CN217988978U - Batch preparation equipment for production of carbon-based non-metal catalyst - Google Patents

Abstract

The utility model provides batch preparation equipment for producing carbon-based non-metal catalysts, which relates to the technical field of batch preparation equipment and comprises a bracket component and a mixing mechanism, wherein a shell component assembled by bolts is arranged on the top side of the bracket component, and a sleeved pressurizing mechanism is arranged on one side of the shell component; the utility model discloses mainly utilize to be the core technology with nitrogen doping carbon, carry out effectual production to carbon base non-metallic catalyst, through mass production carbon base non-metallic catalyst, possess good economic indicator, carbon base non-metallic catalyst's reaction conversion rate and selectivity can satisfy the requirement that the industrialization was used basically, possess good economy shape, and mercury resource crisis can effectively be alleviated in carbon base non-metallic catalyst's application, reduce the unfavorable meaningless waste of abandonment mercury resource recovery and all kinds of pollutions that mercury resource runs off and cause, and reduce the application cost of original catalyst, can bring good economic social.

Description

Batch preparation equipment for production of carbon-based non-metal catalyst

Technical Field

The utility model relates to a prepare equipment technical field in batches, especially relate to a production of carbon back non-metallic catalyst is with preparing equipment in batches.

Background

The mercury-free catalyst is used, so that the contact of a first-line operator to mercury is completely avoided, the mercury content in waste acid and waste gas in the production process is eliminated, the mercury pollution to plants, organisms and the environment is avoided, and the research on the nitrogen-doped carbon-represented nonmetal catalyst is expected to provide a mercury-free solution with low cost, environmental friendliness, high efficiency and stability for the PVC industry;

current batch preparation equipment is when using, and the majority is with the metal catalyst that production contains mercury, can produce more spent acid waste gas in putting into production, can cause serious pollution to the environment, and the cost of the catalyst that contains mercury is higher moreover, can cause the enterprise burden, consequently, the utility model provides a production of carbon base nonmetal catalyst is with batch preparation equipment is in order to solve the problem that exists among the prior art.

Disclosure of Invention

To the above problem, the utility model provides a carbon back non-metal catalyst production is with batch preparation equipment, this carbon back non-metal catalyst production is with batch preparation equipment mainly utilizes to carry out effectual production with nitrogen doping carbon as the core technology to carbon back non-metal catalyst, through mass production carbon back non-metal catalyst, good economic indicator is possessed, carbon back non-metal catalyst's reaction conversion rate and selectivity can satisfy the requirement that the industrialization was used basically, possess good economic shape, and mercury resource crisis can effectively be alleviated in carbon back non-metal catalyst's application, reduce the unfavorable waste of abandonment mercury resource recovery and all kinds of pollutions that mercury resource caused, and reduce the application cost of original catalyst, can bring good economic and social.

For realizing the purpose of the utility model, the utility model discloses a following technical scheme realizes: a batch preparation device for producing carbon-based non-metal catalysts comprises a support assembly and a mixing mechanism, wherein a shell component assembled by bolts is arranged on the top side of the support assembly, a sleeved pressurizing mechanism is arranged on one side of the shell component, a feeding component sleeved by bolts is arranged on the top side of the shell component, the mixing mechanism is arranged on the other side of the shell component, and a discharging component assembled by bolts is arranged on the upper bottom side of the support assembly;

mixing mechanism includes bearing frame, motor, rotary rod and mixed wheelset, the bearing frame cup joints the opposite side of casing component, the interior limit side of bearing frame is provided with the rotary rod of connecting the motor output, the inner outside of rotary rod is provided with multiunit parallel distribution's mixed wheelset.

The further improvement is that the mixed wheel set is in a wind wheel-shaped structure, and five groups are distributed in parallel on the mixed wheel set.

In a further improvement, the bracket assembly comprises a base, a lifting frame and an overhead plate, and the lifting frame connected with the overhead plate through bolts is arranged on the top side of the base.

The improved structure is characterized in that the shell component comprises a bolt plate bottom, an outer shell, an inner pad shell, an inner shell, a splicing frame, a heating ring and a top cover, the outer shell is connected with the top side of the top-mounted plate through a bolt plate bottom bolt, the inner side of the outer shell is provided with the inner pad shell which is attached to the inner side of the outer shell, the inner portion of the inner pad shell is provided with the inner shell which is distributed in the same ring, the splicing frame for installing the heating ring is arranged between the inner pad shell and the inner shell, and the top side of the outer shell is provided with the top cover.

The improvement is that the pressurizing mechanism comprises an inlet pipe, a one-way valve, a pressurizing gas pump, a gas pipe and an inert gas tank, wherein the inlet pipe is sleeved on one side of the outer shell, one end of the inlet pipe is sleeved with the one-way valve connected with the output end of the pressurizing gas pump, and the pressurizing gas pump is sleeved with the inert gas tank through the gas pipe.

The improved structure is characterized in that the feeding component comprises a feeding nozzle, two side valves, an air pump, a nitrogen tank, a powder pump and a carbon powder tank, the feeding nozzle is arranged on the top side of the top cover, the two ends of the feeding nozzle are provided with the two side valves, the two ends of the feeding nozzle are sleeved with the air pump, the two side valves of the powder pump are sleeved with the nitrogen tank, and the input end of the powder pump is sleeved with the carbon powder tank.

The improved structure is characterized in that the discharging component comprises a bolt disc seat, a flange sleeve, a valve pipe and a discharging hole, the bolt disc seat is arranged on the bottom side of the overhead disc, the valve pipe is sleeved below the bolt disc seat through a flange sleeve bolt, and the discharging hole is formed in the bottom side of the valve pipe.

The utility model has the advantages that:

the utility model discloses mainly utilize to be the core technology with nitrogen doping carbon, carry out effectual production to carbon base non-metallic catalyst, through mass production carbon base non-metallic catalyst, possess good economic indicator, carbon base non-metallic catalyst's reaction conversion rate and selectivity can satisfy the requirement that the industrialization was used basically, possess good economy shape, and mercury resource crisis can effectively be alleviated in carbon base non-metallic catalyst's application, reduce the unfavorable meaningless waste of abandonment mercury resource recovery and all kinds of pollutions that mercury resource runs off and cause, and reduce the application cost of original catalyst, can bring good economic social.

Drawings

Fig. 1 is a schematic perspective view of the present invention;

fig. 2 is a schematic bottom perspective view of the present invention;

FIG. 3 is a schematic view of a sectional three-dimensional structure of a shell member of the present invention;

fig. 4 is a schematic view of the three-dimensional structure of the plug-in frame and the heating ring of the present invention.

Wherein: 1. a bracket assembly; 101. a base; 102. lifting the frame; 103. a top-mounted disk; 2. a housing member; 201. the bolt is coiled; 202. an outer housing; 203. an inner pad shell; 204. an inner housing; 205. a plug-in frame; 206. a heating ring; 207. a top cover; 3. a pressurizing mechanism; 301. entering an air pipe; 302. a one-way valve; 303. a pressurized gas pump; 304. a gas delivery pipe; 305. an inert gas tank; 4. a feed member; 401. a feeding nozzle; 402. a double-sided valve; 403. an air pump; 404. a nitrogen tank; 405. a powder pump; 406. a carbon powder tank; 5. a mixing mechanism; 501. a bearing seat; 502. an electric motor; 503. rotating the rod; 504. a mixing wheel set; 6. a discharge member; 601. a bolt disk seat; 602. a flange bushing; 603. a valve tube; 604. and (4) a discharge port.

Detailed Description

In order to deepen the understanding of the present invention, the following embodiments are combined to further detail the present invention, and the present embodiment is only used to explain the present invention, and does not constitute the limitation of the protection scope of the present invention.

According to fig. 1-4, the present embodiment provides a batch preparation apparatus for producing a carbon-based non-metal catalyst, which includes a bracket assembly 1 and a mixing mechanism 5, wherein a bolt-assembled shell member 2 is disposed on a top side of the bracket assembly 1, a sleeved pressurizing mechanism 3 is disposed on one side of the shell member 2, a bolt-sleeved feeding member 4 is disposed on the top side of the shell member 2, the mixing mechanism 5 is disposed on the other side of the shell member 2, and a bolt-assembled discharging member 6 is disposed on an upper bottom side of the bracket assembly 1;

the mixing mechanism 5 comprises a bearing seat 501, a motor 502, a rotating rod 503 and a mixing wheel set 504, the bearing seat 501 is sleeved on the other side of the shell member 2, the rotating rod 503 connected with the output end of the motor 502 is arranged on the inner side of the bearing seat 501, and a plurality of groups of mixing wheel sets 504 distributed in parallel are arranged on the outer side of the inner end of the rotating rod 503.

The mixing wheel set 504 is in a wind wheel shape structure, and five sets of mixing wheel set 504 are distributed in parallel.

In this embodiment, the motor 502 is then started to output power to drive the rotating rod 503 inside the bearing seat 501 to rotate at a high speed, and the rotating rod 503 rotates to drive the mixing wheel set 504 to rotate together, so as to achieve the effect of stirring the raw materials.

The rack assembly 1 comprises a base 101, a lifting frame 102 and an overhead plate 103, wherein the top side of the base 101 is provided with the lifting frame 102 bolted to the overhead plate 103.

In this embodiment, the elevated frame 102 with the base 101 mounted thereon is placed at the processing site, and the top side of the elevated frame 102 is provided with the overhead disk 103, so that the two sides of the overhead disk 103 effectively connect the housing member 2 and the take-off member 6.

The shell component 2 comprises a bolt plate bottom 201, an outer shell 202, an inner cushion shell 203, an inner shell 204, a plug frame 205, a heating ring 206 and a top cover 207, the outer shell 202 is connected to the top side of the overhead plate 103 through the bolt plate bottom 201 in a bolt mode, the inner side of the outer shell 202 is provided with the attached inner cushion shell 203, the inner portion of the inner cushion shell 203 is provided with the inner shell 204 distributed in the same ring, the plug frame 205 for installing the heating ring 206 is arranged between the inner cushion shell 203 and the inner shell 204, and the top side of the outer shell 202 is provided with the top cover 207.

In this embodiment, the heating ring 206 between the inner pad shell 203 and the inner shell 204 is then activated to output heat, the inner pad shell 203 is installed on the inner side of the outer shell 202 to achieve the heat insulation effect, and the heat generated by the heating ring 206 on the plug frame 205 is utilized to heat the inner shell 204 into the space inside the inner shell 204.

The pressurizing mechanism 3 comprises an air inlet pipe 301, a one-way valve 302, a pressurizing gas pump 303, an air conveying pipe 304 and an inert gas tank 305, wherein the air inlet pipe 301 is sleeved on one side of the outer shell 202, one end of the air inlet pipe 301 is sleeved with the one-way valve 302 connected with the output end of the pressurizing gas pump 303, and the pressurizing gas pump 303 is sleeved with the inert gas tank 305 through the air conveying pipe 304.

In this embodiment, after the housing member 2 is closed, the pressurized gas pump 303 is started to output power, so that the pressurized gas pump 303 pumps the inert gas tank 305 connected to the gas transmission pipe 304, and the inert gas is output through the one-way valve 302, so that the inert gas is input into the inner housing 204 through the gas transmission pipe 301, thereby increasing the gas pressure of the equipment to meet the physical conditions of the gas pressure for processing.

The feeding member 4 comprises a feeding nozzle 401, a double-side valve 402, an air pump 403, a nitrogen tank 404, a powder pump 405 and a carbon powder tank 406, the feeding nozzle 401 is arranged on the top side of the top cover 207, the two ends of the feeding nozzle 401 are sleeved with the air pump 403 on the double-side valve 402 of the powder pump 405, the input end of the air pump 403 is sleeved with the nitrogen tank 404, and the input end of the powder pump 405 is sleeved with the carbon powder tank 406.

In this embodiment, when the pressurizing mechanism 3 and the mixing mechanism 5 are both operated, and the housing member 2 generates a higher temperature for the device, the powder pump 405 and the air pump 403 are started to output power together, so that the nitrogen gas and the carbon powder in the nitrogen gas tank 404 and the carbon powder tank 406 are output to the two-sided valve 402 through the air pump 403 and the air pump 403, and are output to the inside of the inner housing 204 through the inlet nozzle 401 via the two-sided valve 402, and a carbon-based non-metal catalyst is formed under the effect of high temperature, high pressure and mixing.

The discharging member 6 comprises a bolt disc seat 601, a flange sleeve 602, a valve pipe 603 and a discharging port 604, the bolt disc seat 601 is arranged at the bottom side of the overhead disc 103, the valve pipe 603 is in bolt sleeve connection with the lower part of the bolt disc seat 601 through the flange sleeve 602, and the discharging port 604 is arranged at the bottom side of the valve pipe 603.

In this embodiment, after the carbon-based non-metal catalyst is fully stacked in the device, the discharge port 604 is opened by stopping the operation of the pressurizing mechanism 3, the mixing mechanism 5 and the housing member 2, and the valve pipe 603 is adjusted to a dredging state, so that the carbon-based non-metal catalyst inside the housing member 2 passes through the flange sleeve 602 and the valve pipe 603, and finally is output from the device through the discharge port 604.

The batch preparation equipment for producing the carbon-based non-metal catalyst has the working principle that: firstly, the lifting frame 102 provided with the base 101 is placed at a processing place, the top side of the lifting frame 102 is provided with the top disc 103, so that the two sides of the top disc 103 effectively connect the shell member 2 and the discharging member 6, when the shell member 2 is closed, the pressurizing gas pump 303 is started to output power, so that the pressurizing gas pump 303 pumps the inert gas tank 305 connected with the gas conveying pipe 304, the inert gas is output through the one-way valve 302, the inert gas is input into the inner shell 204 through the gas inlet pipe 301, so as to increase the gas pressure of the equipment, so as to meet the physical conditions of the gas pressure for processing, as the pressurizing gas is inert gas, chemical reaction cannot be generated, then the motor 502 is started to output power to drive the rotating rod 503 inside the bearing seat 501 to rotate at high speed, the rotating rod 503 rotates to drive the mixing wheel set 504 to rotate together, so as to achieve the effect of stirring raw materials, then, the heating ring 206 between the inner cushion shell 203 and the inner shell 204 is started to output heat, because the inner cushion shell 203 is installed on the inner side of the outer shell 202, so as to achieve the effect of heat insulation, the heat generated by the heating ring 206 on the plug frame 205 is utilized, so that the heat is heated to the space inside the inner shell 204 through the inner shell 204, when the pressurizing mechanism 3 and the mixing mechanism 5 are both in operation, and the shell member 2 generates higher temperature for the equipment, thus the powder pump 405 and the air pump 403 are started to output power together, the nitrogen and carbon powder in the nitrogen tank 404 and the carbon powder tank 406 are output to the double-side valve 402 through the air pump 403 and the air pump 403, the nitrogen and carbon powder are output to the inside of the inner shell 204 through the material inlet nozzle 401 through the double-side valve 402, under the effect of high temperature, high pressure and stirring mixing, the non-metal catalyst is formed, after the carbon-based non-metal catalyst is fully packed in the equipment, by stopping the operation of the pressurizing mechanism 3, the mixing mechanism 5 and the housing member 2, the discharge port 604 is opened, and by adjusting the valve pipe 603 to the unblocked state, the carbon-based non-metal catalyst inside the housing member 2 is allowed to pass through the flange sleeve 602 and the valve pipe 603, and finally is discharged out of the apparatus through the discharge port 604.

The foregoing illustrates and describes the general principles, features and advantages of the present invention. 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 (7)

1. The utility model provides a production of carbon base nonmetal catalyst is with batch preparation equipment, includes bracket component (1) and mixing mechanism (5), its characterized in that: a shell component (2) assembled by bolts is arranged on the top side of the bracket component (1), a sleeved pressurizing mechanism (3) is arranged on one side of the shell component (2), a feeding component (4) sleeved by bolts is arranged on the top side of the shell component (2), a mixing mechanism (5) is arranged on the other side of the shell component (2), and a discharging component (6) assembled by bolts is arranged on the upper bottom side of the bracket component (1);

mixing mechanism (5) are including bearing frame (501), motor (502), rotary rod (503) and mixed wheelset (504), bearing frame (501) cup joint the opposite side of casing member (2), the interior limit side of bearing frame (501) is provided with rotary rod (503) of connecting motor (502) output, the inner outside of rotary rod (503) is provided with mixed wheelset (504) of multiunit parallel distribution.

2. The batch preparation apparatus for producing carbon-based non-metallic catalysts according to claim 1, wherein: the mixing wheel set (504) is of a wind wheel-shaped structure, and five groups of mixing wheel sets (504) are distributed in parallel.

3. The batch preparation apparatus for producing carbon-based non-metallic catalysts according to claim 1, wherein: the bracket component (1) comprises a base (101), a lifting frame (102) and an overhead plate (103), wherein the lifting frame (102) connected with the overhead plate (103) through bolts is arranged on the top side of the base (101).

4. The batch preparation device for producing the carbon-based non-metallic catalyst according to claim 3, wherein: casing component (2) are including bolt plate bottom (201), shell body (202), interior casing (203), interior casing (204), grafting frame (205), heating ring (206) and top cap (207), shell body (202) through bolt plate bottom (201) bolted connection the top side of overhead dish (103), the inboard of shell body (202) is provided with interior casing (203) of laminating, just the inside of interior casing (203) is provided with interior casing (204) that distribute with the ring, be provided with grafting frame (205) of installation heating ring (206) between interior casing (203) and interior casing (204), the top side of shell body (202) sets up top cap (207).

5. The batch preparation apparatus for producing carbon-based non-metallic catalysts according to claim 4, wherein: pressurization mechanism (3) are including going into trachea (301), check valve (302), pressurized gas pump (303), gas-supply pipe (304) and inert gas jar (305), it cup joints to go into trachea (301) one side of shell body (202), the one end of going into trachea (301) is cup jointed check valve (302) of connecting pressurized gas pump (303) output, pressurized gas pump (303) have cup jointed inert gas jar (305) through gas-supply pipe (304).

6. The batch preparation apparatus for producing carbon-based non-metallic catalysts according to claim 4, wherein: the feeding member (4) comprises a feeding nozzle (401), two side valves (402), an air pump (403), a nitrogen tank (404), a powder pump (405) and a carbon powder tank (406), wherein the feeding nozzle (401) is arranged on the top side of the top cover (207), the two ends of the feeding nozzle (401) are sleeved with the two side valves (402) of the air pump (403) on the powder pump (405), the input end of the air pump (403) is sleeved with the nitrogen tank (404), and the input end of the powder pump (405) is sleeved with the carbon powder tank (406).

7. The batch preparation device for producing the carbon-based non-metallic catalyst according to claim 3, wherein: the discharging component (6) comprises a bolt disc seat (601), a flange sleeve (602), a valve pipe (603) and a discharging hole (604), the bolt disc seat (601) is arranged on the bottom side of the overhead disc (103), the valve pipe (603) is sleeved below the bolt disc seat (601) through a flange sleeve (602) in a bolt mode, and the discharging hole (604) is formed in the bottom side of the valve pipe (603).

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