JP2007119120A - Device for bouncing up granular material - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To disperse and bounce up granular materials such as powder and particles while preventing partial ununiformity and to uniformly and properly attach the granular materials to other members. <P>SOLUTION: A vibration base 6 is provided on a base 1 via elastic bodies A. An electromagnetic body 7 and a vibration core 8 are provided on the base 1 and the vibration base 6, respectively. A granular material inserting tub body C is provided on the vibration base 6. By magnetic force excited in the electromagnetic body 7, appropriate vibration can be controlled and supplied to the vibration base 6 and the granular material inserting tub body C. The plurality of elastic bodies A are mounted between the base 1 and the vibration base 6 at equal intervals in a plane view. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  TECHNICAL FIELD The present invention relates to a granular material jumping apparatus that can disperse particles such as particles and powders rather than part of the powder and splash it upward and uniformly apply it to other members.

There have been various kinds of conventional ones, but there is no device that jumps up powder particles in a three-dimensional direction by using an electromagnetic drive body, and the work to make it adhere accurately and uniformly, etc. I couldn't. Moreover, in patent document 1, it was a thing of the structure which gives a vibration and sends powder and was not able to be used for the jumping of a granular material. As a prior art, it does not exist and is a completely new invention.
JP-A-11-139533

  For this reason, the problem (technical problem or object) to be solved by the present invention is to make the powder body splash up uniformly and to attach it to other members accurately.

  In view of this, the inventor has intensively studied to solve the above problems, and as a result, the invention of claim 1 is provided with a vibrating table on the table via an elastic body, and an electromagnet body is provided on the table. The vibrating base plate is provided with a vibrating core, the vibrating base plate is provided with a granular material insertion housing, and the vibrating base plate and the granular material insertion housing are appropriately provided with a magnetic force excited by the electromagnet body. The elastic body is controlled so as to be able to supply various vibrations, and a plurality of the elastic bodies are attached between the base plate and the vibration base plate in an equally divided manner when seen in a plan view. By using the flip-up device, the above-mentioned problem is solved.

  According to a second aspect of the present invention, there is provided a base, a vibration base provided on the base via an elastic body, an electromagnet provided on the base, and a vibration provided on the vibration base. The elastic body includes a core and a granular material insertion housing provided on the vibration table, and is controlled to be able to supply appropriate vibrations to the vibration table by a magnetic force excited in the electromagnet body. The above-mentioned problem is solved by providing a powder body lifting apparatus characterized in that a plurality of parts are mounted in an equal division when viewed in plan between the base and the vibration base. It is.

  According to a third aspect of the present invention, in the configuration described above, the electromagnet body includes a coil portion and an electromagnet portion, and an appropriate gap is formed between the upper end of the electromagnet portion and the lower surface of the vibrating core. The above-mentioned problem is solved by using the powder body jumping apparatus characterized by the above.

  According to a fourth aspect of the present invention, in the above-described configuration, the elastic body includes a leaf spring member, a lower mounting portion, and an upper mounting portion, and the lower mounting portion is disposed on the base plate and the upper mounting portion. The above problem has been solved by using a powder and particle flip-up device characterized by being fixed to the lower surface of the vibration table. According to a fifth aspect of the present invention, there is provided the granular material jumping device characterized in that the angle viewed from the side surface of the elastic body is formed to be 10 degrees to 20 degrees with respect to the plane. This solves the problem.

  In the first aspect of the present invention, in particular, the powder particles can be raised uniformly high (about 10 cm), and adhesion or application can be realized satisfactorily. Further, the invention of claim 2 has the same effect. In the invention of claim 3, a particularly simple configuration can be achieved. The invention of claim 4 can also be simplified. The invention of claim 5 also has an effect of efficiently raising the granular material.

  DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below with reference to the drawings. FIGS. 1 and 2 are general views of the present invention. A vibrating table 6 is placed on a disk-shaped table 1 via an elastic body A. Is provided. A granular material insertion rod C is detachably attached to the vibration table 6. The vibration base 6 is vibrated by the intermittent magnetic force generated by the electromagnet device B. The platform 1 is not limited in shape as long as it is sufficiently stable against vibration and stable. The powder and granule is a general name of the powder and the granule, and will be specifically described later.

  The elastic body A includes a leaf spring member 2, a lower attachment portion 3, and an upper attachment portion 4. The lower mounting portion 3 includes a vertical plate piece 3a and a lower mounting member 3b. The lower end of the plate piece 3a is fixed on the base plate 1, and the lower mounting member 3b and the plate-shaped presser member 3c Thus, the lower end of the leaf spring member 2 is clamped and fixed with bolts and nuts 5.

  The upper mounting portion 4 includes a vertical plate piece 4a and an upper mounting member 4b. The upper end of the plate piece 4a is fixed to the lower surface of the vibration table 6, and the upper mounting member 4b and the plate piece shape The upper end of the leaf spring member 2 is clamped by the presser member 4 c and fixed with bolts and nuts 5. Further, instead of the nut of the bolt / nut 5, a plate piece with a screw hole may be used (see the figure).

  A plurality of the elastic bodies A are attached between the base 1 and the vibration base 6. In the embodiment, the three elastic bodies A are attached in equal divisions when seen in a plan view. In this case, the mounting direction of the upper mounting portion 4 and the lower mounting portion 3 of the elastic body A is provided to be the same. That is, assuming that three elastic bodies A are attached, the upper attachment portions 4 of the respective elastic bodies A are provided so as to be in the same position with respect to the right or left rotation direction when seen in a plan view.

  The leaf spring member 2 is installed at an attachment angle ∠θ of about 10 degrees to about 20 degrees with respect to the horizontal line (see FIG. 3A). Preferably, it is installed so that ∠θ is about 15 degrees with respect to the horizon. In this case, the component force in the vertical direction is Fcosθ, the component force in the horizontal direction is Fsinθ, and the component force in the vertical direction can be increased. That is, it is possible to increase the force that flips the powder and the like upward. Further, the two elastic bodies A may be point-symmetrical, or the four or five elastic bodies A may be equally divided.

  The leaf spring member 2 includes three leaf springs 2a and a spacer 2b interposed therebetween. The material and thickness of the leaf spring 2a are appropriately set so as to obtain vibration that provides good resonance. Further, the leaf spring member 2 may be composed of only one leaf spring 2a, without being a plurality of leaf spring members.

  The electromagnet device B includes an electromagnet body 7 and a vibrating core 8. The electromagnet body 7 includes a coil portion 7 a and an electromagnet portion 7 b, the electromagnet body 7 is fixed on the pedestal 1, and the vibration core 8 is fixed on the lower surface of the vibration table 6. A gap δ is formed between the upper end of the electromagnet portion 7b of the electromagnet body 7 and the lower surface of the vibrating core 8, so that the vibrating core 8 can be vibrated.

  The granule insertion rod C is composed of a rod body 10 and a lower mounting portion 11, and the lower mounting portion 11 is detachably fixed to the vibrating table 6. The cocoon body 10 is appropriately loaded with powder particles. The particle size of the granular material is about 1 mm to 5 mm, and the powder size of the granular material is about 1 μm to 1 mm. Furthermore, fine powder (0.1 μm to 1 μm) or ultrafine powder (0.001 μm to 0.1 μm) can also be used.

  Excited by an AC power source of a commercial power source (100V or 200V) to function as an electromagnet, and the exciting base is lowered while pulling the vibrating core 8 by this exciting action, and the intermittent action of the excitation and the elastic body A The vibration table 6 is vibrated up and down. The electromagnet device B is covered with a separable cylindrical case cover 12. Reference numeral 13 denotes an anti-vibration rubber provided on the lower surface of the base 1.

  In the vibration-related configuration, the spring constant is formed by the mass of the vibration core 8 with respect to the electromagnet body 7 and the leaf spring member 2, and the resonance frequency of this vibration system is determined by these. When the electromagnet body 7 is connected to a commercial AC power source, it vibrates at that frequency, is used for full-wave rectification, and vibrates at half that frequency. In order to make this electric power as small as possible, the mass of the vibration core 8 and the total spring constant of the leaf spring member 2 are designed to be close to this drive frequency.

  Further, it is not always driven in the vicinity of the resonance frequency as in such a design. In this case, the number of leaf spring members 2 is changed or the thickness and width of the leaf springs constituting the leaf spring member 2 are changed. By changing the total spring constant, the resonance frequency is adjusted so as to be substantially equal to the drive frequency. Furthermore, to control the rising height of the granular material having an appropriate particle size, the resonance frequency of the vibration system can be controlled by adjusting the current supplied to the electromagnet body 7.

Next, the effect of the jump will be described with reference to FIG. First, the electromagnet body 7 is vibrated at an appropriate frequency with a commercial AC power source, and the particles inserted into the main body 10 of the granular material insertion basket C are jumped. For clarity this state, _point P moves to P ₂ point splashed to the vertical (90 °) direction to the center point O of the vibration. The granules were moved to _two points P is splashed to the vertical (90 °) direction with respect to the vibration center point O is moved to _three points P. Granules bouncing successively vertically (90 degrees) with respect to the center point O to the direction, _{P 4} points, _{P 5} points, _{P 6} points, _{P 7} points, moved to the outer peripheral direction while bouncing to ₈ points _P. Actually, there are many particles in the central part because countless particles move while colliding with each other.

  In addition, when the special electromagnet body 7 and the leaf spring member 2 are attached, the vertical jumping is larger than the parallel jumping, so that each grain performs the jump described above in various places and positions. , Each can collide and jump in a random direction as well as in the outer circumferential direction, and spread evenly without consolidating in one place.

  The rotation direction in which the particles spread can be changed to the right rotation direction or the left rotation direction according to the inclination mounting direction of the leaf spring member 2. Furthermore, by further increasing the driving force, the jumping force in the vertical direction becomes larger than the jumping force in the horizontal direction. Therefore, the collision force of each granule increases, and the spread can be shown randomly and more uniformly. Such an effect could be similarly tested with powder.

  In this way, it is possible to apply to the insertion of the granular material, the application of the granular material, etc. by jumping up the granular material. Specifically, as an example, an infinite number of fine holes are made in a plate (this is referred to as “adhered body”), and an appropriate powder is placed in the powder insert C of the apparatus of the present invention. By operating the present invention in this state, the granular material is spun up and filled into the innumerable fine holes. In addition, according to the present invention, appropriate colored particles or the like can be applied substantially uniformly to another plate body provided with an adhesive layer (this is referred to as an “adhered body”).

  The present invention can be used for inserting a granular material, applying a granular material, etc., by flipping up the granular material, and has extremely high applicability to processing, transferring, etc. of the granular material. Is.

It is a perspective view of the present invention. (A) is a plan view of the present invention, (B) is a side view partially cut away. (A) is a principal part side view of this invention, (B) is the partially expanded view of (A). (A) is sectional drawing of the granular material insertion coffin part of this invention, (B) is a state figure of the action part of a granular material insertion coffin part. It is a top view of the state where one granule is flipped up.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Base board, A ... Elastic body, B ... Electromagnet apparatus, C ... Powder-particles insertion rod, 2 ... Plate spring member,
6 ... Vibration table, 7 ... Electromagnet body, 8 ... Vibration core, δ ... Gap.

Claims (5)

  A vibration base is provided on the base via an elastic body, an electromagnet body is provided on the base, a vibration core is provided on the vibration base, and a granular material insertion housing is provided on the vibration base. The magnetic body is controlled so as to be able to supply appropriate vibrations to the vibration base plate and the granular material insertion housing by the magnetic force excited in the electromagnet body, and the elastic body is formed between the base plate and the vibration base plate. A granular material jumping apparatus, wherein a plurality of parts are attached in equal divisions as viewed in a plane.   A base, a vibration base provided on the base via an elastic body, an electromagnet provided on the base, a vibration core provided on the vibration base, and provided on the vibration base And the elastic body is controlled to be able to supply an appropriate vibration to the vibration table by the magnetic force excited in the electromagnet body. The elastic body includes the table and the vibration table. A granular material flip-up apparatus, wherein a plurality of parts are attached in an equally divided manner between the board and the board.   The powder according to claim 1 or 2, wherein the electromagnet body includes a coil portion and an electromagnet portion, and an appropriate gap is formed between an upper end of the electromagnet portion and a lower surface of the vibrating core. Granule jumping device.   3. The elastic body according to claim 1, wherein the elastic body includes a leaf spring member, a lower mounting portion, and an upper mounting portion, wherein the lower mounting portion is on the base and the upper mounting portion 4 is the lower surface of the vibration base. A granular material jumping device characterized by being fixed to each other.   3. The powder particle flip-up device according to claim 1, wherein an angle viewed from a side surface of the elastic body is formed to be 10 degrees to 20 degrees with respect to a plane.

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