Riveting device for fan frame partition and server
By designing a riveting device that includes a support platform, a fixing component, and a riveting part, a stable connection between the fan frame and the partition was achieved, solving the problem of shaking and skewing of the partition during the riveting process of the convex bridge, and improving the connection stability and efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- INSPUR SUZHOU INTELLIGENT TECH CO LTD
- Filing Date
- 2026-05-25
- Publication Date
- 2026-06-30
AI Technical Summary
In the existing technology, the connection between the fan frame and the baffle is unstable. In particular, the baffle is prone to shaking and tilting during the riveting process of the convex bridge, resulting in an uneven connection that affects the heat dissipation effect and stability.
Design a riveting device including a support platform, a fixing component and a riveting part, clamping a partition plate by a push block and a positioning wedge block, and simultaneously riveting the protrusions of the partition plate from multiple directions using first and second riveting modules to ensure that the protrusions are completely filled to the riveting position.
The stability and efficiency of the riveting connection of the baffle inside the fan frame have been improved, ensuring stable installation of the baffle and the fan frame and improving the heat dissipation effect.
Smart Images

Figure CN122298911A_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of riveting technology for internal components of a chassis, and more particularly to a riveting device for a fan frame partition and a server. Background Technology
[0002] Servers generate a significant amount of heat during prolonged high-load operation. Cooling fans dissipate this heat by generating airflow, keeping the internal temperature of the server within a safe range. These cooling fans are mounted and secured within the server chassis using fan frames. To improve cooling efficiency, multiple cooling fans can be installed simultaneously within the fan frame, separated by partitions.
[0003] In some related technologies, the fan frame and the partition are riveted together by drawing holes. However, in practical use, the structure of the drawing hole riveting method is limited, and each partition can only be designed with 4 riveting points, which may lead to unstable connection between the partition and the fan frame. Therefore, the partition is currently connected to the fan frame by a convex bridge with square holes. The partition is riveted to the frame on three sides, which requires riveting each side individually. This operation is cumbersome and has low processing efficiency. Furthermore, during the process of pressing down and riveting the convex bridge, the partition that is not fixed will shake, causing the convex bridge to not be completely filled into the square hole. This also results in the partition tilting to both sides and uneven riveting surfaces, which in turn leads to unstable connection between the partition and the fan frame. Summary of the Invention
[0004] This application provides a riveting device and server for fan frame partitions, which can realize the simultaneous riveting connection of multiple partitions to the fan frame on the same side. By fixing the partitions during the riveting process, it is ensured that the convex bridge is completely filled into the corresponding position, thereby improving the riveting connection stability of the partitions inside the fan frame.
[0005] This application provides a riveting device for a fan frame partition, applied to a frame, including a riveting part, a support platform supported at the bottom of the frame, and a fixing component slidably mounted on the support platform. The riveting part includes a first riveting module mounted on the support platform and a second riveting module movably positioned at the top of the frame. The fixing component corresponds to the position of the partition in the frame. The fixing component includes a push block and a positioning wedge block that is slidably connected to the side wall of the push block. The push block is adjusted to move closer to the frame so that the positioning wedge block clamps the partition. The first riveting module rivets the first convex bridge of the partition on both sides along the length direction of the frame, and the second riveting module rivets the second convex bridge of the partition along the top of the frame.
[0006] In one specific embodiment, a plurality of push blocks are spaced apart along the length of the frame, and two positioning inclined blocks respectively installed on two adjacent push blocks are arranged opposite to each other; The push block is provided with a barbed track groove, and the positioning inclined block is provided with a barbed track that slides with the barbed track groove. Two adjacent push blocks move toward the frame so that the two positioning inclined blocks move closer to each other and clamp onto both sides of the partition.
[0007] In one specific embodiment, both the first protrusion and the second protrusion are fixedly connected to the outer side wall of the partition. The first protrusion passes through the first riveting holes on both sides along the length of the frame, and the second protrusion passes through the second riveting hole at the top of the frame.
[0008] In one specific embodiment, a receiving through hole is provided on the support platform, the push block is slidably installed in the receiving through hole, and a driving component is installed at the bottom of the support platform. The driving component is used to drive the push block to slide along the receiving through hole.
[0009] In one specific embodiment, the first riveting module includes a baffle connected to the support platform and a riveting plate connected to the baffle plate near the frame. The riveting plate has a riveting through hole, which corresponds to the position of the first protrusion bridge. A first riveting component is disposed in the riveting through hole.
[0010] In one specific embodiment, the first riveting assembly includes at least two limiting blocks slidably connected within the riveting through hole and a riveting punch movably connected between the two limiting blocks. An elastic element is connected to each limiting block, and the elastic element is used to elastically drive the two limiting blocks to limit the first protrusion before the riveting punch contacts the first protrusion.
[0011] In one specific embodiment, the riveting punch includes an inclined surface disposed on the sidewall along the riveting direction and a plane extending and connected to the inclined surface. The inclined surface and the plane are disposed sequentially along the riveting direction, and the width of the riveting punch at the position of the inclined surface is greater than the width of the riveting punch at the position of the plane.
[0012] In one specific embodiment, the riveting part further includes a fixing plate and a push post vertically mounted on the fixing plate. A protrusion is provided on the side of the pressing plate near the fixing plate, and the end of the push post away from the fixing plate extends between the baffle and the pressing plate and contacts the protrusion.
[0013] In one specific embodiment, the second riveting module includes a pressure plate connected to the side of the fixing plate near the support platform. The pressure plate has a through hole, and a second riveting assembly is disposed in the through hole. The second riveting assembly is used to rivet the second convex bridge. The second riveting assembly may have the same or different structure as the first riveting assembly.
[0014] In one specific embodiment, a guide post is connected to the fixing plate, and a guide hole corresponding to the guide post is provided on the support platform. When the second pressing module rivets the second convex bridge, the guide post passes through the guide hole.
[0015] In one specific embodiment, the support platform is equipped with a positioning block and a positioning element, and a limiting space is provided between the positioning block and the positioning element. The end of the frame along the direction perpendicular to the plane where the partition is located is located within the limiting space.
[0016] This application also provides a server, which includes the riveting device for the fan frame partition as described above.
[0017] 1. This application places the fan frame on a support platform and sets a fixing component and a riveting part on the support platform. Specifically, by adjusting the push block in the fixing component to move closer to the frame, the positioning wedges on both sides of the partition plate are driven to clamp and fix the partition plate from both sides. Then, the first riveting module located on both sides of the frame length direction is adjusted to rivet the first protrusions extending from the partition plate from both sides of the frame, and the second riveting module located at the top of the frame is adjusted to rivet the second protrusions extending from the surface of the partition plate from the top of the frame. This achieves the following: first, the partition plate is clamped and fixed by the fixing component so that the partition plate is vertically installed in the frame; then, the riveting part is used to simultaneously rivet multiple protrusions extending from the square holes of the frame from three sides of the partition plate. This improves the stability of the partition plate installed in the frame and increases the riveting efficiency. Attached Figure Description
[0018] To more clearly illustrate the embodiments of this application, the accompanying drawings used in the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this application. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0019] Figure 1 A schematic diagram illustrating the connection between the frame and partition provided in this embodiment of the application via budding and conical holes; Figure 2 This is a schematic diagram of the budding and conical hole mating state provided in an embodiment of this application; Figure 3 A schematic diagram illustrating the engagement state of the frame and partition provided in an embodiment of this application; Figure 4 A schematic diagram of the convex bridge structure on the partition provided in this application embodiment; Figure 5 A schematic diagram of the riveting state of the convex bridge on the partition provided in an embodiment of this application; Figure 6 This is a schematic diagram of the riveting process of the convex bridge provided in an embodiment of this application; Figure 7 A schematic diagram of the riveting device for the fan frame partition provided in the embodiments of this application; Figure 8 This is a schematic diagram of the second riveting module provided in an embodiment of this application; Figure 9 An exploded view of the riveting device for the fan frame partition provided in an embodiment of this application; Figure 10 An exploded view of the fixing component provided in the embodiments of this application; Figure 11 A schematic diagram of the first riveting module provided in the embodiments of this application; Figure 12 A schematic diagram of the first riveting assembly provided in the embodiments of this application; The above figures include the following reference numerals: 1. Frame; 2. Partition; 201. First convex bridge; 202. Second convex bridge; 3. Sprout; 4. Conical hole; 5. Support platform; 501. Receiving through hole; 6. Fixing component; 601. Push block; 602. Positioning wedge; 7. Riveting part; 701. Fixing plate; 702. Pushing column; 703. Protrusion; 8. First riveting module; 801. Baffle; 802. Riveting plate; 9. Second riveting module; 901, Pressure plate; 902, Through hole; 10, Barbed track groove; 11, Barbed track; 12, Drive assembly; 13, Top plate; 14, Top block; 15, Press-fit through hole; 16, First press-fit assembly; 1601, Limiting block; 1602, Press-fit punch; 1603, Elastic element; 17, Inclined surface; 18, Flat surface; 19, Guide post; 20, Guide hole; 21, Positioning stop; 22, Positioning element. Detailed Implementation
[0020] The technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this application, and not all embodiments. Based on the embodiments of this application, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of this application.
[0021] It should be noted that the terms "center," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," and "circumferential," etc., indicating orientation or positional relationships based on the orientation or positional relationships shown in the accompanying drawings, are only for the convenience of describing this application and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of this application. The terms "installed," "connected," and "linked" should be interpreted broadly, for example, they can be fixed connections, detachable connections, or integral connections; they can be mechanical connections or electrical connections; they can be direct connections or indirect connections through an intermediate medium; they can be internal connections between two elements. The terms "parallel," "perpendicular," and "equal" include the described situation and situations similar to the described situation, the range of which is within an acceptable deviation range, wherein the acceptable deviation range is determined by those skilled in the art taking into account the measurement under discussion and the error associated with the measurement of a particular quantity (i.e., the limitations of the measurement system). For example, "parallel" includes absolute parallelism and approximate parallelism, where an acceptable deviation range for approximate parallelism can be, for example, within 5°; "perpendicular" includes absolute perpendicularity and approximate perpendicularity, where an acceptable deviation range for approximate perpendicularity can also be, for example, within 5°. "Equal" includes absolute equality and approximate equality, where an acceptable deviation range for approximate equality can be, for example, a difference between the two equal items being less than or equal to 5% of either one. Those skilled in the art will understand the specific meaning of the above terms in this application based on the specific circumstances.
[0022] To enable those skilled in the art to better understand the present application, the present application will be further described in detail below with reference to the accompanying drawings and specific embodiments.
[0023] The embodiments of this application provide a riveting device for fan frame partitions, which is applied to the fan frame 1 inside the chassis. In order to enable the frame 1 to install multiple fans at the same time and to ensure that the fans do not interfere with each other when they are running, multiple partitions 2 need to be installed at intervals inside the frame 1 to separate adjacent fans and ensure that the fans inside the chassis can work individually or simultaneously.
[0024] In some related technologies, such as Figure 1 and Figure 2As shown, the partition 2 and the fan frame 1 are connected by a bud 3 and a conical hole 4. This is achieved by extending an extension plate along the outer wall of the partition 2, with buds 3 on the extension plate and conical holes 4 on the frame 1. This allows the partition 2 to be installed within the frame 1. Since the buds 3 occupy space and additional connections are required on the partition 2, the manufacturing process is relatively complex. Furthermore, due to space limitations, there are few connection points between the partition 2 and the frame 1, which can easily lead to unstable connections. Figure 5 and Figure 6 As shown, some related technologies use a method of positioning the convex bridge and then riveting it, but this requires riveting each convex bridge on the partition 2 one by one, which is quite cumbersome.
[0025] To solve the above problems, such as Figure 7 , Figure 8 and Figure 9 As shown, the device in this application specifically includes a support platform 5, a fixing component 6, and a riveting part 7. The support platform 5 is located at the bottom of the frame 1 to support the frame 1 to be riveted. The outer periphery of the partition 2 in this application is fixedly connected to a first protrusion 201 and a second protrusion 202. The first protrusion 201 and the second protrusion 202 are integrally formed with the partition 2 and extend out of the side wall of the partition 2. The first protrusion 201 is fixedly connected to two partition walls of the partition 2 along the length direction of the frame 1, and at least two first protrusions 201 are provided. The second protrusion 202 is fixedly connected to the top side wall of the partition 2 along the height direction of the frame 1, and at least two second protrusions 202 are provided. The fixing component 6 is slidably installed on the support platform 5, and multiple fixing components 6 are provided on the support platform 5. That is, the fixing components 6 correspond one-to-one with the positions of the partitions 2 in the frame 1. The fixing component 6 includes a push block 601 and a positioning inclined block 602 slidably connected to the side wall of the push block 601.
[0026] Furthermore, the riveting part 7 includes a first riveting module 8 and a second riveting module 9. The first riveting module 8 is mounted on the support platform 5 and is movably positioned on both sides of the frame 1 along its length. The second riveting module 9 is movably positioned on the support platform 5 and located at the top of the frame 1. Riveting holes are provided on the frame 1 at corresponding positions to the partition 2 for riveting connection with the frame 1. Specifically, for better assembly with the frame 1, a first riveting hole is provided on the side wall along the length of the frame 1, and multiple first riveting holes are provided on the side wall of the frame 1. A second riveting hole is provided on the top side wall of the frame 1, and multiple second riveting holes are provided on the top side wall of the frame 1 to enhance the fit between the frame 1 and the partition 2. The adjusting push block 601 moves closer to the frame 1 to drive the positioning inclined block 602 to clamp the partition 2. The first protrusion 201 passes through the first riveting holes on both sides along the length of the frame 1. The first riveting module 8 rivets the first protrusion 201 of the partition 2 along both sides along the length of the frame 1. The second protrusion 202 passes through the second riveting hole at the top of the frame 1. The second riveting module 9 rivets the second protrusion 202 of the partition 2 along the top of the frame 1.
[0027] like Figure 10 As shown, in order to ensure that multiple partitions 2 are clamped and fixed at the same time, so as to realize the simultaneous riveting of multiple partitions 2 to the frame 1, several push blocks 601 are set at intervals along the length direction of the frame 1. Two positioning wedges 602 are respectively installed on two adjacent push blocks 601 and are arranged opposite each other. The two push blocks 601 located at both ends along the length direction of the frame 1 are respectively equipped with one positioning wedge 602, and the push blocks 601 located at the non-ends are respectively equipped with two positioning wedges 602. The two positioning wedges 602 are respectively installed on both sides of the push block 601. The push block 601 is provided with a hook track groove 10, and the positioning inclined block 602 is provided with a hook track 11 that slides with the hook track groove 10. The push block 601 and the positioning inclined block 602 are connected by sliding engagement through the hook track groove 10. Two adjacent push blocks 601 at the ends of the non-frame 1 length direction are spaced apart, and a positioning inclined block 602 is set between the two push blocks 601, so that positioning inclined blocks 602 are installed on both the left and right sides of the same push block 601. When it is necessary to position the partition 2 in the frame 1, the push block 601 is driven to move closer to the frame 1, so that the two positioning inclined blocks 602 move closer to each other until they are clamped on both sides of the partition 2, thereby achieving the pressing and positioning of the partition 2 to be riveted.
[0028] It should be noted that, in order to ensure that the push block 601 and the positioning inclined block 602 do not detach from each other when they are slidably connected by the hook track groove 10 without being riveted, the hook track groove 10 is designed to be wider at the top and narrower at the bottom. That is, when not riveted, the positioning inclined block 602 will fit tightly against the hook track groove 10 on one side of the push block 601 under the action of gravity.
[0029] like Figure 9 As shown, in order to improve the efficiency and accuracy of positioning the partition 2, a receiving through hole 501 is provided on the support platform 5. The receiving through hole 501 passes through the support platform 5, and the push block 601 and the positioning inclined block 602 are slidably connected in the receiving through hole 501. A drive assembly 12 is installed at the bottom of the support platform 5. A top plate 13 is installed at the output end of the drive assembly 12. A top block 14 is fixedly connected on the top plate 13 at the position corresponding to the receiving through hole 501, and the top block corresponds one-to-one with the push block 601. The drive assembly 12 is used to drive the push block 601 to slide along the receiving through hole 501 towards the frame 1.
[0030] It should be noted that the drive component 12 in this embodiment is configured as one or more of a hydraulic cylinder, a pneumatic cylinder, or an electric cylinder. By placing the drive component 12 under the support platform 5, when it is necessary to position the partition 2, the drive component 12 is adjusted to drive the top block to move upward, so as to hold the push block 601 to achieve clamping and positioning of the partition 2, thereby improving the efficiency of drive riveting.
[0031] In a specific embodiment, such as Figure 11 As shown, the first riveting module 8 includes a baffle 801 and a riveting plate 802, and the length direction of the baffle 801 and the riveting plate 802 is parallel to the length direction of the frame 1. The baffle 801 is connected to the support platform 5, and the riveting plate 802 is connected to the side of the baffle 801 near the frame 1. The riveting plate 802 has multiple riveting through holes 15, which correspond to the positions of the first convex bridge 201. The first riveting assembly 16 is installed in the riveting through hole 15 to realize the riveting of the first convex bridge 201 through the first riveting assembly 16. By setting multiple first riveting assemblies 16, when it is necessary to rivet the partition 2, the first riveting module 8 is adjusted to rivet multiple first convex bridges 201 from both sides of the frame 1 at the same time, thereby improving the riveting efficiency.
[0032] Specifically, such as Figure 12As shown, the first riveting assembly 16 includes two limiting blocks 1601 and a riveting punch 1602 movably mounted between the two limiting blocks 1601. Before riveting, the two limiting blocks 1601 are positioned closer to the partition plate 2 to be riveted than the riveting punch 1602. An elastic element 1603 is connected to the limiting blocks 1601; specifically, in this embodiment, the elastic element 1603 is configured as a spring. One end of the elastic element 1603 away from the limiting blocks 1601 is connected to the baffle 801, so that before the riveting punch 1602 contacts the first protrusion 201, the two limiting blocks 1601 are elastically driven to slide within the riveting through hole 15 and extend out of the riveting through hole 15 to contact the first protrusion 201.
[0033] like Figure 12 As shown, in order to ensure that the riveting punch 1602 can accurately rivet the position to be riveted, the side wall of the riveting punch 1602 along the riveting direction is provided with an inclined surface 17 and a plane 18 extending and connected to the inclined surface 17. The inclined surface 17 and the plane 18 are arranged sequentially along the riveting direction, and the width of the riveting punch 1602 at the position of the inclined surface 17 is greater than the width of the riveting punch 1602 at the position of the plane 18. This enables the riveting punch 1602 and the limiting block 1601 to be connected through the inclined surface 17, so as to concentrate the force generated by riveting to the riveting punch 1602, further enhance the riveting effect, and enable the convex bridge to completely fill the riveting position.
[0034] In a specific embodiment, such as Figure 11 As shown, the riveting part 7 includes a fixed plate 701 and a pusher post 702. Multiple pusher posts 702 are vertically fixed to the fixed plate 701, and the bottom ends of all pusher posts 702 extend between the baffle 801 and the pressing plate 802. The pressing plate 802 has multiple protrusions 703 on the side near the fixed plate 701, each corresponding to a pusher post 702. The end of the pusher post 702 away from the fixed plate 701 extends between the baffle 801 and the pressing plate 802 and contacts the protrusion 703. When riveting is required, the pusher post 702 moves downwards, and the bottom of the pusher post 702 drives the protrusion 703 to contact, thereby driving the pressing plate 802 to move closer to the frame 1. This completes the simultaneous riveting of multiple protrusions on the partition 2, greatly improving riveting efficiency and stability.
[0035] It should be noted that during the riveting process of the protruding bridge extending from the partition 2, the pressure needs to be gradually increased to flatten and fill the riveting hole from the protruding position. Therefore, the bottom side wall of the push column 702 is set in a stepped shape, and each stepped layer is connected by a chamfer. The side of the protrusion 703 near the push column 702 is set with an inclined slope 17 to achieve sliding fit between the bottom of the protrusion 703 and the bottom of the push column 702. The stepped structure can gradually strengthen the compression of the protrusion 703 as the push column 702 gradually descends, thereby making the first riveting assembly 16 rivet the first protruding bridge 201 into place, so that the first protruding bridge 201 is completely filled in the first riveting hole, thereby strengthening the quality of riveting and ensuring the stable connection between the fan frame 1 and the partition 2.
[0036] like Figure 8 As shown, specifically, the second riveting module 9 includes a pressure plate 901 connected to the side of the fixed plate 701 near the support platform 5. The pressure plate 901 has through holes 902, and several through holes 902 are arranged along the length of the pressure plate 901. The positions of the through holes 902 correspond one-to-one with the positions of the second protrusions 202 on the partition plate 2. A second riveting assembly is arranged in the through holes 902. The second riveting assembly is used to rivet the second protrusions 202. In this embodiment, the second riveting assembly has the same structure as the first riveting assembly 16.
[0037] In this embodiment, four first protrusions 201 and two second protrusions 202 are provided on the outer periphery of the partition 2, meaning that one partition 2 needs to be riveted at six positions. In this embodiment, five partitions 2 are installed inside the frame 1. Through the cooperation of the first riveting module 8 and the second riveting module 9, the riveting of multiple positions of the partition 2 can be completed simultaneously from the left and right sides and the top of the frame 1.
[0038] It should be noted that this device also includes a robotic arm, which is connected to the top of the pressure plate 901. When riveting is required, the robotic arm controls the pressure plate 901 to press down to a preset position to complete the riveting. To ensure that the pressure plate 901 is accurately pressed down to the riveting position, a guide post 19 is connected to the fixed plate 701, and a guide hole 20 corresponding to the guide post 19 is provided on the support platform 5. When the second riveting module 9 rivets the second convex bridge 202, the guide post 19 passes through the guide hole 20 to ensure accurate riveting to the corresponding position and avoid the problem of the pressure plate 901 deflecting during the process of descending and approaching the frame 1.
[0039] like Figure 10As shown, since a certain force needs to be applied to the frame 1 during the riveting process, if the position of the frame 1 moves at this time, it may cause the riveting position to be skewed. Therefore, a positioning block 21 and a positioning element 22 are installed on the support platform 5. A limiting space is set between the positioning block 21 and the positioning element 22. When the frame 1 is placed on the support platform 5, the end of the frame 1 along the direction perpendicular to the plane 18 where the partition 2 is located is located in the limiting space. This further ensures the stability of the frame 1 when multiple positions on the outside of the frame 1 are riveted by the first riveting module 8 and the second riveting module 9, so as to improve the riveting quality and ensure the stable connection between the frame 1 and the partition 2.
[0040] It should be noted that the positioning component 22 in this embodiment includes, but is not limited to, one or more of the following: screws, SMD studs, bolts, self-tapping screws, pull studs, I-beams, and pins.
[0041] Specific implementation process: Place the frame 1 to be riveted and assembled with partition 2 at the corresponding position on the support platform 5 so that the guide post 19 on the fixing plate 701 passes through the guide hole 20 to ensure the accurate placement of partition 2; then adjust the operation of the drive component 12 at the bottom of the support platform 5. The drive component 12 drives the push block 601 to move upward. The push block 601 drives the two positioning inclined blocks 602 to move upward and closer to each other to achieve clamping of partition 2 from both sides.
[0042] Furthermore, the adjusting pressure plate 901 moves from the upper part of the support platform 5 towards the partition 2. As the pressure plate 901 gradually approaches the support platform 5, the pushing column 702 abuts against the riveting plate 802 and drives the riveting plate 802 to press against the frame 1 on both sides along the length direction of the frame 1. Thus, the first riveting assembly 16 on the riveting plate 802 rivets the first protrusion 201 on the partition 2. At the same time, the second riveting assembly at the lower part of the fixing plate 701 also moves to the upper part of the frame 1. At this time, the second riveting assembly rivets the second protrusion 202 on the partition 2. Through the device in this embodiment, multiple protrusions extending from the square holes of the frame 1 are riveted from three sides of the partition 2, thereby improving the stability of the partition 2 installed in the frame 1 and improving the riveting efficiency.
[0043] Corresponding to the above embodiments, this embodiment provides a server, which includes the riveting device for the fan frame partition as described above. The device includes a support platform 5, a fixing component 6, a first riveting module 8, and a second riveting module 9. The fixing component 6 includes a push block 601 and a positioning wedge block 602.
[0044] By placing the fan frame 1 on the support platform 5, and setting the fixing component 6 and the riveting part 7 on the support platform 5, specifically by adjusting the push block 601 in the fixing component 6 to move closer to the frame 1, the positioning inclined blocks 602 on both sides of the partition 2 are driven to clamp and fix the partition 2 from both sides of the partition 2. Then, the first riveting module 8 located on both sides of the frame 1 in the length direction is adjusted to rivet the first protrusion bridge 201 extending from the partition 2 from both sides of the frame 1, and the second riveting module 9 located at the top of the frame 1 is adjusted to rivet the second protrusion bridge 202 extending from the surface of the partition 2 from the top of the frame 1. Thus, the partition 2 is first clamped and fixed by the fixing component 6 so that the partition 2 is vertically installed in the frame 1. Then, the riveting part is used to rivet multiple protrusion bridges extending from the square hole of the frame 1 from the three sides of the partition 2. This improves the stability of the partition 2 installed in the frame 1 and increases the riveting efficiency.
[0045] In one specific embodiment, several push blocks 601 are spaced apart along the length of the frame 1, and two positioning inclined blocks 602 are respectively installed on two adjacent push blocks 601 and are arranged opposite each other; the push block 601 is provided with a hook track groove 10, and the positioning inclined block 602 is provided with a hook track 11 that slides with the hook track groove 10. Two adjacent push blocks 601 move toward the frame 1 so that the two positioning inclined blocks 602 move closer to each other and clamp on both sides of the partition 2.
[0046] By setting the push block 601 and the positioning wedge block 602 to slide and engage with each other through the hook track groove 10, and setting two adjacent push blocks 601 at intervals at the ends of the non-frame 1 length direction, and setting the positioning wedge block 602 between the two push blocks 601, the positioning wedge block 602 is installed on both the left and right sides of the same push block 601. When it is necessary to position the partition 2 in the frame 1, the push block 601 is driven to move towards the frame 1, so that the two positioning wedge blocks 602 move closer to each other until they are clamped on both sides of the partition 2, thereby achieving the pressing and positioning of the partition 2 to be riveted.
[0047] In one specific embodiment, the first convex bridge 201 and the second convex bridge 202 are both fixedly connected to the outer side wall of the partition 2. The first convex bridge 201 passes through the first rivet holes on both sides along the length direction of the frame 1, and the second convex bridge 202 passes through the second rivet hole at the top of the frame 1.
[0048] In one specific embodiment, a receiving through hole 501 is provided on the support platform 5, and a pusher 601 is slidably installed in the receiving through hole 501. A driving assembly 12 is installed at the bottom of the support platform 5, and the driving assembly 12 is used to drive the pusher 601 to slide along the receiving through hole 501.
[0049] In one specific embodiment, the first riveting module 8 includes a baffle 801 connected to the support platform 5 and a riveting plate 802 connected to the side of the baffle 801 near the frame 1. A riveting through hole 15 is opened on the riveting plate 802, and the riveting through hole 15 corresponds to the position of the first convex bridge 201. A first riveting component 16 is provided in the riveting through hole 15.
[0050] In one specific embodiment, the first riveting assembly 16 includes at least two limiting blocks 1601 slidably connected in the riveting through hole 15 and a riveting punch 1602 movably connected between the two limiting blocks 1601. An elastic element 1603 is connected to the limiting block 1601. The elastic element 1603 is used to elastically drive the two limiting blocks 1601 to limit the first protrusion 201 before the riveting punch 1602 contacts the first protrusion 201.
[0051] In one specific embodiment, the riveting punch 1602 includes an inclined surface 17 disposed on the sidewall along the riveting direction and a plane 18 extending and connected to the inclined surface 17. The inclined surface 17 and the plane 18 are arranged sequentially along the riveting direction, and the width of the riveting punch 1602 at the position of the inclined surface 17 is greater than the width of the riveting punch 1602 at the position of the plane 18.
[0052] In one specific embodiment, the riveting part 7 further includes a fixing plate 701, a push post 702 vertically mounted on the fixing plate 701, a protrusion 703 provided on the side of the pressing plate 802 near the fixing plate 701, and the end of the push post 702 away from the fixing plate 701 extends between the baffle 801 and the pressing plate 802 and contacts the protrusion 703.
[0053] In one specific embodiment, the second riveting module 9 includes a pressure plate 901 connected to the side of the fixed plate 701 near the support platform 5. The pressure plate 901 has a through hole 902, and a second riveting assembly is provided in the through hole 902. The second riveting assembly is used to rivet the second convex bridge 202. The second riveting assembly may have the same or different structure as the first riveting assembly 16.
[0054] In one specific embodiment, a guide post 19 is connected to the fixing plate 701, and a guide hole 20 corresponding to the guide post 19 is provided on the support platform 5. When the second pressing module presses and rivets the second convex bridge 202, the guide post 19 passes through the guide hole 20.
[0055] In one specific embodiment, the support platform 5 is equipped with a positioning block 21 and a positioning element 22, and a limiting space is provided between the positioning block 21 and the positioning element 22. The end of the frame 1 along the direction perpendicular to the plane 18 where the partition 2 is located is located within the limiting space.
[0056] For a description of the features in the embodiment corresponding to the server, please refer to the relevant description of the embodiment corresponding to the riveting device for the fan frame partition, which will not be repeated here.
[0057] The foregoing has provided a detailed description of a riveting device and server for a fan frame partition provided in this application. Specific examples have been used to illustrate the principles and implementation methods of this application. The descriptions of the above embodiments are only intended to help understand the method and core ideas of this application. It should be noted that those skilled in the art can make various improvements and modifications to this application without departing from its principles, and these improvements and modifications also fall within the protection scope of this application.
Claims
1. A riveting device for a fan frame partition, characterized in that, Applied to a frame (1), it includes a riveting part (7), a support platform (5) supported at the bottom of the frame (1), and a fixing component (6) slidably mounted on the support platform (5). The riveting part (7) includes a first riveting module (8) mounted on the support platform (5) and a second riveting module (9) movably positioned on the top of the frame (1). The fixing component (6) corresponds to the position of the partition (2) in the frame (1). The fixing component (6) includes a push block (601) and a positioning wedge (602) slidably connected to the side wall of the push block (601). The push block (601) is adjusted to move closer to the frame (1) so that the positioning wedge (602) clamps the partition (2). The first riveting module (8) rivets the first protrusion (201) of the partition (2) on both sides along the length direction of the frame (1), and the second riveting module (9) rivets the second protrusion (202) of the partition (2) along the top of the frame (1).
2. The riveting device for a fan frame partition according to claim 1, characterized in that, The push block (601) is provided with a plurality of spaced blocks along the length of the frame (1), and the two positioning inclined blocks (602) installed on two adjacent push blocks (601) are arranged opposite each other; The push block (601) is provided with a hook track groove (10), and the positioning inclined block (602) is provided with a hook track (11) that slides with the hook track groove (10). Two adjacent push blocks (601) move toward the frame (1) so that the two positioning inclined blocks (602) move closer to each other and clamp on both sides of the partition (2).
3. The riveting device for a fan frame partition according to claim 1 or 2, characterized in that, The first protrusion (201) and the second protrusion (202) are both fixedly connected to the outer side wall of the partition (2). The first protrusion (201) passes through the first riveting holes on both sides along the length direction of the frame (1), and the second protrusion (202) passes through the second riveting hole at the top of the frame (1).
4. The riveting device for a fan frame partition according to claim 3, characterized in that, The support platform (5) is provided with a receiving through hole (501), the push block (601) is slidably installed in the receiving through hole (501), and a driving component (12) is installed at the bottom of the support platform (5). The driving component (12) is used to drive the push block (601) to slide along the receiving through hole (501).
5. The riveting device for a fan frame partition according to claim 1, characterized in that, The first riveting module (8) includes a baffle (801) connected to the support platform (5) and a riveting plate (802) connected to the baffle (801) on the side near the frame (1). A riveting through hole (15) is opened on the riveting plate (802), and the riveting through hole (15) corresponds to the position of the first convex bridge (201). A first riveting component (16) is provided in the riveting through hole (15). The first riveting assembly (16) includes at least two limiting blocks (1601) slidably connected in the riveting through hole (15) and a riveting punch (1602) movably connected between the two limiting blocks (1601). An elastic element (1603) is connected to the limiting block (1601). The elastic element (1603) is used to elastically drive the two limiting blocks (1601) to limit the first convex bridge (201) before the riveting punch (1602) contacts the first convex bridge (201).
6. The riveting device for a fan frame partition according to claim 5, characterized in that, The riveting punch (1602) includes an inclined surface (17) provided on the side wall along the riveting direction and a plane (18) extending and connected to the inclined surface (17). The inclined surface (17) and the plane (18) are arranged sequentially along the riveting direction, and the width of the riveting punch (1602) at the position of the inclined surface (17) is greater than the width of the riveting punch (1602) at the position of the plane (18).
7. The riveting device for a fan frame partition according to claim 5, characterized in that, The riveting part (7) further includes a fixing plate (701) and a push post (702) vertically mounted on the fixing plate (701). The pressing plate (802) has a protrusion (703) on the side near the fixing plate (701). The end of the push post (702) away from the fixing plate (701) extends between the baffle (801) and the pressing plate (802) and contacts the protrusion (703).
8. The riveting device for a fan frame partition according to claim 7, characterized in that, The second riveting module (9) includes a pressure plate (901) connected to the side of the fixed plate (701) near the support platform (5). The pressure plate (901) has a through hole (902). A second riveting assembly is provided in the through hole (902). The second riveting assembly is used to rivet the second convex bridge (202). The second riveting assembly has the same or different structure as the first riveting assembly (16).
9. The riveting device for a fan frame partition according to claim 8, characterized in that, The fixed plate (701) is connected to a guide post (19), and the support platform (5) is provided with a guide hole (20) corresponding to the guide post (19). When the second riveting module (9) rivets the second convex bridge (202), the guide post (19) passes through the guide hole (20). The support platform (5) is equipped with a positioning block (21) and a positioning element (22). A limiting space is provided between the positioning block (21) and the positioning element (22). The end of the frame (1) along the direction perpendicular to the plane (18) where the partition (2) is located is located within the limiting space.
10. A server, characterized in that, The server includes the riveting device for the fan frame partition as described in any one of claims 1 to 9.