CN223589694U - Continuous forming device for activated carbon - Google Patents

Abstract

This utility model relates to the technical field of activated carbon production equipment, specifically to a continuous activated carbon forming device, including a first conveyor table, a second conveyor table, and a sliding support frame. The first conveyor table is located at the front end of the second conveyor table, and the sliding support frame is slidably mounted on the second conveyor table. It also includes a cutting component and a moving component. The cutting component includes multiple connecting plates, multiple steel wires, a transverse support plate, and a lifting component. The multiple connecting plates are fixedly connected to the transverse support plate and are evenly distributed at both ends of the transverse support plate. The multiple steel wires are respectively installed between two connecting plates. The transverse support plate is connected to the sliding support frame through the lifting component and is located below the sliding support frame. The lifting component is mounted on the sliding support frame and connected to the transverse support plate, driving the transverse support plate to move. This achieves continuous operation of the entire device and promotes the movement and conveying of activated carbon, improving the quality of activated carbon production and processing.

Description

Continuous forming device for activated carbon

Technical Field

The utility model relates to the technical field of activated carbon production equipment, in particular to a continuous forming device for activated carbon.

Background

The activated carbon has the remarkable characteristics of low price, high strength and the like, but the impurities are high and difficult to prepare into high-performance activated carbon, the appearance of the activated carbon is generally black cylindrical activated carbon, and the activated carbon is amorphous coal granular activated carbon, which is also called broken carbon. The active carbon is generally prepared from powdery raw materials and binders through the working procedures of kneading, extrusion molding, carbonization, activation and the like, and at present, when the active carbon is produced, production equipment is split, so that a plurality of workers are required to manually assist in completing production, manpower resources are wasted, continuity is not achieved, and production time is delayed.

The prior art CN217230252U discloses a continuous activated carbon production device, including the extrusion molding machine, accomplish the twice shaping work of activated carbon through extrusion molding machine and square groove port post, simultaneously through the infrared sensor in two positioning module, can carry out spacing work to the activated carbon of shaping that first conveying platform was conveyed, and control first conveying platform and extrusion molding machine stop work, also control two synchronous motors, make the sliding support frame accomplish the position, when protruding font square post and contact switch contact, work with first electric hydraulic stem, the clamping cutting subassembly position adjustment work, make the clamping cutting subassembly can carry out cutting work and clamping conveying work to the activated carbon of shaping, thereby make the activated carbon of segmentation carry to the second conveying bench, and accomplish conveying work through the second conveying bench, so not only make whole device have continuity, save production time, but also practiced thrift the manpower resources.

However, in the above technology, the clamping and cutting assembly performs cutting and clamping and conveying operations on the formed activated carbon, and after the whole activated carbon is cut into a plurality of pieces, the activated carbon at two ends needs to be clamped, so that the extruded degrees of the activated carbon from outside to inside are different, the shape of the activated carbon may be damaged, and the production and processing quality is affected.

Disclosure of utility model

The utility model aims to provide an activated carbon continuous forming device, which solves the problems that the shapes of activated carbon are damaged and the production and processing quality is affected due to different extrusion degrees of the activated carbon from outside to inside by clamping and moving the cut activated carbon in the prior art.

In order to achieve the above object, the present utility model provides an activated carbon continuous forming apparatus comprising a first transfer table, a second transfer table, and a slide support, the first transfer table being located at the front end of the second transfer table, the slide support being slidably mounted on the second transfer table,

The device also comprises a cutting assembly and a moving assembly;

The cutting assembly comprises a plurality of connecting plates, a plurality of steel wires, a transverse supporting plate and lifting members, wherein the connecting plates are fixedly connected with the transverse supporting plate and uniformly distributed at the front end and the rear end of the transverse supporting plate, the steel wires are respectively arranged between the two connecting plates, the transverse supporting plate is connected with the sliding supporting frame through the lifting members and is positioned under the sliding supporting frame, and the lifting members are arranged on the sliding supporting frame and are connected with the transverse supporting plate and drive the transverse supporting plate to move.

The lifting component comprises a first electric hydraulic rod and two limiting rods, wherein the first electric hydraulic rod is fixedly arranged on the sliding support frame, the telescopic free end of the first electric hydraulic rod is fixedly connected with the transverse support plate, and the two limiting rods are fixedly connected with the transverse support plate, are positioned at the tops of the two ends of the transverse support plate and penetrate through the sliding support frame.

The sliding support frame is provided with two limiting through holes, the two limiting through holes are formed in two ends of the top of the sliding support frame, penetrate through the sliding support frame and are matched with the limiting rods.

The movable assembly comprises a push plate, a second electric hydraulic rod and a mounting frame, wherein the push plate is fixedly connected with the telescopic free end of the second electric hydraulic rod, the second electric hydraulic rod is fixedly mounted on the mounting frame, and the mounting frame is fixedly connected with the first conveying table and is positioned on the front side of the first conveying table.

The moving assembly further comprises a transition plate fixedly connected with the second conveying table and located between the first conveying table and the second conveying table.

According to the continuous forming device for the activated carbon, the cutting assembly is moved to the position above the first conveying table through the sliding support frame, the transverse support plate is driven to move downwards through the lifting component, the transverse support plate moves downwards to drive the connecting plates and the steel wires to move downwards, the activated carbon is cut through the steel wires, the moving assembly drives the pushing plate to move towards the second conveying table through the second electric hydraulic rod, and the pushing plate pushes the cut activated carbon to move to the second conveying table from the first conveying table through the transition plate, and then the activated carbon is conveyed through the second conveying table.

Drawings

In order to more clearly illustrate the embodiments of the present application 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.

FIG. 1 is a front view of an activated carbon continuous molding apparatus of the present utility model.

FIG. 2 is a schematic view showing the overall structure of the continuous molding apparatus for activated carbon according to the present utility model.

FIG. 3 is a top view of the continuous molding apparatus for activated carbon of the present utility model.

In the figure, the device comprises a first conveying table, a second conveying table, a 103-sliding support frame, a 104-connecting plate, a 105-steel wire, a 106-transverse support plate, a 107-first electric hydraulic rod, a 108-limiting rod, a 109-limiting through hole, a 110-push plate, a 111-second electric hydraulic rod, a 112-mounting frame and a 113-transition plate.

Detailed Description

The following detailed description of embodiments of the utility model, examples of which are illustrated in the accompanying drawings and, by way of example, are intended to be illustrative, and not to be construed as limiting, of the utility model.

Referring to fig. 1 to 3, fig. 1 is a front view of an activated carbon continuous forming apparatus according to the present utility model, fig. 2 is a schematic view of an overall structure of the activated carbon continuous forming apparatus according to the present utility model, and fig. 3 is a top view of the activated carbon continuous forming apparatus according to the present utility model.

The utility model relates to an activated carbon continuous forming device which comprises a first conveying table 101, a second conveying table 102, a sliding support frame 103, a cutting assembly and a moving assembly, wherein the cutting assembly comprises a plurality of connecting plates 104, a plurality of steel wires 105, a transverse support plate 106 and a lifting member, the lifting member comprises a first electric hydraulic rod 107 and two limiting rods 108, the sliding support frame 103 is provided with two limiting through holes 109, and the moving assembly comprises a push plate 110, a second electric hydraulic rod 111, a mounting frame 112 and a transition plate 113. The problems that the shapes of the activated carbon are possibly damaged and the production and processing quality is affected due to different extrusion degrees of the activated carbon from outside to inside after the cut activated carbon is clamped and moved in the prior art are solved through the scheme, and it can be understood that the formed activated carbon can be cut and conveyed through the scheme, so that the cut activated carbon is pushed onto the second conveying table 102 from the first conveying belt, conveying is completed through the second conveying table 102, the whole device has continuity, production time is saved, and manpower resources are saved.

In this embodiment, the first conveying table 101 is located at the front end of the second conveying table 102, and the sliding support 103 is slidably mounted on the second conveying table 102. The position of first conveying platform 101 corresponds with the position of active carbon extrusion molding machine and square groove port post, and with the active carbon transmission of cooperation extrusion molding is placed at the top, second conveying platform 102 with the conveying trend of first conveying platform 101 is perpendicular, is used for keeping away from the active carbon that cuts the direction of first conveying platform 101 conveys, just the both sides support top of second conveying platform 102 all is equipped with the spout, its spout with the bottom cooperation of sliding support frame 103, and be equipped with electric threaded rod in the spout with sliding support frame 103 threaded connection, through electric threaded rod screw drive sliding support frame 103 is in horizontal migration on the second conveying platform 102, through sliding support frame 103 is for cutting the subassembly provides installation and removal condition.

The plurality of connection plates 104 are fixedly connected with the transverse support plates 106, are uniformly distributed at the front end and the rear end of the transverse support plates 106, the plurality of steel wires 105 are respectively installed between the two connection plates 104, the transverse support plates 106 are connected with the sliding support frames 103 through lifting members and located below the sliding support frames 103, and the lifting members are installed on the sliding support frames 103, are connected with the transverse support plates 106 and drive the transverse support plates 106 to move. The device comprises a first conveying table 101, a second conveying table 103, a transverse supporting plate 106, a lifting member, a plurality of connecting plates 104, steel wires 105, a cutting assembly and a cutting assembly, wherein the transverse supporting plate 106 is horizontally arranged above the first conveying table 101 and is mutually horizontal with the top of the sliding supporting frame 103, the lifting member at the top of the sliding supporting frame 103 stretches into the lower portion of the sliding supporting frame 103 and is connected with the transverse supporting plate 106, the transverse supporting plate 106 is driven by the lifting member to move upwards or downwards, the connecting plates 104 and the steel wires 105 are respectively and evenly arranged at the front end and the rear end of the bottom of the transverse supporting plate 106 at intervals, the steel wires 105 are fixedly arranged at the bottoms between every two connecting plates 104, the cutting assembly is used for cutting the activated carbon through the steel wires 105, and the cutting assembly is moved to the upper portion of the first conveying table 101 through the sliding supporting frame 103, the transverse supporting plate 106 is driven by the lifting member to move downwards, and the connecting plates 104 and the steel wires 105 are driven by the downward movement of the transverse supporting plate 106.

Secondly, the first electric hydraulic rod 107 is fixedly mounted on the sliding support frame 103, the telescopic free end of the first electric hydraulic rod 107 is fixedly connected with the transverse support plate 106, and the two limit rods 108 are fixedly connected with the transverse support plate 106, are positioned at the top of two ends of the transverse support plate 106 and penetrate through the sliding support frame 103. The two limit through holes 109 are disposed at two ends of the top of the sliding support 103, penetrate through the sliding support 103, and are matched with the limit rod 108. The first electric hydraulic rod 107 is fixedly installed at the middle position of the top of the sliding support frame 103, the telescopic free end of the first electric hydraulic rod 107 penetrates through the sliding support frame 103 and is fixedly connected with the transverse support plate 106, the transverse support plate 106 is driven to move downwards by the first electric hydraulic rod 107, the transverse support plate 106 drives a plurality of connecting plates 104 and a plurality of steel wires 105 to move downwards, the steel wires 105 are used for cutting activated carbon, the two limiting rods 108 at the top of the transverse support plate 106 penetrate through the two limiting through holes 109 of the sliding support frame 103 respectively, and the limiting with the movement limiting of the transverse support plate 106 is realized by the two limiting through holes 109 and the two limiting rods 108, so that the vertical up-down movement of the transverse support plate 106 is ensured.

Meanwhile, the push plate 110 is fixedly connected with the telescopic free end of the second electric hydraulic rod 111, the second electric hydraulic rod 111 is fixedly installed on the installation frame 112, and the installation frame 112 is fixedly connected with the first conveying table 101 and is located at the front side of the first conveying table 101. The transition plate 113 is fixedly connected to the second transfer stage 102 and is located between the first transfer stage 101 and the second transfer stage 102. The pushing plate is located at the upper end of the front side of the first conveying table 101, and is fixedly connected with the free telescopic end of the second electric hydraulic rod 111, the pushing plate 110 is driven to move back and forth above the first conveying table 101 by the second electric hydraulic rod 111, the second electric hydraulic rod 111 is fixedly installed on the installation frame 112, the installation frame 112 is located on the installation of the second electric hydraulic rod 111 to provide conditions, the installation frame 112 is further provided with an auxiliary bracket, the fixed installation of the second electric hydraulic rod 111 is more stable, the transition plate 113 is fixedly arranged between the first conveying table 101 and the second conveying table 102, the transition plate 113 is the same as the height position of a transmission belt of the first conveying table 101 and the second conveying table 102, so that cut activated carbon is ensured to be smoothly pushed onto the second conveying table 102 from the first conveying table 101, the moving assembly drives the pushing plate 110 to move towards the second conveying table 102 by the second electric hydraulic rod 111, and then the cut activated carbon is conveyed from the second conveying table 102 to the second conveying table 102 by the transition plate 113.

When the continuous forming device for the activated carbon is used, two forming operations of the activated carbon are completed through an activated carbon extrusion forming machine and a square groove port column, the first conveying table 101 is matched with the formed activated carbon to be placed, then the cut activated carbon is moved to the upper portion of the first conveying table 101 through the sliding supporting frame 103, the transverse supporting plate 106 is driven to move downwards through the lifting member, the transverse supporting plate 106 moves downwards to drive the connecting plate 104 and the steel wires 105 to move downwards, the activated carbon is cut through the steel wires 105, the cutting operation of the cut activated carbon is further realized, the push plate 110 is driven to move towards the second conveying table 102 through the second electric hydraulic rod 111 of the moving assembly, the cut activated carbon is pushed to move from the first conveying table 101 to the second conveying table 102 through the transition plate 113, and then the activated carbon is conveyed through the second conveying table 102, so that the whole device has continuous pushing operation, the continuous pushing operation of the activated carbon is realized, the production time is saved, the movement of the activated carbon is avoided, and the production quality is prevented from being damaged, and the activated carbon is prevented from being extruded and processed.

The foregoing disclosure is only illustrative of one or more preferred embodiments of the present application, and it is not intended to limit the scope of the claims hereof, as persons of ordinary skill in the art will understand that all or part of the processes for practicing the embodiments described herein may be practiced with equivalent variations in the claims, which are within the scope of the application.

Claims (5)

1. A continuous activated carbon forming apparatus, comprising a first conveyor table, a second conveyor table, and a sliding support frame, wherein the first conveyor table is located at the front end of the second conveyor table, and the sliding support frame is slidably mounted on the second conveyor table, characterized in that, It also includes cutting components and moving components; The cutting assembly includes multiple connecting plates, multiple steel wires, a transverse support plate, and a lifting component. The multiple connecting plates are fixedly connected to the transverse support plate and are evenly distributed at both ends of the transverse support plate. The multiple steel wires are respectively installed between two of the connecting plates. The transverse support plate is connected to the sliding support frame through the lifting component and is located below the sliding support frame. The lifting component is installed on the sliding support frame and connected to the transverse support plate, and drives the transverse support plate to move. 2. The activated carbon continuous forming apparatus as described in claim 1, characterized in that, The lifting component includes a first electro-hydraulic rod and two limiting rods. The first electro-hydraulic rod is fixedly installed on the sliding support frame, and the free end of the first electro-hydraulic rod is fixedly connected to the transverse support plate. The two limiting rods are fixedly connected to the transverse support plate and are located at the top of both ends of the transverse support plate, and pass through the sliding support frame. 3. The activated carbon continuous forming apparatus as described in claim 2, characterized in that, The sliding support frame has two limiting through holes, which are located at both ends of the top of the sliding support frame, penetrate the sliding support frame, and cooperate with the limiting rod. 4. The activated carbon continuous forming apparatus as described in claim 1, characterized in that, The moving component includes a push plate, a second electro-hydraulic rod, and a mounting frame. The push plate is fixedly connected to the telescopic free end of the second electro-hydraulic rod. The second electro-hydraulic rod is fixedly mounted on the mounting frame. The mounting frame is fixedly connected to the first conveyor table and is located in front of the first conveyor table. 5. The activated carbon continuous forming apparatus as described in claim 4, characterized in that, The moving component also includes a transition plate, which is fixedly connected to the second conveyor and located between the first conveyor and the second conveyor.