer surface of the fan housing 200. The air outlet ring 210 is located at the bottom of the pipe body 203. The air outlet 205 is fixed to the bottom of the air outlet ring 210. The distribution plate 206 is located on the inner surface of the air outlet ring 210. The rotating rod 208 rotates through the inside of the air outlet ring 210. The rotating shaft 207 is located on the outer surface of the rotating rod 208 and fits against both sides of the outer surface of the air outlet ring 210. The handle 209 is rotatably connected to one side of the rotating rod 208.
[0030] When the fan casing 200 is started, its powerful suction quickly draws in outside air. This air first enters the air inlet pipe, which can effectively guide the airflow smoothly to the cooling chamber 202. In the cooling chamber 202, the air undergoes a precise temperature regulation process and is quickly cooled to a suitable temperature. The distribution plate 206 has a unique angle adjustment function, which can be flexibly adjusted according to actual usage needs.
[0031] The fan component also includes an air inlet 201 and a cooling chamber 202. The air inlet 201 is located at one end of the outer surface of the fan housing 200, and the cooling chamber 202 is located between the fan housing 200 and the pipe body 203.
[0032] It also includes a fixing component, which includes a moving groove 301, a support ring 302 and a moving rod 304. The support ring 302 is disposed at one end of the outer surface of the rotating rod 208, the moving groove 301 is opened inside the support ring 302, and the moving rod 304 is fixed to one side of the handle 209 and movably connected inside the moving groove 301.
[0033] When the handle 209 is rotated, the moving rod 304 moves inside the moving groove 301 at the same time, which can support the handle 209 when it is rotated.
[0034] Nut rings 300 are threaded to both ends of the outer surface of the movable rod 304, and the crossbar 303 is fixed between the air outlet ring 210 and the support ring 302;
[0035] Rotating the nut ring 300 causes the threaded ring to be clamped on both sides of the support ring 302, thus fixing the handle 209 after rotation.
[0036] A feed inlet 102 is provided at one end of the top of the granulation chamber 101, and a base 103 is welded to the bottom of the granulator frame 100.
[0037] Working principle: First, when the fan casing 200 is started, its powerful suction quickly draws in outside air. This air first enters the air inlet duct, which effectively guides the airflow smoothly to the cooling chamber 202. In the cooling chamber 202, the air undergoes a precise temperature regulation process and is rapidly cooled to a suitable temperature. The distribution plate 206 has a unique angle adjustment function, which can be flexibly adjusted according to actual usage needs. The operator only needs to hold the handle 209 and turn it gently to drive the distribution plate 206 to make precise angle changes through the rotation of the rotating rod 208. It can flexibly adjust the airflow distribution according to different material characteristics and granulation process requirements, so that the cold air can fully contact the material, improve cooling efficiency, shorten granulation time, and thus improve the efficiency of the entire granulation production. When the operator adjusts the air outlet ring 210... When the inner distribution plate 206 is tilted, the moving rod 304 connected to the handle 209 will slide smoothly in the moving groove 301, providing reliable and stable support for the rotating handle 209. As the handle 209 rotates, the distribution plate 206 gradually adjusts to a specific angle that meets the actual usage requirements. At this time, the operator only needs to tighten the nut ring 300 on the outside of the moving rod 304. The nut ring 300 and the moving rod 304 are threaded together. When the nut ring 300 is tightened, it will be tightly clamped on both sides of the support ring 302, forming a strong and stable fixing force. This ensures that the distribution plate 206 can always maintain the set angle position during long-term use, even if it is impacted by airflow or slightly vibrated during equipment operation, providing a continuous and stable airflow distribution for the granulation process.
[0038] Please see Figure 1 , Figure 2 As shown, this embodiment, based on the above embodiment, further includes:
[0039] The moving component includes a motor 400, a lead screw 401, a turntable 403, and an internal threaded ring 404. The turntable 403 is located at the lower part of one side of the granulation chamber 101. The lead screw 401 is rotatably connected between two turntables 403. The motor 400 is located at the top of the top turntable 403. One side of the internal threaded ring 404 is fixed to one side of the fan housing 200, and the middle part is threaded to the outer surface of the lead screw 401.
[0040] When the motor 400 runs, it drives the turntable 403 and the lead screw 401 to rotate. The internal threaded ring 404 can move up and down by rotating the lead screw 401, and the height of the fan housing 200 can be adjusted according to the usage requirements of the fan housing 200.
[0041] The granulation chamber 101 has grooves 402 on both sides of its outer surface, and a slider 405 is provided on one side of the blower housing 200. The slider 405 is movably connected to the inside of the groove 402.
[0042] When the fan casing 200 is adjusted in height, its slider 405 moves inside the slide groove 402 at the same time, which plays a supporting role.
[0043] Working principle: After the motor 400 starts, it drives the turntable 403 and the lead screw 401 to rotate synchronously at high speed. The internal threaded ring 404 is threadedly engaged with the lead screw 401. As the lead screw 401 rotates, the internal threaded ring 404 can smoothly move up and down along the lead screw 401. During the height adjustment of the fan housing 200, the slider 405 slides smoothly in the slide groove 402, providing a stable and reliable support for the fan housing 200. This support not only ensures that the fan housing 200 remains stable during up and down movement, but also effectively avoids unstable situations such as shaking and tilting, greatly improving the safety of equipment operation. This also makes the adjustment process of the fan casing 200 smoother and more fluid. Operators can easily complete the adjustment without expending too much effort, significantly improving work efficiency. The fan casing 200 can be precisely adjusted to the optimal height according to the heat dissipation requirements of different locations inside the granulator, ensuring that the cooling airflow can efficiently cover key areas, improving heat dissipation and guaranteeing granulation quality. On the other hand, when installing, maintaining, or using the equipment in conjunction with other production equipment, the flexible height adjustment function can effectively adapt to different site conditions and equipment layouts, enhancing the equipment's versatility and adaptability, and reducing the company's equipment procurement and operating costs.
[0044] The preferred embodiments of this utility model disclosed above are merely illustrative of the present utility model. These preferred embodiments do not exhaustively describe all details, nor do they limit the utility model to the specific implementations described. Clearly, many modifications and variations can be made based on the content of this specification. This specification selects and specifically describes these embodiments to better explain the principles and practical applications of this utility model, thereby enabling those skilled in the art to better understand and utilize it. This utility model is limited only by the claims and their full scope and equivalents.
Claims
1. A granulator with a fan structure, characterized in that, include: The granulation component includes a granulator frame (100) and a granulation chamber (101), wherein the granulation chamber (101) is disposed at one end of the top of the granulator frame (100); The fan assembly includes a fan housing (200), a pipe body (203), an air outlet (205), a distribution plate (206), a rotating shaft (207), a rotating rod (208), a handle (209), and an air outlet ring (210). The fan housing (200) is installed on both sides of the outer surface of the granulation chamber (101), the pipe body (203) is located at one end of the outer surface of the fan housing (200), and the air outlet ring (210) is disposed on the pipe body. At the bottom of (203), the air outlet (205) is fixed to the bottom of the air outlet ring (210), the diverter plate (206) is set on the inner surface of the air outlet ring (210), the rotating rod (208) passes through and rotates inside the air outlet ring (210), the rotating shaft (207) is set on the outer surface of the rotating rod (208) and fits against both sides of the outer surface of the air outlet ring (210), and the handle (209) is rotatably connected to one side of the rotating rod (208).
2. A granulator with a fan structure according to claim 1, characterized in that: The fan component also includes an air inlet (201) and a cooling chamber (202). The air inlet (201) is located at one end of the outer surface of the fan housing (200), and the cooling chamber (202) is located between the fan housing (200) and the pipe body (203).
3. A granulator with a fan structure according to claim 1, characterized in that: It also includes a fixing component, which includes a moving groove (301), a support ring (302) and a moving rod (304). The support ring (302) is disposed at one end of the outer surface of the rotating rod (208), the moving groove (301) is opened inside the support ring (302), and the moving rod (304) is fixed to one side of the handle (209) and movably connected inside the moving groove (301).
4. A granulator with a fan structure according to claim 3, characterized in that: The two ends of the outer surface of the movable rod (304) are threaded with nut rings (300), and the crossbar (303) is fixed between the air outlet ring (210) and the support ring (302).
5. A granulator with a fan structure according to claim 1, characterized in that: The granulation chamber (101) has a feed inlet (102) at one end of its top, and a base (103) is welded to the bottom of the granulator frame (100).
6. A granulator with a fan structure according to claim 1, characterized in that: It also includes a moving component, which includes a motor (400), a lead screw (401), a turntable (403), and an internal threaded ring (404). The turntable (403) is located at the lower part of one side of the granulation chamber (101). The lead screw (401) is rotatably connected between the two turntables (403). The motor (400) is located at the top of the top turntable (403). One side of the internal threaded ring (404) is fixed to one side of the fan housing (200), and the middle part is threaded to the outer surface of the lead screw (401).
7. A granulator with a fan structure according to claim 6, characterized in that: The granulation chamber (101) has grooves (402) on both sides of its outer surface, and a slider (405) is provided on one side of the fan housing (200). The slider (405) is movably connected inside the groove (402).