JPH0731935A - Charging apparatus for granular substance - Google Patents

Abstract

PURPOSE:To provide a charging apparatus or granular substance capable of sufficiently charging dry sand even into a slit-like hole part extending in the horizontal direction. CONSTITUTION:Two pairs of vibration exciting parts 102a, 102b, 102c, 102d are fixed confronted each other at a lower surface of a vibration table 101 supported vibratably with a coil spring 103, and vibration mode with uneven amplitude is generated between left and right edge parts and between front and behind edge parts, and then the dry sand can be efficiently filled especially into the slit-like small hole ha through a hole (h) of a frame M on the vibration table 101.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a powder and granular material filling apparatus.

[0002]

2. Description of the Related Art FIG. 19 shows an entire conventional vibration type molding machine, which is indicated by Q as a whole.
The vibrating frame F is supported on the base frame B by a coil spring S so that it can vibrate vertically. A form frame M made of expanded polystyrene is placed on the vibrating frame F, and this is fixed to the vibrating frame F by appropriate means even though not shown. The mold M made of styrofoam has a hole h formed in a desired sand mold shape, which communicates with a sand supply port p formed on the upper wall surface of the styrofoam. An unbalanced weight vibrating portion is fixed to the lower surface of the vibrating frame F, although not explicitly shown.

When a vibrator (not shown) is driven, the vibration table vibrates in the direction of arrow V. That is, although a sine vibration is performed in the vertical direction, the frame M receives this vibration, dry sand is supplied from the sand supply port p into the hole h, and this is diffused into the hole h to move in the vertical direction. Although it fills almost uniformly by vibration, if there is a hole as indicated by ha, that is, a slit-shaped hole ha that extends in the horizontal direction and has a small height, it is difficult to fill dry sand into such a portion. .
The molten metal is not sufficiently filled here, the molten metal is poured into the frame M, and the mold obtained by extinguishing the Styrofoam lacks a portion corresponding to ha or does not have a predetermined shape. This makes the cast product defective.

In order to deal with this, it has been attempted to vibrate the vibrating table F in the horizontal direction in addition to the vertical vibration V, but a slight improvement is recognized, but the filling is still sufficient. There is no such thing. Considering this reason, the transmission of the vibration force received by the dry sand and the table F to this is through the coefficient of friction between the dry sand and the wall surface of the hole h formed in the frame M. The friction coefficient against this wall surface is as small as about 0.3, and it is considered that the vibration of the vibrating table F is not transmitted as it is. Therefore, even if the table F is vibrated horizontally, the sand in the hole h of the frame M and the hole It is considered that the relative movement between h and the wall surface is unlikely to occur, and therefore the filling action hardly occurs.

On the other hand, it has been observed that when a binder is added to wet sand or dry sand and horizontal vibration is applied to the vibration table F, the sand in the holes h is well fluidized and the holes ha are well filled with the sand. . This also proves that the horizontal motion and the friction coefficient are strongly related. Therefore, it is considered that adding horizontal vibration to the filling of the hole ha of dry sand is not a very effective method. Applying vibration to the dry sand in the vertical direction, that is, in the direction of gravity, is effective for filling the sand in the vertical direction, while it is not effective for the horizontally extending eyelets.

On the other hand, in order to sufficiently fill the hole ha with the dry sand, it has been attempted to incline and vibrate the vibrating table F, but the dry sand is biased to one side in the hole h. Is causing the problem.

[0007]

DISCLOSURE OF THE INVENTION The present invention has been made in view of the above-mentioned problems, and a powder capable of efficiently filling dry sand in every corner regardless of the shape of the hole in the frame. An object is to provide a granular material filling device.

[0008]

SUMMARY OF THE INVENTION The above object is to provide a powdery or granular material filling apparatus comprising a table oscillatably supported up and down and a vibrator for vibrating the table. The shaker is achieved by a powder-and-granule filling device, which is characterized by causing the table to cause non-uniform vibration on the table top surface or to generate different vibrations at different points in time.

[0009]

The table causes non-uniform vibrations on its upper surface or temporally different vibrations at each point. Therefore, from above, a hole formed on the table, for example, formed in the frame When dry sand is introduced, all areas can be filled uniformly with dry sand, whatever the shape of the holes.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT A vibration type molding machine according to an embodiment of the present invention will be described below with reference to the drawings. 1 to 15 show a vibration type molding machine according to a first embodiment of the present invention, and FIGS. 1 and 2 show the principle structure thereof.

That is, the substantially rectangular vibration table 10
On the lower surface of 1, there are four vibrators 102 facing each other.
a, 102b, 102c, 102d are attached. Further, the vibration table 101 is supported on the columns 104 arranged at the four corners so as to be vertically vibrable via the coil springs 103 as in the conventional case. Further, it is assumed that the frame M is appropriately mounted on the vibration table 101 via a clamp as in the conventional case. Exciter 102a
7 to 12 show the detailed configuration of the components 102 to 102d. First, the principle of the operation will be described with reference to FIG. That is, according to this embodiment, a pair 102 is formed.
The vibrating forces of a, 102b, 102c, and 102d are configured such that the amplitude changes in the left and right directions of the table 101 in FIG. 3 as indicated by a. That is, the vibrating force of the vibrating portion 102a is far smaller than the vibrating force of the vibrating portion 102b facing the vibrating portion 102a. In addition, the vibrating section 102 which is arranged at a right angle to this and which faces the vibrating section 102.
Similarly, for c and 102d, the vibration force of the vibration unit 102c is the same as that of the vibration unit 102d so that the amplitude at each point changes between the end portions 101c and 101d as shown by A in FIG. It is configured to be sufficiently small in comparison.

The vibrating sections 102a to 102d generate the amplitude as shown in FIG. 3A at each point of the table 101. When a frame M is attached on such a table 101 and dry sand is put into the hole h from the sand supply port p, a small slit-shaped hole that extends horizontally in a part of the hole h and extends horizontally. It has been found that even if there is, dry sand is uniformly filled.

Next, the vibrating section 102 shown in FIGS.
The detailed configuration of a to 102d will be described. In addition,
Since these have the same configuration, the vibration unit 102a is typically used.
The details will be described.

In the drawing, the vibration exciter according to the present embodiment is indicated by 100 as a whole, and the main constitution according to the present invention is incorporated in the exciter casing 1, and various gear parts described later are also incorporated therein. Therefore, the gear cover 2 is fixed to the above-described vibrator casing 1. As shown in FIGS. 1 and 4, the vibrator casing 1 is integrally formed with flat plate-shaped mounting portions 1c, 1d, 1e and 1f for mounting on a vibration molding machine at four corners as clearly shown in FIGS. Further, the upper opening is closed by the weight cover 3. The first drive shaft 10 and the second drive shaft 11 are rotatably supported by a pair of bearings 56A, 57A and 56B, 57B in the vicinity of both ends thereof, as clearly shown in FIG. These bearings 56A, 56
B, 57A, and 57B are side wall portions 1 of the vibrator casing 1.
It is fixed to a and 1b on the outer race side. Then, on the inner race side, the first and second drive shafts 10,
11 is fitted. A drive motor (not shown) is coupled to the left end portion of the first drive shaft 10 in the figure via a universal joint 70. A first drive gear 21A is coaxially fixed to the right end portion of the first drive shaft 10, and this is a first driven gear 25 as shown in FIG.
Meshes with. Further, as the shape is clearly shown in FIG. 3, the above-mentioned first driven gear 25 is provided on the outer race side of the bearing 60b in which the inner race is attached to the support shaft 14 fixed to both side wall portions of the differential frame 6. It is fixed. The second support shaft 13, which meshes with the first driven gear 25 and fixes the second driven gear 24 having the same number of teeth at its axial center, also has bearings 59c, 59 at both ends thereof.
It is supported by d and is fixed to both side wall portions of the differential frame 6 on the outer race side.

The second driven gear 24 is the first drive gear 21.
It is meshed with the third driven gear 23 of A, which is disposed above in FIG. This is fixed to the support shaft 12, and is fixed to the inner races of the bearings 58c and 59a at both ends thereof, and the outer race thereof is fixed to the differential frame 6.
It is fixed to both side wall portions of the sheet as shown in FIG. Further, a fourth driven gear 22 is fixed to the left end portion of the support shaft 12 in FIG. 2, so that it rotates coaxially with the third driven gear 23, which is the fifth driven gear 20A. Meshes with.

A tubular member 34A is provided coaxially with the first drive shaft 10 and is slidable, and the driven gear 20A is fixed at the right end portion thereof. Further, the tubular member 34A
A first unbalanced weight 19A having a substantially semicircular shape when viewed from the front and having a hollow shape is attached to the left end of the first unbalanced weight 19A, which also slides with respect to the first drive shaft 10. It is arranged freely. Also, inside this, the second unbalanced weight 18A
Is fixed to the drive shaft 10. This front shape is also a substantially semicircular shape like the first unbalanced weight 19A.

The differential frame 6, which is a main component for adjusting the relative mounting angle of the second unbalanced weight 18A with respect to the first unbalanced weight 19A, has a shape as shown in FIG. However, as clearly shown in FIG. 2, it is provided with side wall portions 6a and 6b arranged at a predetermined interval,
A pair of bearings 58c, 59a, 58a, 58b, 59 clearly shown in FIGS. 2 and 6 are provided on the side wall portions 6a, 6b.
d, 59c and 60b are attached on the outer race side thereof, and the inner races thereof are respectively attached to the right end portion of the first drive shaft 10 in FIG.
The support shaft 13 and the first support shaft 14 are fixed to the inner race side. Therefore, the differential frame 6 is configured to be rotatable around the axis of the drive shaft 10 in FIG. The above-mentioned second, third and fourth driven gears 25, 24,
Reference numeral 23 is located between both side wall portions 6a and 6b of the differential frame 6 and is attached to the support shafts 14, 13 and 12.

The fifth driven gear 20A described above meshes with the fourth driven gear 22 fixed to the outwardly projecting portion of the differential frame 6 at the left end of the support shaft 12 in FIG. .

The first drive gear 2 as shown in FIG.
1A is in mesh with a driven gear 26A that is rotatably supported by a fifth support shaft via a bearing, and this is a driven gear that is rotatably mounted on the sixth support shaft via a bearing with the same number of teeth. 26B is engaged. The driven gear 26B is fixed to the end of the second drive shaft 11 to form a second gear.
Of the drive gear 21B.

On the other hand, the driven gear 20A which is concentric with the first drive shaft 10 meshes with the driven gear 26C having the same number of teeth, which is also shown in FIG. 3, and this driven gear 26D also has the same number of teeth. Meshes with. These driven gears 26A,
26B, 26C and 26D are rotatably fixed to a shaft supported by a common mounting plate 8 via bearings.
The driven gear 26D meshes with a driven gear 20B coaxially and slidably arranged at the end of the second drive shaft 11. Second
Similarly to the first drive shaft 10, the drive shaft 11 is also provided with unbalanced weights 18B and 19B having the same shape so as to be fixed or slidable.

An angle adjusting knob 72 is provided on the front surface of the gear cover 2, and the rotary shaft 55 shown in FIG. 4 has bearings 61 and 62 attached to both side walls of the adjusting gear frame 42. It is rotatably supported by
An angle adjusting gear 28 is fixed to the intermediate portion. This is meshed with a second angle adjusting gear 27 which has a large diameter, is concentric with the first drive shaft 10 and is rotatable relative thereto, as clearly shown in FIG. The second angle adjusting gear 27 is fixed to the outer race side of the bearing 63 as clearly shown in FIG. 1, and is fixed to the front portion of the gear cover 2 in the inner race.

The vibration exciter 100 according to the embodiment of the present invention is configured as described above. Next, this operation will be described.

It should be noted that FIGS. 3 and 6 show positions in which the differential frame 6 is deviated by 90 degrees around the axis of the first drive shaft 10. Accordingly, FIGS. 1 and 2 correspond to FIGS. 3 and 6, respectively, to illustrate each gear and its associated components.

That is, in the angular position of the differential frame 6 shown in FIGS. 1 and 3, the first and second drive shafts 10, 1 are provided.
The first and second unbalanced weights 18A, 18B, 19A, 19B fixed to or disposed at 1 have the relative angular positions shown in FIG. The drive shaft 10,
11 is fixed at the same phase angle and the maximum excitation force is shown. From this state, when the electric motor coupled to the right end portion of the first drive shaft 10 in FIG. 2 via the universal joint 70 is driven, the first drive shaft 10 rotates counterclockwise as shown in FIG. To do. Therefore, the first unbalanced weight 18A fixed to this also rotates counterclockwise at the same speed. The first drive gear 21A fixed to the end portion of the first drive shaft 10 also rotates at the same speed, but this is engaged with the driven gear 25 of the same diameter as clearly shown in FIG. This gear 25
Rotate in the opposite direction at the same speed. Furthermore, this gear 25
Is engaged with the gear 24 having the same number of teeth, the gear 24 is rotated in the opposite direction at the same speed. Furthermore, this gear 2
Reference numeral 4 meshes with the gear 23 having the same number of teeth to rotate it. As shown in FIG. 2, the gear 23 has bearings 5 on both side walls 6a and 6b of the differential frame 6.
Since it is fixed to the support shaft 12 supported by 8c and 59a, it is rotationally driven at the same speed and the same direction, and the gear 22 fixed to this end is rotated at the same direction and the same speed. The driven gear 20A meshing with this is rotated. Since the edge of the central opening is fixed to one end of the tubular member 34A by a bolt, the tubular member 34A
A is rotated at the same speed and in the same direction, and the second unbalanced weight 19A attached to the left end of the A is rotated at the same speed and
Rotate in the same direction. Therefore, the second unbalanced weight 19A is driven at the same speed in the same direction as the first drive shaft 10. That is, the first unbalanced weight 18A is rotationally driven in the same phase and at the same speed and in the same direction. In FIG. 7, a
Is the initial position, b and c show the state in which the first and second unbalanced weights 18A and 19A are advanced 90 degrees in the counterclockwise and clockwise directions, respectively.
To a rotation phase of “a” to complete one cycle.

Due to the rotation as shown in FIG. 7, the relative angular difference between the first and second unbalanced weights 18A, 18B and 19A, 19B is now 0, so these unbalanced weights 18A, 1B are
8B, 19A, 19B, drive shafts 10, 11
The force applied to is 2f. Therefore, in the rotational phase of a, they are combined to form a force of 4f, and in the phase of b, they are directed in opposite directions, so they cancel each other out.
Further, in the rotational phase of c, these are in the opposite direction to a and face the same direction, so the combined force is 4f. Also, the rotation phase d
In the same way as in the rotation phase b, they are in opposite directions and therefore cancel each other out. As a result, a linear sinusoidal excitation force of 4f can be generated in the horizontal direction in FIG.

Next, while operating the vibration exciter 100, the first
The adjustment operation of the angular positions of the second unbalanced weights 19A and 19B with respect to the unbalanced weights 18A and 18B will be described.

The operator pivotally adjusts the knob 72 shown in FIG. 6 to a desired angular position (now 90 degrees) according to the scale. As a result, as clearly shown in FIG. 1, the first adjusting gear 28 fixed to the rotating shaft 55 rotates by the same angle, and as a result, the large-diameter gear 27 with which it meshes.
Is rotated about the axis of the first drive shaft 10 by a predetermined angle. This causes the differential frame 6 to rotate 90 degrees clockwise in FIG. 6 around the axis of the first drive shaft 10,
Take the position as shown in. By rotating to this position, the driven gear 22 fixed to the support shaft 12 is rotated around the axis of the first drive shaft 10 to rotate the driven gear 20A. That is, the cylindrical member 34A fixing the driven gear 20A
By the rotation of this angle, the second unbalanced weight 19A fixed thereto is rotated by the same angle. Therefore, the relative angle with respect to the first unbalanced weight 18A is changed. It should be noted that the angular position of the second unbalanced weight 19A with respect to the first unbalanced weight 18A was changed for the first drive shaft 10 in this manner. 3, the driven gear 20B fixed to one end of the second tubular member 34B concentric with the second drive shaft 11 via the driven gears 26C and 26D is attached to the first drive shaft 10
The driven gear 20A is rotated at the same angle in the opposite direction. As a result, the unbalanced weights 18B and 19B can also be set to the angular position as clearly shown in FIG. Figure 8
The rotation phases of the drive shafts 10 and 11 in the opposite directions sequentially take the rotational phases indicated by a, b, c, and d. Now, the relative phases of the first and second unbalanced weights 18A and 19A are relatively large. Since the deviation angle is 90 degrees, a force is generated by the vector combination of the centrifugal forces generated by the respective unbalanced weights 18A and 19A. This is now the first and second unbalanced weights 18
If the centrifugal forces of A and 19A are the same magnitude f, then F = √4 /
The size is 2 f. Such synthetic force F is a in FIG.
When generated in the direction indicated by, the combined force of these components cancels the vertical component in the figure, but adds in the horizontal component, resulting in a force in this direction. Similarly, in the rotational phases b, c and d, the vertical components cancel each other out, but the horizontal components add, so that a horizontal excitation force is generated although the excitation force is smaller than in the case of FIG.

In the illustrated embodiment, the differential frame 6 is adjustable about 0 to 90 degrees around the axis of the drive shaft 10. However, theoretically, 360 degrees can be adjusted. . Considering the direction of rotation adjustment, 180 degrees can be adjusted and a range of 0 to maximum excitation force can be obtained. If the relative angle of 180 degrees is changed, the state shown in FIG. 9 is obtained. That is, the unbalanced weights 18A and 19A are the drive shafts 10 and 1 of the centers of gravity thereof.
The positions for 1 are in opposite directions. Therefore, the exciting force f generated on the first unbalanced weight 18A and the exciting force f1 generated on the second unbalanced weight 19A cancel each other in the state of a,
In the rotation phase b, the directions are opposite to each other, and when the first unbalanced weight and the second unbalanced weight generate the centrifugal force of the same magnitude in the rotation phases a to d, the combined force is 0. Become. Therefore, theoretically, the exciting force 0 can be adjusted to the maximum exciting force F = 4f.

As described above, the embodiment of the present invention is constructed and operates, but it has the following effects.

That is, in the vibration exciter developed prior to the present application, the first, second, third and fourth unbalanced weights were mounted on independent drive shafts, respectively, but the same vibration The number of drive shafts is halved while generating vibrating force, and the bearings that support these drive shafts at both ends are first and second.
Since the unbalanced weight can be used commonly, that is, coaxially, the number of parts is reduced. Further, in the previously proposed device, four drive shafts are arranged in parallel in the horizontal plane at equal intervals, but since the two drive shafts can be arranged at substantially the same intervals, The structure can be made more compact.

The vibrating section configured as described above is attached to the molding machine 110 of which specific examples are shown in FIGS. Vibrations as shown by A in FIG. 3 are applied to the belt-shaped members 118a, 118b, 118c and 118d arranged to form the vibration table T at equal intervals. That is, as clearly shown in FIG. 5, the mount 111 is mounted on the support 113 through the air springs 114 at four locations on the base 112.
Is supported, and the above-mentioned strip-shaped members 118a to 118d are mounted thereon, the mold M is placed on this, and the clamps 115 clamp the strip-shaped members 118a to 118d.
It is configured to be fixed to 18d.

As clearly shown in FIG. 4, the vibration table T
Electric motors 120 and 130 for driving the vibrating sections 100A, 100B, 100C and 100D (corresponding to 101a to 101d in FIG. 1, respectively) are arranged on the sides of the belt-shaped members 118a to 118d constituting the above. The rotary shafts 123 and 131 are the bevel gear device 12
1, 122, 132, 134, and between the bevel gears 121, 122 and 132, 134 via connecting shafts 124, 133 connected at both ends by universal joints. The shaft 12 that receives the transmission force of the rotary shafts 123, 131 from the bevel gears 121, 122, 132, 134 in the direction perpendicular to the shaft 12
5, 126, 135 and 136 are vibrating parts 1 whose configurations are clearly shown in FIG.
Each universal joint 70 of 00A to 100D
It is connected to the.

The vibration type molding machine according to the embodiment of the present invention is constructed as described above. Next, its operation will be described.

Although the operation of each of the vibrating sections 100a to 100d has already been described, in the present embodiment, the angle adjusting knob 72 provided in each of the vibrating sections has a relative angle of 180 degrees in the vibrating section 100A. Is 90 degrees) which is the minimum vibration force, and the relative angle is 0 degrees in the vibration unit 100B facing this. Similarly, the vibration units 100C and 100 facing each other
In D, the angle adjustment of 100D is performed at a relative angle of 180 degrees (90 degrees in the illustrated example), and at 100C, a relative angle of 0 degree.

When the electric motors 120 and 130 are driven on this, the amplitude of the belt-shaped member 118b as a part of the vibration table T where the vibrating section 100D is attached as described above is zero or very small. In addition, since the relative angle is 0 degree in the vibrating portion 100C facing this, the belt-shaped member 118d is vibrated with a large amplitude. Therefore, in the belt-shaped members 118a to 118d, the amplitude is increased from the right side to the left side in FIG. 4, and the amplitude distribution is shown as shown in FIG. 3A. Similarly, the vibrating portions 100A and 100B in the direction perpendicular to this also have a non-uniform vibration with a minimum amplitude at one end and a maximum amplitude at the other end in the longitudinal direction of the belt-shaped members 118a to 118d. Vibrates with width distribution. Therefore, the belt-shaped members 118a to 118d
Vibrates three-dimensionally, and the frame M clamped thereon also vibrates in the same manner, and the dry sand introduced from the supply port p into the hole h uniformly extends in the slit particularly in the horizontal direction. It is possible to sufficiently fill even the small holes ha.

In this embodiment, the vibrating section 100A is used.
To 100D, respectively, while being easily driven by the angle adjusting knobs 72 provided, that is, the electric motors 120, 1
Since it is possible to adjust the excitation force while driving 30, it is now possible to observe whether or not the holes h of the attached frame M are sufficiently filled with dry sand (for this, Various sensors are conceivable.) The optimum conditions may be set.

Further, in the above embodiment, the amplitude distribution of the belt-shaped members 118a to 118d constituting the table T is shown by A in FIG. 3, but this can be reversed and each amplitude is shown by C in FIG. The vibration force of the vibration units 100A to 100D may be adjusted. In this case, if A in FIG. 3 is the optimum condition, it is conceivable that the frame M is attached in the left and right directions.

FIG. 16 shows an oscillating molding machine according to the second embodiment of the present invention. On the lower surface of the oscillating table 200, oscillating portions 201a, 20a composed of a pair of oscillating motors are provided.
1b, 201c and 201d are attached. Since these have the same configuration, only the vibration unit 201c will be described. That is, the vibrating section 201c is composed of a pair of vibration motors 201cA and 201cB, which have the same configuration but are symmetrically mounted on a common mounting plate, and are mounted on the lower surface of the vibration table 200 via this. The attached oscillating motor is constructed in a known manner, but substantially semicircular unbalanced weights j are attached to both ends of the rotary shaft g. Further, each electric motor is connected to the control circuit 203. The other vibrating units 201a, 201b and 201d are also configured in the same manner, and their respective power cables are also connected to the control circuit 203.
The number of revolutions is independently changed by an inverter incorporated in the unit 3.

The detailed structure of the vibration table 200 is the same as that of the first embodiment, but currents of different frequencies are supplied from the control circuit 203 to the vibration units 201a to 201d. These are induction motors, which have different rotational speeds. However, in the present embodiment, the output frequency of the inverter in the vibration units 201a and 201b is much smaller in the vibration unit 201a, and Swing unit 2
01b is much larger. Similarly, in the vibration units 201c and 201d facing each other, the frequency is small in 201c, and the frequency is large in 201d. Therefore, since the unbalanced weights j are formed as a pair in each of the vibrating portions, the unbalanced weights j are rotated by synchronizing the phases in opposite directions by receiving the synchronizing force as is well known. As a result, a linear vibration force is generated in each of the vibration units 201a to 201d in a direction perpendicular to the horizontal plane of the table 202. Since the magnitude of the exciting force of this linear vibration force is proportional to the mass of the unbalanced weight j x the distance from the axis center to its center of gravity x the angular velocity ω ² , since ω is greatly different, Similar to the embodiment, the swing mode having the distribution shown in FIG. 3A is obtained from the right end portion to the left end portion in the drawing of the table 200, and thereby the same effect as that of the first embodiment can be obtained. In the case of the present embodiment, the adjusters for changing the independent frequencies of the respective inverters in the control circuit are independently provided, but by adjusting these independently, the exciting force is changed during operation. Therefore, it is obvious that the same effect as the first embodiment can be obtained.

FIG. 17 shows a vibration molding machine according to the third embodiment of the present invention. The vibration table 300 is provided with vibrating sections 301A and 301B facing the lower surface, and the other constitution is the first. Alternatively, although it is similar to the second embodiment, in this embodiment, the electromagnet driving device is the same as 301A and 301B, and therefore one 301B will be described. The fixed electromagnet 303 has the coil 304 wound around it. A movable core 305 attached to the lower surface of the vibrating table 300 is attached so as to face this with a gap G therebetween. The other vibrating section 301A is also configured in the same manner, but the lead wires derived from these electromagnetic coils 304 are connected to the control circuit 306.

In the present embodiment, the current flowing through each coil 304 can be changed independently, and as a result, the vibrating force can be changed in the vertical direction as shown in FIG.
It is possible to generate a swing mode in a mode as shown in. In this case, the same frequency can be obtained although the frequency is the same.

Although the respective embodiments of the present invention have been described above, the present invention is not limited to these, and various modifications can be made based on the technical idea of the present invention.

For example, in the above embodiment, in the first embodiment, the four vibration parts 102a to 10a are provided on the lower surface of the table 101.
Although two 2d are provided facing each other, the number is not limited to this, and for example, two facing 2d, such as 102a and 102b in FIG. 1, are provided as in the third embodiment shown in FIG.
It is also possible to provide only one and omit 102c and 102d.
In this case, the vibration mode as shown in FIG. 3A is obtained from the left edge portion to the right edge portion of the vibration table 101 in FIG. 1, but the same vibration is obtained from the upper edge portion to the lower edge portion in FIG. Although it is the mode, it is possible to obtain substantially the same effect as that of the first embodiment.

Further, in the third embodiment shown in FIG. 17, two electromagnet driving sections facing each other have vibrating sections 301A and 301B.
However, as in the first embodiment, a pair of vibrating sections composed of electromagnet driving sections having the same structure may be attached so as to face each other at the left and right edges.

Further, in the above-described embodiment, the vibration force of the vibrating portions facing each other is made large and small to obtain the vibration mode as shown by A in FIG. 3. However, as already described in the first embodiment, It is clear that the mode shown by C in FIG. 3 can be obtained by reversing the magnitude of this exciting force.

Further, in the present embodiment, the magnitude of the exciting force is changed between the left and right edges or the front and rear edges, but instead of this, even if the exciting force is the same, the change over time can be shifted. Due to
Alternatively, it may be changed with time as indicated by a one-dot chain line a ′ of FIGS. In this case, as shown by B in FIG. 3, the amplitude is the same at a middle point in a certain cycle, but the maximum amplitude and the minimum amplitude at both edge portions 101a and 101b are 180 degrees phase. Is different. It is clear that this also produces the same effect as the above embodiment.

Furthermore, in the above embodiment, the case where a linear vibration force is generated has been described. For example, in the third embodiment, one vibrating motor is used instead of the electromagnet driving unit to generate a circular vibration force. It is also possible to change the vibration force at the left and right or at opposite edges by changing the magnitude relationship between these generated or these or the frequency of the alternating current applied thereto by an inverter.

[0048]

As described above, according to the powdery or granular material filling apparatus of the present invention, even if the void to be filled has any shape, the powdery or granular material to be filled can be uniformly filled. it can.

[Brief description of drawings]

FIG. 1 is a plan view schematically showing a vibration filling device according to a first embodiment of the present invention.

FIG. 2 is a side view of the same.

3A, 3B and 3C are schematic diagrams for explaining the operation of the embodiment.

FIG. 4 is a plan view showing a detailed structure of the apparatus of FIG.

FIG. 5 is a front view of the same.

FIG. 6 is a side view of the same.

7 is a vertical cross-sectional view showing details of one vibration unit in FIG.

8 is a sectional view taken along line [8]-[8] in FIG.

9 is a sectional view taken along line [9]-[9] in FIG.

10 is a cross-sectional view taken along line [10]-[10] in FIG.

11 is a cross-sectional view taken along line [11]-[11] in FIG.

FIG. 12 is a front view of the vibrating section.

FIG. 13 is a side view of the unbalance weight for showing each position of the unbalance weight for explaining the operation of the vibration unit.

FIG. 14 is a front view of an unbalanced weight showing another angular relationship.

FIG. 15 is a front view showing unbalance weights at each phase in the same angular relationship as other unbalance weights.

FIG. 16 is a schematic plan view of a powdery or granular material filling device according to a second embodiment of the present invention.

FIG. 17 is a plan view of a powdery or granular material filling device according to a third embodiment of the present invention.

FIG. 18 is a side view of the same.

FIG. 19 is a side view of a conventional vibration molding machine.

[Explanation of symbols]

 100 Exciter 101 Vibration table 102a Exciting part 102b Exciting part 103c Exciting part 103d Exciting part 100A Exciter 100B Exciter 100C Exciter 100D Exciter 110 Vibration molding machine 203 Control circuit 306 Control circuit 301A Electromagnet driver 301B Electromagnet driver

Claims (3)

[Claims] 1. A powdery or granular material filling device comprising a table oscillatably supported up and down and a vibrating machine for vibrating the table, wherein the vibrating machine moves the table on the upper surface of the table. A powder / granular filling device characterized by causing non-uniform vibration or different vibrations at respective points with respect to time. 2. The vibration exciter includes a first drive shaft, a second drive shaft parallel to the first drive shaft, first and second drive gears concentrically fixed to the drive shafts, and the first drive gear. And a first unbalanced weight fixed to each of the first and second drive shafts, and a first gear device engaged with the A second unbalanced weight provided, and a driven gear fixed to each of the second unbalanced weights, one of which is engaged with the first gear device, and the first and second drive gears. Of the two driven gears, one is engaged with the other, and the other is engaged with the other of the two driven gears and the other of the both driven gears, and the second gear device and the first drive shaft or the second drive shaft are rotationally driven. The electric motor and the first gear device to the first
2. The powdery or granular material filling device according to claim 1, further comprising a relative angle adjusting means for rotating the drive shaft about an axis thereof. 3. The vibrating machine comprises four vibrating sections fixed to the lower surface of the table so as to face each other, each of which is fixed to a first drive shaft and coaxially to the first drive shaft. First driven gear, a first driven gear that meshes with the first driven gear and is rotatably supported by a first support shaft, and a first driven gear that meshes with the first driven gear and is rotatably supported by a second support shaft A second driven gear that is
A third gear that meshes with the driven gear and is coaxially fixed to the third support shaft.
A driven gear, a fourth driven gear that is coaxially fixed to the third support shaft, a fifth driven gear that meshes with the fourth driven gear and is disposed coaxially with the first drive shaft, and 5 a first tubular member that is coaxially fixed to the driven gear and is slidable on the first drive shaft, a first unbalanced weight that is fixed to the first drive shaft, and is fixed to the tubular member. A second unbalanced weight, and a first bearing portion for rotatably supporting the end portion of the first drive shaft on both sides of the first drive gear fixed to the first drive shaft; A differential frame having second, third, and fourth bearing portions attached to rotatably support the second and third support shafts, and the first drive gear mesh with each other, and rotatably supported on the fourth support shaft. A sixth driven gear, a seventh driven gear that meshes with the sixth driven gear and is rotatably supported by a fifth support shaft, and is arranged in parallel with the first drive shaft. Second drive shaft, a second drive gear that meshes with the seventh driven gear that is coaxially fixed to the second drive shaft, and a fifth drive gear that meshes with the sixth drive shaft and is rotatably supported by a sixth support shaft. An eighth driven gear, a ninth driven gear that meshes with the eighth driven gear and is rotatably supported by a seventh supporting shaft, and a ninth gear that meshes with the ninth driven gear and is coaxial with the second drive shaft. And a second tubular member fixed coaxially to the tenth driven gear and slidable on the second drive shaft, and a third non-movable member fixed to the second drive shaft. Balance weight, fourth unbalance weight fixed to the second tubular member, and angle adjusting gear rotatably fixed to the differential frame around the axis of the first drive shaft. The device for filling powdery or granular material according to claim 1, comprising a device.