A scoop press device
By using a heat-conducting block and an electric heating wire to heat the sheet-shaped plastic raw material on both sides in the sampling spoon molding device, and combining this with a temperature controller to control the temperature, the problem of low heating efficiency in the prior art is solved, and efficient preheating and molding of plastic raw materials is achieved.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- XIAMEN YIXIEHANG MEDICAL TECH CO LTD
- Filing Date
- 2025-06-18
- Publication Date
- 2026-06-26
Smart Images

Figure CN224408246U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of sampling spoon manufacturing technology, specifically to a sampling spoon molding device. Background Technology
[0002] A sampling spoon is a tool specifically designed for extracting samples from liquids, powders, or granular substances. It is widely used in fields such as chemistry, pharmaceuticals, food processing, and environmental monitoring. Sampling spoons are made of various materials, including stainless steel, plastic, and horn.
[0003] Plastic sampling spoons are tools commonly used in laboratories, food processing, and pharmaceuticals, primarily for sampling and dispensing powders, granules, or viscous substances. During production, plastic sampling spoons utilize a molding process to process sheet-like plastic raw materials. The sampling spoon molding die has a preheating structure for preheating the sheet-like plastic raw material. However, existing preheating structures on sampling spoon molding dies are all single-sided designs, only heating the bottom or top surface of the sheet-like plastic raw material, resulting in low heating efficiency. Therefore, a sampling spoon molding device is proposed. The sheet-like plastic raw material moves within a channel and is heated by heat-conducting blocks at the bottom and top of the structural block, along with an electric heating wire, resulting in high heating efficiency. Utility Model Content
[0004] To address the problems in the existing technology, this utility model provides a sampling spoon molding device, in which the plastic raw material moves in the channel and is heated by the heat-conducting blocks at the bottom and top of the structural block and the electric heating wire, resulting in high heating efficiency.
[0005] The technical solution adopted by this utility model to solve its technical problem is a sampling spoon forming device, including a base plate, a forming assembly provided on the top of the base plate, the forming assembly including a first gantry frame fixed to the top of the base plate by bolts, a lower mold fixed to the inside of the first gantry frame located on the top of the base plate by bolts, a cylinder mounted on the top of the first gantry frame by a mounting bracket, and an upper mold fixed to the output shaft of the cylinder located inside the first gantry frame by a flange;
[0006] The base plate is provided with a heating component on the top of one side of the first gantry frame. The heating component includes a structural block that is fixed to the top of the base plate by bolts. The top and bottom of the structural block are both fixed with heat-conducting blocks by bolts. Electric heating wires are embedded in the heat-conducting blocks at equal intervals. A through groove is opened on one side of the structural block.
[0007] By adopting the above technical solution, the heat-conducting block transfers the temperature of the electric heating wire to the plate-shaped plastic raw material moving in the channel, preheating it. The cylinder pushes the upper mold down to press it onto the lower mold, molding the preheated plate-shaped plastic raw material to form it.
[0008] Specifically, a thermostat is mounted on one end of the structural block via a mounting base. The detection end of the thermostat is located inside the heat-conducting block, and the current output end of the thermostat is electrically connected to the current input end of the heating wire via a power cord.
[0009] Specifically, the structural block is made of glass fiber material, and the heat-conducting block is made of graphene material.
[0010] Specifically, material conveying assemblies are provided at both ends of the top of the base plate. The material conveying assemblies include a second gantry frame that is fixed to both ends of the top of the base plate by bolts. A conveying roller is rotatably connected inside the second gantry frame through a bearing. A geared motor is mounted on one end of the second gantry frame through a mounting bracket. The output shaft of the geared motor is connected to the rotating shaft of the conveying roller through a connecting sleeve.
[0011] Specifically, the top two ends of the second gantry are connected to uprights, and the bottom of the uprights inside the second gantry is connected to a structural frame through a threaded groove. The bottom of the structural frame is rotatably connected to a pressure roller through a bearing.
[0012] Specifically, a compression spring is fitted on the outer side of the upright at the top of the structural frame.
[0013] The beneficial effects of this utility model are:
[0014] The sampling spoon forming device of this utility model sets a temperature controller to control the heating of the electric heating wire. The heat-conducting block absorbs the temperature after the electric heating wire is heated and conducts it to the plate-shaped plastic material moving in the channel, thereby heating the plate-shaped plastic material and preheating the bottom and top of the plate-shaped plastic material.
[0015] The sampling spoon forming device of this utility model uses a compression spring to push the structural frame and the pressing roller at its bottom to move down, pressing the sheet-shaped plastic raw material onto the conveying roller. The geared motor is turned on to drive the conveying roller to rotate, thus conveying the sheet-shaped plastic raw material. Attached Figure Description
[0016] The present invention will be further described below with reference to the accompanying drawings and embodiments.
[0017] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0018] Figure 2 This is a schematic diagram of the molding assembly structure of this utility model;
[0019] Figure 3 This is a schematic diagram of the heating component structure of this utility model;
[0020] Figure 4 This is a schematic diagram of the material conveying assembly structure of this utility model;
[0021] In the diagram: 1. Base plate; 2. Forming assembly; 201. First gantry frame; 202. Lower mold; 203. Cylinder; 204. Upper mold; 3. Heating assembly; 301. Structural block; 302. Through slot; 303. Heat-conducting block; 304. Electric heating wire; 4. Material conveying assembly; 401. Second gantry frame; 402. Conveyor roller; 403. Gear motor; 404. Upright pole; 405. Structural frame; 406. Pressure roller; 407. Compression spring; 5. Temperature controller. Detailed Implementation
[0022] To make the technical means, creative features, objectives and effects of this utility model easier to understand, the present utility model will be further described below in conjunction with specific embodiments.
[0023] The plastic raw material moves within the channel and is heated by heat-conducting blocks at the bottom and top of the structural block, as well as by electric heating wires, resulting in high heating efficiency. Figure 1-4 As shown, the sampling spoon forming device of this utility model includes a base plate 1, a forming assembly 2 is provided on the top of the base plate 1, the forming assembly 2 includes a first gantry frame 201 fixed to the top of the base plate 1 by bolts, a lower mold 202 is fixed to the inside of the first gantry frame 201 located on the top of the base plate 1 by bolts, a cylinder 203 is mounted on the top of the first gantry frame 201 by a mounting bracket, and an upper mold 204 is fixed to the output shaft of the cylinder 203 located inside the first gantry frame 201 by a flange;
[0024] The base plate 1 is provided with a heating component 3 on the top of one side of the first gantry frame 201. The heating component 3 includes a structural block 301 fixed to the top of the base plate 1 by bolts. The top and bottom of the structural block 301 are both fixed with heat-conducting blocks 303 by bolts. Electric heating wires 304 are embedded in the heat-conducting blocks 303 at equal intervals. A through groove 302 is provided on one side of the structural block 301.
[0025] In use, the heat-conducting block 303 conducts the temperature of the heated electric heating wire 304 to the plate-shaped plastic material moving in the channel 302 to preheat it. The cylinder 203 pushes the upper mold 204 down to press it onto the lower mold 202, molding the preheated plate-shaped plastic material to form it.
[0026] For example, such as Figure 1 , Figure 3 As shown, the present invention also includes a thermostat 5 mounted on one end of the structural block 301 via a mounting base. The detection end of the thermostat 5 is located inside the heat-conducting block 303, and the current output end of the thermostat 5 is electrically connected to the current input end of the electric heating wire 304 via a power cord.
[0027] During use, the heating of the electric heating wire 304 and its heating temperature can be controlled by the thermostat 5.
[0028] For example, such as Figure 3 As shown, the present invention also includes that the structural block 301 is made of glass fiber material and the heat-conducting block 303 is made of graphene material.
[0029] In use, the structural block 301 made of glass fiber material serves as insulation and heat insulation, while the heat-conducting block 303 made of graphene material has good thermal conductivity.
[0030] For example, such as Figure 4 As shown, the present invention also includes a material conveying assembly 4 provided at both ends of the top of the base plate 1. The material conveying assembly 4 includes a second gantry frame 401 fixed to both ends of the top of the base plate 1 by bolts. A conveying roller 402 is rotatably connected inside the second gantry frame 401 through a bearing. A reduction motor 403 is mounted on one end of the second gantry frame 401 through a mounting bracket. The output shaft of the reduction motor 403 is connected to the rotating shaft of the conveying roller 402 through a connecting sleeve.
[0031] In use, the geared motor 403 drives the conveyor roller 402 to rotate, conveying the sheet-shaped plastic raw material.
[0032] For example, such as Figure 4 As shown, the present invention also includes a vertical pole 404 that is sleeved through both ends of the top of the second gantry frame 401. The bottom end of the vertical pole 404 located inside the second gantry frame 401 is connected to a structural frame 405 through a threaded groove. The bottom of the structural frame 405 is rotatably connected to a pressure roller 406 through a bearing.
[0033] During use, the pressure roller 406 presses the sheet-shaped plastic raw material onto the conveyor roller 402.
[0034] For example, such as Figure 4 As shown, the present invention also includes a compression spring 407 sleeved on the outer side of the upright 404 at the top of the structural frame 405.
[0035] In use, the compression spring 407 can push the structural frame 405 and the pressure roller 406 at its bottom to move downward.
[0036] In use, the user connects the device to an external power source using a power cord, pulls up the upright 404 to move the structural frame 405 upward, inserts the sheet-shaped plastic material into the second gantry 401 and the through groove 302, and after releasing the upright 404, the compression spring 407 pushes the structural frame 405 and the pressing roller 406 at its bottom downward to press the sheet-shaped plastic material onto the conveyor roller 402. The reduction motor 403 is turned on to drive the conveyor roller 402 to rotate and transport the sheet-shaped plastic material.
[0037] The temperature controller 5 sets the set value to control the heating of the electric heating wire 304. The heat-conducting block 303 absorbs the temperature after the electric heating wire 304 is heated and conducts it to the plate-shaped plastic material moving in the channel 302, thereby heating the plate-shaped plastic material and preheating the bottom and top of the plate-shaped plastic material.
[0038] After the preheated sheet-shaped plastic raw material enters between the lower mold 202 and the upper mold 204, the cylinder 203 is opened to push the upper mold 204 down, so that it presses on the lower mold 202. The preheated sheet-shaped plastic raw material is molded by the upper mold 204 and the lower mold 202.
[0039] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The descriptions of the above embodiments and specifications are merely illustrative of the principles of this utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of protection claimed by this utility model. The scope of protection of this utility model is defined by the appended claims and their equivalents.
Claims
1. A sampling spoon forming device, characterized in that, Includes a base plate (1), and a forming assembly (2) is provided on the top of the base plate (1). The forming assembly (2) includes a first gantry frame (201) fixed to the top of the base plate (1) by bolts. The first gantry frame (201) is located inside the top of the base plate (1) and a lower mold (202) is fixed by bolts. A cylinder (203) is mounted on the top of the first gantry frame (201) by a mounting bracket. The output shaft of the cylinder (203) located inside the first gantry frame (201) is fixed to an upper mold (204) by a flange. The base plate (1) is provided with a heating component (3) on the top of one side of the first gantry frame (201). The heating component (3) includes a structural block (301) fixed to the top of the base plate (1) by bolts. The top and bottom of the structural block (301) are both fixed with heat-conducting blocks (303) by bolts. Electric heating wires (304) are embedded in the heat-conducting blocks (303) at equal intervals. A through groove (302) is opened on one side of the structural block (301).
2. The sampling spoon forming device according to claim 1, characterized in that, A thermostat (5) is mounted on one end of the structural block (301) via a mounting base. The detection end of the thermostat (5) is located inside the heat-conducting block (303). The current output end of the thermostat (5) is electrically connected to the current input end of the electric heating wire (304) via a power line.
3. The sampling spoon forming device according to claim 1, characterized in that, The structural block (301) is made of glass fiber material, and the heat-conducting block (303) is made of graphene material.
4. The sampling spoon forming device according to claim 1, characterized in that, The bottom plate (1) is provided with material conveying components (4) at both ends of the top. The material conveying components (4) include a second gantry frame (401) fixed to both ends of the top of the bottom plate (1) by bolts. The second gantry frame (401) is rotatably connected to a conveying roller (402) through a bearing. A geared motor (403) is installed at one end of the second gantry frame (401) through a mounting bracket. The output shaft of the geared motor (403) is connected to the rotating shaft of the conveying roller (402) through a connecting sleeve.
5. The sampling spoon forming device according to claim 4, characterized in that, The top two ends of the second gantry frame (401) are connected to uprights (404). The bottom end of the uprights (404) inside the second gantry frame (401) is connected to a structural frame (405) through a threaded groove. The bottom of the structural frame (405) is rotatably connected to a pressure roller (406) through a bearing.
6. The sampling spoon forming device according to claim 5, characterized in that, The upright (404) is fitted with a compression spring (407) on the outer side of the top of the structural frame (405).