CN216442874U

CN216442874U - Environment-friendly elastic injection molding material screening mechanism

Info

Publication number: CN216442874U
Application number: CN202122721971.3U
Authority: CN
Inventors: 杨君平
Original assignee: Qingdao Haoke Plastic Products Co ltd
Current assignee: Qingdao Haoke Plastic Products Co ltd
Priority date: 2021-11-09
Filing date: 2021-11-09
Publication date: 2022-05-06
Anticipated expiration: 2031-11-09

Abstract

The utility model provides an environment-friendly elastic injection molding material screening mechanism, which comprises: the vibration-damping device comprises a top frame, a feed inlet, an enclosure shell, a machine body, a discharge port, a shell, a vibration motor, a sliding chute, a sliding block, a connecting column, a hopper, a resonance column, a limiting block, a connecting plate, a baffle, a hopper dam, a spacer block, a feeding groove, a screening material clamp, a screening material groove, a blanking plate, a vibration-damping column and a base, wherein the feed inlet is formed in the inner side of the top frame, the enclosure shell is installed on the lower end face of the top frame, the vibration motor is installed on the left side of the upper end of the inner side of the shell, the connecting column is installed on the lower end face of the vibration motor, and the sliding block is installed on the left end face of the connecting column. The vibration slow release can be carried out on the lower end of the machine body by using the shock absorption column, and the injection molding material can be screened by using the hopper and the vibration motor, so that the screening effect of the utility model is improved.

Description

Environment-friendly elastic injection molding material screening mechanism

Technical Field

The utility model belongs to the technical field of injection molding materials, relates to an injection molding material screening device, and particularly relates to an environment-friendly elastic injection molding material screening mechanism.

Background

Screening is a method for separating particle groups according to the particle size, specific gravity, electric charge, magnetism and other powder properties, and the operation of dividing mixed materials with different particle sizes into various particle size grades by using a screen surface with holes is called screening.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects in the prior art, the utility model aims to provide an environment-friendly elastic injection molding material screening mechanism, which solves the problems in the background technology.

The utility model is realized by the following technical scheme: the utility model provides an environmental protection elasticity injection molding material screening mechanism, includes: the shock absorber comprises a top frame, a feed inlet, an enclosure shell, a machine body, a discharge port, a blanking plate, a shock absorbing column and a base, wherein the feed inlet is formed in the inner side of the top frame;

the machine body comprises a shell, a vibration motor, a chute, a sliding block, a connecting column, a hopper, a resonance column, a limiting block, a connecting plate, a baffle, a hopper dam, spacing blocks, a feeding groove, a screening card and a screening groove, wherein the vibration motor is installed on the left side of the upper end of the inner side of the shell, the connecting column is installed on the lower end face of the vibration motor, the sliding block is installed on the left end face of the connecting column, the chute is arranged on the left end face of the sliding block, the hopper is installed on the right end face of the connecting column, the limiting blocks are installed on the upper side and the lower side of the right end face of the hopper, the resonance column is installed on the left side of the limiting block on the upper end, the connecting plate is installed on the lower end face of the left side of the hopper, the hopper dam is installed on the right side of the lower end face of the hopper dam, the feeding groove is arranged between every two groups of the spacing blocks, and the screening card is installed in the middle position inside the feeding groove, and a screening trough is formed in the upper end face of the feeding trough.

In a preferred embodiment, the top frame is made of rubber material in actual use, the top frame is fixedly connected with the enclosure shell in actual use, the enclosure shell is made of metal material in actual use, and the cross section of the enclosure shell is in a trapezoidal structure in actual use.

As a preferred embodiment, the cross section of the feeding port is rectangular in practical use, the feeding port is communicated with the inside of the machine body in practical use, the upper end of the machine body is provided with a blanking groove in practical use, the cross section area of the feeding port is smaller than that of the blanking groove in practical use, and the cross sections of the feeding port and the blanking groove are the same in shape in practical use.

As a preferred embodiment, three groups of the discharge ports and the blanking plate are arranged in actual use, the three groups of the discharge ports and the blanking plate are respectively identical in actual use, the cross section of the discharge port is of a rectangular structure in actual use, and the width of the cross section of the discharge port is smaller than that of the blanking plate in actual use.

As a preferred embodiment, three groups of hoppers are installed in actual use, the specifications of the three groups of hoppers in actual use are the same, a group of connecting columns, a group of sliding blocks and a group of sliding grooves are installed on the left side of each group of hoppers in actual use, a slow release component is installed on the lower end face of each connecting column in actual use, and a spring and a lower support arm are installed inside each slow release component in actual use.

As a preferred embodiment, the diameters of the cross sections of the feeding grooves in the three groups of hoppers are reduced from top to bottom in actual use, the inner part of the bottommost hopper is of a planar structure in actual use, the cross section of the hopper dam is of a right-angled trapezoid structure in actual use, and the limiting blocks are fixedly connected with the shell and the hoppers in actual use.

After the technical scheme is adopted, the utility model has the beneficial effects that: the vibration slow release can be carried out on the lower end of the machine body by using the shock absorption column, and the injection molding material can be screened by using the hopper and the vibration motor, so that the screening effect of the utility model is improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic structural view of an environmentally friendly elastic injection molding material screening mechanism according to the present invention;

FIG. 2 is a front sectional view of the machine body of the sieving mechanism for environmental protection elastic injection molding material of the present invention;

FIG. 3 is a right sectional view of a hopper of the sieving mechanism for environmental protection elastic injection molding material according to the present invention;

in the figure: 1-top frame, 2-feed inlet, 3-enclosure, 4-machine body, 5-discharge outlet, 6-blanking plate, 7-shock-absorbing column, 8-base, 41-shell, 42-vibration motor, 43-chute, 44-slide block, 45-connecting column, 46-hopper, 47-resonance column, 48-limiting block, 49-connecting plate, 461-baffle, 462-hopper dam, 463-spacing block, 464-feeding groove, 465-screening card and 466-screening groove.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-3, an environmentally friendly elastic plastic material sieving mechanism includes: the device comprises a top frame 1, a feed inlet 2, an enclosure shell 3, a machine body 4, a discharge outlet 5, a blanking plate 6, a shock absorption column 7 and a base 8, wherein the feed inlet 2 is formed in the inner side of the top frame 1, the enclosure shell 3 is installed on the lower end face of the top frame 1, the machine body 4 is installed on the lower end face of the enclosure shell 3, the discharge outlet 5 is formed in the right end face of the machine body 4, the blanking plate 6 is installed on the right end face of the discharge outlet 5, the shock absorption column 7 is installed on the lower end face of the machine body 4, and the base 8 is installed on the lower end face of the shock absorption column 7;

the machine body 4 comprises a shell 41, a vibration motor 42, a chute 43, a sliding block 44, a connecting column 45, a hopper 46, a resonance column 47, a limiting block 48, a connecting plate 49, a baffle 461, a hopper dam 462, a separating block 463, a feeding groove 464, a screening card 465 and a screening groove 466, wherein the left side of the upper end of the inner side of the shell 41 is provided with the vibration motor 42, the lower end surface of the vibration motor 42 is provided with the connecting column 45, the left end surface of the connecting column 45 is provided with the sliding block 44, the left end surface of the sliding block 44 is provided with the chute 43, the right end surface of the connecting column 45 is provided with the hopper 46, the upper side and the lower side of the right end surface of the hopper 46 are provided with the limiting blocks 48, the left side of the upper limiting block 48 is provided with the resonance column 47, the lower end of the left side of the hopper 46 is provided with the connecting plate 49, the upper side of the hopper 46 is provided with the baffle 461, the lower end surface of the hopper dam 462 is provided with a plurality of groups of separating blocks 463, and the feeding groove 464 is arranged between each two groups of separating blocks 463, a material screening clamp 465 is arranged in the middle of the inner part of the feeding groove 464, and a material screening groove 466 is formed in the upper end face of the feeding groove 464.

Top frame 1 is made for rubber materials in actual use, and top frame 1 is connected fixedly between actual use and enclosing shell 3, and enclosing shell 3 is made for metal materials in actual use, and 3 cross sections of enclosing shell are the trapezium structure in actual use, can make the outside machine of injecting the injection molding material keep inside seal with top frame 1.

The cross section of the feed inlet 2 is of a rectangular structure in actual use, the feed inlet 2 is communicated with the interior of the machine body 4 in actual use, the upper end of the machine body 4 is provided with the lower trough in actual use, the cross section area of the feed inlet 2 is smaller than that of the lower trough in actual use, the shape of the feed inlet 2 is the same as that of the cross section of the lower trough in actual use, and injection molding materials can be conveniently fed into the machine body 4.

Three groups of discharge ports 5 and blanking plates 6 are arranged in actual use, the three groups of discharge ports 5 and the blanking plates 6 are respectively identical in actual use, the cross section of each discharge port 5 is of a rectangular structure in actual use, the width of the cross section of each discharge port 5 is smaller than that of each blanking plate 6 in actual use, and the injection molding materials can be conveniently discharged after being screened.

Three groups of hoppers 46 are installed in actual use, the specifications of the three groups of hoppers 46 are the same in actual use, a group of connecting columns 45, a group of sliders 44 and a group of chutes 43 are installed on the left side of each group of hoppers 46 in actual use, a slow release component is installed on the lower end face of each connecting column 45 in actual use, a spring and a lower supporting arm are installed inside the slow release component in actual use, and injection molding materials can be conveniently screened.

The diameters of the cross sections of the feeding grooves 464 in the three groups of hoppers 46 are reduced from top to bottom in actual use, the inner part of the bottommost hopper 46 is of a planar structure in actual use, the cross section of the hopper dam 462 is of a right-angled trapezoid structure in actual use, and the limiting block 48 is fixedly connected with the shell 41 and the hoppers 46 in actual use, so that injection plastic splashing can be prevented in the screening process.

As an embodiment of the present invention: in the actual use, the worker leads the external injection molding material into the feed port 2, so that the injection molding material enters from the feed port 2, the feed port 2 is communicated with the inside of the machine body 4 in the actual use, the upper end of the machine body 4 is provided with a blanking groove in the actual use, the cross section area of the feed port 2 is smaller than that of the blanking groove in the actual use, the cross sections of the feed port 2 and the blanking groove are the same in shape in the actual use, the injection molding material rapidly enters the inside of the machine body 4 through the feed port 2 and falls into a screening groove 466 in the hopper 46 at the uppermost layer, the vibration motor 42 is started, the vibration motor 42 drives the connecting column 45 to vibrate, the connecting column 45 drives the hopper 46 at the uppermost layer to vibrate and screen the material, in the screening process, the connecting column 45 drives the sliding block 44 to move in the sliding groove 43, so that the left side of the hopper 46 can integrally vibrate and screen the material, and meanwhile, the slow release component is installed on the lower end face of the connecting column 45 in the actual use, the spring and the lower supporting arm are arranged in the slow-release component in the actual use, the reaction force can be effectively resisted in the material sieving process, the vibration supporting force of the connecting column 45 is reduced, meanwhile, the resonance column 47 effectively conducts the vibration on the left side of the hopper 46, so that the left side and the right side of the hopper 46 uniformly vibrate and screen materials, when the injection molding material is screened out, the limiting block 48 keeps the right side of the hopper 46 static to prevent the injection molding material from spurting out from the discharge port 5, and when the upper end hopper 46 vibrates, drive other hopper 46 vibrations through connecting plate 49, and because the inside pan feeding groove 464 of three group's hoppers 46 reduces in proper order cross section diameter from the top down in the in-service use, the bottom hopper 46 is inside to be planar structure in the in-service use, can classify and sieve to injection molding material diameter size, and the injection molding material gets into inside the back of pan feeding groove 464, can fall into lower extreme hopper 46 through sieve material card 465 in order inside.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims

1. The utility model provides an environmental protection elasticity injection molding material screening mechanism, includes: top frame (1), feed inlet (2), enclose shell (3), organism (4), discharge gate (5), blanking plate (6), shock absorber post (7) and base (8), its characterized in that: a feeding hole (2) is formed in the inner side of the top frame (1), an enclosure shell (3) is mounted on the lower end face of the top frame (1), a machine body (4) is mounted on the lower end face of the enclosure shell (3), a discharging hole (5) is formed in the right end face of the machine body (4), a blanking plate (6) is mounted on the right end face of the discharging hole (5), a shock absorption column (7) is mounted on the lower end face of the machine body (4), and a base (8) is mounted on the lower end face of the shock absorption column (7);

the machine body (4) comprises a shell (41), a vibration motor (42), a sliding groove (43), a sliding block (44), a connecting column (45), a hopper (46), a resonance column (47), a limiting block (48), a connecting plate (49), a baffle (461), a hopper dam (462), a separating block (463), a feeding groove (464), a screening card (465) and a screening groove (466), wherein the vibration motor (42) is installed on the left side of the upper end of the inner side of the shell (41), the connecting column (45) is installed on the lower end face of the vibration motor (42), the sliding block (44) is installed on the left end face of the connecting column (45), the sliding groove (43) is formed in the left end face of the sliding block (44), the hopper (46) is installed on the right end face of the connecting column (45), the limiting blocks (48) are installed on the upper and lower sides of the right end face of the hopper (46), and the resonance column (47) is installed on the left side of the upper limiting block (48), connecting plate (49) are installed to hopper (46) left side lower extreme, baffle (461) are installed to hopper (46) upside, fill dam (462) are installed to baffle (461) lower terminal surface, a plurality of groups of spacer blocks (463) are installed on fill dam (462) lower terminal surface right side, and per two sets of pan feeding groove (464) have been seted up between spacer block (463), sieve material card (465) are installed to the inside intermediate position of pan feeding groove (464), sieve material groove (466) have been seted up to pan feeding groove (464) upper end surface.

2. The environment-friendly elastic injection molding material screening mechanism of claim 1, characterized in that: the top frame (1) is made of rubber materials, the top frame (1) is fixedly connected with the enclosure shell (3), the enclosure shell (3) is made of metal materials, and the cross section of the enclosure shell (3) is of a trapezoidal structure.

3. The environment-friendly elastic injection molding material screening mechanism of claim 1, characterized in that: the cross section of the feed inlet (2) is of a rectangular structure, the feed inlet (2) is communicated with the inside of the machine body (4) in a mutual mode, the upper end of the machine body (4) is provided with a feed chute, the cross section area of the feed inlet (2) is smaller than that of the feed chute, and the cross section shape of the feed inlet (2) is the same as that of the feed chute.

4. The environment-friendly elastic injection molding material screening mechanism of claim 1, characterized in that: three groups of discharging ports (5) and three groups of blanking plates (6) are arranged, the three groups of discharging ports (5) and the three groups of blanking plates (6) are respectively identical, the cross section of each discharging port (5) is of a rectangular structure, and the width of the cross section of each discharging port (5) is smaller than that of each blanking plate (6).

5. The environment-friendly elastic injection molding material screening mechanism of claim 1, characterized in that: three groups are installed to hopper (46), and three hopper (46) specifications of group are the same, every group a set of spliced pole (45), a set of slider (44) and a set of spout (43) are all installed to hopper (46) left side, the terminal surface is installed to spliced pole (45) and is slowly-releasing parts, slowly-releasing parts internally mounted has spring and lower brace arm.

6. The environment-friendly elastic injection molding material screening mechanism of claim 1, characterized in that: the diameters of cross sections of feeding grooves (464) in the three groups of hoppers (46) are sequentially reduced from top to bottom, the bottoms of the feeding grooves are of a planar structure in the hoppers (46), the cross sections of the hopper dams (462) are of right-angle trapezoidal structures, and the limiting blocks (48) are fixedly connected with the shell (41) and the hoppers (46).