A shaping device for processing puncture-resistant gloves

By combining multiple placement mechanisms and an electric push rod to drive the lifting plate, the problem of quickly adapting gloves of different sizes is solved. The lubrication mechanism solves the friction and wear between the slider and the slide rod, thus improving the production efficiency and stability of the puncture-resistant glove processing device.

CN224494613UActive Publication Date: 2026-07-14LANGXI RUNXIANG RUBBER NEW MATERIAL CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
LANGXI RUNXIANG RUBBER NEW MATERIAL CO LTD
Filing Date
2025-09-09
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

Existing puncture-resistant glove processing equipment requires changing the placement plate when changing to different sizes of gloves, lacking a quick positioning and locking structure, resulting in low production line changeover efficiency; the slider and slide rod lack a lubrication structure, which easily leads to wear and jamming of parts due to friction.

Method used

The system employs multiple placement mechanisms and detachable placement plates, combined with an electric push rod to drive the lifting plate, enabling rapid adaptation of gloves of different sizes; a lubrication mechanism is set up to deliver lubricating oil through a pump to reduce friction between the sliding sleeve and the guide rod.

Benefits of technology

It enables rapid replacement and stable fixation of gloves of different sizes, improves production efficiency, reduces equipment investment costs, avoids component wear, and ensures consistent shaping quality and device stability.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a shaping device is used in puncture -resistant glove processing belongs to glove processing technical field, includes, work table, its top parallel top plate is provided with, the symmetry of work table is vertically fixed with a plurality of guide rod, the top of a plurality of guide rods and top plate bottom wall fixedly connected, the lifting plate is liftable and is installed between top plate and work table, and the both ends of lifting plate and both sides guide rod sliding fit, and a plurality of groups of placing mechanism are arranged in sequence and are spaced apart on the lifting plate, and every group placing mechanism can detachably connect the placing plate, and the abutting component drives the abutting plate to adapt to abutting the placing plate with the elastic force of first spring, and can complete the preliminary fixation without extra tool, and the adjusting component can pass to the cooperation of the cooperation of the plug rod and the insertion hole through the removal first sleeve, and the abutting position is adjusted flexibly, and adapts S / M / L etc.
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Description

Technical Field

[0001] This utility model relates to a shaping device for processing puncture-resistant gloves, belonging to the field of glove processing technology. Background Technology

[0002] Puncture-resistant gloves, as a type of hand protection product with special protective functions, are widely used in various fields such as machining, construction, logistics handling, garden pruning, and military and police security. Their core function lies in using special materials and composites to resist puncture injuries to the user's hands from sharp objects, ensuring personal safety during operation. Shaping is a crucial step in the manufacturing process of puncture-resistant gloves.

[0003] For example, utility model patent CN222987630U discloses a glove shaping device, specifically including a processing table; a top plate, which is disposed above the processing table and is fixedly connected to the processing table by a support frame, forming a glove processing area between the top plate and the processing table; and a pressing plate, which is vertically slidably connected between the processing table and the top plate, and the pressing plate and the top plate cooperate to form a glove shaping structure. After the glove to be shaped is placed on the pressing plate, the pressing plate can be pushed upward until the pressing plate and the top plate cooperate to press the glove, thus completing the glove shaping operation. This replaces manual glove shaping, reduces manual labor, and improves the efficiency of glove shaping.

[0004] However, the above solution has the following shortcomings in practical use:

[0005] First, the above-mentioned device can only place a single-size placement plate. If it is necessary to switch to different sizes of gloves (such as S / M / L sizes), the corresponding size placement plate needs to be replaced. However, the patent does not design a quick positioning and locking structure for the placement plate. When changing manually, it is necessary to repeatedly adjust and align, which takes a long time and affects the changeover efficiency of the production line.

[0006] Second, the extrusion plate slides on the slide rod via a slider sleeve, but the patent does not mention the lubrication structure between the slider and the slide rod. After long-term use, the parts are prone to wear due to friction, resulting in sliding jamming. Utility Model Content

[0007] To solve the above-mentioned technical problems, this utility model provides a shaping device for processing puncture-resistant gloves, which realizes the placement and locking of placement plates of different sizes. At the same time, a lubrication mechanism is provided on this device to lubricate the guide rod and the sliding sleeve, so as to avoid wear of parts due to friction during long-term use.

[0008] The technical solution adopted by this utility model to solve its technical problem is:

[0009] A shaping device for processing puncture-resistant gloves includes a workbench with a top plate arranged parallel to it. Multiple guide rods are symmetrically erected and fixed on the workbench, with the top ends of the guide rods fixed to the bottom wall of the top plate. A lifting plate is movably mounted between the top plate and the workbench, with the guide rods at both ends and sides of the lifting plate slidingly engaged. Multiple sets of placement mechanisms are arranged at intervals on the lifting plate, each set of placement mechanisms having a detachable placement plate. Each placement mechanism has a placement groove formed on the lifting plate, with a clamping component movably connected within the groove to clamp the placement plate. An adjusting component is provided on the side wall of the lifting plate to adjust the clamping position of the clamping component.

[0010] In this solution, multiple placement mechanisms on the lifting plate, through the cooperation of placement slots, clamping components, and adjusting components, enable detachable connection and fixation of placement plates of different sizes. There is no need to redesign the overall structure for different glove sizes (such as S / M / L sizes); only the corresponding placement plate needs to be replaced and the components adjusted for fixation, thus improving the device's versatility.

[0011] The clamping component effectively clamps the placement plate, and the adjusting component allows for flexible adjustment of the clamping position, ensuring stable installation of placement plates of different sizes. This solves the problem of repeated alignment adjustments required when changing placement plates in traditional devices, shortens changeover time, and improves production efficiency.

[0012] The device, with its detachable placement plate and adjustable clamping structure, eliminates the need to redesign the entire equipment for different glove sizes. Simply replacing the corresponding placement plate completes the processing adaptation, reducing equipment investment costs and expanding the device's applicability.

[0013] Preferably, at least one electric push rod is fixedly installed on the top wall of the workbench, and the output end of the electric push rod is fixedly connected to the bottom wall of the lifting plate.

[0014] In this solution, the lifting plate is driven to rise and fall by an electric push rod. Compared with manual pushing or other mechanical driving methods, it can achieve precise control of lifting speed and lifting height, ensuring uniform and stable squeezing force between the lifting plate and the top plate, and improving the consistency of the shaping quality of the puncture-resistant gloves.

[0015] The automated drive of electric linear actuators replaces manual operation, reducing physical labor intensity. At the same time, it can be linked with the production line control system to realize the automated connection of the shaping process and improve the overall production efficiency.

[0016] Preferably, the clamping assembly includes: a through groove formed on the side wall of the lifting plate and communicating with the placement groove; a first sleeve slidably connected in the through groove; a push rod passing through the first sleeve and slidingly engaging with the first sleeve; one end of the push rod extending into the placement groove and fixedly connected to a clamping plate; a first limiting ring fixedly connected to the outer wall of the push rod inside the first sleeve; and a first spring sleeved on the outer wall of the push rod on the side of the first limiting ring away from the placement groove.

[0017] In this design, the push rod, under the elastic force of the first spring, drives the clamping plate to press against the placement plate. The clamping force can be automatically adjusted according to the thickness of the placement plate, which can ensure that the placement plate is stable and does not loosen, and can also avoid damage to the placement plate due to excessive clamping force.

[0018] The first limiting ring restricts the sliding range of the push rod within the first sleeve, preventing the push rod from coming out of the sleeve and ensuring the structural integrity and service life of the clamping assembly.

[0019] The elastic clamping structure of the clamping component allows for the installation and removal of the placement plate without additional tools, simplifying the operation and further improving the efficiency of replacing the placement plate.

[0020] Preferably, the adjusting assembly includes: a second sleeve fixed to the top wall of the lifting plate, a rod slidably connected inside the second sleeve, the bottom end of the rod extending into the through groove, a second limiting ring fixed to the outer wall of the rod inside the second sleeve, and a second spring sleeved on the outer wall of the rod on the side of the second limiting ring away from the lifting plate, and a plurality of insertion holes equally spaced along the length of the top wall of the first sleeve, the rod being inserted into one of the insertion holes.

[0021] In this solution, the position of the first sleeve in the through groove is moved, and then the insertion rod is used to insert into different holes to achieve fixation. The clamping position of the clamping component can be flexibly adjusted according to the size of the placement plate, ensuring that it can effectively clamp different specifications of placement plates, and has stronger adaptability.

[0022] The cooperation between the insert rod and the insertion hole enables precise positioning of the first sleeve, preventing positional displacement of the clamping component during the shaping process, ensuring the stability of the placement plate, and thus guaranteeing the shaping accuracy.

[0023] Pulling the insert rod upwards will release the restriction on the first sleeve. After adjustment, release the insert rod, and the insert rod will automatically insert into the socket under the action of the second spring to complete the fixation. The adjustment process requires no complicated tools and is highly efficient.

[0024] Preferably, sliding sleeves are fixedly connected to both sides of the lifting plate, and the sliding sleeves are slidably sleeved on the outside of the guide rod. A lubrication mechanism is also provided on the top plate. The lubrication mechanism connects to multiple sliding sleeves. The lubrication mechanism has: a storage tank fixedly connected to the top plate, and the storage tank is filled with lubricating oil. An annular groove is opened inside the sliding sleeve. An oil outlet is opened on the inner peripheral wall of the sliding sleeve that fits against the guide rod and connects to the annular groove. The annular groove and the storage tank are connected by a connecting hose, and a pump body is fixedly connected to the connecting hose.

[0025] In this scheme, the lubrication mechanism uses a pump to deliver lubricating oil from the storage tank to the annular groove of the sliding sleeve via a connecting hose, and then applies it to the surface of the guide rod through the oil outlet. This effectively reduces the frictional resistance between the sliding sleeve and the guide rod, avoids slippage and jamming, and ensures smooth lifting of the lifting plate.

[0026] Continuous lubrication reduces wear between the sleeve and the guide rod, lowers the probability of damage to components due to friction, reduces the frequency of replacement and maintenance, and reduces the operating cost of the device.

[0027] The pump body enables automatic delivery of lubricating oil, eliminating the need for frequent manual grease addition, reducing manual maintenance workload, and improving the continuity and stability of equipment operation.

[0028] Preferably, multiple oil outlets are provided and are distributed at equal angles on the inner peripheral wall of the sliding sleeve.

[0029] In this design, multiple oil outlets distributed at equal angles can evenly deliver lubricating oil to the outer peripheral wall of the guide rod, ensuring that the contact surface between the guide rod and the sleeve is covered with lubricating oil, avoiding wear or jamming caused by insufficient local lubrication, and further improving the lubrication effect.

[0030] Uniform lubrication of the guide rod surface allows for more even force distribution when the sleeve slides on the guide rod, reducing the shaking of the lifting plate caused by uneven local friction and ensuring stability and shaping accuracy during the shaping process.

[0031] Compared with the prior art, the beneficial effects of this utility model are as follows:

[0032] 1. By combining the clamping component and the adjusting component in the placement mechanism, the problem of repeated alignment adjustments required when changing placement plates in traditional devices is solved. The clamping component uses the elastic force of the first spring to drive the clamping plate to adaptively clamp the placement plate, achieving initial fixation without additional tools. The adjusting component can flexibly adjust the clamping position by moving the first sleeve and using the cooperation of the insert rod and the insertion hole to adapt to placement plates of different sizes such as S / M / L, achieving precise positioning and locking, significantly shortening changeover time and improving the continuity of the production line.

[0033] 2. To address the problem of insufficient lubrication between the slider and guide rod in traditional devices, which easily leads to wear and jamming due to friction, this device is equipped with a lubrication mechanism. This mechanism stores lubricating oil in a storage tank, and uses a pump to deliver the lubricating oil through a connecting hose to the annular groove of the sliding sleeve. Then, it is evenly applied to the surface of the guide rod through multiple oil outlets, effectively reducing the frictional resistance between the sliding sleeve and the guide rod and preventing jamming during lifting. Attached Figure Description

[0034] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art 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 the structures shown in these drawings without creative effort.

[0035] Figure 1 This is a front view of the present invention;

[0036] Figure 2 This is a top sectional view of the lifting plate in this utility model;

[0037] Figure 3 This utility model Figure 2 Enlarged view of the structure at point A in the middle;

[0038] Figure 4 This is a front sectional view of the lifting plate in this utility model;

[0039] Figure 5 This is a top view of the first sleeve in this utility model;

[0040] In the picture:

[0041] 1. Workbench; 11. Top plate; 12. Guide rod; 13. Electric push rod;

[0042] 2. Lifting plate; 21. Sliding sleeve;

[0043] 3. Placement mechanism; 31. Placement slot; 32. Anchoring assembly; 321. Through slot; 322. First sleeve; 323. Push rod; 324. Anchoring plate; 325. First spring; 326. First limiting ring; 33. Adjustment assembly; 331. Second sleeve; 332. Insert rod; 333. Second limiting ring; 334. Second spring; 335. Insertion hole;

[0044] 4. Lubrication mechanism; 41. Storage tank; 42. Annular groove; 43. Oil outlet; 44. Connecting hose; 45. Pump body. Detailed Implementation

[0045] 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.

[0046] Please see Figure 1-5 This utility model provides a technical solution:

[0047] A shaping device for processing puncture-resistant gloves includes a workbench 1 with a top plate 11 arranged parallel above it. Multiple guide rods 12 are symmetrically erected and fixed on the workbench 1, with the top ends of the multiple guide rods 12 fixed to the bottom wall of the top plate 11. A lifting plate 2 is movably installed between the top plate 11 and the workbench 1, and the two ends of the lifting plate 2 are slidably engaged with the guide rods 12 on both sides. Multiple sets of placement mechanisms 3 are arranged at intervals on the lifting plate 2. Each set of placement mechanisms 3 can be detachably connected to a placement plate. The placement mechanism 3 has a placement groove 31 opened on the lifting plate 2, and a clamping component 32 for clamping the placement plate is movably connected in the placement groove 31. An adjusting component 33 for adjusting the clamping position of the clamping component 32 is provided on the side wall of the lifting plate 2.

[0048] Specifically, multiple guide rods 12 are symmetrically erected and fixed on the top wall of the workbench 1, and the top plate 11 is placed horizontally above the workbench 1, so that the bottom wall of the top plate 11 is fixedly connected to the top of the multiple guide rods 12. The workbench 1, the top plate 11 and the guide rods 12 form a stable support frame for the device.

[0049] Among them, the overall length of the lifting plate 2 ( Figure 1 The distance between the front and rear side walls of the lifting plate 2 in the view is greater than the length of the worktable 1 and the top plate 11. The extended length corresponds to the position of the adjustment component 32, so that the adjustment component 32 will not collide with the top plate 11 after the lifting plate 2 is raised or lowered.

[0050] In addition, a placement cavity is provided at the top of the placement plate, and gloves to be processed are placed inside the placement cavity.

[0051] A lifting plate 2 with a sliding sleeve 21 fixedly attached is placed between the top plate 11 and the worktable 1, so that the sliding sleeve 21 is fitted onto the outer side of the guide rods 12 on both sides, realizing a sliding fit between the lifting plate 2 and the guide rods 12. At least one electric push rod 13 is fixedly installed on the top wall of the worktable 1, and the output end of the electric push rod 13 is fixedly connected to the center position of the bottom wall of the lifting plate 2. The lifting plate 2 is stably raised and lowered along the guide rods 12 by the extension and retraction of the electric push rod 13.

[0052] Furthermore, at least one electric push rod 13 is fixedly installed on the top wall of the workbench 1, and the output end of the electric push rod 13 is fixedly connected to the bottom wall of the lifting plate 2.

[0053] Furthermore, the clamping assembly 32 includes: a through groove 321 formed on the side wall of the lifting plate 2 and connected to the placement groove 31; a first sleeve 322 slidably connected in the through groove 321; a push rod 323 passing through the first sleeve 322; the push rod 323 and the first sleeve 322 slidingly engaging; one end of the push rod 323 extending into the placement groove 31 and fixedly connected to a clamping plate 324; a first limiting ring 326 fixedly connected to the outer wall of the push rod 323 in the first sleeve 322; and a first spring 325 sleeved on the outer wall of the push rod 323 on the side of the first limiting ring 326 away from the placement groove 31.

[0054] Furthermore, the adjustment assembly 33 includes: a second sleeve 331 fixed to the top wall of the lifting plate 2, a rod 332 slidably connected inside the second sleeve 331, the bottom end of the rod 332 extending into the through groove 321, a second limiting ring 333 fixed to the outer wall of the rod 332 inside the second sleeve 331, and a second spring 334 sleeved on the outer wall of the rod 332 on the side of the second limiting ring 333 away from the lifting plate 2, and a plurality of insertion holes 335 equally spaced along the length of the top wall of the first sleeve 322, and the rod 332 is inserted into one of the insertion holes 335.

[0055] Specifically, a through groove 321 is opened on the side wall of the lifting plate 2 to connect with the placement groove 31. The first sleeve 322 is slidably installed in the through groove 321. The push rod 323 passes through the first sleeve 322, so that the push rod 323 and the first sleeve 322 are slidably engaged. A clamping plate 324 is fixedly connected to one end of the push rod 323 that extends into the placement groove 31. A first limiting ring 324 is fixedly connected to the outer wall of the push rod 323 inside the first sleeve 322. A first spring 325 is sleeved on the outer wall of the push rod 323 on the side of the first limiting ring 324 away from the placement groove 31. The elastic force of the first spring 325 is used to push the push rod 323 and the clamping plate 324 to press against the placement plate placed in the placement groove 31.

[0056] A second sleeve 331 is fixed to the top wall of the lifting plate 2 at the position corresponding to the through groove 321. The insertion rod 332 is slidably inserted into the second sleeve 331, so that the bottom end of the insertion rod 332 extends into the through groove 321. A second limiting ring 333 is fixed to the outer wall of the insertion rod 332 inside the second sleeve 331. A second spring 334 is sleeved on the outer wall of the insertion rod 332 on the side of the second limiting ring 333 away from the lifting plate 2. Multiple insertion holes 335 are equally spaced along the length of the top wall of the first sleeve 322. The insertion rod 332 is pushed into one of the insertion holes 335 by the elastic force of the second spring 334, so that the position of the first sleeve 322 in the through groove 321 is fixed. Pulling the insertion rod 332 upward can release the fixation. After sliding the first sleeve 322 to adjust the pressing position, the insertion rod 332 can be released to re-fix it.

[0057] Furthermore, sliding sleeves 21 are fixedly connected to both sides of the lifting plate 2, and the sliding sleeves 21 are slidably sleeved on the outside of the guide rod 12. A lubrication mechanism 4 is also provided on the top plate 11. The lubrication mechanism 4 connects multiple sliding sleeves 21. The lubrication mechanism 4 has: a storage tank 41 fixedly connected to the top plate 11, and the storage tank 41 is filled with lubricating oil. An annular groove 42 is opened inside the sliding sleeve 21. An oil outlet 43 connecting the annular groove 42 is opened on the inner peripheral wall of the sliding sleeve 21 that fits against the guide rod 12. The annular groove 42 and the storage tank 41 are connected by a connecting hose 44, and a pump body 45 is fixedly connected to the connecting hose 44.

[0058] Specifically, the storage tank 41 is fixed to the top plate 11, and the storage tank 41 is filled with lubricating oil. An annular groove 42 is formed inside the sliding sleeve 21, and multiple oil outlets 43 connected to the annular groove 42 are formed at equal angles along the circumference on the inner peripheral wall of the sliding sleeve 21 that fits against the guide rod 12. The annular groove 42 is connected to the storage tank 41 through a connecting hose 44, and a pump body 45 is fixed to the connecting hose 44. After the pump body 45 is started, the lubricating oil in the storage tank 41 is transported to the annular groove 42 through the connecting hose 44, and then evenly coated on the surface of the guide rod 12 through the multiple oil outlets 43, thereby achieving lubrication between the sliding sleeve 21 and the guide rod 12.

[0059] Furthermore, multiple oil outlets 43 are provided and are distributed at equal angles on the inner peripheral wall of the sliding sleeve 21.

[0060] It should be noted that the connecting hose 44 has a certain degree of stretching and extension capacity, which can ensure that it will not break or detach when stretched or contracted.

[0061] The workflow of this embodiment is as follows:

[0062] Select the corresponding placement plate according to the size of the puncture-resistant glove to be shaped, pull the insertion rod 332 upward, slide the first sleeve 322 to adjust the position of the clamping component 32 so that the distance between the clamping plate 324 and the inner side wall of the placement groove 31 matches the size of the placement plate, then put the placement plate into the placement groove 31, release the insertion rod 332 to insert it into the corresponding insertion hole 335 and fix it, and the clamping plate 324 clamps the placement plate under the action of the first spring 325;

[0063] Place the glove to be shaped on the placement plate, start the electric push rod 13, push the lifting plate 2 to move upward along the guide rod 12 until the glove is in contact with the top plate 11. The glove is shaped by the compression between the lifting plate 2 and the top plate 11. After the shaping is completed, the electric push rod 13 retracts and drives the lifting plate 2 to return to its original position. Manually pull the top rod 323 to make the pressing plate 324 move away from the placement plate, and the placement plate and the shaped glove can be removed.

[0064] During the operation of the device, the pump body 45 is started periodically to deliver lubricating oil to the contact point between the guide rod 12 and the sliding sleeve 21 to ensure smooth sliding of the lifting plate 2.

[0065] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A shaping device for processing puncture-resistant gloves, characterized in that, Includes a workbench with a top plate arranged parallel to it, and multiple guide rods symmetrically erected and fixed on the workbench, with the top ends of the multiple guide rods fixed to the bottom wall of the top plate; A lifting plate is movably installed between the top plate and the worktable, and the guide rods at both ends and sides of the lifting plate are slidably engaged. The lifting plate is provided with multiple sets of placement mechanisms spaced at intervals, and each set of placement mechanisms can be detachably connected to a placement plate. The placement mechanism has the following features: A placement slot is provided on the lifting plate, and a clamping component for clamping the placement plate is movably connected in the placement slot. An adjustment component for adjusting the clamping position of the clamping component is provided on the side wall of the lifting plate.

2. The shaping device for processing puncture-resistant gloves according to claim 1, characterized in that, At least one electric push rod is fixedly installed on the top wall of the workbench, and the output end of the electric push rod is fixedly connected to the bottom wall of the lifting plate.

3. The shaping device for processing puncture-resistant gloves according to claim 1, characterized in that, The clamping component includes: A through slot is formed on the side wall of the lifting plate and communicates with the placement slot. A first sleeve is slidably connected in the through slot. A top rod passes through the first sleeve and is slidably engaged with the first sleeve. One end of the top rod extends into the placement slot and is fixedly connected to a clamping plate. A first limiting ring is fixed to the outer wall of the push rod inside the first sleeve, and a first spring is sleeved on the outer wall of the push rod on the side of the first limiting ring away from the placement groove.

4. The shaping device for processing puncture-resistant gloves according to claim 3, characterized in that, The adjustment component includes: A second sleeve is fixed to the top wall of the lifting plate, and a rod is slidably connected inside the second sleeve, with the bottom end of the rod extending into the through groove; A second limiting ring is fixed to the outer wall of the insertion rod inside the second sleeve, and a second spring is sleeved on the outer wall of the insertion rod on the side of the second limiting ring away from the lifting plate; The top wall of the first sleeve has multiple insertion holes spaced at equal intervals along its length, and the insertion rod is inserted into one of the insertion holes.

5. A shaping device for processing puncture-resistant gloves according to claim 1, characterized in that, Sliding sleeves are fixedly connected to both sides of the lifting plate, and the sliding sleeves are slidably sleeved on the outside of the guide rod. The top plate is also provided with a lubrication mechanism, which is connected to multiple sliding sleeves, and the lubrication mechanism has the following features: A storage tank is fixed to the top plate and is filled with lubricating oil. An annular groove is provided inside the sliding sleeve. An oil outlet communicating with the annular groove is provided on the inner peripheral wall of the sliding sleeve that fits against the guide rod. The annular groove and the storage tank are connected by a connecting hose, and a pump body is fixed to the connecting hose.

6. The shaping device for processing puncture-resistant gloves according to claim 5, characterized in that, The oil outlet is provided in multiple locations and is distributed at equal angles on the inner peripheral wall of the sliding sleeve.