The present invention relates to a silo for storing material, and particularly, to a silo de-bridging device.
When a silo outputs the stored material to the outside, a bridged camber surface having a dome shape will be easily formed in the silo, which presents the material from flowing downwards and hinders the normal output of the material. How to de-bridge so that the material can be outputted smoothly is always a difficulty attracting people's attention. Current existing de-bridging devices mainly adopt the modes such as vibration de-bridging and pneumatic de-bridging. The vibration de-bridging activates the material in the silo through the vibration of a vibrator, so as to reduce the shear stress between the materials and the friction between the material and silo walls, thereby promoting the flow and the output of the material. The pneumatic de-bridging mounts some compressed air nozzles in the silo, aligns them with the areas where a bridge is easily formed, and sprays the compressed air towards the bridged material so that it collapses, thereby achieving the object of de-bridging. The two modes have a certain de-bridging effect on the dry powder material or the material having a good dispersion. However, for a material having a high humidity or viscosity, such as the biologic material, the bridging of the material will be more solid after the vibration. In addition, the pneumatic de-bridging produces a weak power while providing much air into the silo, which also cannot really produce the de-bridging effect.
Therefore, it is necessary to provide a silo de-bridging device, so as to overcome the defects of the existing de-bridging devices, and meet the de-bridging requirements of various materials.
The object of the present invention is to provide a silo de-bridging device capable of performing an effective de-bridging of the material in the silo, so that the material in the silo flows smoothly.
The above object of the present invention can be achieved through a silo de-bridging device, comprising: a rotary shaft rotatably supported in a silo and disposed in an axial direction of the silo, having an input end connected to a drive mechanism and driven by the drive mechanism to rotate; and at least one de-bridging unit connected to the rotary shaft, each de-bridging unit comprising: a fixed sleeve fixedly sleeving on the rotary shaft and being driven by the rotary shaft to rotate; a movable sleeve moveably sleeving on the rotary shaft, wherein one of two end surfaces of the movable sleeve and the fixed sleeve adjoining each other is formed as an end surface cam contour, and the other is provided with an abutting member that abuts against the end surface cam contour, the end surface cam contour coordinates with the abutting member to constitute an end surface cam structure, so that the movable sleeve is moveable to and fro in the axial direction of the silo when the fixed sleeve and the movable sleeve rotate relative to each other; and at least one de-bridging arm having one end connected to the movable sleeve, and the other end extending to a position close to an inner wall of the silo in a radial direction of the silo.
In an optional example of the present invention, the two end surfaces of the movable sleeve and the fixed sleeve adjoining each other may be formed as end surface cam contours concave-convex fitted with each other, and a protrusion of one of the end surface cam contours may be formed as the abutting member.
In another optional example of the present invention, the abutting member may be a contact protrusion protruding from the end surface of the movable sleeve or the end surface of the fixed sleeve.
In still another optional example of the present invention, the abutting member may be a roller structure.
In an optional example of the end surface cam contour of the present invention, the end surface cam contour may be a sine curve of at least one cycle after being deployed.
In another optional example of the end surface cam contour of the present invention, the end surface cam contour may include at least one V-groove contour.
In an optional example, the axial direction of the silo may be a vertical direction, and the movable sleeve may be located above the fixed sleeve.
In an optional example of the present invention, each de-bridging unit may be further provided with an elastic pushing device applying to the movable sleeve a pushing force towards the fixed sleeve.
In a specifically embodied structure of the above example, the elastic pushing device may comprise a fixed retainer connected to the rotary shaft, and an elastic member abutting between the fixed retainer and the movable sleeve.
In a specific example, the elastic member may be a compression spring.
For the silo de-bridging device having at least two de-bridging units, the sub arms at the ends of the de-bridging arms of the neighboring de-bridging units may be disposed alternatively in the radial direction of the silo.
The rotary shaft of the silo de-bridging device of the present invention may be rotatably supported in the silo through a rotary shaft centering frame.
In the silo de-bridging device of the present invention, when the silo outputs a material to the outside, the fixed sleeve of the de-bridging unit is driven by the rotary shaft to rotate. When the material encounters a small resistance, no relative movement occurs between the movable sleeve and the fixed sleeve, and the movable sleeve drives the de-bridging arm thereon to rotate along with the fixed sleeve. When the resistance to the material increases, the rotation of the movable sleeve is hindered, a relative movement occurs between the movable sleeve and the fixed sleeve, and the movable sleeve moves to and fro in the axial direction under the action of the end surface cam structure between the movable sleeve and the fixed sleeve, so as to drive the de-bridging arm thereon to move to and fro, thereby disturbing the material in the axial direction of the silo. Thus in the silo, due to the to-and-fro movement of the de-bridging arm in the axial direction, the material cannot be supported by the silo wall to form a bridged camber surface, thereby achieving an effective de-bridging of the silo. As compared with the existing vibration de-bridging and pneumatic de-bridging, the de-bridging device of the present invention has a simple structure and a low cost, and it is not limited by the humidity and viscosity of the material, so as to effectively achieve the effective silo de-bridging of many materials, particularly the biologic material.
In order to more clearly describe the technical solutions in the prior art or the embodiments of the present invention, the drawings to be used in the descriptions of the prior art or the embodiments are briefly introduced as follows. Obviously, the following drawings just illustrate some embodiments of the present invention, and a person skilled in the art can obtain other drawings from these drawings without paying a creative effort.
The technical solutions of the embodiments of the present invention will be clearly and completely described as follows with reference to the drawings. Obviously, those described herein are just parts of the embodiments of the present invention rather than all the embodiments. Based on the embodiments of the present invention, any other embodiment obtained by a person skilled in the art without paying any creative effort shall fall within the protection scope of the present invention.
As illustrated in
When the silo 2 outputs a material to the outside, the fixed sleeve 101 of the de-bridging unit 10 is driven by the rotary shaft 11 to rotate. When the material encounters a small resistance, no relative movement occurs between the movable sleeve 102 and the fixed sleeve 101, and the movable sleeve 102 drives the de-bridging arm 103 thereon to rotate along with the fixed sleeve 101. When the resistance to the material increases, the rotation of the movable sleeve 102 is hindered, a relative movement occurs between the movable sleeve 102 and the fixed sleeve 101, and the movable sleeve 102 moves to and fro in the axial direction under the action of the end surface cam structure between the movable sleeve 102 and the fixed sleeve 101, so as to drive the de-bridging arm 103 thereon to move in the axial direction of the silo. Thus in the silo 2, the de-bridging arm 103 moves in the axial direction of the silo, and the material cannot be supported by the silo wall to form a bridged camber surface, thereby achieving an effective de-bridging of the silo.
In an optional example of the silo de-bridging device of the present invention, i.e., Embodiment 1 of the silo de-bridging device as illustrated in
As illustrated in
The embodiment 2 of the present invention ensures abutment between the abutting member of the end surface cam structure and the end surface cam contour through the elastic pushing device, without utilizing the gravity, thus as illustrated in
In a specific example of the elastic pushing device 106 of the de-bridging unit 10 of the present invention, the elastic pushing device 106 may include a fixed retainer 1061 connected to the rotary shaft 11, and an elastic member 1062 abutting between the fixed retainer 1061 and the movable sleeve 102. The elastic member 1062 specifically may be a compression spring.
As illustrated in
As illustrated in
As illustrated in
Although only a few examples of the end surface cam contour 104 are given above, a person skilled in the art shall appreciate that the above examples are just exemplary, and the end surface cam contour 104 is not limited thereto, provided that the end surface cam contour 104 enables the movable sleeve 102 to be moveable to and fro in the axial direction of the silo 2 when the movable sleeve 102 and the fixed sleeve 101 rotate relative to each other. The present invention may be implemented using many existing end surface cam contours, which are omitted herein.
As illustrated in
As illustrated in
Although only a few examples of the abutting member 105 are given above, a person skilled in the art shall appreciate that the above examples are just exemplary, and the abutting member 105 is not limited thereto, provided that the abutting member 105 abuts against the end surface cam contour 104, so that the end surface cam structure enables the movable sleeve 102 to be moveable to and fro in the axial direction of the silo 2 when the movable sleeve 102 and the fixed sleeve 101 rotate relative to each other. The specific structure of the abutting member 105 may not be limited.
In optional examples of the end surface cam structure of the present invention, as illustrated in
As illustrated in
In the present invention, in an optional example, the de-bridging arm 103 may be fixedly connected to the movable sleeve 102. In another optional example, the de-bridging arm 103 may be hinged to the movable sleeve 102, and provided with a limiting structure for limiting the action angle of the de-bridging, e.g., limiting that the de-bridging arm 103 shall act in a range not more than 15 degrees.
For the silo de-bridging device 100 having at least two de-bridging units 10, the sub arms 1031 at the ends of the de-bridging arms 103 of the neighboring de-bridging units 10 may be disposed alternatively in the radial direction of the silo 2, so as to prevent friction between the sub arm 1031 and the inner wall of the silo due to the uneven wall surface of the silo 2.
In the present invention, the number of the de-bridging units 10 and the number of the de-bridging arms 103 in each de-bridging unit may be selected upon demand according to height, diameter and material condition of the silo.
As illustrated in
The examples shown in
The above descriptions of the present invention are just exemplary, thus various modifications not deviating from the main idea of the present invention shall fall within the scope of the present invention, and those modifications shall not be deemed as deviating from the spirit and scope of the present invention.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/CN2010/080118 | 12/22/2010 | WO | 00 | 7/29/2013 |