A precision stainless steel material surface treatment equipment
The stainless steel surface treatment equipment, which uses a transfer cylinder and a drive motor to work together, solves the problem of limit error in traditional stainless steel processing, and achieves efficient and precise surface treatment and chip removal, thereby improving processing efficiency and accuracy.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- NINGBO HONGKE PRECISION STAINLESS STEEL CO LTD
- Filing Date
- 2024-07-22
- Publication Date
- 2026-06-05
AI Technical Summary
Traditional rod-shaped or tubular special stainless steel materials require manual adjustment of the limit switches during small-batch, high-precision processing due to limitations in the compatibility between the material and the machine tool. This leads to limit errors and affects the consistency of the processing.
The system employs a rotating cylinder and a drive motor working in tandem, combined with a feeding rack and a passive limit seat, to achieve rotary delivery and alignment clamping of stainless steel materials. It also incorporates machine tool components for high-precision surface treatment and uses a micro-motor to drive a rotating sleeve and a rotating abutment to form an adaptive rotary adjustment mechanism, enabling continuous feeding, discharging, and rotational adjustment.
It improves the processing efficiency and precision of stainless steel materials, ensures the quick removal of surface treatment debris, and meets the requirements of high-precision processing.
Smart Images

Figure CN118905671B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of stainless steel material processing technology, specifically to a precision stainless steel material surface treatment device. Background Technology
[0002] Precision stainless steel is a high-quality and high-precision material that is widely used in many industries. It has a variety of excellent properties, such as high strength, corrosion resistance, high temperature resistance and wear resistance. Common precision stainless steel materials include precision stainless steel tubes and precision stainless steel strips.
[0003] In light of the above, it should be noted that: when traditional rod-shaped or tubular special stainless steel materials are processed in small batches with high precision, the compatibility between the material itself and the machine tool is limited, which requires manual adjustment of the limit position and processing one by one. This can easily lead to limit position errors, resulting in certain differences after the same batch of materials is processed and formed, and thus failing to meet the requirements for use.
[0004] To address the aforementioned technical shortcomings, a solution is proposed. Summary of the Invention
[0005] The purpose of this invention is to provide a precision stainless steel surface treatment device, which uses a transfer cylinder and a drive motor to work together to deliver, push and pick up stainless steel materials in a rotating manner, combined with a feeding rack. The device uses an adapter and a passive limit seat to work together to form a centering and clamping limit for the delivered stainless steel materials. In the continuous rotating state, the limited stainless steel materials are fixed above the processing station, which is used to cooperate with the machine tool components to perform high-precision inverted treatment on the surface, which is conducive to the quick removal of debris generated during surface treatment by its own weight.
[0006] The micro motor, through a rotating sleeve, stainless steel material, and rotating abutment, forms an adaptive rotary adjustment mechanism, which is beneficial to improving the processing efficiency and precision of stainless steel material, and realizing the continuous feeding, unloading, and rotary adjustment process of stainless steel material during surface treatment, thus solving the problems raised.
[0007] To achieve the above objectives, the present invention provides the following technical solution: a precision stainless steel material surface treatment device, comprising a bracket, an inclined frame provided on the end face of the bracket, a rotating ring provided on the top of the bracket, a machine tool adapter frame provided on the side of the inclined frame, an adapter ring provided on the inner wall of the rotating ring, an arc-shaped cover clamp provided on the inner wall of the adapter ring, and a transfer cylinder provided at the center inside the adapter ring, a guide wheel provided on one end surface of the transfer cylinder, a passive limiting seat provided on the other end surface of the transfer cylinder, and a drive motor provided at one end of the transfer cylinder;
[0008] A feeding frame is provided above the end face of the drive motor, and a discharging frame is provided on the side of the feeding frame. A rotating sleeve is provided in the middle of the passive limiting seat, and a movable disc and a clamping block are provided inside the rotating sleeve.
[0009] Furthermore, the bracket has a stop block slidably disposed at the middle of both ends, and a limit frame is disposed on the cross section of the ramp frame near the machine tool adapter frame. An air nozzle is disposed in the middle of the limit frame near the top of the ramp frame, and a stop rod is slidably disposed at the top of the limit frame.
[0010] Furthermore, the inner wall of the adapter ring has multiple sets of adjustment grooves, and the top wall of the adjustment groove is provided with a spring damper connected to the arc-shaped cover clamp. The top of both ends of the arc-shaped cover clamp is provided with a limit protrusion, and the inner wall of the adapter ring is provided with a latch located between the multiple sets of adjustment grooves.
[0011] Furthermore, an active groove is formed on one end surface of the transfer cylinder, and a limiting arc block connected to the guide wheel is provided inside the active groove. A sleeve is provided at one end of the limiting arc block, and a rotating abutment is sleeved on the end face of the sleeve. A magnetic suction arc frame connected to the sleeve is provided below the rotating abutment. A limiting guide block 1 is provided at the bottom of the sleeve and slidably connected to the bottom wall of the active groove, and an active spring pull rod is sleeved in the middle of the limiting guide block 1.
[0012] Furthermore, a passive groove is provided on the surface of the other end of the transfer cylinder, and a passive spring rod is provided inside the passive groove. An end cap is provided on the end face of the other end of the transfer cylinder, and a collar that penetrates into the interior of the transfer cylinder is provided in the middle of the end cap. A buckle plate that is staggered with the passive groove and the active groove is provided on the outer surface of the middle part of the transfer cylinder.
[0013] Furthermore, the passive limiting seat is provided with a limiting protrusion 2 at the top and a limiting guide block 2 at the bottom. One end of the passive limiting seat is provided with an anti-arc frame that is slidably connected to the bottom of the rotating sleeve, and the other end of the passive limiting seat is provided with a micro motor that is drively connected to the rotating sleeve.
[0014] Furthermore, the clamping block is hinged to the inner wall of the rotating sleeve, and a rack connected to the clamping block is provided at the center of the inner wall of the rotating sleeve. The movable disk is slidably connected inside the rotating sleeve, and a traction line connected to the rack is provided on the outer periphery of the movable disk.
[0015] Furthermore, the end face of the drive motor is provided with an irregularly shaped guide frame that fits into the transfer cylinder, and an irregularly shaped guide rail is provided on the inner wall of the irregularly shaped guide frame. The output end of the drive motor is provided with a fixed flange that connects to the transfer cylinder.
[0016] Furthermore, adjustment plates are provided on the inner walls of both sides of the feeding rack, and multiple sets of fine-tuning cylinders are provided between the adjustment plates and the inner walls of the feeding rack. Multiple sets of rotary cylinders are slidably provided on the inner walls of both ends of the discharging rack, and magnetic suction clamps are provided between the rotary cylinders. An extension plate is provided at the bottom of the outer side of the discharging rack.
[0017] The beneficial effects of this invention are:
[0018] 1. This invention utilizes a transfer cylinder and a drive motor in synergy to deliver and feed stainless steel materials in a rotary manner, combined with a feeding rack. An adapter and a passive limit seat work in conjunction to center and clamp the delivered stainless steel material, fixing it above the processing station during continuous rotation. This allows for high-precision inverted surface treatment using machine tool components, facilitating the rapid detachment of surface-processed debris by its own weight. Furthermore, a micro-motor, through a rotating sleeve, stainless steel material, and rotating abutment, forms an adaptive adjustment mechanism, improving processing efficiency and precision. This invention also enables continuous feeding, unloading, and rotary adjustment of stainless steel materials during surface treatment.
[0019] 2. This invention uses a ramp frame in conjunction with a transfer cylinder to perform secondary adaptive lifting and limiting on the stainless steel material initially delivered and clamped. A small rectangular stable support structure is formed between the ramp frame and the transfer cylinder, which is beneficial for the machine tool components to perform high-precision surface treatment. Attached Figure Description
[0020] To facilitate understanding by those skilled in the art, the present invention will be further described below with reference to the accompanying drawings;
[0021] Figure 1 This is a perspective view of the overall structure of the present invention;
[0022] Figure 2 This is a schematic diagram of the connection structure between the adapter ring and the bracket of the present invention;
[0023] Figure 3 This is a schematic diagram of the structure of the adapter ring of the present invention;
[0024] Figure 4 This is a schematic diagram of the structure of the transfer cylinder in this invention;
[0025] Figure 5 This is a schematic diagram of the structure of the sleeve disk of the present invention;
[0026] Figure 6 This is a schematic diagram of the passive limiting seat of the present invention;
[0027] Figure 7 This is a schematic diagram of the internal structure of the rotating sleeve of the present invention;
[0028] Figure 8 This is a schematic diagram of the connection structure of the feeding rack, the discharging rack, and the drive motor of the present invention;
[0029] Figure 9 This is a partial cross-sectional view of the feeding rack and discharging rack of the present invention.
[0030] Reference numerals: 1. Bracket; 101. Inclined frame; 102. Rotating ring; 103. Limiting frame; 104. Abutment rod; 105. Air nozzle; 106. Abutment block; 2. Transfer cylinder; 201. End cap; 202. Collar; 203. Passive groove; 204. Buckle plate; 205. Passive spring rod; 206. Active groove; 207. Active spring rod; 208. Guide wheel; 209. Limiting arc block; 210. Sleeve plate; 211. Rotating abutment plate; 212. Magnetic arc frame; 213. Limiting guide block one; 3. Machine tool adapter frame; 4. Feed frame; 401. Fine-tuning cylinder; 402. Adjusting plate 5. Discharge rack; 501. Magnetic suction clamp; 502. Extension plate; 503. Rotary cylinder; 6. Drive motor; 601. Fixed flange; 602. Irregular guide frame; 603. Irregular guide rail; 7. Adapter ring; 701. Adjustment groove; 702. Spring damper; 703. Limiting protrusion one; 704. Arc-shaped cover clamp; 705. Lock; 8. Passive limiting seat; 801. Limiting protrusion two; 802. Micro motor; 803. Rotating sleeve; 804. Clamping block; 805. Movable disc; 806. Anti-detachment arc frame; 807. Limiting guide block two; 808. Rack; 809. Traction line. Detailed Implementation
[0031] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.
[0032] Example 1: This example addresses the problem that, during the small-batch, high-precision processing of traditional rod-shaped or tubular special stainless steel materials, the compatibility between the material itself and the machine tool limits the need for manual adjustment of the limit switches and processing, which can easily lead to limit errors. This results in differences in the finished product of the same batch of materials, making it impossible to meet the requirements for use.
[0033] Please see Figure 1 - Figure 9As shown, this embodiment is a precision stainless steel material surface treatment equipment, including a bracket 1, an inclined frame 101 is provided on the end face of the bracket 1, and a rotating ring 102 is provided on the top of the bracket 1. A machine tool adapter frame 3 is provided on the side of the inclined frame 101. An adapter ring 7 is provided on the inner wall of the rotating ring 102. An arc-shaped cover clamp 704 is provided on the inner wall of the adapter ring 7. A transfer cylinder 2 is provided at the center inside the adapter ring 7. A guide wheel 208 is provided on one end surface of the transfer cylinder 2, and a passive limit seat 8 is provided on the other end surface of the transfer cylinder 2. A drive motor 6 is provided at one end of the transfer cylinder 2.
[0034] By using bracket 1 and machine tool adapter 3 together, the transfer cylinder 2 and the machine tool components for surface treatment are linked and assembled to form an integral precision stainless steel surface treatment equipment. By sequentially feeding the stainless steel materials to be processed into the feeding rack 4, the drive motor 6 is started. The drive motor 6 drives the transfer cylinder 2 to rotate, and then the stainless steel materials are progressively limited and delivered to the top of the inclined frame 101. Using the machine tool components on the machine tool adapter 3, the surface of the stainless steel materials is subjected to high-precision, continuous and fast surface treatment. The stainless steel materials are in the form of rods or tubes.
[0035] The bracket 1 has a stop block 106 slidably disposed at the middle of both ends. The inclined frame 101 is provided with a limit frame 103 on the cross section near the machine tool adapter frame 3. The limit frame 103 is provided with an air nozzle 105 near the top of the inclined frame 101 in the middle, and a stop rod 104 is slidably disposed at the top of the limit frame 103. When the stainless steel material moves to the top of the inclined frame 101, a horizontal push cylinder connected to the limit frame 103 is provided inside the inclined frame 101. The horizontal push cylinder drives the limit frame 103 to move closer to the bottom of the passive limit seat 8, and the stop rod 104 is located directly below the limit protrusion 801.
[0036] A lifting cylinder 2 is provided on the inner wall of the limit frame 103. The lifting cylinder 2 drives the push rod 104 to slide upward and abut against the limit protrusion 801, further connecting the passive limit seat 8. Combined with the push block 106, bracket 1, ramp frame 101, limit frame 103, push rod 104 and transfer cylinder 2, a temporary rectangular stable structure is formed. When the stainless steel material is surface treated by the machine tool components, the debris falls off and moves along the ramp surface of the ramp frame 101 and collects. After the individual stainless steel material is processed, it is rotated away. When the machine tool components are temporarily reset, the limit frame 103 drives the air nozzle 105 to move along the axial direction of the ramp frame 101. Air is supplied through the external air supply equipment pipeline to pneumatically clean the debris stuck on the surface of the ramp frame 101.
[0037] Multiple adjustment grooves 701 are provided on the inner wall of the adapter ring 7, and a spring damper 702 connected to the arc-shaped cover clamp 704 is provided on the top wall of the adjustment groove 701. The adapter ring 7 is connected to the buckle plate 204 through the latch 705, thereby limiting the transfer cylinder 2 above the bracket 1. When the transfer cylinder 2 rotates and pulls the adapter ring 7 to move synchronously, the adapter ring 7 is provided with a ball connected to the rotating ring 102 on its outer wall, which cooperates with the transfer cylinder 2 to rotate at a constant speed along the top of the bracket 1 under the drive of the drive motor 6. The spring damper 702 on the inner wall of the adjustment groove 701 is pre-adjusted to drive the arc-shaped cover clamp 704 to maintain the moving distance between the arc-shaped cover clamp 704 and the retainer.
[0038] The retainer is located between the active groove 206 and the passive groove 203, and the retainer and the buckle plate 204 are staggered. An expansion airbag is embedded on the surface of the retainer near the passive groove 203. When the stainless steel material is clamped and limited by the rotating abutment plate 211 and the movable plate 805 bracket, the expansion airbag is supplied with air through the external air supply equipment pipeline to expand and lift the middle part of the stainless steel material between the rotating abutment plate 211 and the movable plate 805. This keeps the stainless steel material in a centrally calibrated and balanced state between the rotating abutment plate 211 and the movable plate 805, so as to satisfy the passage of the stainless steel material and limit its movement.
[0039] The top of both ends of the arc-shaped cover clamp 704 is provided with limiting protrusions 703. The inner wall of the adapter ring 7 is provided with a latch 705 located between multiple sets of adjustment grooves 701. When the arc-shaped cover clamp 704 moves the stainless steel material to the top of the inclined frame 101 in coordination with the adapter ring 7 and the transfer cylinder 2, the bracket 1 is provided with a lifting cylinder connected to the abutment 106. The lifting cylinder drives the abutment 106 to slide upward, causing the abutment 106 to connect with the bottom of both ends of the limiting protrusions 703. Under the influence of the continuous lifting force of the lifting cylinder, the arc-shaped cover clamp 704 is further lifted and slid upward, causing the distance between the arc-shaped cover clamp 704 and the active groove 206 to be further reduced until the surface of the stainless steel material stuck between the active groove 206 and the arc-shaped cover clamp 704 is clamped and limited.
[0040] An active groove 206 is provided on one end surface of the transfer cylinder 2. A limiting arc block 209 connected to the guide wheel 208 is provided inside the active groove 206. When the active groove 206 located directly below the feed rack 4 receives stainless steel material, the non-magnetic arc frame 212 is energized to generate magnetic attraction, causing one end of the stainless steel material that has initially fallen into the active groove 206 to be firmly attached to the inner wall of the magnetic arc frame 212. When the drive motor 6 drives the transfer cylinder 2 to rotate, the guide wheel 208 rotates with the transfer cylinder 2. The guide wheel 208 is affected by the trajectory of the irregular guide rail 603, and then the limiting arc block 209 is pulled along the active groove 206 from one end to the other.
[0041] One end of the limiting arc block 209 is provided with a sleeve plate 210, and a rotating abutment plate 211 is sleeved on the end face of the sleeve plate 210. A magnetic suction arc frame 212 connected to the sleeve plate 210 is provided below the rotating abutment plate 211. A limiting guide block 213 that is slidably connected to the bottom wall of the active groove 206 is provided at the bottom of the sleeve plate 210, and an active spring pull rod 207 is sleeved in the middle of the limiting guide block 213. The limiting arc block 209 drives the magnetic suction arc frame 212 and the stainless steel material to move synchronously through the sleeve plate 210. The sleeve plate 210 squeezes the spring element on the surface of the active spring pull rod 207 through the limiting guide block 213, causing the spring element on the surface of the active spring pull rod 207 to be compressed until the guide wheel 208 deflects 180° along the top of the inner wall of the irregular guide rail 603.
[0042] In this state, the sleeve 210 drives the magnetic suction arc frame 212 to move and insert into one end of the retainer surface, forming a temporary fit. The magnetic suction arc frame 212 is de-energized, and the stainless steel material is continuously pushed by the sleeve 210. The two ends of the stainless steel abut against the rotating abutment 211 and the movable plate 805 respectively. Affected by the centering and clamping of the movable plate 805, the stainless steel is leveled, and the stainless steel material is pushed into the passive groove 203 by the continuous movement of the sleeve 210.
[0043] Example 2: This example is a precision stainless steel material surface treatment equipment, including a passive groove 203 opened on the other end surface of the transfer cylinder 2, and a passive spring rod 205 is provided inside the passive groove 203. An end cap 201 is provided on the other end face of the transfer cylinder 2, and a collar 202 penetrating into the interior of the transfer cylinder 2 is provided in the middle of the end cap 201. A buckle plate 204 is provided on the outer surface of the middle part of the transfer cylinder 2, which is staggered with the passive groove 203 and the active groove 206.
[0044] When the other end of the stainless steel material contacts the movable disc 805, the movable disc 805 is pressed and moves along the inside of the rotating sleeve 803, squeezing the spring element two between them. At the same time, the movable disc 805 drags the traction line 809. The traction line 809 is limited by multiple sets of positioning guide rollers and drags the rack 808. The end of the rack 808 away from the traction line 809 is provided with a spring element three that connects to the inner wall of the rotating sleeve 803. The hinge area between the clamping block 804 and the rotating sleeve 803 is provided with a toothed ring that meshes with the rack 808. Driven by the movement of the rack 808, the gear ring drives the clamping block 804 to deflect along the hinge point. Multiple sets of clamping blocks 804 deflect in coordination, so that the stainless steel material enters the outer wall of the end face of the rotating sleeve 803 for clamping. Under the influence of the pushing force transmitted by the stainless steel material, the rotating sleeve 803 moves away from the adapter frame along the surface of the passive groove 203 until the stainless steel material stops being pushed. In this state, the set of limited stainless steel materials is deflected by the transfer cylinder 2 by 180° and is located directly above the inclined frame 101.
[0045] A feeding rack 4 is provided above the end face of the drive motor 6, and a discharging rack 5 is provided on the side of the feeding rack 4. A rotating sleeve 803 is provided in the middle of the passive limit seat 8, and a movable disk 805 and a clamping block 804 are provided inside the rotating sleeve 803. During the surface treatment of the stainless steel material by the machine tool assembly on the machine tool adapter 3, the micro motor 802 drives the rotating sleeve 803 to rotate along the middle of the passive limit seat 8, and then drives the stainless steel material and the rotating abutment 211 to rotate synchronously through the rotating sleeve 803, which is used to adapt to the comprehensive surface treatment of the stainless steel material by the machine tool assembly.
[0046] The passive limiting seat 8 is provided with a limiting protrusion 801 at the top and a limiting guide block 807 at the bottom. One end of the passive limiting seat 8 is provided with an anti-arc frame 806 that is slidably connected to the bottom of the rotating sleeve 803, and the other end of the passive limiting seat 8 is provided with a micro motor 802 that is drively connected to the rotating sleeve 803.
[0047] The clamping block 804 is hinged to the inner wall of the rotating sleeve 803, and a rack 808 connected to the clamping block 804 is provided at the center of the inner wall of the rotating sleeve 803. The movable disk 805 is slidably connected inside the rotating sleeve 803, and a traction line 809 connected to the rack 808 is provided on the outer periphery of the movable disk 805.
[0048] The drive motor 6 has a special-shaped guide frame 602 that is sleeved with the transfer cylinder 2 on its end face, and a special-shaped guide rail 603 is provided on the inner wall of the special-shaped guide frame 602. The output end of the drive motor 6 has a fixed flange 601 that is connected to the transfer cylinder 2. The drive motor 6 is connected to one end of the transfer cylinder 2 through the fixed flange 601 and drives the transfer cylinder 2 to rotate along the inside of the special-shaped guide frame 602 and the adapter ring 7. Multiple sets of guide wheels 208 provided on one end surface of the transfer cylinder 2 contact the special-shaped guide rail 603 and move along the trajectory of the special-shaped guide rail 603.
[0049] Adjustment plates 402 are provided on the inner walls of both sides of the feeding rack 4, and multiple sets of fine-tuning cylinders 401 are provided between the adjustment plates 402 and the inner wall of the feeding rack 4. The fine-tuning cylinders 401 are used according to the thickness of the stainless steel material. The fine-tuning cylinders 401 drive the adjustment plates 402 to move closer to each other, thereby adapting to the stainless steel material to be processed in this batch. As needed, the stainless steel material is fed through the feeding rack 4 one by one and falls into the active groove 206 located directly below the feeding rack 4.
[0050] Multiple sets of rotary cylinders 503 are slidably arranged on the inner walls of both ends of the discharge rack 5, and magnetic suction clamps 501 are arranged between the rotary cylinders 503. An extension plate 502 is arranged at the bottom of the outer side of the discharge rack 5. When the discharge rack 5 rotates again to approach the discharge rack 5 after the processing of a single set of stainless steel materials is completed, the guide wheel 208 is reset and moved away from the retainer by the influence of the irregular guide rail 603 in this state.
[0051] Furthermore, while the guide wheel 208 is away from the retainer, the magnetic arc frame 212 is re-energized to generate magnetic force, which attracts and limits the stainless steel material. A vertical cylinder connected to the rotary cylinder 503 is provided on the inner wall of the discharge rack 5. The vertical cylinder drives the magnetic suction clamp 501 to approach the stainless steel material through the rotary cylinder 503. The magnetic arc frame 212 is de-energized, and the magnetic suction clamp 501 is energized to clamp the stainless steel material and slide it upward until the stainless steel material is close to the top of the extension plate 502. The rotary cylinder 503 drives the magnetic suction clamp 501 to deflect and de-energize. Affected by its own weight and the tilt angle of the magnetic suction clamp 501, the stainless steel material rolls down to the surface of the extension plate 502 and rolls along the extension plate 502 into the collection container.
[0052] Combining Embodiments 1 and 2, the transfer cylinder 2 and drive motor 6 can work together to deliver and push stainless steel materials in a rotating manner, in conjunction with the feeding rack 4. The adapter frame and passive limit seat 8 work together to form a centering and clamping limit for the delivered stainless steel materials. In the continuous rotating state, the limited stainless steel materials are fixed above the processing station, which is used to cooperate with the machine tool components to perform high-precision inverted treatment on its surface, which is conducive to the quick removal of debris generated during surface treatment by its own weight. The micro motor 802 can form an adaptive rotation mechanism through the rotating sleeve 803, the stainless steel materials and the rotating abutment 211, which is conducive to improving the processing efficiency and accuracy of stainless steel materials, and realizing the continuous feeding, unloading and rotation adjustment process of stainless steel materials during surface treatment.
[0053] The above description is merely an example and illustration of the structure of the present invention. Those skilled in the art can make various modifications or additions to the specific embodiments described, or use similar methods to replace them, as long as they do not deviate from the structure of the invention or exceed the scope defined in the claims, all of which should fall within the protection scope of the present invention.
[0054] 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 invention. In this specification, 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.
[0055] The preferred embodiments of the present invention disclosed above are merely illustrative of the invention. These preferred embodiments do not exhaustively describe all details, nor do they limit the invention to any specific implementation. 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 the invention, thereby enabling those skilled in the art to better understand and utilize the invention. The invention is limited only by the claims and their full scope and equivalents.
Claims
1. A precision stainless steel material surface treatment device, comprising a bracket (1), characterized in that, The bracket (1) is provided with a ramp frame (101) on its end face, and a rotating ring (102) is provided on the top of the bracket (1). A machine tool adapter frame (3) is provided on the side of the ramp frame (101). An adapter ring (7) is provided on the inner wall of the rotating ring (102). An arc-shaped cover clamp (704) is provided on the inner wall of the adapter ring (7). A transfer cylinder (2) is provided in the center of the adapter ring (7). A guide wheel (208) is provided on one end surface of the transfer cylinder (2). A passive limit seat (8) is provided on the other end surface of the transfer cylinder (2). A drive motor (6) is provided at one end of the transfer cylinder (2). A feeding rack (4) is provided above the end face of the drive motor (6), and a discharging rack (5) is provided on the side of the feeding rack (4). A rotating sleeve (803) is provided in the middle of the passive limiting seat (8), and a movable disc (805) and a clamping block (804) are provided inside the rotating sleeve (803). The transfer cylinder (2) has an active groove (206) on one end surface. The active groove (206) is provided with a limiting arc block (209) connected to the guide wheel (208). A sleeve plate (210) is provided at one end of the limiting arc block (209), and a rotating abutment plate (211) is sleeved on the end face of the sleeve plate (210). A magnetic suction arc frame (212) connected to the sleeve plate (210) is provided below the rotating abutment plate (211). A limiting guide block (213) is provided at the bottom of the sleeve plate (210) and is slidably connected to the bottom wall of the active groove (206). An active spring pull rod (207) is sleeved in the middle of the limiting guide block (213). The passive limiting seat (8) is provided with a limiting protrusion 2 (801) at the top and a limiting guide block 2 (807) at the bottom. One end of the passive limiting seat (8) is provided with an anti-arc bracket (806) that is slidably connected to the bottom of the rotating sleeve (803), and the other end of the passive limiting seat (8) is provided with a micro motor (802) that is drively connected to the rotating sleeve (803). The end face of the drive motor (6) is provided with a special-shaped guide frame (602) that is sleeved with the transfer cylinder (2), and a special-shaped guide rail (603) is provided on the inner wall of the special-shaped guide frame (602). The output end of the drive motor (6) is provided with a fixed flange (601) that is connected to the transfer cylinder (2).
2. The precision stainless steel material surface treatment equipment according to claim 1, characterized in that, The bracket (1) has a stop block (106) slidably disposed at the middle of both ends. The ramp frame (101) has a limit frame (103) disposed on the cross section near the machine tool adapter frame (3). The limit frame (103) has an air nozzle (105) disposed in the middle near the top of the ramp frame (101), and a stop rod (104) slidably disposed on the top of the limit frame (103).
3. The precision stainless steel material surface treatment equipment according to claim 1, characterized in that, Multiple sets of adjustment grooves (701) are provided on the inner wall of the adapter ring (7), and a spring damper (702) connected to the arc-shaped cover clamp (704) is provided on the top wall of the adjustment groove (701). Limiting protrusions (703) are provided at the top of both ends of the arc-shaped cover clamp (704), and a latch (705) located between the multiple sets of adjustment grooves (701) is provided on the inner wall of the adapter ring (7).
4. The precision stainless steel material surface treatment equipment according to claim 1, characterized in that, The other end surface of the transfer cylinder (2) is provided with a passive groove (203), and a passive spring rod (205) is provided inside the passive groove (203). The other end face of the transfer cylinder (2) is provided with an end cap (201), and a collar (202) that penetrates into the interior of the transfer cylinder (2) is provided in the middle of the end cap (201). A buckle plate (204) that is staggered with the passive groove (203) and the active groove (206) is provided on the outer surface of the middle part of the transfer cylinder (2).
5. The precision stainless steel material surface treatment equipment according to claim 1, characterized in that, The clamping block (804) is hinged to the inner wall of the rotating sleeve (803), and a rack (808) connected to the clamping block (804) is provided at the center of the inner wall of the rotating sleeve (803). The movable disk (805) is slidably connected inside the rotating sleeve (803), and a traction line (809) connected to the rack (808) is provided on the outer periphery of the movable disk (805).
6. The precision stainless steel material surface treatment equipment according to claim 1, characterized in that, Adjustment plates (402) are provided on the inner walls of both sides of the feeding rack (4), and multiple sets of fine-tuning cylinders (401) are provided between the adjustment plates (402) and the inner walls of the feeding rack (4). Multiple sets of rotary cylinders (503) are slidably provided on the inner walls of both ends of the discharging rack (5), and magnetic suction clamps (501) are provided between the rotary cylinders (503). An extension plate (502) is provided at the bottom of the outer side of the discharging rack (5).