CN115420118B

CN115420118B - A fully automatic graphitization internal series furnace linkage conductive equipment

Info

Publication number: CN115420118B
Application number: CN202210858788.4A
Authority: CN
Inventors: 谈嘉豪
Original assignee: Qingdao Yibo Technology Co ltd
Current assignee: Qingdao Yibo Technology Co ltd
Priority date: 2022-07-20
Filing date: 2022-07-20
Publication date: 2025-04-18
Anticipated expiration: 2042-07-20
Also published as: CN115420118A

Abstract

The invention relates to the technical field of graphitization, in particular to full-automatic graphitization inner-series furnace linkage conductive equipment. The device comprises a movable frame, a high-voltage transformer is arranged on the movable frame, an upward moving device is arranged on the upper side of the movable frame, a low-voltage transformer is arranged on the upward moving device, and the low-voltage transformer is arranged on the upper side of the high-voltage transformer. This through setting up the supply of electric energy to the cluster stove in low-voltage transformer and the high-voltage transformer, when earlier stage, provide low pressure low current to the cluster stove in the graphitization through low-voltage transformer, when entering into later stage, high-voltage transformer carries out the supply of high pressure high current to the cluster stove in the graphitization again, make the graphitization in the in-process of using, can receive different voltage current, so as to accomplish the rational utilization of power, dislocation setting about low-voltage transformer and the high-voltage transformer through adapting mechanism simultaneously, make low-voltage transformer and high-voltage transformer realize the individual operation.

Description

Full-automatic graphitized inner series furnace linkage conductive equipment

Technical Field

The invention relates to the technical field of graphitization, in particular to full-automatic graphitization inner-series furnace linkage conductive equipment.

Background

At present, the graphitized inner string furnace is a transformer and can only use a high-voltage transformer, but the graphitized inner string furnace needs to use low voltage and low current when in initial use and power supply, and only needs to use high voltage and high current at later stage, and the initial use of the high voltage and the high current can cause power waste.

Disclosure of Invention

The invention aims to provide full-automatic graphitized inner series furnace linkage conductive equipment so as to solve the problems in the background technology.

In order to achieve the above-mentioned purpose, the utility model provides a cluster stove linkage conduction equipment in full-automatic graphitization, including removing the frame, remove and be provided with high-voltage transformer on the frame, the upside that removes the frame is provided with the device that moves up, it is provided with low-voltage transformer to move up on the device that moves up, low-voltage transformer sets up the upside at high-voltage transformer when low-voltage transformer and high-voltage transformer do not use, move up the device and drive low-voltage transformer and move down, drive low-voltage transformer to one side of high-voltage transformer, low-voltage transformer and high-voltage transformer adopt the form of sending of dual power supply, just low-voltage transformer and high-voltage transformer carry out the individual operation, remove the frame and include the movable plate, the upside of movable plate is provided with accepting mechanism, accepting mechanism is used for accepting the low-voltage transformer and places, it includes the plate that moves up to move up, the downside of movable plate is provided with pushing mechanism, pushing mechanism drives the plate and moves up and moves down, just the upper side of low-voltage transformer that moves up at the side.

As a further improvement of the technical scheme, the bearing mechanism comprises two brackets, the upper sides of the two brackets are fixedly provided with placing plates, the low-voltage transformer is arranged on the placing plates, and when the upper moving plate lifts the low-voltage transformer, the placing plates and the upper sides of the upper moving plate are in the same plane.

As a further improvement of the technical scheme, a blocking groove is formed in one side, close to the upper moving plate, of the placing plate, the blocking groove is formed downwards, a blocking rod matched with the blocking groove is arranged on the side wall, close to the placing plate, of the upper moving plate, the blocking rod is in contact with the side wall of the blocking groove, and the blocking groove blocks the upward movement of the blocking rod.

As a further improvement of the technical scheme, the pushing mechanism comprises two rear hinge rods hinged to one side of the upward moving plate, the two rear hinge rods are arranged close to the placing plate, the two sides of one end of the upward moving plate, far away from the placing plate, are hinged to front hinge rods, and the rear hinge rods and the front hinge rods are hinged to the upper side wall of the moving plate.

As a further improvement of the technical scheme, the hinged positions of the rear hinge rod and the movable plate are arranged on one side, close to the bracket, of the side edge of the movable plate, and the hinged positions of the front hinge rod and the movable plate are arranged on the position, close to the middle, of the side edge of the movable plate.

As a further improvement of the technical scheme, an upper extension plate is fixed at the position of the front hinge rod, which is close to the middle part, and a hydraulic rod is arranged on one side of the upper extension plate, and one end of a piston rod of the hydraulic rod is rotationally connected with the upper extension plate.

As a further improvement of the technical scheme, the bottom bearing plate is fixed on the upper side of the movable plate far away from one end of the placing plate in a bilateral symmetry manner, one end of the hydraulic rod is hinged to the outer side wall of the bottom bearing plate, and the hinged positions of the front hinge rod and the movable plate are higher than those of the hydraulic rod and the bottom bearing plate.

As a further improvement of the technical scheme, the bottom of the upward moving plate is in contact with the upper surface of the bottom bearing plate, the upper surface of the bottom bearing plate is an inclined surface inclined towards the direction close to the placing plate, and when the low-voltage transformer moves onto the placing plate, the upward moving plate forms a platform for a person to stand.

As a further improvement of the technical scheme, the upper sides of the placing plates and the upper sides of the upward moving plates are symmetrically fixed with side clamping strips, a sliding bearing plate is arranged between the two opposite side clamping strips in a sliding mode, the low-voltage transformer is arranged on the sliding bearing plate, and the high-voltage transformer is arranged on the moving plate below the placing plates.

Compared with the prior art, the invention has the beneficial effects that:

1. In this full-automatic graphitization inner string stove linkage conductive equipment, through setting up the supply of electric energy to graphitization inner string stove of low-voltage transformer and high-voltage transformer, in earlier stage, provide low-voltage low current to graphitization inner string stove through low-voltage transformer, when entering the later stage, high-voltage transformer carries out the supply of high-voltage high current to graphitization inner string stove again, make graphitization inner string stove in the in-process of using, can receive different voltage and current, so as to accomplish the rational utilization of power, dislocation set about with low-voltage transformer and high-voltage transformer through the adapting mechanism simultaneously, make low-voltage transformer and high-voltage transformer realize the individual operation, thereby accelerate the production speed of product in the graphitization inner string stove.

2. In the full-automatic graphitized inner string furnace linkage conductive equipment, when the smelting period of the graphitized inner string furnace is changed from the earlier stage to the later stage, the high-voltage transformer provides electric energy for the graphitized inner string furnace entering the later stage, and the low-voltage transformer provides electric energy for the new graphitized inner string furnace at the moment, so that the low-voltage transformer and the high-voltage transformer perform continuous operation, the working rate of the graphitized inner string furnace is further improved, the yield of the graphitized inner string furnace is improved, and continuous production of multiple furnaces is realized.

3. In this full-automatic graphitization internal string stove linkage conductive equipment, move the upside of high-voltage transformer to low-voltage transformer through the device that moves up that sets up, make low-voltage transformer and high-voltage transformer carry out the staggered arrangement, thereby accomplish the independent operation of low-voltage transformer and high-voltage transformer, simultaneously when needs transport the device, drive the low-voltage transformer through the device that moves up and be close to the movable plate, make the device at the in-process that removes, need not to consider the stability of low-voltage transformer, in order to accomplish the effect that makes things convenient for the device to remove.

Drawings

FIG. 1 is a schematic view of the whole moving structure of the present invention;

FIG. 2 is a schematic view of the overall structure of the present invention in use;

FIG. 3 is a schematic diagram of the whole structure of the present invention when regulating a low voltage transformer;

FIG. 4 is a schematic view of an assembled structure of a mobile frame and an upward moving device according to the present invention;

FIG. 5 is a schematic view of a movable frame according to the present invention;

Fig. 6 is a schematic structural view of an upward moving device according to the present invention.

The meaning of each reference sign in the figure is:

1. a moving rack; 11, a movable plate, 12, a bracket, 13, a placing plate, 14, a bottom bearing plate, 15, a side clamping strip, 16 and a blocking groove;

2. An upward moving device; 21, an up-moving plate, 22, a rear hinge rod, 23, a front hinge rod, 24, a hydraulic rod, 25 and a stop lever;

3. low-voltage transformer, 4, high-voltage transformer, 5, sliding bearing plate.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the description of the present invention, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

Example 1

Referring to fig. 1-6, the present embodiment is directed to a full-automatic graphitized inner-string furnace linkage conductive device, which comprises a movable frame 1, wherein a high-voltage transformer 4 is arranged on the movable frame 1, the high-voltage transformer 4 is a 340V transformer, a high-voltage high-current is provided for the graphitized inner-string furnace, considering that the high-voltage high-current is not needed in the early stage of the graphitized inner-string furnace, only a low-voltage low-current is needed, when the high-voltage high-current is needed to supply power to the graphitized inner-string furnace through the high-voltage transformer 4, electric energy is wasted, and the graphitized inner-string furnace needs to have high-voltage high-current in the later stage of smelting, so that an upward moving device 2 is arranged on the upper side of the movable frame 1, a low-voltage transformer 3 is arranged on the upward moving device 2, the low-voltage transformer 3 is a 220V transformer, the low-voltage low-current is provided for the graphitized inner-string furnace through the low-voltage transformer 3, when the graphitized inner string furnace is smelted in the earlier stage, the low-voltage transformer 3 provides electric energy, so that electric energy is saved, meanwhile, the low-voltage transformer 3 is arranged on the upper side of the high-voltage transformer 4, the low-voltage transformer 3 and the high-voltage transformer 4 are arranged in a staggered way, the low-voltage transformer 3 and the high-voltage transformer 4 adopt a double-power-supply mode, the low-voltage transformer 3 and the high-voltage transformer 4 can independently operate in the using process, the low-voltage transformer 3 and the high-voltage transformer 4 can not be affected mutually, when the graphitized inner string furnace is smelted in the earlier stage, the low-voltage transformer 3 supplies power to the graphitized inner string furnace, when the smelting period of the graphitized inner string furnace is changed from the earlier stage to the later stage, the high-voltage transformer 4 supplies power to the graphitized inner string furnace entering the later stage of smelting, at the moment, the low-voltage transformer 3 supplies power to the new graphitized inner string furnace in the earlier stage, therefore, the low-voltage transformer 3 and the high-voltage transformer 4 achieve the effect of continuous operation, the operation rate is greatly improved, and the production speed of products in the graphitized inner-string furnace is accelerated.

When the device needs to move, the installation position of the low-voltage transformer 3 arranged on the upper side of the high-voltage transformer 4 is too high, shaking easily occurs in the moving process, dangers are brought to the movement of the device, the low-voltage transformer 3 is driven to move downwards by the upward moving device 2 when the device is fixed on the low-voltage transformer 3 and the high-voltage transformer 4 and is driven to one side of the high-voltage transformer 4, so that the gravity center position of the device is lowered, the moving stability of the device is ensured, and in order to enable the upward moving device 2 to move the low-voltage transformer 3, the low-voltage transformer 3 is required to be supported by a device;

The structure of the low-voltage transformer 3 is specifically supported by the movable frame 1, wherein the movable frame 1 comprises a movable plate 11, in order to facilitate the movement of the movable plate 11, movable wheels are arranged at four corners of the bottom of the movable plate 11, meanwhile, a bearing mechanism is arranged at the upper side of the movable plate 11 and is used for bearing and placing the low-voltage transformer 3, the bearing mechanism comprises two brackets 12, a placing plate 13 is fixed at the upper sides of the two brackets 12, the low-voltage transformer 3 is arranged on the placing plate 13, the low-voltage transformer 3 is borne through the placing plate 13, a high-voltage transformer 4 is arranged on the movable plate 11 at the lower side of the placing plate 13, the low-voltage transformer 3 is arranged at the upper side of the high-voltage transformer 4, and the low-voltage transformer 3 and the high-voltage transformer 4 are arranged in a vertically staggered structure, so that the low-voltage transformer 3 and the high-voltage transformer 4 are convenient to be used separately;

When the device needs to move, the lower-voltage transformer 3 is required to be carried down by the upward moving device 2 from the placing plate 13, the specific structure of the upward moving device 2 is that the upward moving device 2 comprises an upward moving plate 21, a pushing mechanism is arranged at the bottom side of the upward moving plate 21, the upward moving plate 21 is driven by the pushing mechanism to move up and down, the lower-voltage transformer 3 is arranged at the upper side of the upward moving plate 21, the upward moving plate 21 carries out carrying lifting on the lower-voltage transformer 3, the upward moving plate 21 can carry out carrying on the lower-voltage transformer 3 placed on the placing plate 13, simultaneously, in order to facilitate the placing of the placing plate 13 on the lower-voltage transformer 3 on the upward moving plate 21, a sliding bearing plate 5 is arranged on the placing plate 13 in a sliding way, and the lower-voltage transformer 3 is arranged on the sliding bearing plate 5, the sliding bearing plate 5 is driven to move to the upward moving plate 21 by pushing the sliding bearing plate 5, in order to limit the sliding bearing plate 5 on the placing plate 13, the upper side of the upward moving plate 21 is clamped on the upper side of the upper plate 21, and the upper sliding plate 15 is arranged on the sliding plate 15 opposite to the upper side of the upper plate 21, and the sliding bearing plate 15 is arranged on the sliding plate 15, and the upper side of the upper plate is opposite to the upper plate 13 is guaranteed;

After the upper moving plate 21 is connected to the low-voltage transformer 3, the low-voltage transformer 3 needs to be driven to move downwards by a pushing mechanism, the pushing mechanism comprises two rear hinge rods 22 hinged on one side of the upper moving plate 21, the two rear hinge rods 22 are arranged close to the placing plate 13, front hinge rods 23 are hinged on two sides of one end of the upper moving plate 21 far away from the placing plate 13, both the rear hinge rods 22 and the front hinge rods 23 are hinged on the upper side wall of the moving plate 11, meanwhile, in order to ensure that the upper moving plate 21 moves downwards, the upper moving plate 21 is prevented from being far away from the placing plate 13, the low-voltage transformer 3 is prevented from shaking due to overlarge distance when moving to the high-voltage transformer 4 in the later stage, the hinged positions of the rear hinge rods 22, the front hinge rods 23 and the moving plate 11 are fixedly limited, the hinged positions of the rear hinge rods 22 and the moving plate 11 are arranged on one side of the moving plate 11 close to the bracket 12, the hinged position of the front hinge rod 23 and the movable plate 11 is arranged at the position close to the middle of the side edge of the movable plate 11, when the rear hinge rod 22 and the front hinge rod 23 rotate, the upward moving plate 21 rotates around the hinged position of the rear hinge rod 22 and the movable plate 11 to limit the displacement distance of the upward moving plate 21, and in order to ensure that the rear hinge rod 22 and the front hinge rod 23 rotate around the hinged position of the movable plate 11, the low-voltage transformer 3 supported by the rear hinge rod 22 and the front hinge rod 23 stably moves downwards, an upward extending plate is fixed at the position close to the middle of the front hinge rod 23, a hydraulic rod 24 is arranged at one side of the upward extending plate, one end of a piston rod of the hydraulic rod 24 is rotationally connected with the upward extending plate, a bottom bearing plate 14 is symmetrically fixed at one end of the upper side of the movable plate 11 far from the placing plate 13, one end of the hydraulic rod 24 is hinged on the outer side wall of the bottom bearing plate 14, the hydraulic rod 24 is driven to slowly rotate by the contraction of the piston rod 24, the stable downward movement of the low-voltage transformer 3 is controlled, meanwhile, in order to ensure that the low-voltage transformer 3 needs to move upwards in the later period, the hydraulic rod 24 is convenient for pushing the front hinge rod 23 to rotate, the hinged position of the front hinge rod 23 and the movable plate 11 is higher than the hinged position of the hydraulic rod 24 and the bottom bearing plate 14, so that the drop of the two ends of the hydraulic rod 24 is formed, and the hydraulic rod 24 can push the front hinge rod 23 obliquely upwards to push the low-voltage transformer 3 when the piston rod of the hydraulic rod 24 stretches out;

When the upper moving plate 21 drives the low-voltage transformer 3 to fall, the position of the upper moving plate 21 needs to be supported, so that the bottom of the upper moving plate 21 is contacted with the upper surface of the bottom bearing plate 14, the bottom bearing plate 14 supports the upper moving plate 21, and meanwhile, the upper surface of the bottom bearing plate 14 is set to be inclined towards the direction close to the placing plate 13, after the low-voltage transformer 3 moves onto the placing plate 13, the upper moving plate 21 forms a platform for a person to stand, and the worker can conveniently stand on the upper moving plate 21 to operate the low-voltage transformer 3;

After the device is moved, the low-voltage transformer 3 is required to be jacked and moved onto the placing plate 13, and in the process of upward movement of the upward moving plate 21, accurate connection with the placing plate 13 cannot be achieved, so that the baffle groove 16 is formed in one side of the placing plate 13 close to the upward moving plate 21, the baffle groove 16 is formed downwards, a stop lever 25 matched with the baffle groove 16 is arranged on the side wall of the upward moving plate 21 close to the placing plate 13, the side wall of the stop lever 25 is contacted with the side wall of the baffle groove 16, the baffle groove 16 stops upward movement of the stop lever 25, and one end of the upward moving plate 21 is connected with one end of the placing plate 13, so that normal movement of the low-voltage transformer 3 is facilitated.

The foregoing has shown and described the basic principles, principal features and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the above-described embodiments, and that the above-described embodiments and descriptions are only preferred embodiments of the present invention, and are not intended to limit the invention, and that various changes and modifications may be made therein without departing from the spirit and scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The full-automatic graphitization inner-series furnace linkage conductive equipment comprises a movable frame (1), wherein a high-voltage transformer (4) is arranged on the movable frame (1), an upward movement device (2) is arranged on the upper side of the movable frame (1), and a low-voltage transformer (3) is arranged on the upward movement device (2), and the full-automatic graphitization inner-series furnace linkage conductive equipment is characterized in that the low-voltage transformer (3) is arranged on the upper side of the high-voltage transformer (4), when the low-voltage transformer (3) and the high-voltage transformer (4) are not used, the upward movement device (2) drives the low-voltage transformer (3) to move downwards, the low-voltage transformer (3) is driven to one side of the high-voltage transformer (4), the low-voltage transformer (3) and the high-voltage transformer (4) adopt a double-power-supply point feeding mode, the low-voltage transformer (3) and the high-voltage transformer (4) perform independent operation, the movable frame (1) comprises a movable plate (11), an upper side of the movable plate (11) is provided with a mechanism, and an upper side of the movable plate (21) is arranged on the upper side of the movable plate (21), and the upper plate (21) is driven by the upper plate (21);

The pushing mechanism comprises two rear hinge rods (22) hinged to one side of an upper moving plate (21), the two rear hinge rods (22) are arranged close to a placing plate (13), front hinge rods (23) are hinged to two sides of one end, far away from the placing plate (13), of the upper moving plate (21), and the rear hinge rods (22) and the front hinge rods (23) are both hinged to the upper side wall of the moving plate (11);

The bearing mechanism comprises two brackets (12), a placement plate (13) is fixed on the upper sides of the two brackets (12), the low-voltage transformer (3) is arranged on the placement plate (13), and when the upper moving plate (21) lifts the low-voltage transformer (3), the placement plate (13) and the upper side of the upper moving plate (21) are in the same plane;

an upper extension plate is fixed at the position of the front hinge rod (23) close to the middle part, a hydraulic rod (24) is arranged at one side of the upper extension plate, and one end of a piston rod of the hydraulic rod (24) is rotationally connected with the upper extension plate;

The upper side of placing board (13) and the upside of upward shifting board (21) are all bilateral symmetry and are fixed with side card strip (15), and slide between two relative side card strip (15) and be provided with slip joint board (5), low-voltage transformer (3) are installed on slip joint board (5), high-voltage transformer (4) are installed on movable board (11) of placing board (13) downside.

2. The full-automatic graphitization inner series furnace linkage conductive device according to claim 1, wherein a blocking groove (16) is formed in one side, close to the upper moving plate (21), of the placing plate (13), the blocking groove (16) is formed downwards, a blocking rod (25) matched with the blocking groove (16) is arranged on the side wall, close to the placing plate (13), of the upper moving plate (21), the side wall of the blocking rod (25) is in contact with the side wall of the blocking groove (16), and the blocking groove (16) blocks the blocking rod (25) from moving upwards.

3. The full-automatic graphitized inner-series furnace linkage conductive device according to claim 1, wherein the hinged position of the rear hinge rod (22) and the movable plate (11) is arranged on one side of the side edge of the movable plate (11) close to the bracket (12), and the hinged position of the front hinge rod (23) and the movable plate (11) is arranged on the side edge of the movable plate (11) close to the middle.

4. The full-automatic graphitized inner series furnace linkage conductive device according to claim 1, wherein a bottom carrier plate (14) is symmetrically fixed at one end of the upper side of the movable plate (11) far away from the placing plate (13), one end of the hydraulic rod (24) is hinged on the outer side wall of the bottom carrier plate (14), and the hinged position of the front hinge rod (23) and the movable plate (11) is higher than the hinged position of the hydraulic rod (24) and the bottom carrier plate (14).

5. The full-automatic graphitized inner series furnace linkage conductive equipment according to claim 1, wherein the bottom of the upward moving plate (21) is in contact with the upper surface of the bottom support plate (14), the upper surface of the bottom support plate (14) is an inclined surface inclined towards the direction approaching the placing plate (13), and the upward moving plate (21) forms a platform for a person to stand when the low-voltage transformer (3) moves onto the placing plate (13).