Rotary filter element cooling and setting device
The rotating cooling and shaping device uses a clamping assembly that is vertically positioned and rotates cyclically for cooling, which solves the problems of a large number of molds and large equipment footprint in the traditional air conditioning filter cooling and shaping method, and achieves faster filter replacement speed and cost savings.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- GUANGZHOU TONGYUE AUTOMATION EQUIP CO LTD
- Filing Date
- 2025-05-13
- Publication Date
- 2026-07-07
AI Technical Summary
Existing methods for cooling and shaping air conditioning filters require a large number of molds or large equipment footprints, resulting in high costs and low efficiency.
A vertically arranged clamping assembly is used for rotary cooling. The cooling operation is carried out by the clamping assembly during the cyclic rotation, avoiding reliance on linear production lines and molds. The filter element is clamped and released by the circumferential rotation of the clamping assembly.
This reduced the number of molds required, lowered production costs, increased the speed of changing filter models, and saved space and resources.
Smart Images

Figure CN224465076U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of air conditioning filter manufacturing technology, specifically relating to a rotary filter cooling and shaping device. Background Technology
[0002] An air conditioning filter element includes a filter element body, a long side, and a short side disposed on the outer periphery of the filter element body. In the prior art, after applying hot melt adhesive to the outer periphery of the filter element body, the corresponding long and short sides are attached using an edge-fitting device that works with the filter element mounted on a mold. Some filter elements have flanges on the long or short sides that are attached to the upper end face of the filter element body. Due to the nature of hot melt adhesive, it is in a fluid state when it is hot-melted, but in a solid state when cooled to room temperature. Thus, the air conditioning filter element achieves the effect of fixing the long and short sides to the outside of the filter element body by applying hot melt adhesive and then cooling it. However, in the prior art, after the long and short sides of the air conditioning filter element are attached, there are two cooling methods: one is cooling and shaping on a mold, and the other is cooling and shaping on a conveyor belt. The above-mentioned cooling methods have certain drawbacks. Cooling and shaping on the mold increases the number of molds, reduces the speed of changing models, and increases costs. Cooling and shaping on the conveyor belt increases the length of the equipment and requires a large area. To solve at least one of the above technical problems, it is necessary to develop a horizontal rotating filter element cooling and shaping device. Utility Model Content
[0003] The purpose of this invention is to provide a rotary filter element cooling and shaping device to solve the above-mentioned technical problems. The device is vertically arranged and rotates. After the clamping component clamps the filter element with the edge attached, a cooling operation is performed during the cyclic rotation. After cooling, the filter element with the edge attached is placed back in place, and this cycle is repeated. Because the cooling is rotary, it does not rely on a linear production line, requiring less space. Since it does not rely on molds for cooling, it effectively reduces mold occupancy, requiring fewer molds, thereby increasing the speed of changing filter element models and saving costs.
[0004] To achieve the above-mentioned objectives, the technical solution adopted by this utility model is as follows:
[0005] A rotary filter element cooling and shaping device includes a clamping assembly for gripping the filter element and a first driving device for circumferentially rotating the clamping assembly to cool the filter element. The radial direction of the circumferential rotation of the clamping assembly is arranged on the same vertical plane. Vertically positioned and rotating, the clamping assembly grips the filter element after edge bonding and performs a cooling operation during cyclic rotation. After cooling, the edge-bonded filter element is repositioned, and this cycle is repeated. Because the cooling is rotary, it does not rely on a linear production line, requiring less space. Since it does not rely on molds for cooling, it effectively reduces mold occupancy, requiring fewer molds, thereby increasing the speed of filter element replacement and saving costs.
[0006] Preferably, the clamping assembly includes a first clamping assembly, a second clamping assembly, a third clamping assembly, and a fourth clamping assembly arranged circumferentially and rotating synchronously. The first, second, third, and fourth clamping assemblies are circumferentially spaced and each is connected to the first driving device. Through the sequentially arranged circumferential clamping assemblies, each clamping assembly clamps the filter element to be cooled, then rotates it for cooling. After cooling, the cooled filter element is removed. The operation of clamping and cooling the filter element is completed during the rotation of multiple clamping assemblies, requiring less space and not relying on a mold for cooling.
[0007] Preferably, the first, second, third, and fourth clamping components each include a clamping module and a second driving device that drives the clamping module to perform clamping or releasing actions. One end of the second driving device is connected to the first driving device; the second driving device drives the clamping module, thereby controlling the space between the clamping modules to control the clamping or releasing of the filter element.
[0008] Preferably, the clamping module includes a left clamping plate and a right clamping plate facing the left clamping plate, both of which are connected to a second driving device. The relative distance between the left and right clamping plates is controlled by the second driving device, thereby controlling the operation of clamping or releasing the filter element.
[0009] Preferably, a first support plate is provided below the left clamping plate, and / or a second support plate is provided below the right clamping plate. Providing the first and second support plates prevents the filter element from falling off due to lack of support at its lower end during the clamping process.
[0010] Preferably, the first support plate is alternately provided with first protrusions and first grooves;
[0011] The second support plate is alternately provided with second protrusions and second grooves;
[0012] The first protrusion faces the second groove, and the second protrusion faces the first groove. This reduces the overall weight while allowing them to interlock when smaller filter elements need to be clamped, thus providing a support surface at the bottom of the filter element for both larger and smaller filter elements.
[0013] Preferably, a first pressure plate cylinder is provided on the side of the left clamping plate away from the right clamping plate, and the movable end of the first pressure plate cylinder is connected to a first upper pressure bar;
[0014] A second pressure plate cylinder is installed on the right clamping plate away from the left clamping plate, and the movable end of the second pressure plate cylinder is connected to a second upper pressure bar. One or more first and second pressure plate cylinders are provided, and their orientations are perpendicular to either the first or second support plate. Along the radial direction of the gripping assembly's rotation, the first support plate and the first upper pressure bar are sequentially arranged, as are the second support plate and the second upper pressure bar. The first pressure plate cylinder controls the raising and lowering of the first upper pressure bar, and the second pressure plate cylinder controls the raising and lowering of the second upper pressure bar, thereby pressing the flange attached to the upper end of the filter element and limiting the upper end of the filter element to prevent it from falling out during the rotation of the gripping assembly.
[0015] Preferably, one side of the first upper pressure strip is positioned close to the left clamping plate, and the other side of the first upper pressure strip is positioned facing the right clamping plate;
[0016] The second upper pressure strip is positioned near the right clamping plate on one side and facing the left clamping plate on the other side. This arrangement of the first and second upper pressure strips between the left and right clamping plates facilitates the pressing operation of the filter element placed between them.
[0017] Preferably, the left clamping plate is provided with a first positioning cylinder, the movable end of the first positioning cylinder can pass through the left clamping plate and is positioned towards the right clamping plate;
[0018] The right clamping plate is equipped with a second positioning cylinder, the movable end of which passes through the right clamping plate and faces the left clamping plate. With both a first and second positioning cylinder, after the left and right clamping plates release their grip on the filter element, the movable ends of the first and second positioning cylinders extend to maintain the filter element's position. This prevents the filter element from being deviated from its designated position due to the presence of hot melt adhesive or friction, thus ensuring it can be removed from its specific location. This also facilitates the subsequent removal of the cooled filter element by an external clamping device, reducing operational difficulty.
[0019] Preferably, one or more of the first positioning cylinder and the second positioning cylinder are provided. They can be arranged symmetrically in groups to facilitate synchronous extension and retraction operations.
[0020] Preferably, the second driving device includes a first clamping plate cylinder and a second clamping plate cylinder, wherein the movable end of the first clamping plate cylinder is connected to the left clamping plate and the movable end of the second clamping plate cylinder is connected to the right clamping plate.
[0021] Both the first and second clamping cylinders are connected to the first driving device. The movable end of the first clamping cylinder faces the right clamping plate; the movable end of the second clamping cylinder faces the left clamping plate; one or more of the first and second clamping cylinders are provided. The first driving device drives the first and second clamping cylinders to rotate, thereby driving the clamping module to rotate, facilitating the clamping and cooling of the filter element; and by extending and retracting the movable ends of the first and second clamping cylinders, the relative or opposite movement of the left and right clamping plates is controlled, thereby controlling the clamping or releasing action of the filter element.
[0022] Preferably, the first driving device is connected to a rotating shaft, the rotating shaft is connected to a first rotating disk and a second rotating disk, there is a gap between the first rotating disk and the second rotating disk, and the left clamping plate and the right clamping plate are disposed between the first rotating disk and the second rotating disk;
[0023] The first clamping plate cylinder is connected to the first rotating disk;
[0024] The second clamping cylinder is connected to the second rotating disk. The first driving device is a pneumatic or electric drive, specifically a motor in this technical solution. The first and second rotating disks are arranged parallel to each other, with the radial direction of the first rotating disk perpendicular to the rotating shaft. A first positioning cylinder is connected to the first rotating disk, and a second positioning cylinder is connected to the second rotating disk. The left and right clamping plates move in a direction parallel to the rotating shaft, i.e., perpendicular to the first or second rotating disk. The rotating shaft drives the first and second rotating disks to rotate synchronously, thereby causing a single set of first and second clamping cylinders to rotate, and a single set of left and right clamping plates to rotate synchronously. This allows for the rotational cooling operation after clamping the filter element to be cooled. This rotational method requires less space for cooling the filter element, avoiding the problem of requiring a large space for cooling operations in a linear transport process.
[0025] This application has achieved beneficial technical effects:
[0026] The clamping component of this invention is vertically arranged and rotates. After clamping the filter element with the edge attached, the clamping component performs a cooling operation during the cyclic rotation. After the cooling operation is completed, the filter element with the edge attached is placed back in place. This cycle is repeated. Since the cooling is performed by rotation, it does not rely on a linear production line and requires less space. Since the cooling does not rely on molds, it can effectively reduce the occupation of molds and reduce the number of molds required, thereby increasing the speed of changing filter element models and saving costs. Attached Figure Description
[0027] Figure 1 The diagram shows the installation structure of the rotary cooling and shaping device.
[0028] Figure 2 The image shown is one of the structural schematic diagrams of a rotary cooling and shaping device;
[0029] Figure 3 The second schematic diagram shows the structure of a rotary cooling and shaping device;
[0030] Figure 4 The third schematic diagram of the rotary cooling and shaping device is shown.
[0031] Figure 5 The diagram shown is a schematic of the workstation layout.
[0032] Figure 6 The diagram shows the structural flow of the gripping and releasing action of the gripping module.
[0033] Figure Labels
[0034] 50-First driving device; 51-First clamping assembly; 52-Second clamping assembly; 53-Third clamping assembly; 54-Fourth clamping assembly; 55-Clamping module; 56-Second driving device; 551-Left clamping plate; 552-Right clamping plate; 553-First support plate; 554-Second support plate; 5531-First protrusion; 5532-First groove; 5541-Second protrusion; 5542-Second groove; 5511-First pressure plate cylinder; 5512-First upper pressure bar; 5521-Second pressure plate cylinder; 5522-Second upper pressure bar; 555-First positioning cylinder; 556-Second positioning cylinder; 561-First clamping plate cylinder; 562-Second clamping plate cylinder; 500-Rotating shaft; 501-First rotating disk; 502-Second rotating disk. Detailed Implementation
[0035] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the specific implementation methods of this utility model will be described below with reference to the accompanying drawings. Obviously, the drawings described below are merely some embodiments of this utility model. For those skilled in the art, other drawings and other implementation methods can be obtained based on these drawings without any creative effort.
[0036] The technical solution of this utility model will be described in detail below with specific embodiments.
[0037] Reference Figures 1 to 6As shown, a rotary filter element cooling and shaping device includes a clamping assembly for gripping the filter element and a first driving device 50 for circumferentially rotating the clamping assembly to cool the filter element. The radial direction of the circumferential rotation of the clamping assembly is arranged on the same vertical plane. Vertically positioned and rotating, the clamping assembly grips the filter element after edge bonding and performs a cooling operation during cyclic rotation. After cooling, the edge-bonded filter element is repositioned, and this cycle is repeated. Because the cooling is rotary, it does not rely on a linear production line, requiring less space. Since it does not rely on molds for cooling, it effectively reduces mold occupancy, requiring fewer molds, thereby increasing the speed of filter element replacement and saving costs.
[0038] The clamping assembly includes a first clamping assembly 51, a second clamping assembly 52, a third clamping assembly 53, and a fourth clamping assembly 54 arranged circumferentially and rotating synchronously. The first clamping assembly 51, the second clamping assembly 52, the third clamping assembly 53, and the fourth clamping assembly 54 are circumferentially spaced and all connected to the first driving device 50. Through the sequentially arranged circumferential clamping assemblies 51, 52, 53, and 54, each clamping assembly clamps the filter element to be cooled, then rotates it for cooling. After cooling, the cooled filter element is removed. The operation of clamping and cooling the filter element is completed during the rotation of multiple clamping assemblies, requiring less space and not relying on a mold for cooling.
[0039] The first clamping assembly 51, the second clamping assembly 52, the third clamping assembly 53, and the fourth clamping assembly 54 each include a clamping module 55 and a second driving device 56 that drives the clamping module 55 to perform clamping or releasing actions. One end of the second driving device 56 is connected to the first driving device; the second driving device 56 drives the clamping module, thereby controlling the space between the clamping modules 55 to control the clamping or releasing of the filter element.
[0040] The clamping module 55 includes a left clamping plate 551 and a right clamping plate 552 facing the left clamping plate 551. Both the left clamping plate 551 and the right clamping plate 552 are connected to the second driving device 56. The relative distance between the left clamping plate 551 and the right clamping plate 552 is controlled by the second driving device 56, thereby controlling the operation of clamping or releasing the filter element.
[0041] A first support plate 553 is provided below the left clamping plate 551, and / or a second support plate 554 is provided below the right clamping plate 552. The first support plate 553 and the second support plate 554 are provided to prevent the filter element from falling off due to lack of support at its lower end during the clamping process.
[0042] The first support plate 553 is alternately provided with a first protrusion 5531 and a first groove 5532;
[0043] The second support plate 554 is alternately provided with a second protrusion 5541 and a second groove 5542;
[0044] The first protrusion 5531 and the second groove 5542 are arranged facing each other, and the second protrusion 5541 and the first groove 5532 are arranged facing each other. This reduces the overall weight and allows them to fit together when smaller filter elements need to be clamped, thus providing a support surface at the bottom of the filter element for both larger and smaller filter elements.
[0045] A first pressure plate cylinder 5511 is provided on the side of the left clamping plate 551 away from the right clamping plate 552, and the movable end of the first pressure plate cylinder 5511 is connected to the first upper pressure bar 5512.
[0046] A second pressure plate cylinder 5521 is provided on the side of the right clamping plate 552 away from the left clamping plate 551. The movable end of the second pressure plate cylinder 5521 is connected to the second upper pressure bar 5522. One or more of the first pressure plate cylinder 5511 and the second pressure plate cylinder 5521 are provided, and the orientation of both the first pressure plate cylinder 5511 and the second pressure plate cylinder 5521 is perpendicular to either the first support plate 553 or the second support plate 554. Along the radial direction of rotation of the clamping assembly, the first support plate 553 and the first upper pressure bar 5512 are arranged sequentially, and the second support plate 554 and the second upper pressure bar 5522 are arranged sequentially. The first pressure plate cylinder 5511 controls the lifting and lowering of the first upper pressure bar 5512, and the second pressure plate cylinder 5521 controls the lifting and lowering of the second upper pressure bar 5522, thereby pressing the flange attached to the upper end of the filter element and limiting the upper end of the filter element to prevent the filter element from falling off during the rotation of the clamping assembly.
[0047] The first upper pressure bar 5512 is positioned close to the left clamping plate 551 on one side, and the other side of the first upper pressure bar 5512 is positioned towards the right clamping plate 552.
[0048] The second upper pressure strip 5522 is positioned close to the right clamping plate 552 on one side, and the other side of the second upper pressure strip 5522 faces the left clamping plate 551. The first upper pressure strip 5512 and the second upper pressure strip 5522 are positioned between the left clamping plate 551 and the right clamping plate 552, which facilitates the pressing operation of the filter element placed between the left clamping plate 551 and the right clamping plate 552.
[0049] The left clamping plate 551 is provided with a first positioning cylinder 555, the movable end of the first positioning cylinder 555 can pass through the left clamping plate 551 and is positioned towards the right clamping plate 552.
[0050] The right clamping plate 552 is equipped with a second positioning cylinder 556. The movable end of the second positioning cylinder 556 passes through the right clamping plate 552 and faces the left clamping plate 551. With the first positioning cylinder 555 and the second positioning cylinder 556, after the left clamping plate 551 and the right clamping plate 552 release their grip on the filter element, the movable ends of the first positioning cylinder 555 and the second positioning cylinder 556 extend out, maintaining the position of the filter element and preventing it from being deviated from its designated position due to the presence of hot melt adhesive or friction, thus preventing it from being moved out of the filter element at a specific location. This facilitates the subsequent removal of the cooled filter element by an external clamping device at a specific location, reducing operational difficulty.
[0051] One or more of the first positioning cylinder 555 and the second positioning cylinder 556 are provided. They can be arranged symmetrically in groups to facilitate synchronous extension and retraction operations.
[0052] The second driving device 56 includes a first clamping cylinder 561 and a second clamping cylinder 562. The movable end of the first clamping cylinder 561 is connected to the left clamping plate 551, and the movable end of the second clamping cylinder 562 is connected to the right clamping plate 552.
[0053] Both the first clamping cylinder 561 and the second clamping cylinder 562 are connected to the first driving device 50. The movable end of the first clamping cylinder 561 faces the right clamping plate 552; the movable end of the second clamping cylinder 562 faces the left clamping plate 551; one or more of the first clamping cylinder 561 and the second clamping cylinder 562 are provided. The first driving device 50 drives the first clamping cylinder 561 and the second clamping cylinder 562 to rotate, thereby driving the clamping module to rotate, facilitating the clamping and cooling of the filter element; and by extending and retracting the movable ends of the first clamping cylinder 561 and the second clamping cylinder 562, the relative or opposite movement of the left clamping plate 551 and the right clamping plate 552 is controlled, thereby controlling the clamping or releasing action of the filter element.
[0054] The first driving device 50 is connected to a rotating shaft 500, the rotating shaft 500 is connected to a first rotating disk 501 and a second rotating disk 502, there is a gap between the first rotating disk 501 and the second rotating disk 502, and the left clamping plate 551 and the right clamping plate 552 are disposed between the first rotating disk 501 and the second rotating disk 502.
[0055] The first clamping plate cylinder 561 is connected to the first rotating disk 501;
[0056] The second clamping plate cylinder 562 is connected to the second rotating disk 502. The first driving device 50 is a pneumatic or electric drive device; in this technical solution, it is specifically a motor. The first rotating disk 501 and the second rotating disk 502 are arranged in parallel, and the radial direction of the first rotating disk 501 is perpendicular to the rotating shaft 500. The first positioning cylinder 555 is connected to the first rotating disk 501, and its movable end passes through the first rotating disk 501. The second positioning cylinder 556 is connected to the second rotating disk 502, and its movable end passes through the second rotating disk 502. The left clamping plate 551 and the right clamping plate 552 move in a direction parallel to the rotating shaft, i.e., perpendicular to the first rotating disk 501 or the second rotating disk 502. The first rotating disk 501 and the second rotating disk 502 are driven to rotate synchronously by the rotating shaft 500; thereby driving the single set of first clamping plate cylinder 561 and second clamping plate cylinder 562 to rotate, and the single set of left clamping plate 551 and right clamping plate 552 to rotate synchronously. Thus, after clamping the filter element to be cooled, the rotation cooling operation is performed. The space required for cooling the filter element in this rotation method is small, avoiding the problem of large space required for cooling operation in the linear transmission process.
[0057] An operating method includes the aforementioned rotary filter element cooling and shaping device, wherein a clamping assembly clamps the filter element and rotates it circumferentially for cooling the filter element, wherein the radial direction of the rotation of the clamping assembly is arranged on the same vertical plane.
[0058] Workstation 1, Workstation 2, Workstation 3, and Workstation 4 are defined and set sequentially in the circumferential rotation direction, with Workstation 1 set at the top in the vertical direction;
[0059] The clamping component in station one clamps the placed filter element to be cooled. The clamping component rotates circumferentially to cool the filter element. When the clamping component rotates circumferentially and returns to station one, it releases the clamp on the cooled filter element. The cooled filter element is removed and a new filter element to be cooled is placed. This cycle continues.
[0060] In the initial state, station one, station two, station three, and station four correspond to the first gripping component 51, the second gripping component 52, the third gripping component 53, and the fourth gripping component 54, respectively.
[0061] When the first clamping component 51 rotates to station one, it releases its grip on the cooled filter element, removes the cooled filter element, and clamps the repositioned filter element to be cooled.
[0062] The first clamping component 51, which has completed the clamping operation, rotates to station two, and the second clamping component 52 rotates to station one to release the clamping of the cooled filter element, remove the cooled filter element, and clamp the repositioned filter element to be cooled.
[0063] The second gripping component 52, which has completed the gripping operation, rotates to station two, and the third gripping component 53 rotates to station one to release the gripping of the cooled filter element, remove the cooled filter element, and grip the repositioned filter element to be cooled.
[0064] The third clamping component 53, having completed the clamping operation, rotates to station two, while the fourth clamping component 54 simultaneously rotates to station one to release the clamping of the cooled filter element, remove the cooled filter element, and clamp the repositioned filter element to be cooled.
[0065] The fourth clamping component 54, which has completed the clamping operation, rotates to station two, and the first clamping component 51 rotates to station one at the same time, forming a cooled filter element. The clamping of the cooled filter element is released, the cooled filter element is removed from station one, and the placed filter element to be cooled is clamped again.
[0066] This circumferential rotation is used for cooling.
[0067] During the process of releasing the clamping of the cooled filter element, the moving ends of the first clamping cylinder 561 and the second clamping cylinder 562 move in opposite directions, thereby driving the left clamping plate 551 and the right clamping plate 552 to move in opposite directions to release the clamping of the filter element.
[0068] Both the movable ends of the first positioning cylinder 555 and the movable ends of the second positioning cylinder 556 extend and respectively abut against both sides of the filter element.
[0069] The extension amount of the movable ends of the first positioning cylinder 555 and the second positioning cylinder 556 is constant. In this technical solution, the extension amount of the first positioning cylinder 555 and the second positioning cylinder 556 is kept constant, maintaining a distance of 50cm between the movable ends of the first positioning cylinder 555 and the second positioning cylinder 556. The specific distance can be adjusted according to the size of the filter element and the required positioning position.
[0070] During the process of clamping the placed filter element to be cooled, the left clamping plate 551 and the right clamping plate 552 move towards each other to clamp the filter element, and the moving ends of the first positioning cylinder 555 and the second positioning cylinder 556 both retract.
[0071] During the process of clamping the placed filter element to be cooled, the first support plate 553 and the second support plate 554 move towards each other; the first upper pressure bar 5512 moves toward the first support plate 553 and the second upper pressure bar 5522 moves toward the second support plate 554 to press the upper end of the filter element.
[0072] The rotary filter element cooling and shaping device further includes a shaping frame; the two ends of the rotating shaft are respectively movably connected to the shaping frame, so that the rotating shaft is set horizontally.
[0073] by Figure 2Based on perspective, Figure 5 This is a schematic diagram of the corresponding workstation layout;
[0074] The left clamping plate is provided with a groove to avoid interfering with the movement of the first upper pressure bar; the right clamping plate is provided with a groove to avoid interfering with the movement of the first upper pressure bar.
[0075] It also includes a touchscreen for inputting operating parameters;
[0076] The rotary filter element cooling and shaping device has four stations. After the touch screen outputs the product model parameters, the pneumatic or electric device on the station drives the lead screw (rotor shaft) to rotate, causing the left and right clamping plates to automatically adjust to the appropriate positions. At station one, the left and right clamping plates, as well as the first and second upper pressure strips, are in the open state. When the edge-attaching machine has finished attaching the product and rotated it to the appropriate position, it is clamped by the external clamping plates and transferred to station one. At station one, the first and second clamping plate cylinders actuate to clamp the product, and the first and second pressure plate cylinders actuate to press the product firmly. After the product is fixed, the pneumatic or electric... The actuator drives the first and second rotating disks to rotate 90 degrees synchronously to station two. At this time, when the product from station four rotates to station one, the first and second pressure plate cylinders activate to open the pressure plate, the first and second positioning cylinders extend, and the first and second clamping cylinders activate to open the clamping plate. The first and second positioning cylinders then retract, and the external clamping plate clamps the product out of the rotating filter element cooling and shaping device and places it into the trimming machine for trimming. At the same time, the external clamping plate puts the product that has been edged by the edge-attaching machine back into the clamping assembly at station one, and this action is repeated.
[0077] The technical features of the above embodiments can be combined in any way. For the sake of brevity, not all possible combinations of the technical features in the above embodiments are described. However, as long as there is no contradiction in the combination of these technical features, they should be considered to be within the scope of this specification.
[0078] The embodiments described above are merely illustrative of several implementations of this utility model, and while the descriptions are relatively specific and detailed, they should not be construed as limiting the scope of the utility model patent. It should be noted that those skilled in the art can make various modifications and improvements without departing from the concept of this utility model, and these all fall within the protection scope of this utility model. Therefore, the protection scope of this utility model patent should be determined by the appended claims.
[0079] The embodiments of the rotary filter element cooling and shaping device and its operating method provided by this utility model have been described in detail above. Specific examples have been used to illustrate the principle and implementation of this utility model. The descriptions of the embodiments above are only for the purpose of helping to understand the core idea of this utility model. It should be noted that for those skilled in the art, several improvements and modifications can be made to this utility model without departing from the principle of this utility model, and these improvements and modifications also fall within the protection scope of the claims of this utility model.
Claims
1. A rotary filter element cooling and shaping device, characterized in that, The device includes a clamping assembly for clamping a filter element and a first driving device (50) for circumferentially rotating the clamping assembly to cool the filter element, wherein the radial direction of the circumferential rotation of the clamping assembly is arranged on the same vertical plane.
2. The rotary filter element cooling and shaping device according to claim 1, characterized in that, The clamping assembly includes a first clamping assembly (51), a second clamping assembly (52), a third clamping assembly (53), and a fourth clamping assembly (54) arranged circumferentially and rotating synchronously.
3. The rotary filter element cooling and shaping device according to claim 2, characterized in that, The first clamping assembly (51), the second clamping assembly (52), the third clamping assembly (53), and the fourth clamping assembly (54) all include a clamping module (55) and a second driving device (56) that drives the clamping module (55) to complete the clamping or releasing action.
4. The rotary filter element cooling and shaping device according to claim 3, characterized in that, The clamping module (55) includes a left clamping plate (551) and a right clamping plate (552) facing the left clamping plate (551). Both the left clamping plate (551) and the right clamping plate (552) are connected to the second driving device (56).
5. The rotary filter element cooling and shaping device according to claim 4, characterized in that, A first support plate (553) is provided below the left clamping plate (551), and / or a second support plate (554) is provided below the right clamping plate (552).
6. The rotary filter element cooling and shaping device according to claim 5, characterized in that, The first support plate (553) is alternately provided with a first protrusion (5531) and a first groove (5532); The second support plate (554) is alternately provided with a second protrusion (5541) and a second groove (5542); The first protrusion (5531) and the second groove (5542) are arranged facing each other, and the second protrusion (5541) and the first groove (5532) are arranged facing each other.
7. The rotary filter element cooling and shaping device according to claim 4, characterized in that, A first pressure plate cylinder (5511) is provided on the side of the left clamping plate (551) away from the right clamping plate (552), and the movable end of the first pressure plate cylinder (5511) is connected to the first upper pressure bar (5512). A second pressure plate cylinder (5521) is provided on the side of the right clamping plate (552) away from the left clamping plate (551), and the movable end of the second pressure plate cylinder (5521) is connected to the second upper pressure bar (5522).
8. The rotary filter element cooling and shaping device according to claim 4, characterized in that, The left clamping plate (551) is provided with a first positioning cylinder (555), the movable end of the first positioning cylinder (555) can pass through the left clamping plate (551) and is positioned towards the right clamping plate (552); The right clamping plate (552) is provided with a second positioning cylinder (556), the movable end of the second positioning cylinder (556) passes through the right clamping plate (552) and is positioned towards the left clamping plate (551).
9. The rotary filter element cooling and shaping device according to claim 4, characterized in that, The second driving device (56) includes a first clamping cylinder (561) and a second clamping cylinder (562). The movable end of the first clamping cylinder (561) is connected to the left clamping plate (551), and the movable end of the second clamping cylinder (562) is connected to the right clamping plate (552). The first clamping plate cylinder (561) and the second clamping plate cylinder (562) are both connected to the first driving device (50).
10. The rotary filter element cooling and shaping device according to claim 9, characterized in that, The first driving device (50) is connected to a rotating shaft (500), which is connected to a first rotating disk (501) and a second rotating disk (502). There is a gap between the first rotating disk (501) and the second rotating disk (502). The left clamping plate (551) and the right clamping plate (552) are disposed between the first rotating disk (501) and the second rotating disk (502). The first clamping plate cylinder (561) is connected to the first rotating disk (501); The second clamping plate cylinder (562) is connected to the second rotating disk (502).