CN221092360U - Broken material feeding unit of lithium cell electricity core - Google Patents

Abstract

The utility model discloses a lithium battery cell crushing and feeding device, which comprises a conveying belt which circularly operates, wherein rotating rollers are sleeved on two sides of the conveying belt, a plurality of ribs are arranged on the outer side surface of the conveying belt, a plurality of rollers are uniformly arranged on two corresponding sides of the conveying belt, and wheel grooves for supporting and rolling the rollers are arranged on two corresponding sides of a conveying part on the upper side of the conveying belt. Because the conveyer belt is the rubber material, and the transport of electric core crushed aggregates needs certain bearing capacity, so conveyer belt both sides installation gyro wheel improves the supporting strength, and the wheel groove can be used as electrolyte collecting vat simultaneously, because the conveyer belt upside has the rib, in the transportation process, electrolyte can flow to the contained angle position between rib and the conveyer belt surface, then flows to both sides along the contained angle position, finally flows to the wheel groove, through the same collection in wheel groove end, prevents that electrolyte from flowing everywhere problem.

Description

Broken material feeding unit of lithium cell electricity core

Technical Field

The utility model belongs to the technical field of lithium battery crushing and recycling, and particularly relates to a lithium battery cell crushing and feeding device.

Background

A lithium iron phosphate battery is an ionic battery using lithium iron phosphate (LiFePO ₄) as a positive electrode material and carbon as a negative electrode material. During charging, lithium ions enter electrolyte from the surface of the lithium iron phosphate crystal under the action of an electric field force, pass through a diaphragm, migrate to the surface of the graphite crystal and then are intercalated into a graphite lattice. After lithium ions are deintercalated from the lithium iron phosphate, the lithium iron phosphate is converted into ferric phosphate, and when the lithium ions are discharged, the lithium ions are deintercalated from the graphite crystal, enter electrolyte, pass through a diaphragm, migrate to the surface of the lithium iron phosphate crystal, and then are re-intercalated into the crystal lattice of the lithium iron phosphate. The lithium iron phosphate battery has the advantages of high working voltage, high energy density, long cycle life, good safety performance, small self-discharge rate and no memory effect.

Along with the popularization of new energy, more and more lithium battery industries are developed, and meanwhile, huge waste battery recycling problems are brought, and the batteries contain various heavy metals and are directly discarded to easily cause pollution problems. The lithium iron phosphate battery has huge recycling value, and the recycling of the lithium battery comprises the steps of crushing, separating, filtering, screening and the like. The battery crushing process is completed in a plurality of steps, namely shearing and crushing, then filtering electrolyte, drying, grinding and crushing and the like, wherein the process is a continuous working process, all equipment is conveyed by a conveying belt, broken battery cell waste residues are filtered by the electrolyte, but remain, the electrolyte flows to two sides easily in the conveying process of the conveying belt, and workshop pollution is caused because the electrolyte is difficult to collect. The utility model is thus improved on the basis of a conveyor belt, facilitating the collection of insufficiently filtered electrolyte.

Disclosure of utility model

The utility model aims to provide a lithium battery cell crushing and feeding device, which is improved on the basis of a conveying belt and is convenient for collecting insufficiently filtered electrolyte.

In order to solve the technical problems, the utility model is realized by the following technical scheme:

the utility model provides a broken material feeding unit of lithium cell electricity core, includes the conveyer belt of circulation operation, the both sides of conveyer belt have cup jointed the roller, the conveyer belt lateral surface is provided with a plurality of arriss, the arriss length direction is perpendicular with the conveyer belt direction of operation, the arriss is along conveyer belt length direction even arrangement;

The conveying belt is characterized in that a plurality of rollers are uniformly arranged on two corresponding sides of the conveying belt, and wheel grooves for supporting and rolling the rollers are arranged on two corresponding sides of a conveying part on the upper side of the conveying belt.

Further, the rollers on two sides corresponding to the conveying belt are symmetrically arranged, the symmetrically arranged rollers are sleeved at two ends of the same rotating shaft, and the side of the conveying belt is provided with a shaft sleeve sleeved with the rotating shaft.

Further, the roller comprises a roller shaft, the roller shaft is sleeved with a fluted disc, and a tooth slot corresponding to the fluted disc is clamped with the rotating shaft and used for driving the conveying belt to run.

Further, the rotating roller is divided into a driving roller and a driven roller, the end part of the roller shaft corresponding to the driving roller is sleeved with a belt pulley, and the belt pulley is in driving fit through a motor.

Further, baffles for protecting fluted discs are arranged on two sides of the conveying belt, and through holes for the roll shafts to pass through are formed in the baffles.

Further, the wheel groove is provided with an arc section which is bent outwards corresponding to the end part of the rotating roller.

The utility model has the following beneficial effects: because the conveyer belt is the rubber material, and the transport of electric core crushed aggregates needs certain bearing capacity, so conveyer belt both sides installation gyro wheel improves the supporting strength, and the wheel groove can be used as electrolyte collecting vat simultaneously, because the conveyer belt upside has the rib, in the transportation process, electrolyte can flow to the contained angle position between rib and the conveyer belt surface, then flows to both sides along the contained angle position, finally flows to the wheel groove, through the same collection in wheel groove end, prevents that electrolyte from flowing everywhere problem.

Drawings

In order to more clearly illustrate the technical solution of the embodiments of the present utility model, the drawings used for describing the embodiments will be briefly described below.

Fig. 1: the utility model relates to a rotary roller disassembling structure schematic diagram.

Fig. 2: the wheel groove disassembling structure of the utility model is schematically shown.

Fig. 3: the whole installation structure of the utility model is schematically shown.

In the drawings, the list of components represented by the various numbers is as follows: conveyor belt 1, rib 11, gyro wheel 2, wheel groove 3, pivot 21, axle sleeve 12, roller 41, fluted disc 4, belt pulley 42, baffle 5, arc section 31.

Detailed Description

The following description of the embodiments of the present utility model 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 utility model, but not all embodiments.

As shown in fig. 1-3: the utility model provides a broken material feeding unit of lithium cell electricity core, includes conveyer belt 1 of circulation operation, and the both sides of conveyer belt 1 cup joint the roller, and conveyer belt 1 lateral surface is provided with a plurality of arriss 11, and the arriss is fixed with the conveyer belt is perpendicular integrative, and the arriss 11 length direction is perpendicular with conveyer belt 1 running direction, and arriss 1 is along conveyer belt 1 length direction even arrangement; the conveyer belt is the rubber material, and the rib can strengthen the supporting strength of conveyer belt on the one hand, and simultaneously, the installation of most conveyer belts is the slope installation, and the pay-off of being convenient for is to the eminence, and the rib forms step formula check and keeps off, and the crushed electric core crushed aggregates of mode landing on the conveyer belt.

A plurality of rollers 2 are uniformly arranged on two corresponding sides of the conveying belt 1, and wheel grooves 3 for supporting and rolling the rollers 2 are arranged on two corresponding sides of the conveying part on the upper side of the conveying belt 1. The wheel groove is strip, and the cross-section is 匚 shape for providing the gyro wheel and support and roll, because the conveyer belt is the rubber material, and the transport of electricity core crushed aggregates needs certain bearing capacity, so conveyer belt both sides installation gyro wheel improves the support intensity, and the wheel groove can be used as electrolyte collecting vat simultaneously, because the conveyer belt upside has the arris, in-process, the electrolyte can flow to the contained angle position between arris and the conveyer belt surface, then flows to both sides along contained angle position, finally flows to the wheel groove, through the same collection in wheel groove end, prevents that the electrolyte from flowing everywhere problem.

As shown in fig. 1-3: the rollers 2 on two sides corresponding to the conveyer belt 1 are symmetrically arranged, the symmetrically arranged rollers 2 are sleeved at two ends of the same rotating shaft 21, and the side of the conveyer belt 1 is provided with a shaft sleeve 12 sleeved with the rotating shaft. The shaft sleeve is integrally arranged with the conveyer belt, the rotating shaft is perpendicular to the running direction of the conveyer belt and is used for rotating the rollers, and meanwhile, the supporting strength of the conveyer belt is improved.

The rotating roller comprises a roller shaft 41, the roller shaft 41 is sleeved with a fluted disc 4, and a tooth slot corresponding to the fluted disc 4 is clamped with the rotating shaft 21 and used for driving the conveying belt 1 to run. The slipping position can be prevented, and the driving effect is improved. The rotating roller is divided into a driving roller and a driven roller, the end part of the roller shaft corresponding to the driving roller is sleeved with a belt pulley 42, and the driving roller and the driven roller are in driving fit through a motor. Baffle plates 5 for protecting fluted disc are arranged on two sides of the conveyor belt 1, and through holes for the roll shafts 41 to pass through are formed in the baffle plates 5. Preventing the safety problem of fluted disc operation and operation outgoing line.

As shown in fig. 2: the wheel groove 3 is provided with an arc-shaped section 31 bent outwards at the end position corresponding to the rotating roller. The device is used for smooth transition of the roller, so that the roller and the wheel groove can be accurately positioned.

The embodiments were chosen and described in order to best explain the principles of the utility model and the practical application, to thereby enable others skilled in the art to best understand and utilize the utility model.

Claims (6)

1. The utility model provides a broken material feeding unit of lithium cell electricity core which characterized in that:

The automatic conveying device comprises a conveying belt (1) which circularly operates, rotating rollers are sleeved on two sides of the conveying belt (1), a plurality of ribs (11) are arranged on the outer side face of the conveying belt (1), the length direction of each rib (11) is perpendicular to the operation direction of the conveying belt (1), and the ribs (11) are uniformly arranged along the length direction of the conveying belt (1);

The conveying belt is characterized in that a plurality of rollers (2) are uniformly arranged on two corresponding sides of the conveying belt (1), and wheel grooves (3) used for supporting and rolling the rollers (2) are arranged on two corresponding sides of a conveying part on the upper side of the conveying belt (1).

2. The lithium battery cell crushing and feeding device according to claim 1, wherein: the conveying belt is characterized in that rollers (2) on two sides corresponding to the conveying belt (1) are symmetrically arranged, the symmetrically arranged rollers (2) are sleeved at two ends of the same rotating shaft (21), and shaft sleeves (12) sleeved on the rotating shaft are arranged on the side of the conveying belt (1).

3. The lithium battery cell crushing and feeding device according to claim 2, wherein: the rotary roller comprises a roller shaft (41), the roller shaft (41) is sleeved with a fluted disc (4), and a tooth slot corresponding to the fluted disc (4) is clamped with the rotary shaft (21) and used for driving the conveying belt (1) to run.

4. A lithium battery cell crushing and feeding device according to claim 3, wherein: the rotary roller is divided into a driving roller and a driven roller, the end part of a roller shaft corresponding to the driving roller is sleeved with a belt pulley (42), and the belt pulley is in driving fit through a motor.

5. A lithium battery cell crushing and feeding device according to claim 3, wherein: baffle plates (5) for protecting fluted discs are arranged on two sides of the conveying belt (1), and through holes for the roll shafts (41) to pass through are formed in the baffle plates (5).

6. The lithium battery cell crushing and feeding device according to claim 1, wherein: the wheel groove (3) is provided with an arc section (31) which is bent outwards corresponding to the end part of the rotating roller.