A feed bin for a multi-point feeder
By installing a vibrating plate and connecting rod structure inside the feeding bin of the multi-point feeder, and using an external power mechanism to drive the vibrating plate to vibrate, the problem of milling material sticking is solved, the feeding efficiency and stability are improved, and the labor intensity and equipment maintenance costs are reduced.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SICHUAN RUIXIN SUPPLY CHAIN MANAGEMENT CO LTD
- Filing Date
- 2025-07-31
- Publication Date
- 2026-06-26
Smart Images

Figure CN224412253U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of feeding machinery technology, specifically to a feeding bin for a multi-point feeder. Background Technology
[0002] In the field of modern road construction and maintenance, the recycling technology of asphalt mixtures has become a key means to achieve resource conservation and environmental protection. Milled material, which is waste material milled from old asphalt pavement, is crushed, screened, and then stacked in bins according to specifications for use in the production of recycled asphalt mixtures. This process not only reduces the exploitation of natural resources but also lowers engineering costs. However, in practical applications, the processing and supply of milled material still face many challenges. Existing technologies, such as the milled material processing and supply device in the asphalt mixing plant shown in patent CN114789888A, although optimizing the processing flow of milled material to some extent, still have significant shortcomings in the supply stage.
[0003] Specifically, the specification of patent CN114789888A Figure 4 This paper demonstrates a device for handling and feeding milled material at an asphalt mixing plant. The device uses a vibrating screen to sieve the milled material, ensuring that materials of different particle sizes are stacked in designated bins according to specifications. Its initial design aim is to improve the processing efficiency of milled material and reduce manual intervention. However, in practical applications, due to residual asphalt components, the milled material easily clumps together during screening and stacking. This clumping phenomenon is particularly pronounced during feeding, especially in the initial stages when the recycled material has extremely poor flowability, causing the feeder to malfunction. To ensure smooth feeding, workers have to frequently perform manual unclogging, which not only increases labor intensity but also severely impacts production efficiency.
[0004] Within the asphalt mixing plant, milled material is crushed, screened, and then stored in bins according to specifications for later use in asphalt mixture production. Typically, a feeder located beneath the bins is used for direct feeding. While convenient, this method suffers from the presence of residual asphalt in the milled material, causing the recycled material to clump together. Especially in the initial feeding stage, the recycled material lacks fluidity, making the feeder's conveying mechanism prone to clogging. For example, see the specification of patent CN114789888A. Figure 4 The device shown in the image, while screening the milled material using a vibrating screen, often experiences jamming during startup of the feeder due to the adhesion of recycled material. Workers are forced to frequently stop the machine to manually clear the blockage, increasing labor intensity and severely impacting production efficiency. Furthermore, this frequent downtime for cleaning can accelerate equipment wear, further increasing maintenance costs. Therefore, effectively solving the problem of milled material adhesion during feeding, and improving feeding efficiency and stability, without excessively increasing costs, is a pressing technical challenge.
[0005] In view of the above, this application is hereby submitted. Utility Model Content
[0006] The purpose of this utility model is to provide a feeding bin for a multi-point feeder. The feeding bin has openings, and a connecting rod extends a vibrating plate into the bin body to realize the vibration of the vibrating plate in the feeding bin, so as to solve the problem in the prior art that recycled materials stick together and clump together, causing the feeder to malfunction.
[0007] This utility model embodiment is achieved through the following technical solution: This utility model embodiment provides a feeding bin for a multi-point feeder, comprising:
[0008] The silo body includes a top opening and a bottom opening. The top opening is used for feeding, and the bottom opening is used for discharging.
[0009] The vibrating component includes a connecting rod, a vibrating plate, and an opening provided on the main body of the chamber. The connecting rod extends through the opening and into the main body of the chamber. One end of the connecting rod inside the main body of the chamber is connected to the vibrating plate, and the other end of the connecting rod outside the main body of the chamber can be connected to an external power mechanism and driven.
[0010] The vibrating plate is designed to vibrate within the warehouse body after being driven by the connecting rod.
[0011] Optionally, the vibrating plate includes a horizontal plate, and a first limiting groove and a second limiting groove are provided on the inner wall of the bin body. One end of the horizontal plate is movably installed in the first limiting groove, and the other end is movably installed in the second limiting groove. The width of the first limiting groove and the width of the second limiting groove are both greater than the width of the horizontal plate.
[0012] The horizontal plate is configured to vibrate back and forth along the width direction of the first limiting groove and the second limiting groove.
[0013] Optionally, the horizontal plate is provided with at least one first protrusion and at least one second protrusion, the first protrusion extending along the upper part of the horizontal plate and the second protrusion extending along the lower part of the horizontal plate;
[0014] There is a gap between two adjacent first protrusions, and there is a gap between two adjacent second protrusions.
[0015] Optionally, the horizontal plate is provided with two left-right symmetrical first convex plates and two left-right symmetrical second convex plates, and the two first convex plates and the two second convex plates are symmetrical vertically.
[0016] Optionally, the horizontal plate includes a first mounting end and a second mounting end, the first mounting end being installed in a first limiting groove and the second mounting end being installed in a second limiting groove;
[0017] Both the first mounting end and the second mounting end are inclined ends. The opening of the first limiting groove is inclined synchronously with the first mounting end, and the opening of the second limiting groove is inclined synchronously with the second mounting end.
[0018] Optionally, the first mounting end is provided with a first through hole, and the opposite side walls of the first limiting groove are respectively provided with a second through hole and a third through hole. The first through hole, the second through hole and the third through hole are configured to be connected by a screw, so that the first through hole is limited to be coaxial with the second through hole and the third through hole, and the first through hole can move along the axial direction of the screw.
[0019] Optionally, the second mounting end is provided with a fourth through hole, and the opposite side walls of the second limiting groove are respectively provided with a fifth through hole and a sixth through hole. The fourth through hole, the fifth through hole and the sixth through hole are configured to be connected by the screw, so that the fourth through hole is limited to be coaxial with the fifth through hole and the sixth through hole, and the fourth through hole can move along the axial direction of the screw.
[0020] Optionally, the opening is inclined downwards, a bushing is installed inside the opening, the connecting rod passes through the bushing, and the horizontal plate is inclined downwards; the vibrating plate is configured to be driven by the connecting rod to vibrate at an inclination within the bin body.
[0021] Optionally, an end cap is movably provided at the bottom opening, and at least one telescopic component is provided on the outside of the compartment body, with each telescopic component connected to the end cap.
[0022] At least one telescopic component is configured to control the degree of opening or closing of the bottom opening via telescopic control of the end cap component.
[0023] Optionally, the end cap includes an extended through groove and an arc plate. The arc plate extends along the top of one side wall of the extended through groove. A first mounting plate and a second mounting plate are respectively provided on both sides of the arc plate. The first mounting plate is used to hinge with one of the outer side walls of the container body, and the second mounting plate is used to hinge with the other opposite outer side wall of the container body.
[0024] A telescopic component is provided on the outside of the main body of the container, which is configured to drive the end cover to rotate around the bottom opening;
[0025] When the lower opening of the extended through slot is parallel to the bottom opening, the bottom opening is opened; when the arc plate covers the bottom opening, the bottom opening is closed.
[0026] Compared with the prior art, the embodiments of this utility model have the following advantages and beneficial effects:
[0027] 1. The feeding bin of the multi-point feeder provided in this utility model embodiment has an external power mechanism that transmits power to the connecting rod through connection with the connecting rod. The connecting rod drives the vibrating plate to vibrate inside the bin. The vibration of the vibrating plate makes the material inside the bin less likely to stick together and maintains good fluidity. When the material needs to be fed, it can be smoothly discharged from the bottom opening and enter the subsequent feeding equipment, thereby realizing the normal feeding function of the feeding bin.
[0028] 2. In this embodiment of the utility model, the rotation of the end cap is controlled by setting a telescopic component. The end cap includes an extended through groove and an arc plate. The rotational movement of the arc plate directly controls the opening and closing of the bottom opening. When the telescopic component extends or retracts, it drives the end cap to rotate around the bottom opening, so that the lower opening of the extended through groove is parallel to the bottom opening or the bottom opening is covered by the arc plate, thereby improving the accuracy of material feeding and the response speed of the system.
[0029] In general, the multi-point feeder feeding bin provided by the embodiments of this utility model has an opening, through which a vibrating plate is extended into the bin body by a connecting rod, so as to realize the vibration of the vibrating plate in the feeding bin, thereby reducing the adhesion and clumping of recycled materials and preventing the feeder from malfunctioning. Attached Figure Description
[0030] To more clearly illustrate the technical solutions of the embodiments of this utility model, the drawings used in the embodiments will be briefly introduced below. It should be understood that the following drawings only show some embodiments of this utility model and should not be regarded as a limitation on the scope. For those skilled in the art, other related drawings can be obtained based on these drawings without creative effort.
[0031] Figure 1 A first-view structural schematic diagram of the feeding bin of the multi-point feeder provided in an embodiment of this utility model;
[0032] Figure 2 A second-view structural schematic diagram of the feeding bin of the multi-point feeder provided in an embodiment of this utility model;
[0033] Figure 3 A schematic diagram of the cross-sectional structure of the feeding bin provided in an embodiment of this utility model;
[0034] Figure 4 A side view of the feeding bin provided for an embodiment of this utility model;
[0035] Figure 5 A schematic diagram of the vibration element structure provided in an embodiment of this utility model;
[0036] Figure 6 Detailed installation diagram of the vibration plate provided for an embodiment of this utility model;
[0037] Figure 7 A front view of the installation state of the vibration plate provided in an embodiment of this utility model;
[0038] Figure 8 A structural diagram of the vibration plate provided in an embodiment of this utility model;
[0039] Figure 9 A perspective view of the back of the end cap provided in an embodiment of this utility model;
[0040] Figure 10 A front perspective view of the end cap component provided in an embodiment of this utility model;
[0041] Figure 11 This is a diagram showing the bottom opening fully open.
[0042] Figure 12 This is a diagram showing the bottom opening completely closed.
[0043] Figure 13 This is a double-sided end cap control structure in other embodiments of this utility model.
[0044] The attached diagram shows the markings and corresponding component names:
[0045] 1-Cavity body, 2-Top opening, 3-Bottom opening, 4-Connecting rod, 5-Vibration plate, 6-Opening, 7-Horizontal plate, 8-First limiting groove, 9-Second limiting groove, 10-First protruding plate, 11-Second protruding plate, 12-First mounting end, 13-Second mounting end, 14-First through hole, 15-Second through hole, 16-Third through hole, 17-Fourth through hole, 18-Fifth through hole, 19-Sixth through hole, 20-Shaft sleeve, 21-End cover, 22-Telescopic component, 23-Extended through groove, 24-Arc plate, 25-First mounting plate, 26-Second mounting plate, 27-Triangular plate. Detailed Implementation
[0046] To make the objectives, technical solutions, and advantages of the embodiments of this utility model clearer, the technical solutions of the embodiments of this utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this utility model, not all embodiments. The components of the embodiments of this utility model described and shown in the accompanying drawings can typically be arranged and designed in various different configurations.
[0047] Therefore, the following detailed description of the embodiments of the present invention provided in the accompanying drawings is not intended to limit the scope of the claimed invention, but merely to illustrate selected embodiments of the invention. All other embodiments obtained by those skilled in the art based on the embodiments of the present invention without inventive effort are within the scope of protection of the present invention.
[0048] It should be noted that similar labels and letters in the following figures indicate similar items. Therefore, once an item is defined in one figure, it does not need to be further defined and explained in subsequent figures.
[0049] In the description of this utility model, it should be noted that the terms "first", "second", "third", etc. are used only for distinguishing descriptions and should not be construed as indicating or implying relative importance.
[0050] Example
[0051] Please refer to the reference. Figures 1-4 As shown, this utility model embodiment provides a feeding bin for a multi-point feeder, including a bin body 1 and a vibrating component. The bin body 1 includes a top opening 2 and a bottom opening 3. The top opening 2 is used for feeding, and the bottom opening 3 is used for discharging. The vibrating component includes a connecting rod 4, a vibrating plate 5, and an opening 6 on the bin body 1. The connecting rod 4 extends into the bin body 1 after passing through the opening 6. One end of the connecting rod 4 on the inner side of the bin body 1 is connected to the vibrating plate 5, and the other end of the connecting rod 4 on the outer side of the bin body 1 can be connected to an external power mechanism and driven. The vibrating plate 5 is configured to generate vibration inside the bin body 1 after being driven by the connecting rod 4.
[0052] Specifically, the main body 1 is the main structure of the feeding hopper, ensuring that materials can smoothly enter and be temporarily stored, while facilitating discharge from the bottom opening 3 during feeding. The shape of the main body 1 is not limited here; it can be a cuboid, cylinder, or other structures. As a preferred embodiment of this utility model, the main body 1 is as follows: Figure 1 The structure shown combines a cube and a cone. A connecting rod 4 connects the vibrating plate 5 to an external power mechanism. This external power mechanism can be an existing device such as a motor or cylinder; there are no restrictions here, as long as it can provide sufficient vibration energy. In this embodiment, the connecting rod 4 transmits the power generated by the external power mechanism to the vibrating plate 5. Since the connecting rod 4 passes through the opening 6 on the chamber body 1, it can drive the vibrating plate 5 to vibrate within the chamber body 1 under the drive of the external power mechanism.
[0053] When the connecting rod 4 is driven by an external power mechanism, the vibrating plate 5 vibrates accordingly, making the material less likely to stick together and allowing it to be discharged more smoothly from the bottom opening 3. This embodiment of the invention prevents materials from sticking together and improves their flowability through vibration, thereby solving the problem of recycled material sticking causing the feeder to malfunction. It reduces frequent manual unclogging and equipment cleaning due to material sticking, lowers labor intensity and equipment wear, and ultimately reduces equipment maintenance costs.
[0054] Preferably, the opening 6 is inclined downwards, a bushing 20 is installed inside the opening 6, the connecting rod 4 passes through the bushing 20, and the horizontal plate 7 is inclined downwards; the vibrating plate 5 is configured to be driven by the connecting rod 4 to vibrate inclinedly within the chamber body 1. Further, combined with... Figure 1 , Figure 2 , Figure 5 and Figure 6 As shown, the vibrating plate 5 includes a horizontal plate 7. A first limiting groove 8 and a second limiting groove 9 are provided on the inner wall of the bin body 1. One end of the horizontal plate 7 is movably installed in the first limiting groove 8, and the other end is movably installed in the second limiting groove 9. The width of the first limiting groove 8 and the second limiting groove 9 is greater than the width of the horizontal plate 7. The horizontal plate 7 is configured to vibrate back and forth along the width direction of the first limiting groove 8 and the second limiting groove 9.
[0055] Specifically, the first limiting groove 8 and the second limiting groove 9 provide guidance and limiting for the vibration of the horizontal plate 7, ensuring that the horizontal plate 7 can move stably in a predetermined direction during vibration and preventing the horizontal plate 7 from shifting or getting stuck during vibration. When the connecting rod 4 drives the horizontal plate 7 to vibrate, the horizontal plate 7 reciprocates along the width direction of the limiting grooves under the constraint of the first limiting groove 8 and the second limiting groove 9. This movement mode can effectively break the adhesion between materials, causing the materials to loosen under the action of vibration, thereby improving the flowability of the materials.
[0056] More preferably, the horizontal plate 7 is provided with at least one first protrusion 10 and at least one second protrusion 11, the first protrusion 10 extending above the horizontal plate 7 and the second protrusion 11 extending below the horizontal plate 7; there is a gap between two adjacent first protrusions 10 and a gap between two adjacent second protrusions 11.
[0057] Specifically, the first convex plate 10 extends above the horizontal plate 7, forming an upwardly protruding structure. During vibration, the first convex plate 10 can apply an upward force to the material, further breaking the adhesion between the materials and making the material easier to loosen under vibration. The second convex plate 11 extends below the horizontal plate 7, forming a downwardly protruding structure. During vibration, the second convex plate 11 can apply a downward force to the material, which also helps to break the adhesion between the materials and makes the material easier to loosen under vibration.
[0058] Because at least one first protruding plate 10 is provided on the horizontal plate 7, and there is a gap between two adjacent first protruding plates 10, the first protruding plate 10 can apply force to the material at different positions during vibration. At the same time, the gap avoids mutual interference between adjacent protruding plates, ensuring the vibration effect. Because at least one second protruding plate 11 is provided on the horizontal plate 7, and there is a gap between two adjacent second protruding plates 11, similar to the first protruding plate 10, the second protruding plate 11 can apply force to the material at different positions during vibration. At the same time, the gap avoids mutual interference between adjacent protruding plates, ensuring the vibration effect. When the connecting rod 4 drives the horizontal plate 7 to vibrate, the first protruding plate 10 and the second protruding plate 11 will vibrate together with the horizontal plate 7. This structure can more comprehensively break the adhesion between materials, making the materials easier to loosen under vibration.
[0059] For example, the horizontal plate 7 is provided with two left-right symmetrical first protrusions 10 and two left-right symmetrical second protrusions 11, and the two first protrusions 10 and two second protrusions 11 are vertically symmetrical. It should be noted that the connection method between the first limiting groove 8 and the second limiting groove 9 and the inner wall of the bin body 1 is not limited. It can be by bonding, snap-fitting, threaded connection, or even welding, as long as sufficient connection stability can be achieved. In other embodiments, only the first protrusion 10 or the second protrusion 11 may be provided, and the number of first protrusions 10 and second protrusions 11 is not limited to two, nor is it limited to left-right symmetrical or vertically symmetrical structures. The specific configuration can be set according to actual needs and is not limited here. Preferably, the horizontal plate 7 is located at the center of the bin body 1, the first protrusion 10 extends upward to below the vibratory opening 2, and the second protrusion 11 extends downward to above the vibratory opening 3, which can maximize the range of vibration contact.
[0060] To improve the installation efficiency and stability of the horizontal plate 7, please combine... Figure 7 and Figure 8 The horizontal plate 7 includes a first mounting end 12 and a second mounting end 13. The first mounting end 12 is installed in a first limiting groove 8, and the second mounting end 13 is installed in a second limiting groove 9. Both the first mounting end 12 and the second mounting end 13 are inclined ends. The opening of the first limiting groove 8 is inclined synchronously with the first mounting end 12, and the opening of the second limiting groove 9 is inclined synchronously with the second mounting end 13. The cooperation between the inclined mounting ends of the horizontal plate 7 and the synchronously inclined openings of the limiting grooves ensures that the horizontal plate 7 can be accurately positioned in the limiting grooves during installation, thereby ensuring the stability and effectiveness of the horizontal plate 7 during vibration. Of course, in other embodiments, the first mounting end 12, the second mounting end 13, the first limiting groove 8, and the second limiting groove 9 can all be square structures.
[0061] Combined with reference Figure 1 , Figure 2 , Figure 5 and Figure 6 As shown, to prevent the mounting end of the horizontal plate 7 from curling up and affecting the vibration effect, the first mounting end 12 is provided with a first through hole 14. The opposite side walls of the first limiting groove 8 are respectively provided with a second through hole 15 and a third through hole 16. The first through hole 14, second through hole 15, and third through hole 16 are configured to be connected by a screw, limiting the first through hole 14 to be coaxial with the second through hole 15 and third through hole 16, allowing the first through hole 14 to move axially along the screw. The second mounting end 13 is provided with a fourth through hole 17. The opposite side walls of the second limiting groove 9 are respectively provided with a fifth through hole 18 and a sixth through hole 19. The fourth through hole 17, fifth through hole 18, and sixth through hole 19 are configured to be connected by a screw, limiting the fourth through hole 17 to be coaxial with the fifth through hole 18 and sixth through hole 19, allowing the fourth through hole 17 to move axially along the screw.
[0062] Specifically, by passing through the first through hole 14, the second through hole 15, the third through hole 16, the fourth through hole 17, the fifth through hole 18, and the sixth through hole 19, the mounting end of the horizontal plate 7 is fixed in the limiting groove, while maintaining a certain axial movement capability, thus ensuring the stability of the horizontal plate 7. The first through hole 14 and the fourth through hole 17 are limited to positions coaxial with the corresponding second and third through holes 16 and fifth and sixth through holes 19, ensuring the stability and accuracy of the horizontal plate 7 during vibration. In actual operation, nuts can be set at both ends of the screw, namely the outer sides of the second through hole 15 and the third through hole 16, and the outer sides of the fifth through hole 18 and the sixth through hole 19, respectively, to ensure the installation stability of the screw at both ends.
[0063] Furthermore, in conjunction with reference Figure 9 and Figure 10 As shown, an end cap 21 is movably installed at the bottom opening 3, and at least one telescopic member 22 is installed on the outside of the compartment body 1. Each telescopic member 22 is connected to the end cap 21. The at least one telescopic member 22 is configured to control the opening or closing of the bottom opening 3 by telescopic control of the end cap 21.
[0064] Specifically, the telescopic member 22 controls the end cap 21 through its telescopic movement. When the telescopic member 22 extends, it can push the end cap 21 to move, thereby opening the bottom opening 3 or increasing its size; when the telescopic member 22 retracts, it can pull the end cap 21, thereby closing the bottom opening 3 or decreasing its size. The structure of the telescopic member 22 and the principle of pushing the end cap 21, including the hinge structure between the end cap 21 and the chamber body 1, are not limited here. The structure described in existing patents such as CN114789888A can be used, or the telescopic member 22 can be set as an existing cylinder structure, etc. The specific structure of the telescopic member 22 is not the inventive point of this utility model embodiment and will not be described in detail here. Existing telescopic structures can be used to achieve this.
[0065] In this embodiment of the present invention, preferably, the end cap 21 includes an extended through groove 23 and an arc plate 24. The arc plate 24 extends along the top of one side wall of the extended through groove 23. A first mounting plate 25 and a second mounting plate 26 are respectively provided on both sides of the arc plate 24. The first mounting plate 25 is used to hinge with one side wall of the storage body 1, and the second mounting plate 26 is used to hinge with the other opposite side wall of the storage body 1. A telescopic member 22 is provided on the outside of the storage body 1. The telescopic member 22 is configured to drive the end cap 21 to rotate around the bottom opening 3. When the lower opening of the extended through groove 23 is parallel to the bottom opening 3, the bottom opening 3 is opened (see reference). Figure 11 When the arc plate 24 covers the bottom opening 3, the bottom opening 3 is closed (see reference). Figure 12 ).
[0066] Specifically, the first mounting plate 25 and the second mounting plate 26 are used to hinge the end cap 21 to the outer wall of the container body 1, allowing the end cap 21 to rotate around the bottom opening 3. The first mounting plate 25 is hinged to one side wall of the container body 1, and the second mounting plate 26 is hinged to the other opposite outer wall of the container body 1, so that the end cap 21 can rotate around the bottom opening 3 to realize the opening and closing action. This embodiment of the utility model achieves precise control of the opening and closing degree of the bottom opening 3 by providing an extended through groove 23 and an arc plate 24 on the end cap 21 and using a telescopic member 22 to control the rotation of the end cap 21. Preferably, a triangular plate 27 can be provided at the bottom of the arc plate 24. The triangular plate 27 is preferably located on the center line of the outer side of the arc plate 24. When the triangular plate 27 is vertically downward, the bottom opening 3 is completely closed.
[0067] In this embodiment of the invention, an extended structure can be provided below the bottom opening 3 to reduce the splashing and leakage of recycled material. Since this embodiment also includes an extended through groove 23 with a certain height, see reference... Figure 11As shown, when the bottom opening 3 is fully opened, the extended through groove 23 can connect to the bottom of the extended structure on the bottom opening 3, further extending the length of the discharge port and further reducing the phenomenon of recycled material splashing and leakage.
[0068] Of course, in other embodiments, the limitations are not limited to Figure 11 and Figure 12 The single-sided control structure in the middle can also be set as follows: Figure 13 The dual-sided control structure shown is exemplarily as follows: Figure 13 As shown, the end cap includes two independent plates, and the main body of the compartment is provided with two independent telescopic components. Each telescopic component controls a single plate. When the two plates are in contact, the bottom opening is closed, and when the two plates are separated, the bottom opening is opened.
[0069] It should be noted that in actual operation, the feeding bin provided in this utility model embodiment can be applied to the scenario described in patent CN114789888A, as well as other similar application scenarios. Specifically, it can be used with the belt conveyor set below, with a metering device set on the belt conveyor to continuously measure the feeding, and then the speed of the belt conveyor drive motor is controlled by the frequency converter to adjust the conveying amount of recycled material, etc.
[0070] The above description is merely a preferred embodiment of this utility model and is not intended to limit the utility model. Various modifications and variations can be made to this utility model by those skilled in the art. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of this utility model should be included within the protection scope of this utility model. It should be noted that the structures or components illustrated in the accompanying drawings are not necessarily drawn to scale, and descriptions of well-known components, processing techniques, and processes are omitted to avoid unnecessarily limiting the utility model.
Claims
1. A feeding bin for a multi-point feeder, characterized in that, include: The silo body (1) includes a top opening (2) and a bottom opening (3), the top opening (2) being used for feeding and the bottom opening (3) being used for discharging. The vibrating component includes a connecting rod (4), a vibrating plate (5), and an opening (6) provided on the bin body (1). The connecting rod (4) extends through the opening (6) and into the bin body (1). One end of the connecting rod (4) inside the bin body (1) is connected to the vibrating plate (5), and the other end of the connecting rod (4) outside the bin body (1) can be connected to an external power mechanism and driven. The vibrating plate (5) is configured to generate vibration within the chamber body (1) after being driven by the connecting rod (4).
2. The feeding bin of a multi-point feeder according to claim 1, characterized in that, The vibrating plate (5) includes a horizontal plate (7). The inner wall of the chamber body (1) is provided with a first limiting groove (8) and a second limiting groove (9). One end of the horizontal plate (7) is movably installed in the first limiting groove (8), and the other end is movably installed in the second limiting groove (9). The width of the first limiting groove (8) and the second limiting groove (9) are both greater than the width of the horizontal plate (7). The horizontal plate (7) is configured to vibrate back and forth along the width direction of the first limiting groove (8) and the second limiting groove (9).
3. The feeding bin of a multi-point feeder according to claim 2, characterized in that, The horizontal plate (7) is provided with at least one first protrusion (10) and at least one second protrusion (11), the first protrusion (10) extending above the horizontal plate (7) and the second protrusion (11) extending below the horizontal plate (7); There is a gap between two adjacent first protrusions (10) and a gap between two adjacent second protrusions (11).
4. The feeding bin of a multi-point feeder according to claim 3, characterized in that, The horizontal plate (7) is provided with two left-right symmetrical first convex plates (10) and two left-right symmetrical second convex plates (11), and the two first convex plates (10) and the two second convex plates (11) are vertically symmetrical.
5. The feeding bin of a multi-point feeder according to claim 2, characterized in that, The horizontal plate (7) includes a first mounting end (12) and a second mounting end (13). The first mounting end (12) is installed in the first limiting groove (8), and the second mounting end (13) is installed in the second limiting groove (9). Both the first mounting end (12) and the second mounting end (13) are inclined ends. The opening of the first limiting groove (8) is inclined synchronously with the first mounting end (12), and the opening of the second limiting groove (9) is inclined synchronously with the second mounting end (13).
6. The feeding bin of a multi-point feeder according to claim 5, characterized in that, The first mounting end (12) is provided with a first through hole (14), and the opposite side walls of the first limiting groove (8) are respectively provided with a second through hole (15) and a third through hole (16). The first through hole (14), the second through hole (15) and the third through hole (16) are configured to be connected by a screw, so that the first through hole (14) is limited to be coaxial with the second through hole (15) and the third through hole (16), and the first through hole (14) can move along the axial direction of the screw.
7. The feeding bin of a multi-point feeder according to claim 6, characterized in that, The second mounting end (13) is provided with a fourth through hole (17), and the second limiting groove (9) is provided with a fifth through hole (18) and a sixth through hole (19) on opposite side walls respectively. The fourth through hole (17), the fifth through hole (18) and the sixth through hole (19) are configured to be connected by a screw, so that the fourth through hole (17) is limited to be coaxial with the fifth through hole (18) and the sixth through hole (19), and the fourth through hole (17) can move along the axial direction of the screw.
8. The feeding bin of a multi-point feeder according to claim 2, characterized in that, The opening (6) is inclined downward, and a bushing (20) is installed in the opening (6). The connecting rod (4) passes through the bushing (20), and the horizontal plate (7) is set obliquely downward. The vibration plate (5) is set to vibrate in the bin body (1) after being driven by the connecting rod (4).
9. The feeding bin of a multi-point feeder according to any one of claims 1-8, characterized in that, An end cap (21) is movably provided at the bottom opening (3), and at least one telescopic member (22) is provided on the outside of the main body (1), and each telescopic member (22) is connected to the end cap (21). At least one of the telescopic members (22) is configured to control the degree of opening or closing of the bottom opening (3) by telescopic control of the end cap (21).
10. The feeding bin of a multi-point feeder according to claim 9, characterized in that, The end cap (21) includes an extended through groove (23) and an arc plate (24). The arc plate (24) extends along the top of one side wall of the extended through groove (23). A first mounting plate (25) and a second mounting plate (26) are respectively provided on both sides of the arc plate (24). The first mounting plate (25) is used to hinge with one of the outer side walls of the container body (1), and the second mounting plate (26) is used to hinge with the other opposite outer side wall of the container body (1). A telescopic component (22) is provided on the outside of the main body (1). The telescopic component (22) is configured to drive the end cap (21) to rotate around the bottom opening (3). When the lower end opening of the extended through groove (23) is parallel to the bottom opening (3), the bottom opening (3) is opened; when the arc plate (24) covers the bottom opening (3), the bottom opening (3) is closed.