CN217963480U - A high-efficient screening mechanism for glass bead production line - Google Patents

Abstract

The application provides a high-efficient screening mechanism for glass bead production line includes: screening machine case, branch sieve frame, screening subassembly, first collection box, second collection box and vibrator. Offer the slip through-hole on the screening machine case, the inside wall installation divides the sieve frame, and the screening subassembly setting is in the top of dividing the sieve frame and can relative motion, and the one end fixedly connected with of screening subassembly passes the first silo of slip through-hole, and first collection box and second are collected the box and are respectively for the below with first silo and screening subassembly, and vibrator rotates with the other end of screening subassembly to be connected. In the working process, vibrating device is used for driving the screen assembly to reciprocate and produce vibrations, can shake out the screen assembly with the big granularity glass bead that piles up on the screen assembly, falls into first collection box through first silo, and the filter hole is passed to small granularity glass bead, falls into the second through the second silo and collects the box. The glass beads with the sizes and the granularities can be completely screened, and the screening efficiency is improved.

Description

A high-efficient screening mechanism for glass bead production line

Technical Field

The disclosure generally relates to the technical field of screening machines, in particular to a high-efficiency screening mechanism for a glass bead production line.

Background

The glass beads are a novel material which has wide application and special performance and is developed in recent years. The performance of the glass beads expressed by different particle size sections is different, and is particularly reflected on the optical performance; in order to meet the specified optical performance requirements of the reflective material, the glass beads need to be screened by a screening machine after being formed to obtain glass beads with different particle sizes.

At present, in a screening machine used in the prior art, the diameter of a filtering hole of a filtering net is larger than that of a glass bead with small granularity and smaller than that of a glass bead with large granularity. The screening effect is realized by enabling the glass beads with small particle sizes to pass through the filtering holes and leaving the glass beads with large particle sizes on the filtering net. In the actual screening process, the glass beads with large particle size tend to block the filter holes, so that the subsequent glass beads with small particle size are prevented from passing through. The large-particle-size glass beads are mixed with the small-particle-size glass beads, the screening effect is poor, and the screening efficiency is low.

SUMMERY OF THE UTILITY MODEL

In view of the above-mentioned deficiencies or inadequacies of the prior art, it would be desirable to provide an efficient screening mechanism for a glass bead production line.

The application provides a high-efficient screening mechanism for glass bead production line includes:

screening the machine case; a sliding through hole is formed in the side wall of the screening machine box;

the screening machine frame is fixedly arranged on the inner side wall of the screening machine box;

the screening assemblies are arranged on the screening machine frame and can slide relatively; one end of the screening component is connected with a first discharging groove; the first blanking groove penetrates through the sliding through hole and can slide in the sliding through hole;

the first collecting box is arranged on the outer side of the screening machine box and is positioned below the first discharging groove;

a second collection box mounted inside the screen chassis and below the screen assemblies;

the vibrating device is fixedly installed in the screening machine case, and the driving end of the vibrating device is connected with one end of the screening component in a rotating mode and used for driving the screening component to vibrate.

According to the technical scheme that this application embodiment provided, the inside of screening machine case just is located the limiting plate is installed to the screening subassembly top, and it is right to be used for the screening subassembly is spacing.

According to the technical scheme provided by the embodiment of the application, a first bearing plate is installed in the screening machine box and located below the screening assembly, and a second discharging groove is installed at one end of the first bearing plate; the upper surface of the first bearing plate is coplanar with the inner wall of the second discharging groove.

According to the technical scheme provided by the embodiment of the application, the height of one side, close to the second blanking groove, of the first bearing plate is lower than the height of one side, far away from the second blanking groove, of the first bearing plate.

According to the technical scheme provided by the embodiment of the application, the screening assembly comprises:

the screen separating plate is positioned above the first bearing plate and provided with filtering holes, and the radius of each filtering hole is larger than that of the small-granularity glass beads and smaller than that of the large-granularity glass beads;

one end of the second bearing plate is fixedly connected with the screening mesh plate, and the other end of the second bearing plate is fixedly connected with the first discharging groove; the upper surface of the second bearing plate is coplanar with the inner wall of the first discharging groove;

accept the loop bar, it installs to accept the loop bar divide the sieve plate to keep away from the second accept the one end of board and with vibrator's drive end rotates to be connected.

According to the technical scheme provided by the embodiment of the application, the height of one end, close to the first discharging groove, of the second bearing plate is lower than that of the screen separating plate.

According to the technical scheme provided by the embodiment of the application, the vibration device comprises:

the driving motor is fixedly arranged in the screening machine box;

one end of the crankshaft is fixedly connected with the driving end of the driving motor, and the other end of the crankshaft is rotatably connected with the side wall of the screening case; the crankshaft is provided with a connecting rod journal which is parallel to the axis and is not coincident with the axis, and the bearing sleeve rod is sleeved on the connecting rod journal and can be driven by the driving end to rotate relatively.

The beneficial effect of this application lies in:

the screening machine box is provided with a sliding through hole, the inner side wall of the screening machine box is provided with the screening rack, the screening component is arranged above the screening rack and can move relatively, one end of the screening component is fixedly connected with a first blanking groove penetrating through the sliding through hole, the first collecting box and the second collecting box are respectively arranged below the first blanking groove and the screening component, and the vibrating device is rotatably connected with the other end of the screening component. In the working process, vibrator is used for driving screening subassembly reciprocating motion and production vibrations can will pile up big particle size glass bead on the screening subassembly shakes out the screening subassembly falls into through first silo down first collection box, small particle size glass bead pass the filtration pore, fall into through second silo down the box is collected to the second. The glass beads with the sizes and the granularities can be completely screened, and the screening efficiency is improved.

Drawings

Other features, objects and advantages of the present application will become more apparent upon reading of the detailed description of non-limiting embodiments made with reference to the following drawings:

FIG. 1 is a schematic structural diagram of a high-efficiency screening mechanism for a glass bead production line according to the present application;

FIG. 2 is another schematic structural diagram of the efficient screening mechanism for the glass bead production line provided by the present application

FIG. 3 is a schematic structural view of a screen assembly;

FIG. 4 is a further structural schematic view of the screen assembly;

FIG. 5 is a schematic structural view of a vibration device;

wherein: 1. screening the case; 2. a limiting plate; 3. a screening assembly; 31. a screening machine frame; 32. a crankshaft; 33. a drive motor; 34. screening the screen plate; 35. receiving the loop bar; 36. a second bearing plate; 37. a first discharging groove; 38. a second discharging groove; 4. a first collection box; 5. a second collection box.

Detailed Description

The present application will be described in further detail with reference to the following drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the relevant invention and not restrictive of the invention. It should be noted that, for convenience of description, only the portions related to the present invention are shown in the drawings.

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. The present application will be described in detail below with reference to the embodiments with reference to the attached drawings.

Referring to fig. 1 and fig. 2, a schematic diagram of a high-efficiency screening mechanism for a glass bead production line provided in this embodiment includes:

screening the case 1; a sliding through hole is formed in the side wall of the screening machine case 1;

the screening machine frame 31 is fixedly arranged on the inner side wall of the screening machine case 1;

the screen assemblies 3 are mounted on the screen frame 31 and can slide relatively; a first discharging chute 37 is connected to one end of the screen assembly 3; the first material discharging groove 37 penetrates through the sliding through hole and can slide in the sliding through hole;

a first collecting box 4, said first collecting box 4 being mounted outside said screening chassis 1 and below said first chute 37;

a second collection box 5, said second collection box 5 being mounted inside the screen box 1 and below the screen assemblies 3;

vibrator, vibrator fixed mounting be in screening machine incasement 1, vibrator's drive end with the one end of screening subassembly 3 is rotated and is connected, is used for driving screening subassembly 3 vibrations.

Specifically, glass beads are poured into the screening machine case 1, and the glass beads with small particle size pass through the filtering holes of the screened components and fall into the second collecting box 5; glass particles having a large particle size are accumulated in the filter holes of the screen assemblies 3. At this moment, the vibration device is started, and the vibration device drives the screening component 3 to reciprocate to generate vibration so as to drive the first discharging groove 37 to relatively slide in the sliding through hole. Large sized glass particles may be separated from the screen assemblies 3 by vibration and fall through the first chute 37 into the first collection box 4. The glass beads with large particle sizes can be prevented from being accumulated, the glass beads with large particle sizes can be completely screened, and the screening efficiency is improved.

Further, referring to fig. 3, inside of screening machine case 1 and being located install limiting plate 2 above screening subassembly 3, be used for right screening subassembly 3 is spacing.

In some embodiments, two limiting plates 2 are arranged on the screening machine case 1 and used for limiting the screening assemblies 3, so that the damage of the whole structure due to over severe vibration is prevented, and the safety of the whole device is improved.

Further, a first bearing plate is installed in the screening machine box 1, the first bearing plate is located below the screening component 3, and a second discharging groove 38 is installed at one end of the first bearing plate; the upper surface of the first bearing plate is coplanar with the inner wall of the second blanking groove 38.

In some embodiments, the first receiving plate located below the screening component 3 is installed in the screening machine case 1, and can play a role in receiving small-size glass beads, so that the small-size glass beads falling to too high heights are prevented from falling into gaps of the device.

Further, the height of the first receiving plate on the side close to the second discharging chute 38 is lower than the height of the first receiving plate on the side far from the second discharging chute 38.

In some embodiments, the height of the first receiving plate is lower on the side close to the second chute 38 than on the side far from the second chute 38; the small-sized glass beads are conveniently gathered and fall into the second collection box 5.

Further, with reference to fig. 4, the screen assemblies 3 comprise:

the screen separating plate 34 is positioned above the first bearing plate, the screen separating plate 34 is provided with filtering holes, and the radius of the filtering holes is larger than that of the glass microspheres with small granularity and smaller than that of the glass microspheres with large granularity;

one end of the second bearing plate 36 is fixedly connected with the screen separating plate 34, and the other end of the second bearing plate 36 is fixedly connected with the first discharging groove 37; the upper surface of the second bearing plate 36 is coplanar with the inner wall of the first discharging groove 37;

and the bearing sleeve rod 35 is arranged at one end, far away from the second bearing plate 36, of the screen separating plate 34, and the bearing sleeve rod 35 is rotationally connected with the driving end of the vibration device.

Specifically, the driving end of the vibration device is rotatably connected with the bearing sleeve rod 35, and when the vibration device vibrates, the bearing sleeve rod 35 drives the screen separation plate 34 and the second bearing plate 36 to vibrate, so that the glass beads with large granularity are vibrated away from the filter holes. The glass particles with large particle size enter the first discharging groove 37 through the upper surface of the second receiving plate 36 and fall into the first collecting box 4. The screening of the glass beads with large particle sizes can be realized, the glass beads with large particle sizes are prevented from being accumulated on the screening net plate 34, and the screening efficiency is improved.

Further, the height of one end of the second bearing plate 36 close to the first discharging groove 37 is lower than that of the screen plate 34.

In some embodiments, the height of the second receiving plate 36 near the first discharging chute 37 is lower than the height of the screen plate 34; the glass beads with large particle size can fall into the first collecting box 4 through the first discharging groove 37 along with the vibration of the screen plate 34 and the second receiving plate 36, so that the collection of the glass beads with large particle size is facilitated.

Further, referring to fig. 5, the vibration device includes:

the driving motor 33, the driving motor 33 is fixedly installed in the screening machine box 1;

one end of the crankshaft 32 is fixedly connected with the driving end of the driving motor 33, and the other end of the crankshaft 32 is rotatably connected with the side wall of the screening machine box 1; the crankshaft 32 is provided with a connecting rod journal which is parallel to the axis and is not coincident with the axis, and the bearing sleeve rod 35 is sleeved on the connecting rod journal and can be driven by the driving end to rotate relatively.

Specifically, the receiving sleeve rod 35 is sleeved on the connecting rod journal, and when the crankshaft 32 is driven by the driving motor 33 to rotate along the axis, the connecting rod journal can move around the axis of the crankshaft 32, so as to drive the receiving sleeve rod 35 to reciprocate to generate vibration. The screen plate 34 can be vibrated to separate the large-sized glass beads from the filtering holes.

In some embodiments, two connecting rod journals are disposed on the crankshaft 32, and two receiving rods 35 are disposed and respectively sleeved on the two connecting rod journals; when the driving motor 33 is started to drive the crankshaft 32 to rotate along the axis, the two receiving loop bars 35 vibrate under the driving of the two connecting rod journals. The two receiving rods 35 are arranged so that the screen plates 34 do not slide relative to each other in the axial direction of the crankshaft 32 during vibration.

The working process is as follows:

1. the driving motor 33 is started, the crankshaft 32 is driven by the driving motor 33 to rotate along an axis, the connecting rod journal rotates around the axis, and the bearing sleeve rod 35 sleeved on the connecting rod journal vibrates under the driving of the connecting rod journal, so as to drive the screen separating plate 34 to vibrate.

2. Pouring the glass beads into screening machine case 1, the glass beads of small particle size pass through earlier the filtration hole of screening otter board 34 falls into first accepting the board, pass through again second unloading groove 38 falls into the second is collected the box.

3. The glass beads with large particle size are separated from the filtering holes under the action of vibration and then fall into the first collecting box 4 through the second bearing plate 36 and the first discharging groove 37 in sequence.

The above description is only a preferred embodiment of the application and is illustrative of the principles of the technology employed. It will be appreciated by a person skilled in the art that the scope of the invention according to the present application is not limited to the specific combination of the above-mentioned features, but also covers other embodiments where any combination of the above-mentioned features or their equivalents is made without departing from the inventive concept. For example, the above features may be replaced with (but not limited to) features having similar functions disclosed in the present application.

Claims (7)

1. The utility model provides a high efficiency divides sieve mechanism for glass bead production line which characterized in that includes:

a screening machine box (1); the side wall of the screening machine box (1) is provided with a sliding through hole;

the screening machine frame (31), the screening machine frame (31) is fixedly installed on the inner side wall of the screening machine box (1);

the screen assemblies (3) are mounted on the screen frame (31) and can slide relatively; one end of the screening assembly (3) is connected with a first discharging groove (37); the first blanking groove (37) penetrates through the sliding through hole and can slide in the sliding through hole;

a first collection box (4), said first collection box (4) being mounted outside said screening chassis (1) and below said first chute (37);

-a second collection box (5), said second collection box (5) being mounted inside said screen box (1) and below said screen assemblies (3);

the vibrating device is fixedly installed in the screening machine case (1), and a driving end of the vibrating device is connected with one end of the screening component (3) in a rotating mode and used for driving the screening component (3) to vibrate.

2. The efficient screening mechanism for the glass bead production line as claimed in claim 1, wherein a limiting plate (2) is installed inside the screening machine case (1) and above the screening assembly (3) and used for limiting the screening assembly (3).

3. The high-efficiency screening mechanism for the glass bead production line as claimed in claim 1, wherein a first receiving plate is installed in the screening machine case (1), the first receiving plate is located below the screening assembly (3), and a second discharging groove (38) is installed at one end of the first receiving plate; the upper surface of the first bearing plate is coplanar with the inner wall of the second discharging groove (38).

4. The high efficiency screening mechanism for a glass bead production line as claimed in claim 3, wherein the height of the side of the first receiving plate close to the second blanking groove (38) is lower than the height of the side far away from the second blanking groove (38).

5. A high efficiency screening mechanism for a glass bead production line as claimed in claim 3, wherein said screen assembly (3) includes:

the screen separating plate (34) is positioned above the first bearing plate, the screen separating plate (34) is provided with filtering holes, and the radius of each filtering hole is larger than that of the small-granularity glass beads and smaller than that of the large-granularity glass beads;

one end of the second bearing plate (36) is fixedly connected with the screen separating plate (34), and the other end of the second bearing plate (36) is fixedly connected with the first discharging groove (37); the upper surface of the second bearing plate (36) is coplanar with the inner wall of the first discharging groove (37);

accept loop bar (35), accept loop bar (35) and install divide sieve net board (34) to keep away from the second accepts the one end of board (36) and with vibrator's drive end rotates and is connected.

6. The high-efficiency screening mechanism for a glass bead production line as claimed in claim 5, wherein the height of one end of the second receiving plate (36) close to the first discharging groove (37) is lower than the height of the screen plate (34).

7. The efficient screening mechanism for a glass bead production line as recited in claim 5, wherein said vibrating device comprises:

the driving motor (33), the driving motor (33) is fixedly installed in the screening machine box (1);

one end of the crankshaft (32) is fixedly connected with the driving end of the driving motor (33), and the other end of the crankshaft (32) is rotatably connected with the side wall of the screening machine box (1); the crankshaft (32) is provided with a connecting rod journal which is parallel to the axis and is not coincident with the axis, and the bearing sleeve rod (35) is sleeved on the connecting rod journal and can rotate relatively under the driving of the driving end.

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