Feeding structure for polishing a steamer body
By designing an automated feeding structure and heat dissipation system, the safety hazards of loading and unloading the pot body and the problem of removing it at high temperatures in the steam pot grinding equipment have been solved, achieving efficient and safe pot body processing and improving production efficiency and safety.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JIANGMEN XINGHUA KITCHENWARE PRODUCTS CO LTD
- Filing Date
- 2025-06-06
- Publication Date
- 2026-06-23
AI Technical Summary
Existing automated steamer grinding equipment has safety hazards and low production capacity during the loading and unloading of the pot, and the high temperature of the pot can easily burn the operators when it is removed.
A feeding structure for grinding the body of a steamer was designed. The automatic delivery of the steamer body is achieved by using a conveyor belt, conveyor component one, and conveyor component two. The steamer body is cooled quickly by heat dissipation components, including a servo motor-driven sliding plate and a pneumatic push rod working with a suction cup to grasp and move the steamer body. The cooling is achieved by combining a fan and a dustproof mesh with heat dissipation grooves.
The system enables automated loading and unloading of the pot, improving production efficiency and reducing safety hazards. Furthermore, the rapid heat dissipation solves the problem of removing the high-temperature pot, enhancing the safety and productivity of the equipment.
Smart Images

Figure CN224390785U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the technical field of steam pot grinding equipment, and in particular relates to a feeding structure for grinding the body of a steam pot. Background Technology
[0002] A steamer is a type of cooking utensil, usually made of iron or stainless steel. The production process of a steamer involves several steps, including grinding and polishing. The grinding and polishing process is carried out using a grinding and polishing machine, which includes a worktable, a grinding mechanism, a rotating table, and a pot positioning mold.
[0003] Chinese patent application CN215317925U discloses an automated iron pot grinding and polishing device. This device includes a semi-enclosed polishing table and a robotic arm. The semi-enclosed polishing table contains a rotating platform, and the rotating platform has a positioning mold for clamping and positioning the iron pot. The robotic arm has a rotatable polishing wheel at its end. The rotating polishing wheel rubs against the rotating iron pot to achieve grinding and polishing. The workpiece is placed on the positioning mold, a polishing wheel suitable for the iron pot model is mounted on the robotic arm, the iron pot is placed on the positioning mold, the initial position is adjusted, and the device is turned on. The high-speed rotating polishing wheel rubs against the high-speed rotating iron pot to achieve the grinding and polishing purpose. This method produces products with stable and reliable quality, high efficiency, eliminates safety hazards caused by improper human operation, saves labor costs and equipment investment, and creates benefits for the company.
[0004] The aforementioned automated iron pot polishing equipment features a semi-enclosed polishing table with a rotating platform and a positioning mold. The positioning mold clamps and positions the pot. However, the semi-enclosed polishing table lacks other structures, requiring manual loading and unloading of the pots before and after polishing. This manual operation poses significant safety hazards and is slow, impacting production capacity. Furthermore, the rotating platform and positioning mold can only hold one pot at a time, requiring manual handling. This manual handling of individual pots, especially after polishing, can cause burns due to the pot's high temperature. Therefore, we provide a feeding structure for steam pot polishing to address these problems. Utility Model Content
[0005] The purpose of this utility model is to provide a feeding structure for grinding a steam pot body. By using a conveyor belt, conveyor component one and conveyor component two, the steam pot body can be automatically delivered to the grinding equipment. The heat dissipation component can quickly cool the pot body, thus solving the problems of the aforementioned automated iron pot grinding and polishing equipment.
[0006] To solve the above-mentioned technical problems, this utility model is achieved through the following technical solution:
[0007] This utility model relates to a feeding structure for grinding the body of a steamer, comprising a base; a conveyor belt is fixedly installed on the upper right end of the base, and a conveying assembly one is mounted on the upper left end of the conveyor belt. The conveying assembly one includes a connecting column fixed on the base, and a sliding frame is fixedly installed on the upper end of the connecting column. A sliding plate is slidably connected inside the sliding frame. Both ends of the sliding plate are provided with lead screws, and the shaft ends of the lead screws are connected to a servo motor. An electric push rod is fixedly installed on the bottom side wall of the sliding plate, and a hanging plate is fixedly installed on the other end of the electric push rod. A sliding pin is inserted into the hanging plate, and the hanging plate is connected to the base plate through the sliding pin. A conveying assembly two is provided on the left end of the conveying assembly one. The conveying assembly two includes a carrier box fixed on the base. Elastic tubes are fixedly installed on both outer walls of the carrier box, and the carrier box is connected to the side plate through the elastic tubes. A carrier component is embedded on the upper part of the carrier box, and a heat dissipation component is provided on the side of the carrier component.
[0008] The present invention is further configured such that a support column is welded to the upper right side wall of the base, and two support columns are provided in total. The two support columns are respectively located on both sides of the conveyor belt, and the top of the support column is fixedly connected to the outer walls of both sides of the conveyor belt by bolts.
[0009] The present invention is further configured such that a connecting plate is welded to the middle position of the base, and the base is fixedly connected to the side plate through the connecting plate, and a pneumatic push rod is fixedly installed on the side wall of the side plate facing the carrier box, and the side plate is connected to the carrier box through the pneumatic push rod.
[0010] The present invention is further configured such that an installation hole is provided at the center of the upper side wall of the carrier box, and a heat dissipation groove is provided on the side wall of the installation hole, and the carrier includes a rotating table fixed in the installation hole.
[0011] The present invention is further configured such that a fixing plate is fixedly provided at the rotating end of the rotating table, and the rotating table is fixedly connected to the positioning mold through the fixing plate; the heat dissipation component includes a dustproof net fixed in the heat dissipation groove, and an exhaust fan is fixedly installed below the dustproof net.
[0012] The present invention is further configured such that sliding rods are inserted at the four corners of the carrier box, and the sliding rods are also slidably connected to the side plates. Ventilation windows are embedded in the side plates, and the internal environment of the carrier box is connected to the external environment through the ventilation windows.
[0013] The present invention is further configured such that the bottom of the sliding column is fixedly connected to the base plate, and a spring is also sleeved on the sliding column, with the two ends of the spring being fixedly connected to the base plate and the hanging plate respectively.
[0014] The present invention is further configured such that a proximity sensor is fixedly installed on the side wall of the base plate, a suction cup is embedded in the center of the base plate, and a rubber column is fixedly installed on the bottom side wall of the base plate.
[0015] This utility model has the following beneficial effects:
[0016] This invention utilizes a conveyor belt, a first conveyor assembly, and a second conveyor assembly. In use, the steamer body to be polished is placed on the conveyor belt, which carries the steamer body to the location of the first conveyor assembly. The first conveyor assembly then operates, extending an electric push rod that lowers the base plate on its shaft until the suction cup and rubber column contact the steamer body. At this point, the suction cup, supported by air from the air pipe and the air pump on the production line, creates negative pressure on the steamer body and adsorbs it. After adsorption, the electric push rod retracts, moving the steamer body upwards. Simultaneously, because the electric push rod is mounted on a sliding plate, a servo motor operates, pushing the sliding plate along the sliding frame via a lead screw. As the steamer body moves... When the conveyor assembly reaches position two, and the pot is directly above the support, the electric push rod moves down, lowering the pot and placing it onto the fixed mold of the support. During this process, the proximity sensor remains active, detecting whether the pot has fallen or been attracted. After conveyor assembly one completes its work, it returns to its initial state. Conveyor assembly two then operates, extending its pneumatic push rod to push the support on the support box, carrying the pot towards the working platform of the grinding equipment. Once the pot has finished grinding, the pneumatic push rod on the other side operates, moving the pot to its initial position. During the movement of the pot, the heat dissipation component also operates simultaneously, drawing in the gas around the pot to cool it down.
[0017] This utility model incorporates a second conveying component and a heat dissipation component. The heat dissipation component, which includes an exhaust fan and a dustproof net, is embedded in the upper side wall of the carrier box in the second conveying component. The exhaust fan draws the gas above the carrier box into the carrier box and discharges it through the heat dissipation slots on both sides of the carrier box. Before entering the exhaust fan, the gas comes into contact with the dustproof net, which effectively blocks metal dust and prevents it from entering the exhaust fan. During this process, the gas in the surrounding environment of the pot is drawn away, which accelerates the cooling effect of the pot. Attached Figure Description
[0018] 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.
[0019] Figure 1 This is a schematic diagram of a feeding structure for grinding the body of a steamer.
[0020] Figure 2 This is a structural diagram of the base and conveyor belt.
[0021] Figure 3 This is a structural schematic diagram of the first conveyor component.
[0022] Figure 4 for Figure 3 Enlarged view of the structure at point A in the diagram.
[0023] Figure 5 This is a schematic diagram of the structure of conveyor component two.
[0024] Figure 6 This is a structural disassembly diagram of conveyor component two.
[0025] The attached diagram lists the components represented by each number as follows:
[0026] 1-Base, 101-Support column, 102-Connecting plate, 103-Connecting sleeve, 2-Conveyor belt, 3-Conveyor assembly one, 301-Sliding frame, 302-Connecting column, 303-Slide plate, 303a-Electric push rod, 304-Lead screw, 305-Servo motor, 306-Hanging plate, 307-Sliding column, 307a-Spring, 308-Base plate, 308a-Suction cup, 308b-Proximity sensor, 308c-Rubber Column, 4-Conveying assembly two, 401-Carrier box, 401a-Mounting hole, 401b-Heat dissipation groove, 401c-Connecting ring, 401d-Pneumatic push rod, 402-Carrier component, 402a-Rotating table, 402b-Fixing plate, 402c-Positioning mold, 403-Heat dissipation component, 403a-Exhaust fan, 403b-Dustproof net, 404-Slide rod, 405-Elastic tube, 406-Side plate, 406a-Ventilation window. Detailed Implementation
[0027] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention. Example 1
[0028] Please see Figures 1-2 This utility model is a feeding structure for grinding the body of a steamer, including a base 1 and a conveyor belt 2, which can initially transport the body of the steamer.
[0029] Specifically, a support column 101 is welded onto the base 1, and the support column 101 is connected to the outer shell of the conveyor belt 2 by bolts.
[0030] Furthermore, the conveyor belt 2 is located at the right end of the base 1, and there are two support columns 101, which are located on both sides of the conveyor belt 2.
[0031] The operation process of this embodiment is as follows: When in use, the pot body of the steamer that needs to be polished is placed on the conveyor belt 2, and the conveyor belt 2 is used to place the pot body of the steamer. Under the action of the conveyor belt 2, the pot body is transported to the location of the conveyor component 3. Example 2
[0032] Please see Figures 3-4 Based on embodiment 1, a conveying component 3 is also provided. The conveying component 3 can not only grab the pot body, but also transport it to the conveying component 4.
[0033] Specifically, a connecting sleeve 103 is welded onto the base 1. The conveying assembly 3 includes a connecting column 302 fixedly connected to the connecting sleeve 103. A sliding frame 301 is fixedly installed on the top of the connecting column 302. A sliding plate 303 is slidably arranged inside the sliding frame 301. Screws 304 are provided at both ends of the sliding plate 303. The shaft end of the screw 304 is connected to a servo motor 305. An electric push rod 303a is fixedly installed on the bottom side wall of the sliding frame 301. A hanging plate 306 is fixedly installed on the bottom side wall of the electric push rod 303a.
[0034] Furthermore, a base plate 308 is provided below the hanging plate 306. A sliding post 307 is provided on the base plate 308, and a spring 307a is sleeved on the sliding post 307. The base plate 308 is connected to the hanging plate 306 through the sliding post 307. A rubber post 308c is fixedly installed on the bottom side wall of the base plate 308. The rubber post 308c is used to buffer the contact between the pot body and the base plate 308 during the adsorption process to avoid scratches. A suction cup 308a is embedded in the center of the base plate 308, and a proximity sensor 308b is fixedly installed on the outer side wall of the base plate 308.
[0035] The operation process of this embodiment is as follows: During use, the electric push rod 303a extends, driving the bottom plate 308 on its shaft end to move downward until the suction cup 308a and the rubber column 308c contact the pot body and then stop extending. At this time, the suction cup 308a generates negative pressure on the pot body and adsorbs it with the air source support of the air pipe and the air pump on the production line. After the adsorption work is completed, the electric push rod 303a retracts and drives the pot body to move upward. At the same time, since the electric push rod 303a is installed on the slide plate 303 and the servo motor 305 is working, it pushes the slide plate 303 to move on the sliding frame 301 through the lead screw 304. When the pot body moves to the position of the second conveying component 4 and the pot body is exactly above the carrier 402, the electric push rod 303a moves downward and lowers the pot body and puts it on the fixed mold 402c of the carrier 402. During this process, the proximity sensor 308b is always in working state and is used to detect and determine whether the pot body has fallen or has been adsorbed. Example 3
[0036] Please see Figures 5-6 Based on Embodiment 1 and Embodiment 2, a second conveying component 4 is also provided. The second conveying component 4 can deliver the steamer body to the grinding equipment, and the heat dissipation component 403 can quickly cool the steamer body.
[0037] Specifically, a connecting plate 102 is welded onto the base 1, and the second conveying component 4 includes a carrier box 401. Elastic tubes 405 are fixedly installed on both sides of the carrier box 401, and the other end of the elastic tubes 405 is connected to the side plate 406. The side plate 406 is fixedly installed on the connecting plate 102. A carrier component 402 is embedded in the center of the upper side wall of the carrier box 401, and a heat dissipation component 403 is provided on the side of the carrier component 402.
[0038] Furthermore, a mounting hole 401a is provided at the center of the carrier box 401, and a heat dissipation groove 401b is provided on the side of the mounting hole 401a. The carrier component 402 includes a rotating platform 402a fixed in the mounting hole 401a, and the rotating end of the rotating platform 402a is connected to the positioning mold 402c through the fixing plate 402b. The heat dissipation component 403 is wrapped with a dustproof net 403b embedded in the heat dissipation groove 401b, and an exhaust fan is fixedly installed below the dustproof net 403b. Machine 403a, connecting rings 401c are fixed on the outer walls of both sides of the bearing box 401, and the bearing box 401 is connected to the elastic tube 405 through the connecting rings 401c. Ventilation windows 406a are also embedded in the side plate 406. Pneumatic push rods 401d are also installed on the side plate 406, and the other end of the pneumatic push rods 401d is connected to the bearing box 401. Slide rods 404 are fixedly inserted at the four corners of the bearing box 401, and the slide rods 404 are also slidably connected to the side plate 406.
[0039] The operation process of this embodiment is as follows: When in use, the pneumatic push rod 401d extends and pushes the carrier 402 on the carrier box 401 to move the pot body toward the working platform side of the grinding equipment. After the pot body completes the grinding work, the pneumatic push rod 401d on the other side works to move the pot body to the initial position. During the movement of the pot body, the heat dissipation component 403 also works at the same time, which draws in the gas around the pot body to achieve the effect of cooling the pot body.
[0040] In the description of this specification, references to terms such as "an embodiment," "example," "specific example," etc., indicate that a specific feature, structure, material, or characteristic described in connection with that embodiment or example is included in at least one embodiment or example of the present invention. In this specification, the illustrative expressions of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the specific features, structures, materials, or characteristics described may be combined in any suitable manner in one or more embodiments or examples.
Claims
1. A feeding structure for grinding the body of a steamer, comprising a base (1); characterized in that: A conveyor belt (2) is fixedly installed on the upper right side of the base (1), and a conveyor assembly (3) is mounted on the upper left side of the conveyor belt (2). The conveyor assembly (3) includes a connecting column (302) fixed on the base (1), and a sliding frame (301) is fixedly installed on the upper end of the connecting column (302). A sliding plate (303) is slidably connected inside the sliding frame (301). Both ends of the sliding plate (303) are also provided with lead screws (304), and the shaft end of the lead screw (304) is connected to a servo motor (305). An electric push rod (303a) is fixedly installed on the bottom side wall of the sliding plate (303), and the other end of the electric push rod (303a) is fixedly provided with a... A hanging plate (306) is provided, and a sliding pin (307) is inserted into the hanging plate (306). The hanging plate (306) is connected to the base plate (308) through the sliding pin (307). A conveying component two (4) is provided at the left end of the first conveying component (3). The second conveying component two (4) includes a carrier box (401) fixed on the base (1). Elastic tubes (405) are fixed on the outer walls of both sides of the carrier box (401). The carrier box (401) is connected to the side plate (406) through the elastic tubes (405). A carrier component (402) is embedded and installed above the carrier box (401). A heat sink component (403) is provided on the side of the carrier component (402).
2. The feeding structure for grinding the body of a steamer according to claim 1, characterized in that, The upper right side wall of the base (1) is welded with a support column (101). There are two support columns (101) in total. The two support columns (101) are respectively located on both sides of the conveyor belt (2). The top of the support column (101) is fixedly connected to the outer walls of both sides of the conveyor belt (2) by bolts.
3. The feeding structure for grinding the body of a steamer according to claim 1, characterized in that, A connecting plate (102) is welded to the middle of the base (1), and the base (1) is fixedly connected to the side plate (406) through the connecting plate (102). A pneumatic push rod (401d) is fixedly installed on the side wall of the side plate (406) facing the carrier box (401), and the side plate (406) is connected to the carrier box (401) through the pneumatic push rod (401d).
4. The feeding structure for grinding the body of a steamer according to claim 1, characterized in that, The upper side wall of the carrier box (401) is provided with a mounting hole (401a) and a heat dissipation groove (401b) is provided on the side wall of the mounting hole (401a). The carrier (402) includes a rotating table (402a) fixed in the mounting hole (401a).
5. The feeding structure for grinding the body of a steamer according to claim 4, characterized in that, The rotating end of the rotating table (402a) is fixedly provided with a fixing plate (402b), and the rotating table (402a) is fixedly connected to the positioning mold (402c) through the fixing plate (402b). The heat dissipation component (403) includes a dustproof net (403b) fixed in the heat dissipation groove (401b), and an exhaust fan (403a) is fixedly installed below the dustproof net (403b).
6. The feeding structure for grinding the body of a steamer according to claim 5, characterized in that, The four corners of the carrier box (401) are connected to sliding rods (404), and the sliding rods (404) are also slidably connected to the side plate (406). The side plate (406) is inlaid with ventilation windows (406a), and the internal environment of the carrier box (401) is connected to the external environment through the ventilation windows (406a).
7. The feeding structure for grinding the body of a steamer according to claim 1, characterized in that, The bottom of the sliding column (307) is fixedly connected to the base plate (308), and a spring (307a) is also sleeved on the sliding column (307). The two ends of the spring (307a) are fixedly connected to the base plate (308) and the hanging plate (306) respectively.
8. The feeding structure for grinding the body of a steamer according to claim 7, characterized in that, A proximity sensor (308b) is fixedly installed on the side wall of the base plate (308), and a suction cup (308a) is embedded in the center of the base plate (308). A rubber column (308c) is fixedly installed on the bottom side wall of the base plate (308).