CN219390552U - Discharging equipment - Google Patents

Abstract

The utility model discloses discharging equipment which comprises an operation platform, a material collecting device, a material conveying device, a cooling device and a packaging device, wherein the operation platform is arranged above one graphitizing unit of a box-type graphitizing furnace; the material collecting device is provided with a material sucking part which can extend into each box body to suck materials; the material conveying device is provided with a feeding part and a discharging part, the feeding part is aligned with a discharging pipe of the material collecting device, and materials are unloaded from the discharging pipe to the feeding part; the cooling device is arranged around the outside of the material conveying device and used for cooling materials in the material conveying device; the packing device is aligned with the discharging part to receive and pack the materials from the material conveying device. According to the utility model, the discharging equipment can transfer materials without moving, the materials can be rapidly cooled in the transferring process, and the materials can be timely collected and packaged after being cooled, so that the discharging time of graphitized materials is shortened, the operating efficiency is improved, and the equipment and factory cost is reduced.

Description

Discharging equipment

Technical Field

The utility model relates to the technical field of manufacturing of lithium ion battery cathode materials, in particular to discharge equipment of a graphitization furnace.

Background

With the rapid development of new energy automobiles, digital electronic products and energy storage systems, lithium ion batteries are widely used. The artificial graphite anode material has good compatibility with organic electrolyte, obvious advantages in the aspects of cycle performance, multiplying power charge-discharge performance, temperature applicability and the like, and the market share is stabilized above 80%. Graphitization is a key step for producing the artificial graphite cathode material of the lithium ion battery, and the traditional Acheson crucible furnace has a tendency of being replaced by a box furnace with outstanding energy-saving effect and lower production cost due to high energy consumption and production cost.

After graphitizing the cathode material by a box furnace, the material is generally sucked into a temporary storage tank by a material sucking crown block, then the material sucking crown block moves to a discharging area to discharge the material, and the material is further cooled and treated and packaged. When unloading, the material sucking crown block needs to interrupt the material sucking operation and move to the unloading area for unloading, and the time consumed by unloading, cooling and cooling is long, so that the whole operation process efficiency is lower. Meanwhile, when the material absorbing crown block is continuously operated above the box body and repeatedly moved, magnetic foreign matters containing metal iron on the equipment and the roof of the factory building are easily introduced into the negative electrode material, so that the performance of the product is reduced. In addition, the material absorbing crown block is high in manufacturing cost, the weight of the material absorbing crown block and the weight of the negative electrode material in the storage tank are often more than 100 tons, and the requirement on the structural strength of the factory building is very high, so that the manufacturing cost of the factory building is also very high, and the investment of equipment and the factory building is excessively large.

Disclosure of Invention

The utility model mainly aims to provide a discharging device which can accelerate the cooling speed of materials, can pack the materials without transferring the devices and has low manufacturing cost, so as to shorten the time required by the whole discharging process, improve the production efficiency and reduce the investment of the devices and plants.

In order to achieve the above object, the present utility model provides a discharging apparatus for a box-type graphitizing furnace, wherein the discharging apparatus comprises:

the working platform is arranged above one graphitizing unit;

the material collecting device is arranged on the operation platform and is provided with a material sucking part, and the material sucking part can extend into each box body to suck materials;

the material conveying device is arranged on the working platform and is provided with a feeding part and a discharging part, the feeding part is aligned with a discharging pipe of the material collecting device, and materials are unloaded from the inside of the material collecting device to the feeding part of the material conveying device through the discharging pipe;

the cooling device is arranged around the outside of the material conveying device and used for cooling the materials conveyed from the feeding part to the discharging part; the method comprises the steps of,

the packaging device is arranged on the working platform, the packaging device is aligned with the discharging part of the material conveying device, the cooled material is transferred from the material conveying device to the packaging device through the discharging part, and the packaging device receives and packages the cooled material.

Preferably, the material collecting device comprises a vacuum feeder, and the vacuum feeder comprises:

the vacuum hopper is used for temporarily storing materials;

one end of the material sucking hose is communicated with the vacuum hopper, and the other end of the material sucking hose is provided with a stainless steel suction nozzle and can extend into the box body to suck materials into the vacuum hopper; the method comprises the steps of,

the vacuum generator is communicated with the vacuum hopper so as to form negative pressure in the vacuum hopper;

the material sucking part comprises the material sucking hose and a stainless steel suction nozzle.

Preferably, the material collecting device comprises a vacuum feeder, and the vacuum feeder comprises:

the vacuum hopper is communicated with the material sucking part and is used for temporarily storing materials sucked from the box body by the material sucking part;

the discharging pipe is arranged at the bottom of the vacuum hopper and is communicated with the vacuum hopper; the method comprises the steps of,

the blanking gate is arranged at the bottom of the inner cavity of the vacuum hopper and is in a closed state and an open state;

when the blanking gate is in a closed state, the blanking gate seals the bottom of the vacuum hopper so that negative pressure can be formed in the vacuum hopper;

when the blanking gate is in an open state, the vacuum hopper is communicated with the blanking pipe, and materials move from the inside of the vacuum hopper to the feeding part of the material conveying device through the blanking pipe.

Preferably, the material conveying device comprises a screw conveyer, a feeding hole is formed in one end of the screw conveyer, which is aligned with the discharging pipe of the material collecting device, and a discharging hole is formed in one end of the screw conveyer, which is aligned with the packaging device;

wherein, the feed portion includes the feed inlet, the discharge portion includes the discharge gate.

Preferably, the cooling device comprises a water-cooled sleeve sleeved around the outside of the material conveying device.

Preferably, the bottom side of the water-cooling sleeve is provided with a water inlet, and the top side of the water-cooling sleeve is provided with a water outlet.

Preferably, the packaging device comprises:

the conveying platform is arranged on the operation platform; the method comprises the steps of,

ton package is located along being close to or keeping away from the direction activity of material transfer device is located on the conveying platform, ton package's opening can with the ejection of compact portion counterpoint, in order to receive from the material of ejection of compact portion derivation.

Preferably, the discharging device further comprises a moving device, and the moving device can move the working platform along the arrangement direction of the graphitization units.

Preferably, the mobile device comprises:

the two guide rails are arranged above the furnace chamber along the arrangement direction of the graphitizing units;

the pulleys are arranged on two sides of the working platform and are matched with the corresponding guide rails so that the working platform can move along the arrangement direction of the graphitizing units; the method comprises the steps of,

and each motor is in driving connection with the corresponding pulley.

Preferably, the material of the discharging device comprises stainless steel.

The technical scheme of the utility model provides discharging equipment, which comprises an operation platform, wherein the operation platform is arranged above a graphitizing unit, and a material collecting device, a material conveying device and a packaging device are arranged on the operation platform, wherein a material sucking part of the material collecting device can extend into each box body of a box-type graphitizing furnace to suck materials; the material conveying device is provided with a feeding part and a discharging part, the feeding part is aligned with a discharging pipe of the material collecting device, and materials are unloaded from the material collecting device to the feeding part of the material conveying device through the discharging pipe; the material conveying device is provided with a cooling device for cooling the materials conveyed from the material feeding part to the material discharging part; the packing device is aligned with the discharging part of the material conveying device, the cooled material is transferred to the packing device from the material conveying device through the discharging part, and the packing device receives and packs the cooled material. The discharging equipment provided by the utility model is provided with the material conveying device, the cooling device and the packaging device, the discharging equipment can transfer the sucked materials without moving, the materials can be cooled in the process of transferring the materials, and the materials can be collected and packaged in time after being cooled, so that the discharging time of graphitized materials of the box-type graphitizing furnace is greatly shortened, the operating efficiency is improved, and the manufacturing cost of the equipment and a factory building is reduced.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to the structures shown in these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view of an embodiment of a discharging apparatus according to the present utility model;

FIG. 2 is a schematic diagram of the material collecting device in FIG. 1;

FIG. 3 is a schematic structural view of the material conveying device in FIG. 1;

FIG. 4 is a schematic cross-sectional view of the cooling device of FIG. 1;

FIG. 5 is a schematic diagram of a combined structure of a cooling device and a material conveying device;

fig. 6 is a schematic view of the packaging device in fig. 1:

fig. 7 is a schematic structural diagram of the graphitizing unit in fig. 1.

Reference numerals illustrate:

reference numerals	Name of the name	Reference numerals	Name of the name
				1000	Discharging equipment	41	Screw conveyor
1	Furnace chamber	42	Feed inlet
				11	Graphitization unit	4	Material conveying device
111	Box body	43	Discharge port
				2	Work platform	5	Cooling device
3	Material collecting device	51	Water-cooling sleeve
				31	Vacuum hopper	52	Water inlet
32	Vacuum generator	53	Water outlet
				33	Material sucking hose	6	Packaging device
34	Stainless steel suction nozzle	61	Conveying platform
				35	Discharging pipe	62	Ton bag

The achievement of the objects, functional features and advantages of the present utility model will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

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

It should be noted that all directional indicators (such as up, down, left, right, front, and rear … …) in the embodiments of the present utility model are merely used to explain the relative positional relationship, movement, etc. between the components in a particular posture (as shown in the drawings), and if the particular posture is changed, the directional indicator is changed accordingly.

Furthermore, the description of "first," "second," etc. in this disclosure is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present utility model.

With the rapid development of new energy automobiles, digital electronic products and energy storage systems, lithium ion batteries are widely used. The artificial graphite anode material has good compatibility with organic electrolyte, obvious advantages in the aspects of cycle performance, multiplying power charge-discharge performance, temperature applicability and the like, and the market share is stabilized above 80%. Graphitization is a key step for producing the artificial graphite cathode material of the lithium ion battery, and the traditional Acheson crucible furnace has a tendency of being replaced by a box furnace with outstanding energy-saving effect and lower production cost due to high energy consumption and production cost.

After graphitizing the cathode material by a box furnace, the material is generally sucked into a temporary storage tank by a material sucking crown block, then the material sucking crown block moves to a discharging area to discharge the material, and the material is further cooled and treated and packaged. When unloading, the material sucking crown block needs to interrupt the material sucking operation and move to the unloading area for unloading, and the time consumed by unloading, cooling and cooling is long, so that the whole operation process efficiency is lower. Meanwhile, when the material absorbing crown block is continuously operated above the box body and repeatedly moved, magnetic foreign matters containing metal iron on the equipment and the roof of the factory building are easily introduced into the negative electrode material, so that the performance of the product is reduced. In addition, the material absorbing crown block is high in manufacturing cost, the weight of the material absorbing crown block and the weight of the negative electrode material in the storage tank are often more than 100 tons, and the requirement on the structural strength of the factory building is very high, so that the manufacturing cost of the factory building is also very high, and the investment of equipment and the factory building is excessively large.

In order to solve the problems, the utility model provides a discharging device, which aims to provide a discharging device capable of accelerating the cooling speed of materials, packaging the materials without transferring the devices and having low manufacturing cost, so as to shorten the time required by the whole discharging process, improve the production efficiency and reduce the investment of the devices and plants. Fig. 1 to fig. 7 are schematic structural diagrams of an embodiment of a discharging device provided by the present utility model.

Referring to fig. 1 to 7, the present utility model proposes a discharging device 1000 for a box-type graphitizing furnace, where the box-type graphitizing furnace includes a furnace chamber 1, the furnace chamber 1 includes a plurality of rows of graphitizing units 11 disposed in front and back directions, the graphitizing units 11 include a plurality of box bodies 111 disposed in a left-right direction, the discharging device 1000 includes a working platform 2, a material collecting device 3, a material conveying device 4, a cooling device 5 and a packaging device 6, and the working platform 2 is disposed above one of the graphitizing units 11; the material collecting device 3 is arranged on the operation platform 2, and the material collecting device 3 is provided with a material sucking part which can extend into each box 111 to suck materials; the material conveying device 4 is arranged on the operation platform 2, the material conveying device 4 is provided with a feeding part and a discharging part, the feeding part is aligned with the blanking pipe 35 of the material collecting device 3, and materials are unloaded from the interior of the material collecting device 3 to the feeding part of the material conveying device 4 through the blanking pipe 35; the cooling device 5 is arranged around the outside of the material conveying device 4 and is used for cooling the materials conveyed from the feeding part to the discharging part; the packing device 6 is arranged on the working platform 2, the packing device 6 is aligned with the discharging part of the material conveying device 4, the cooled material is transferred from the material conveying device 4 to the packing device 6 through the discharging part, and the packing device 6 receives and packs the cooled material.

The technical scheme of the utility model provides a discharging device 1000, which comprises an operation platform 2, wherein the operation platform 2 is arranged above a graphitization unit 11, and the operation platform 2 is provided with a material collecting device 3, a material conveying device 4 and a packaging device 6, wherein a material sucking part of the material collecting device 3 can extend into each box 111 to suck materials; the material conveying device 4 is provided with a feeding part and a discharging part, the feeding part is aligned with a discharging pipe 35 of the material collecting device 3, and materials are unloaded from the interior of the material collecting device 3 to the feeding part of the material conveying device 4 through the discharging pipe 35; the cooling device 5 is arranged around the outside of the material conveying device 4 so as to cool the materials conveyed from the feeding part to the discharging part; the packing device 6 is aligned with the discharging part of the material conveying device 4, the cooled material is transferred from the material conveying device 4 to the packing device 6 through the discharging part, and the packing device 6 receives and packs the cooled material. The discharging equipment 1000 is provided with the material conveying device 4, the cooling device 5 and the packaging device 6, the discharging equipment 1000 can transfer the sucked materials without moving, can cool the materials in the process of transferring the materials, can collect and package the materials in time after cooling, greatly shortens the discharging time of graphitized materials of the whole box-type graphitizing furnace system, has lower manufacturing cost and has low requirements on the structural strength of a factory building.

The material collecting device 3 may be a vacuum pump or a vacuum generator, and the utility model is not particularly limited to this. Compared with a vacuum pump, the vacuum generator has the advantages of simple structure, small volume, light weight and small vibration, and therefore, the vacuum generator is preferable to form negative pressure in the utility model.

Specifically, as shown in fig. 2, the material collecting device 3 includes a vacuum feeder, the vacuum feeder includes a vacuum hopper 31, a vacuum generator 32 and a material sucking hose 33, the vacuum hopper 31 is used for temporarily storing materials, the vacuum generator 32 is communicated with the vacuum hopper 31 so as to form negative pressure in the vacuum hopper 31, one end of the material sucking hose 33 is communicated with the vacuum hopper 31, and the other end is provided with a stainless steel suction nozzle 34 and can extend into the box body, and the materials are sucked into the vacuum hopper 31 under the action of the negative pressure; wherein the suction part comprises the suction hose 33 and a stainless steel suction nozzle 34.

In order to transfer the material from the material collecting device 3 to the material transferring device 4, in an embodiment of the present utility model, the material collecting device 3 includes a vacuum feeder, the vacuum feeder includes a vacuum hopper 31, a discharging pipe 35 and a discharging gate, the vacuum hopper 31 is communicated with the material sucking part, and the vacuum hopper 31 is used for temporarily storing the material sucked by the material sucking part from the box 111; the blanking pipe 35 is arranged at the bottom of the vacuum hopper 31 and is communicated with the vacuum hopper 31, the blanking gate is arranged at the bottom of an inner cavity of the vacuum hopper 31 and is positioned above the blanking pipe 35, and the blanking gate has a closed state and an open state, wherein when the blanking gate is in the closed state, the blanking gate seals the bottom of the vacuum hopper 31, and the vacuum hopper 31 and the blanking pipe 35 are disconnected from each other so that negative pressure can be formed in the vacuum hopper 31; when the discharging gate is in an open state, the vacuum hopper 31 is communicated with the discharging pipe 35, the negative pressure in the vacuum hopper 31 disappears, and the material moves from the inside of the vacuum hopper 31 to the feeding part of the material conveying device 4 through the discharging pipe 35.

The material conveying device 4 may be a conveyor belt or a screw conveyor, which is not particularly limited in the present utility model. Compared with a conveyor belt, the screw conveyor continuously turns up and down in the process of conveying materials, the temperature of the materials at each position is uniform, and the materials can be fully cooled by the cooling device 5, so that the cooling time is shortened.

Specifically, as shown in fig. 3, the material conveying device 4 includes a screw conveyor 41, a feeding port 42 is disposed at an end of the screw conveyor 41 aligned with the discharging pipe 35 of the material collecting device 3 to receive the material from the vacuum hopper 31, and a discharging port 43 is disposed at an end of the screw conveyor 41 aligned with the packaging device 6 to transfer the material to the packaging device 6; wherein, the feeding part comprises the feeding hole 42, and the discharging part comprises the discharging hole 43.

The cooling device 5 may be a fan or a water-cooled jacket, which is not particularly limited in the present utility model. Compare in fan cooling inefficiency, and can cause the operating area raise dust, the water-cooling sleeve pipe can be right all materials in the pass material device 4 cool off fast to maintain operational environment.

Specifically, as shown in fig. 4 and 5, the cooling device 5 includes a water-cooling sleeve 51, and the water-cooling sleeve 51 is disposed around the outside of the material conveying device 4 to cool the material in the material conveying device 4.

It will be appreciated that, in order to ensure the cooling effect of the water-cooling jacket 51 on the material, in an embodiment of the present utility model, a water inlet 52 is provided at the bottom side of the water-cooling jacket 51, and a water outlet 53 is provided at the top side of the water-cooling jacket 51, so that the water-cooling jacket 51 is filled with cooling water.

As shown in fig. 6, in order to timely transfer the cooled material to reduce the load of the working platform 2, in an embodiment of the present utility model, preferably, the packaging device 6 includes a conveying platform 61 and a ton bag 62, the conveying platform 61 is disposed on the working platform 2, the ton bag 62 is movably disposed on the conveying platform 61 along a direction approaching or separating from the material conveying device 4, an opening of the ton bag 62 can be aligned with a discharging portion of the material conveying device 4 to receive the material guided from the discharging portion, when the material received by the ton bag 62 reaches a predetermined amount, the conveying platform 61 conveys the ton bag 62 along a direction separating from the material conveying device 4, and then the ton bag 62 storing the material is taken away from the working platform 2 to reduce the load of the working platform 2, and the material conveying device 4, the cooling device 5 and the packaging device 6 cooperate to complete cooling and packaging during the material collecting process of the material collecting device 3, so that the time required for collecting and packaging is greatly shortened. The conveying platform 61 may be a roller conveyor, a belt conveyor, or other types of conveyors, which are not particularly limited in the present utility model.

In order to facilitate the movement of the discharging apparatus 1000 above the graphitizing units 11 of the furnace chamber 1 for taking the material, in an embodiment of the present utility model, the discharging apparatus 1000 further includes a moving device capable of moving the working platform 2 along the arrangement direction of the plurality of graphitizing units 11, and the moving device moves the discharging apparatus 1000 above the graphitizing units 11 that are not taken and takes the material after the material in the boxes 111 of the graphitizing units 11 below the discharging apparatus 1000 is sucked.

It should be noted that the mobile device may be a travelling crane or a sliding component, which is not particularly limited in the present utility model. The use of a sliding assembly to move the outfeed device 1000 is more energy efficient than the use of a travelling crane, and thus the present utility model prefers a sliding assembly as the moving means.

Specifically, the moving device includes two guide rails, a plurality of pulleys and a plurality of motors, the two guide rails are arranged above the furnace chamber 1 along the arrangement direction of the graphitizing units 11, the pulleys are arranged on two sides of the working platform 2, the pulleys are matched with the corresponding guide rails, and the motors are in driving connection with the corresponding pulleys so as to drive the working platform 2 to move along the arrangement direction of the graphitizing units 11.

In order to avoid introducing magnetic foreign matters such as rust into the material, in an embodiment of the utility model, the material of the discharging device 1000 includes stainless steel, so as to prevent the material from being doped with the magnetic foreign matters such as rust, and ensure the performance of the material.

The foregoing description is only of the preferred embodiments of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structural changes made by the description of the present utility model and the accompanying drawings or direct/indirect application in other related technical fields are included in the scope of the utility model.

Claims (10)

1. A discharging device for box graphitizing furnace, box graphitizing furnace includes the stove chamber, the stove chamber includes the graphitizing unit of multirow fore-and-aft direction setting, graphitizing unit includes a plurality of boxes of controlling to arranging the setting, its characterized in that, discharging device includes:

the working platform is arranged above one graphitizing unit;

the material collecting device is arranged on the operation platform and is provided with a material sucking part, and the material sucking part can extend into each box body to suck materials;

the material conveying device is arranged on the working platform and is provided with a feeding part and a discharging part, the feeding part is aligned with a discharging pipe of the material collecting device, and materials are unloaded from the inside of the material collecting device to the feeding part of the material conveying device through the discharging pipe;

the cooling device is arranged around the outside of the material conveying device and used for cooling the materials conveyed from the feeding part to the discharging part; the method comprises the steps of,

the packaging device is arranged on the working platform, the packaging device is aligned with the discharging part of the material conveying device, the cooled material is transferred from the material conveying device to the packaging device through the discharging part, and the packaging device receives and packages the cooled material.

2. The discharge apparatus of claim 1, wherein the mining device comprises a vacuum feeder comprising:

the vacuum hopper is used for temporarily storing materials;

one end of the material sucking hose is communicated with the vacuum hopper, and the other end of the material sucking hose is provided with a stainless steel suction nozzle and can extend into the box body to suck materials into the vacuum hopper; the method comprises the steps of,

the vacuum generator is communicated with the vacuum hopper so as to form negative pressure in the vacuum hopper;

the material sucking part comprises the material sucking hose and a stainless steel suction nozzle.

3. The discharge apparatus of claim 1, wherein the mining device comprises a vacuum feeder comprising:

the vacuum hopper is communicated with the material sucking part and is used for temporarily storing materials sucked from the box body by the material sucking part;

the discharging pipe is arranged at the bottom of the vacuum hopper and is communicated with the vacuum hopper; the method comprises the steps of,

the blanking gate is arranged at the bottom of the inner cavity of the vacuum hopper and is in a closed state and an open state;

when the blanking gate is in a closed state, the blanking gate seals the bottom of the vacuum hopper so that negative pressure can be formed in the vacuum hopper;

when the blanking gate is in an open state, the vacuum hopper is communicated with the blanking pipe, and materials move from the inside of the vacuum hopper to the feeding part of the material conveying device through the blanking pipe.

4. The discharging device according to claim 1, wherein the material conveying device comprises a screw conveyor, a feeding port is arranged at one end of the screw conveyor aligned with the discharging pipe of the material collecting device, and a discharging port is arranged at one end of the screw conveyor aligned with the packaging device;

wherein, the feed portion includes the feed inlet, the discharge portion includes the discharge gate.

5. The tapping device according to claim 1, wherein the cooling means comprises a water cooled jacket, which jacket is arranged around the outside of the material conveying means.

6. The discharge apparatus of claim 5, wherein the bottom side of the water-cooled jacket is provided with a water inlet and the top side of the water-cooled jacket is provided with a water outlet.

7. The outfeed apparatus of claim 1, wherein said packaging device comprises:

the conveying platform is arranged on the operation platform; the method comprises the steps of,

ton package is located along being close to or keeping away from the direction activity of material transfer device is located on the conveying platform, ton package's opening can with the ejection of compact portion counterpoint, in order to receive from the material of ejection of compact portion derivation.

8. The discharge apparatus of claim 1, further comprising a moving device capable of moving the work platform in the direction of arrangement of the plurality of graphitization units.

9. The outfeed apparatus of claim 8, wherein the moving means comprises:

the two guide rails are arranged above the furnace chamber along the arrangement direction of the graphitizing units;

the pulleys are arranged on two sides of the working platform and are matched with the corresponding guide rails so that the working platform can move along the arrangement direction of the graphitizing units; the method comprises the steps of,

and each motor is in driving connection with the corresponding pulley.

10. The tapping device according to claim 1, wherein the tapping device comprises stainless steel.