CN215141898U - Continuous flow production device for preparing composite nano-pore material - Google Patents

Abstract

The utility model discloses a preparation of compound nanopore material is with continuous flow apparatus for producing, including the bottom plate, still include screening mechanism and lubricated mechanism in advance, screening mechanism specifically comprises L shape connecting rod, splint, rubber pad, feeder hopper, screw thread frame, filtration otter board, rotatory strip and vibrating motor in advance, feeder hopper inside wall fixedly connected with screw thread frame, screw thread frame inside wall threaded connection has the filtration otter board, filter the rotatory strip of otter board upper end fixedly connected with, feeder hopper lower extreme fixedly connected with splint. This preparation of compound nanopore material falls on filtering the otter board after the raw materials gets into the feeder hopper with continuous flow apparatus for producing, work behind the vibrating motor switch on, vibrating motor drives the feeder hopper vibration of top, and L shape connecting rod joint cooperates the vibration in the rubber pad of splint inboard, drives filtering the otter board then and carries out the vibration screening, filters the otter board and sieves upper raw materials, and the raw materials after the screening filtration impurity flows through the discharge gate of feeder hopper.

Description

Continuous flow production device for preparing composite nano-pore material

Technical Field

The utility model relates to a compound nanopore material preparation technical field, in particular to compound nanopore material preparation is with continuous flow apparatus for producing.

Background

Composite nanomaterials are nanoparticle systems consisting of two or more components with distinct physicochemical properties, the components having an interface between them.

Patent No. CN201510017359.4 discloses a method for preparing a nanocomposite mesoporous material. The method comprises the steps of preparing graphite oxide, loading hollow iron oxide nanoparticles on the surface of a graphene sheet layer by a solvothermal method, coating polyaniline on the surface of the graphene sheet layer loaded with hollow nano ferroferric oxide to prepare a graphene/hollow ferroferric oxide/polyaniline nano composite material, and finally preparing the mesoporous material by high-temperature carbonization treatment. The method is convenient and fast, and the material can be used as an electromagnetic wave absorbing material and an environment adsorbing material.

The composite nano-pore material has the following disadvantages in preparation: 1. the raw materials for manufacturing the composite nano-pore material during preparation can be mixed with larger granular impurities, so that the quality of subsequent finished products is influenced; 2. the composite nano-porous material is conveyed by a flow conveying belt in the preparation process, but a transmission roller shaft is frequently abraded in the transmission process. Therefore, we propose a continuous flow production device for preparing composite nano-porous materials.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a main purpose is providing a continuous flow apparatus for producing is used in preparation of compound nanopore material, the raw materials falls on filtering the otter board after getting into the feeder hopper, work behind the vibrating motor switch on, vibrating motor drives the feeder hopper vibration of top, L shape connecting rod joint cooperates the vibration in the inboard rubber pad of splint, then drive and filter the otter board and carry out vibration screening, filter the otter board and sieve the upper raw materials, the raw materials after sieving and filtering impurity flows through the discharge gate of feeder hopper, can effectively solve the problem in the background art.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a continuous flow production device for preparing composite nano-pore materials comprises a bottom plate, a pre-screening mechanism and a lubricating mechanism, the pre-screening mechanism is composed of an L-shaped connecting rod, a clamping plate, a rubber pad, a feed hopper, a thread frame, a filter screen plate, a rotating strip and a vibrating motor, the inner side wall of the feed hopper is fixedly connected with a threaded frame, the inner side wall of the threaded frame is in threaded connection with a filter screen plate, the upper end of the filter screen plate is fixedly connected with a rotating strip, the lower end of the feed hopper is fixedly connected with a clamping plate, rubber pads are bonded on the inner surface of the clamping plate, the L-shaped connecting rods are clamped between the rubber pads, the lower ends of the L-shaped connecting rods are respectively and fixedly connected with a side edge plate A and a side edge plate B, vibrating motor is installed to the feeder hopper bottom, lubricated mechanism specifically comprises lubricated collets A, lubricated collets B and notes oil pipe.

Furthermore, the upper end of the bottom plate is fixedly connected with a side plate A and a side plate B, a driving motor is installed on the outer side wall of the side plate A, and the power output end of the driving motor is connected with the power input end of the transmission shaft; the driving motor works after being connected with an external power supply, and then the driving motor drives the transmission shaft to rotate.

Further, the outer side wall of the transmission shaft is fixedly connected with a transmission roller, and the outer surface of the transmission roller is in transmission connection with a transmission belt; the transmission roller is driven to rotate through the transmission shaft, and the transmission roller drives the transmission belt to transmit and feed materials.

Furthermore, a lubricating sleeve block A is embedded and connected on the side edge plate A, a lubricating sleeve block B is embedded and connected on the side edge plate B, and the inner side walls of the lubricating sleeve block A and the lubricating sleeve block B are rotatably connected with a transmission shaft; the transmission shaft rotates along the inner walls of the lubricating sleeve block A and the lubricating sleeve block B and is in matched transmission.

Furthermore, oil injection pipes are clamped and embedded in the inner side walls of the side plate A and the side plate B and are inserted into the lubricating sleeve block A and the lubricating sleeve block B; lubricating oil is injected into the lubricating sleeve block A and the lubricating sleeve block B through the oil injection pipe, and flows between the lubricating sleeve block and the transmission shaft, so that the purpose of lubricating and reducing wear is achieved.

Compared with the prior art, the utility model has the following beneficial effects of 1, through adding the pre-screening mechanism, the pre-screening mechanism is specifically composed of an L-shaped connecting rod, a clamping plate, a rubber pad, a feeding hopper, a thread frame, a filter screen plate, a rotating strip and a vibrating motor, the raw material falls on the filter screen plate after entering the feeding hopper, the vibrating motor works after being powered on, the vibrating motor drives the feeding hopper above to vibrate, the L-shaped connecting rod is clamped in the rubber pad at the inner side of the clamping plate to cooperate with vibration, then the filter screen plate is driven to carry out vibration screening, the filter screen plate screens the upper raw material, the raw material after screening and filtering impurities flows out through a discharge port of the feeding hopper, and is conveyed through a conveying mechanism below under the guidance of a guide sliding plate; 2. work behind the driving motor switch-on external power source, then driving motor drives the transmission shaft and rotates, it is rotatory to drive the driving roller through the transmission shaft, the driving roller drives the transmission band and transmits the pay-off, the transmission shaft rotates along lubricated cover block A and lubricated cover block B inner wall, the cooperation transmission, through annotating oil pipe to lubricated cover block A and the inside lubricating oil that pours into of lubricated cover block B, lubricating oil flows between lubricated cover block and transmission shaft, reach lubricated reducing wear's purpose then.

Drawings

Fig. 1 is a schematic view of the whole structure of the continuous flow production device for preparing the composite nano-porous material.

Fig. 2 is a schematic view of the cross-sectional structure of the continuous flow production apparatus for preparing composite nano-porous material of the present invention.

Fig. 3 is a schematic structural diagram of a position a of the continuous flow production apparatus for preparing a composite nano-porous material of the present invention.

In the figure: 1. a base plate; 2. a side plate A; 3. an L-shaped connecting rod; 4. a splint; 5. a rubber pad; 6. a feed hopper; 7. a side plate B; 8. a thread frame; 9. a filter screen plate; 10. Rotating the strip; 11. a vibration motor; 12. a drive motor; 13. a conveyor belt; 14. a drive shaft; 15. lubricating a sleeve block A; 16. lubricating a sleeve block B; 17. a driving roller; 18. an oil filling pipe; 19. a pre-screening mechanism; 20. and a lubricating mechanism.

Detailed Description

In order to make the technical means, creation features, achievement purposes and functions of the present invention easy to understand, the present invention is further described below with reference to the following embodiments.

As shown in fig. 1-3, a continuous flow production device for preparing a composite nanopore material, comprises a bottom plate 1, a pre-screening mechanism 19 and a lubricating mechanism 20, wherein the pre-screening mechanism 19 comprises an L-shaped connecting rod 3, a clamping plate 4, a rubber pad 5, a feeding hopper 6, a threaded frame 8, a filter screen plate 9, a rotating strip 10 and a vibrating motor 11, the threaded frame 8 is fixedly connected to the inner side wall of the feeding hopper 6, the filter screen plate 9 is in threaded connection with the inner side wall of the threaded frame 8, the rotating strip 10 is fixedly connected to the upper end of the filter screen plate 9, the clamping plate 4 is fixedly connected to the lower end of the feeding hopper 6, the rubber pad 5 is bonded to the inner surface of the clamping plate 4, the L-shaped connecting rod 3 is clamped between the rubber pads 5, the L-shaped connecting rod 3 comprises two L-shaped connecting rods 3, the lower ends of the L-shaped connecting rods 3 are respectively and fixedly connected with a side plate a2 and a side plate B7, the vibrating motor 11 is installed at the bottom of the feeding hopper 6, the lubricating mechanism 20 is composed of a lubricating sleeve block A15, a lubricating sleeve block B16 and an oil filling pipe 18.

The upper end of the bottom plate 1 is fixedly connected with a side plate A2 and a side plate B7, a driving motor 12 is installed on the outer side wall of the side plate A2, and the power output end of the driving motor 12 is connected with the power input end of a transmission shaft 14; the driving motor 12 is powered on and then works, and then the driving motor 12 drives the transmission shaft 14 to rotate.

The outer side wall of the transmission shaft 14 is fixedly connected with a transmission roller 17, and the outer surface of the transmission roller 17 is in transmission connection with a transmission belt 13; the transmission shaft 14 drives the transmission roller 17 to rotate, and the transmission roller 17 drives the transmission belt 13 to transmit and feed materials.

The side plate A2 is connected with a lubricating sleeve block A15 in an embedded mode, the side plate B7 is connected with a lubricating sleeve block B16 in an embedded mode, and the inner side walls of the lubricating sleeve block A15 and the lubricating sleeve block B16 are rotatably connected with a transmission shaft 14; the transmission shaft 14 rotates along the inner walls of the lubricating sleeve block A15 and the lubricating sleeve block B16, and is matched for transmission.

The lubricating device comprises a lubricating sleeve block A15, a lubricating sleeve block B16, a side edge plate A2, a side edge plate B7 and a lubricating oil pipe 18, wherein the lubricating oil pipe 18 is embedded in the inner side walls of the side edge plate A2 and the side edge plate B7 in a clamping mode; lubricating oil is injected into the lubricating sleeve block A15 and the lubricating sleeve block B16 through the oil injection pipe 18, and flows between the lubricating sleeve block and the transmission shaft 14, so that the aims of lubricating and reducing wear are fulfilled.

It should be noted that, the utility model relates to a continuous flow production device for preparing composite nanopore material, in operation, through adding pre-screening mechanism 19, pre-screening mechanism 19 specifically comprises L-shaped connecting rod 3, splint 4, rubber pad 5, feeder hopper 6, screw frame 8, filter screen plate 9, rotating strip 10 and vibrating motor 11, the raw material falls on filter screen plate 9 after entering feeder hopper 6, vibrating motor 11 works after switching on the power supply, vibrating motor 11 drives feeder hopper 6 above to vibrate, L-shaped connecting rod 3 joint cooperates the vibration in rubber pad 5 of splint 4 inboard, then drive filter screen plate 9 to carry out the vibration screening, filter screen plate 9 screens the upper raw material, the raw material after screening and filtering impurity flows out through the discharge gate of feeder hopper 6, fall into the transport mechanism below through the guide slide guide and transport; work behind the driving motor 12 switch-on external power source, then driving motor 12 drives transmission shaft 14 and rotates, it is rotatory to drive driving roller 17 through transmission shaft 14, driving roller 17 drives transmission band 13 and transmits the pay-off, transmission shaft 14 rotates along lubricated nest block A15 and lubricated nest block B16 inner wall, the cooperation transmission, through oiling pipe 18 to lubricated nest block A15 and the inside lubricating oil that pours into of lubricated nest block B16, lubricating oil flows between lubricated nest block and transmission shaft 14, then reach lubricated mesh that reduces wearing and tearing.

The basic principles and the main features of the invention and the advantages of the invention have been shown and described above. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (5)

1. A continuous flow production device for preparing composite nano-porous materials comprises a bottom plate (1), and is characterized in that: the screening device is characterized by further comprising a pre-screening mechanism (19) and a lubricating mechanism (20), wherein the pre-screening mechanism (19) is composed of an L-shaped connecting rod (3), clamping plates (4), rubber pads (5), a feeding hopper (6), a threaded frame (8), a filtering screen plate (9), a rotating strip (10) and a vibrating motor (11), the threaded frame (8) is fixedly connected to the inner side wall of the feeding hopper (6), the filtering screen plate (9) is connected to the inner side wall of the threaded frame (8) in a threaded manner, the rotating strip (10) is fixedly connected to the upper end of the filtering screen plate (9), the clamping plates (4) are fixedly connected to the lower end of the feeding hopper (6), the rubber pads (5) are bonded to the inner surface of the clamping plates (4), the L-shaped connecting rod (3) is clamped between the rubber pads (5), the L-shaped connecting rod (3) is specifically provided with two L-shaped connecting rods (3), and the lower end of the L-shaped connecting rod (3) is fixedly connected with a side plate A (2) and a side plate B (7) respectively, vibrating motor (11) are installed to feeder hopper (6) bottom, lubricated mechanism (20) specifically comprise lubricated collets A (15), lubricated collets B (16) and oiling pipe (18).

2. The continuous flow production apparatus for the preparation of composite nanoporous material as defined in claim 1, wherein: bottom plate (1) upper end and side board A (2) and side board B (7) fixed connection, driving motor (12) are installed to side board A (2) lateral wall, the power take off of driving motor (12) is connected with the power input of transmission shaft (14).

3. The continuous flow production apparatus for the preparation of composite nanoporous material as defined in claim 2, wherein: the outer side wall of the transmission shaft (14) is fixedly connected with a transmission roller (17), and the outer surface of the transmission roller (17) is in transmission connection with a transmission belt (13).

4. The continuous flow production apparatus for the preparation of composite nanoporous material as defined in claim 1, wherein: the side plate A (2) is connected with a lubricating sleeve block A (15) in an embedded mode, the side plate B (7) is connected with a lubricating sleeve block B (16) in an embedded mode, and the inner side walls of the lubricating sleeve block A (15) and the lubricating sleeve block B (16) are rotatably connected with a transmission shaft (14).

5. The continuous flow production apparatus for the preparation of composite nanoporous material as defined in claim 1, wherein: and oil injection pipes (18) are embedded in the inner side walls of the side plate A (2) and the side plate B (7) in a clamping manner, and the oil injection pipes (18) are inserted into the lubricating sleeve blocks A (15) and the lubricating sleeve blocks B (16).

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