JP2926967B2 - Vibration sieve device - Google Patents

Description

The present invention relates to a vibrating sieve device.

[Conventional technology and its problems]

Japanese Unexamined Patent Publication No. 2-99174 discloses that a material is transferred on the sieve mesh by vibrating a trough on which a sieve mesh is stretched, and a rod-shaped member extending in a direction substantially perpendicular to the sieve mesh. A plurality of sieve mesh vibration driving units for applying a vibration force are attached to a mounting plate which is stretched and fixed to both edges of the trough. The lower end of the rod-shaped member is fixed to a sieve net, and when the driving unit is driven, the rod-shaped member vibrates in the axial direction thereof, causing the sieve net attached to the lower end to vibrate. When replacing the screen with a new screen, not only the mounting plate but also the lower end of the rod-shaped member of the drive unit for screen vibration fixed to this Bolts, etc., which are means for fixing the wire and the sieve net, must be removed. Since a plurality of sieve mesh vibration driving units are provided, all of them must be removed, and then the sieve mesh is replaced with a new one. Very troublesome.

[Problems to be solved by the invention]

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and provides a vibration which can easily replace a sieve mesh with a rod-shaped member extending in a direction perpendicular to the sieve mesh while improving the sieving efficiency. It is intended to provide a sieve device.

[Means for solving the problem]

The object of the present invention is to incline and / or vibrate a frame on which a sieve mesh is stretched so as to transfer the material on the sieve mesh, and to provide a rod-like member extending substantially vertically in the sieve mesh. In a vibration sieve device in which at least one sieve mesh vibration drive unit that applies a vibration force to a member is supported by the frame, the rod-shaped member is inserted through an opening formed in a bottom wall of the frame, and The tip is fixed to the sieve mesh, and the lower end is connected to the casing via an elastic member in a casing fixed to the bottom wall of the frame, and the rod-shaped member is axially inserted into the casing. This is achieved by a vibrating sieve device, wherein a vibrating mechanism for vibrating is provided.

[Action]

The rod-shaped member is inserted into the opening formed in the bottom wall of the frame, for example, the trough from below, and is fixed to the upper screen at the tip thereof. Although the sieving efficiency of the material is as high as before, when replacing the sieving mesh, the tip of the rod upper member and the sieving mesh are connected from above the trough, for example, a bolt is used to sieving the mesh. The sieve mesh is free from the sieve mesh vibration drive only by loosening and removing it by the number of drive units, for example, by simply loosening the screen attachment means attached to the side edge of the trough at both edges. , Can be exchanged sieve net.

〔Example〕

Hereinafter, a vibration sieve device according to an embodiment of the present invention will be described with reference to the drawings.

FIG. 1 shows a vibrating sieve device according to a first embodiment of the present invention, which is generally indicated by (1), and a sieve net (3) is stretched in a trough (2). In FIG. 1, a sieve material outlet (4) and a sieve lower material outlet (5) are formed at the right end of the trough (2), and a sieve material supply port (6) is formed at the left end. ing. A vibration driving unit mounting plate (7) is integrally formed on the bottom wall of the trough (2), and a pair of known vibration motors (8
a) (8b) is fixed.

The trough (2) is a pair of pillars (9a) (9
b), (10a) and (10b) with anti-vibration springs (11) (11) (11) (1
1) is supported through. In addition, in the present embodiment, five sieve mesh vibration driving parts (12) according to the present invention are attached to the bottom wall of the trough (2) as clearly shown in FIG.
An electromagnetic vibration feeder (14) is provided immediately above a sieve material supply port (6) formed at the left end of the trough (2), and sieve material is supplied from a hopper (13). It has become so. The hopper (13) and the electromagnetic vibration feeder (14) are arranged on a gantry (15).

Next, the sieve mesh vibration driving section (12) according to the present invention will be described in detail. In the present embodiment, these are arranged at five locations as shown in FIG. 3, but all have the same configuration, so that one sieve mesh vibration driving unit (12) shown in FIG.
Will be described. This is provided with a cup-shaped casing (21) as shown in FIG. 4, and its upper end is fixed to the bottom wall (2a) of the trough (2) by, for example, welding as shown in FIG. It is fixed to the pair of angle members (23a) (23b) by bolts (19) (19). As shown in FIG. 4, a fixed electromagnet (28) is wound around a coil (29) and fixed to the bottom wall of the casing (21). There is a pair of springs (30)
Supported by The lower end of the rod (26) is fixed to the center right of the movable core (27).
As shown in the figure, an opening (24) formed in the bottom wall of the trough (2) is inserted, and a diameter increasing portion (32) as a sieve mesh attachment portion is integrally formed at the upper end. An umbrella member (31) made of a cup-shaped metal is fixed so as to surround the portion, which is protruded from the bottom wall (2a) of the trough (2) of the rod (26) and to the upper end thereof. The sieve is arranged so as to cover that the lower portion of the sieve is falling toward the increased diameter portion (32) formed integrally. Further, a sieve mesh attaching member (33) is opposed to the umbrella member (31) with a sieve mesh (3) interposed therebetween, and a diameter increasing portion (3) is provided by a bolt (34).
2) Fixed to. That is, a screw hole (not shown) is formed in the increased diameter portion (32), and the bolt (34) is inserted into the bolt insertion hole formed in the mounting member (33), and the screw portion of the bolt (34) is The distal end of the rod (26) is configured to be clamped and fixed to the sieve mesh (3) by screwing into a screw hole formed in the diameter increasing portion (32).
An opening (24) formed in the bottom wall (2a) of the trough (2)
A cylindrical projection (25) is integrally formed on the periphery of the rod, and the rod (26) penetrates the projection.
A covering member (35) made of a cylindrical rubber is elastically fixed to the enlarged diameter portion and the protruding portion (25) at the upper end and the lower end between the upper end and the increased diameter portion (32). ing.

As described above, the rod (26) is completely covered with the material below the sieve. Next, a structure for attaching the sieve net (3) to the trough (2) will be described with particular reference to FIG.

At both ends of the sieve net (3), mounting members (42a) (42b) bent in a V-shape are mounted, and a pair of holding members (90
a) (90b) extends along the longitudinal direction of the trough (2), and its upper ends (41a) (41b) are elastically pressed against the inner wall of the trough (2). As shown in FIG. 5, the mounting members (42a) and (42b) are engaged with the lower end of the holding member (90), and bolts () are formed in holes formed in the vertical plate portions of the holding members (90a) and (90b). 43a) and (43b) are inserted through the opening of the side wall (2b) of the trough (2), and the bolts (43a) and (43b) are screwed with the springs (44a) (44b). ) Is inserted through the opening of the spring receiving member (45a) (45b), and then the nut (46a) (46b) is screwed into the spring (44a).
(3b) sieve with tension according to the compression force of (44b)
Are mounted in tension in the trough (2).

The vibration sieving apparatus according to the first embodiment of the present invention is configured as described above. Next, its operation will be described.

In FIG. 1, when a pair of vibration motors (8a) and (8b) are energized, the known unbalanced weight rotates synchronously, and the trough moves in the direction indicated by the arrow a by the linear vibration force generated by these combined forces. Vibrates linearly. In addition, each sieve mesh vibration drive unit (12)
It is assumed that power is also supplied to In FIG. 1, a sieve material is supplied from a hopper (13) to a sieve material supply port (6) of a trough (2) by an electromagnetic vibration feeder (14). Since the trough (2) vibrates linearly in the direction of arrow a, the sieving material supplied from the supply port (6) is transported to the right in FIG. In this process, the screen is divided into a screen on the screen (3) and a screen on the screen. According to the present embodiment, five screen driving units (12) are fixed to the screen. As shown in FIG. 4, alternating current is applied to the coil (29), so that an alternating attractive force is generated between the coil (29) and the movable core (27), whereby the rod (26) vibrates in the vertical direction. . Therefore, the sieve mesh (3) fixed at its tip is vibrated. The frequency of the alternating current applied to the coil of the drive unit (12) is assumed to be sufficiently high, and the sieve net (3) vibrates at a high frequency accordingly to give an impact force. The sieve material is efficiently and sharply sieved without clogging into the upper and lower sieves. Thus, in FIG. 1, the upper sieve material conveyed to the right of the trough (2) is discharged outward from the upper sieve discharge port (4) and the lower sieve material is discharged from the lower sieve discharge port (5). Is discharged.

The material is sieved on the sieve net (3) as described above, and the material under the sieve falls onto the bottom wall (2a) of the trough (2). Then, the trough is transferred by linear vibration on the bottom wall. In this process, the bottom wall (2a) of the trough has a cylindrical projection (25) on the periphery of the opening as clearly shown in FIG. ) Is formed, so that it is transported around the periphery and does not enter the cylindrical projection (25). That is, it does not enter the casing (21) of the vibration drive section (12). Further, according to the present embodiment, since the covering member (35) made of cylindrical rubber is fixed between the diameter-increasing portion (32) at the upper end of the rod (26) and the projection (25), the rod (26) is completely fixed. The lower sieving material is prevented from entering the casing (21) of the drive section (12). Furthermore, since the umbrella member (31) is attached so as to cover the increased diameter portion (32), the material under the sieve falls on the bottom wall (2a) of the trough (2) so as to avoid the projection (25). Not only prevents the drive unit (12) from entering the casing (21), but also prolongs the life of the rubber covering member (35). Because there is no). The sieve mesh (3) and the bottom wall (2a) of the trough (2) vibrate relative to each other, but this is absorbed by the bending because the tubular member (31) is made of rubber. Rod (2
There is no adverse effect on the vibration of 6).

The vibrating sieve device according to the embodiment of the present invention performs the above-described operation. Next, the operation of replacing the sieve net (3) will be described.

When replacing with a new sieve net, use bolts (3
4) Easy to loosen all screen drive (1
The sieve net (3) can be removed from 2). At this time, at both edges of the sieve net (3), the mounting portions (42a) (42
The nut (46) screwed into the bolt (43a) (43b) passing through the holding member (90a) (90b) engaged with the b)
a) The sieve net (3) can be easily removed by loosening (46b). Next, since the both sides of the new sieve mesh are provided with mounting portions similar to the mounting portions (42a) and (42b), the lower ends of the holding members (90a) and (90b) are provided as shown in FIG. Bolt (43a)
(43b) with a spring (44a) (44b)
a) By tightening (46b), a new sieve net can be installed in the trough (2) under a predetermined tension. Then, the bolts (34) are screwed into the screw holes of the diameter-increasing portion (32) with the mounting members (33) interposed therebetween, so that the tip of the rod (26) of each sieve driving unit (12) is a new sieve. It can be fixed to the net (3). According to the present embodiment, the casing (21) of the drive unit (12) is connected to the bottom wall portion (2a) of the trough via the pair of mounting members (23a) (23b) as shown in FIG. ), It is possible to replace the sieve net while it is attached, and the exchange operation of the sieve net is greatly simplified as compared with the related art.

FIGS. 7, 8 and 9 show a vibration sieve device according to a second embodiment of the present invention. In this embodiment, the upper opening of the trough (61) is covered with a hood (68). An exhaust port (69) is formed therein, and a material supply port (70) is formed at the left end in FIG. 7, and inspection windows (71) and (72) are provided therebetween. Can be opened and closed at any time by opening and closing mechanisms (73, 74).

Also in this embodiment, a sieve net (67) is stretched in the trough (61), and the trough (61) is on a pair of columns (64a) (64b), (65a) (65b) which are paired in front, back, left and right. Anti-vibration spring (66)
Supported by A plurality of sieve mesh vibration drive units (62) are attached to the bottom wall of the trough (61) in the same manner as in the first embodiment.
It has the same configuration as 2). That is, the tip of the rod that vibrates up and down is fixed to a sieve net (67). The trough (61) is a pair of vibration motors (63a) (6
3b) applies a linear vibration force in the direction of arrow a.

Further, according to the present embodiment, a pipe (75) is stretched in a hood (68), and a plurality of air nozzles (76) are attached to the hood (68) at equal angular intervals. 67).

In this embodiment, the same operation as that of the first embodiment is performed and the effect is obtained.
8) Dispose a pipe (75) inside and prevent clogging by the sieve mesh vibration drive (62) until air is blown onto the sieve mesh (67) by the air nozzle (76) attached to it. In addition, the prevention of clogging can be further ensured.

Also in this embodiment, since the drive rod of the screen driving unit (62) extends upward from below and is fixed to the screen (67), the space above the screen becomes wider than before.
The arrangement of such an air nozzle (76) is made possible.

FIG. 10 and FIG. 11 show a vibration sieving apparatus according to a third embodiment of the present invention.
0) Attachment plate (83a) (83b)
Are fixed upright, and a pair of vibration motors (85
a) (85b) is mounted at an inclination as shown.
That is, it is mounted so as to perform linear vibration in the direction of arrow b. Further, a sieve net (82) is stretched in the trough (80), and a plurality of sieve net vibration driving units (81) are provided and fixed below this as in the above embodiment.
This casing is also the bottom wall (80a) of the trough (80)
The rod is vertically inserted through an opening formed in the rod, and the tip of the rod is attached to a sieve net (82). In addition, on both side walls of the trough (80), suspension members (84) are engaged in front, rear, left and right, and the center of the suspension members (84) is connected to the building via vibration-proof springs (85). (84a)
Hanged at. A hook (not shown) is engaged with the hook so that the entire trough (80) is suspended from the building.

This embodiment also has the same effect as the above embodiment, and has the same effect. However, in this embodiment, the sieve mesh vibration driving unit (81) is attached to the bottom wall of the trough (80). Since the upper part of the net (82) is free space, the mounting members (83a) (83b) for mounting the vibration motors (85a) (85b) on the trough (80) are much easier than before. can do.

As described above, each embodiment of the present invention has been described.
The present invention is not limited to these, and various modifications are possible based on the technical idea of the present invention.

For example, in the above embodiment, a pair of vibration motors is used to vibrate the trough. However, the excitation drive unit is not limited to this, and an electromagnet drive unit may be used.

Further, in the above embodiment, the electromagnet is used as the sieve mesh vibration driving unit. Of course, the present invention is not limited to this, and another vibration driving unit, for example, a pair of small vibration motors may be used.
Or you may utilize the vibration force by rotation of the steel ball by compressed air. Alternatively, the frame may simply be inclined downward.

Further, in the above embodiment, five vibration driving units are provided, but of course, one vibration driving unit may be provided, or more sieve vibration driving units may be provided.

〔The invention's effect〕

As described above, according to the vibration sieve device of the present invention,
By directly oscillating the sieve net, replacement of the sieve net can be made much easier than before while obtaining high sieving efficiency.

[Brief description of the drawings]

FIG. 1 is a side view of a vibration sieve device according to a first embodiment of the present invention, FIG. 2 is a front view thereof, FIG. 3 is a plan view thereof, and FIG. 5, an enlarged sectional view taken along line VV in FIG. 3,
FIG. 6 is a sectional view taken along the line VI-VI in FIG. 5, FIG. 7 is a side view of the vibration sieve device according to the second embodiment, FIG. 8 is a plan view thereof, FIG. Fig. 11 is a side view of a vibration sieve device according to a third embodiment of the present invention, and Fig. 11 is a front view thereof. In the figures, (1) ... vibrating sieve device (2) (61) (80) ... trough (2a) ... bottom wall (3) (67) (82) ... sieve net (12) (62) ) Sieve mesh vibration drive unit (24) Opening (26) Rod (27) Movable core (28) Fixed electromagnet (29) Coil (33) Mounting member (34) ) Bolt (80a) Bottom wall

Claims (2)

(57) [Claims] 1. A rod-like member extending in a substantially vertical direction, wherein a material is transported on the screen by tilting and / or vibrating a frame on which the screen is stretched. In a vibration sieve device in which at least one sieve mesh vibration drive unit that applies a vibration force to a member is supported by the frame, the rod-shaped member is inserted through an opening formed in a bottom wall of the frame, and The tip is fixed to the sieve mesh, and the lower end is connected to the casing via an elastic member in a casing fixed to the bottom wall of the frame, and the rod-shaped member is axially inserted into the casing. A vibration sieving device, wherein a vibration mechanism for vibrating is provided. 2. A cylindrical projection is provided on an edge of an opening in a bottom wall of the frame, and a cylindrical member made of rubber is fixed between the projection and an upper end of the rod-shaped member. The vibration sieving device according to claim 1, wherein the vibration sieving device is used.