CN112964027A - Small-capacity heat conduction type vacuum drying device and intelligent drying system thereof - Google Patents

Abstract

In new energy automobiles, lithium batteries are indispensable parts and are more important power sources. In the production process of the lithium battery, the lithium battery material needs to be dried first, and then the liquid injection process can be continued. The utility model belongs to the technical field of battery drying equipment technique and specifically relates to a heat-conduction formula vacuum drying device of small capacity is related to, it includes the base, installs closing plate, evacuation subassembly and heating element on the base, the base has the cavity, install the backup pad in the cavity of base, lithium cell material place in the backup pad, the closing plate is used for sealing the cavity of base, evacuation subassembly intercommunication the base, heating element is used for right the cavity of base heats. This application has the effect of the long problem consuming time of dewatering mode among the improvement correlation technique.

Description

Small-capacity heat conduction type vacuum drying device and intelligent drying system thereof

Technical Field

The application relates to the technical field of battery drying equipment, in particular to a small-capacity heat conduction type vacuum drying device and an intelligent drying system thereof.

Background

With the progress of science and technology, new energy automobiles have started to be popularized continuously. The new energy automobile generally refers to an automobile which adopts unconventional automobile fuel as a power source (or adopts conventional automobile fuel and a novel vehicle-mounted power device), integrates advanced technologies in the aspects of power control and driving of the automobile, and is advanced in technical principle, new in technology and new in structure.

In new energy automobiles, lithium batteries are indispensable parts and are more important power sources. In the production process of the lithium battery, the lithium battery material needs to be dried first, and then the subsequent liquid injection process can be carried out continuously. At present, generally, carry out the drying to lithium battery material through the oven, put into the oven lithium battery material promptly, start the oven, the oven removes water to lithium battery material after vacuum dewatering, intensification and the three step of cooling.

With respect to the related art among the above, the inventors consider that the following drawbacks occur: in the related art, the mode of removing water from the lithium battery material through the oven generally heats the lithium battery material through a heat radiation mode, and the oven has a slow heating speed due to the large volume and capacity of the oven, that is, the drying time is long, and the efficiency requirement in production is difficult to meet.

Disclosure of Invention

In order to solve the problem that the dewatering mode is long in time consumption in the related art, the application provides a small-capacity heat conduction type vacuum drying device and an intelligent drying system thereof.

The technical scheme provided by the application is as follows:

in a first aspect, the present application provides a small-capacity conduction-type vacuum drying device, which adopts the following technical scheme:

the utility model provides a small capacity heat-conduction formula vacuum drying device, includes the base, installs closing plate, evacuation subassembly and heating element on the base, the base has the cavity, install the backup pad in the cavity of base, lithium battery material place in the backup pad, the closing plate is used for sealing the cavity of base, evacuation subassembly intercommunication the base, heating element is used for right the cavity of base heats.

Through adopting above-mentioned technical scheme, when needs remove water to lithium cell or lithium cell material, put into the cavity of base with lithium cell or lithium cell material, use the closing plate to seal the base afterwards, start evacuation subassembly after to the base evacuation, the heating element in the base of restarting, just can remove water to lithium cell or lithium cell material in the base, relative ratio is in the oven, under the condition of same heating power, the volume of base is less, the programming rate of temperature of base is fast and the temperature distribution in the base is more even, lithium cell or lithium cell material that are located in the base can be heated more evenly and carry out the dewatering, then accelerate the drying rate to the lithium cell, thereby the longer problem of dewatering mode among the correlation technique has been improved.

Optionally, a heating groove is formed in the base, heating oil is filled in the heating groove, the heating assembly comprises a heat conduction sleeve and an electric heating tube, the heat conduction sleeve is installed on the base and immersed in the heating oil, the electric heating tube is installed in the heat conduction sleeve, and two sides of the width direction of the supporting plate are attached to the inner wall of the base.

Through adopting above-mentioned technical scheme, when the cavity of base was heated to needs, start the electrothermal tube, the electrothermal tube just can heat up to heat the heating oil in the heating tank, after the temperature rise of heating oil, heating oil will give the backup pad with heat transfer, thereby heats the lithium cell material of placing in the backup pad.

Optionally, the heat-conducting sleeve is provided with an installation flange, and the installation flange is in threaded connection with the base.

Through adopting above-mentioned technical scheme, the heat conduction sleeve just installs on the base through threaded connection's mode, because threaded connection has the advantage of the dismouting of being convenient for, is convenient for pull down the heat conduction sleeve from the base and changes or maintain, increases vacuum drying device's convenient usability.

Optionally, a sliding block is arranged on the sealing plate, a sliding groove is formed in the base, and the sliding block is connected with the sliding groove in a sliding mode.

By adopting the technical scheme, the closing plate is arranged on the base in a sliding connection mode, and the closing plate can slide on the base by applying a pushing force or a pulling force to the closing plate, so that the opening and closing of the cavity of the base are controlled.

Optionally, the sliding groove is a T-shaped groove, and the shape of the sliding block is matched with the shape of the sliding groove.

Through adopting above-mentioned technical scheme, through setting up the spout into T type groove, and the shape adaptation of the shape of slider and spout, when the slider slides in the spout, the slider is difficult for following the roll-off in the spout to increase the job stabilization nature of closing plate.

Optionally, a driving assembly is installed on the base and comprises a driving motor and a threaded rod, the driving motor and the threaded rod are installed on the base, a threaded hole is formed in the sliding block, the threaded rod is in threaded connection with the threaded hole of the sliding block, and one end of the threaded rod is coaxially installed with the output end of the driving motor.

Through adopting above-mentioned technical scheme, through setting up drive assembly, just can realize the drive to the closing plate through drive assembly, start driving motor, driving motor can drive the threaded rod rotatory, and rotatory threaded rod can drive the slider and slide in the spout. The closing plate does not need to be opened and closed manually, and the convenience and the usability of the vacuum drying device are improved.

Optionally, install the pushing assembly in the base, the pushing assembly is including installing cylinder and installation on the base push pedal on the cylinder, the pushing assembly be used for with lithium battery material in the backup pad is released from the base.

Through adopting above-mentioned technical scheme, lithium battery material in the base is by the dry back, opens the closing plate, starts the cylinder, and the cylinder just can drive the push pedal ejecting to place lithium battery material in the backup pad and release from the base, through setting up the promotion subassembly, need not the manual work lithium battery material in the base of taking, increase vacuum drying device's convenient usability.

In a second aspect, the present application provides an intelligent drying system, which adopts the following technical scheme:

an intelligent drying system, comprising a support frame and at least two small-capacity heat conduction type vacuum drying devices installed on the support frame, wherein the small-capacity heat conduction type vacuum drying devices are the small-capacity heat conduction type vacuum drying devices as claimed in any one of claims 1 to 7.

Through adopting above-mentioned technical scheme, through set up a plurality of small capacity heat conduction formula vacuum drying device on the support frame, can dry a plurality of lithium battery material simultaneously to raise the efficiency.

Optionally, the lithium battery charging rack further comprises a collecting assembly, wherein the collecting assembly comprises a discharging pipeline and a collecting box, the discharging pipeline is communicated with the collecting box, the discharging pipeline is located on one side of the supporting frame, and lithium battery materials can enter the discharging pipeline after being taken out of the base.

Through adopting above-mentioned technical scheme, through setting up unloading pipeline and collecting box, lithium battery material is dry back in the base, can take out lithium battery material from the base and place on the unloading pipeline, and lithium battery material just can slide on the unloading pipeline and get into and collect in the collecting box.

Optionally, a plurality of damping springs and elastic pieces are installed in the collecting box, one ends of the damping springs are installed in the collecting box, and the other ends of the damping springs are fixedly connected with the elastic pieces.

Through adopting above-mentioned technical scheme, through setting up damping spring and elastic component, when lithium battery material transported to the collecting box in through the unloading pipeline, damping spring and elastic component can take place elastic deformation, and lithium battery material is difficult for receiving the damage in unloading and the collection process promptly.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the small-capacity heat conduction type vacuum drying device comprises a base, a supporting plate, a sealing plate, a vacuumizing assembly and a heating assembly, when lithium battery materials are required to be dried, the lithium battery materials are placed on the supporting plate, the sealing plate is used for sealing the base, the vacuumizing assembly is started to vacuumize the base, then the heating assembly is started to heat a cavity of the base, the lithium battery materials in the base can be heated and dried, the capacity of the base is small, the heating speed of the base is high, the heating and drying speed of the lithium battery materials in the base can be accelerated, and therefore the problem that water removal in the related technology is long in time consumption is solved;

2. the small-capacity heat conduction type vacuum drying device further comprises a pushing assembly, the pushing assembly is arranged, after lithium battery materials in the base are dried, the pushing assembly is started, the lithium battery materials can be pushed out from the base by the pushing assembly, manual work is not needed for taking the lithium battery materials, and the convenience and the usability of the vacuum drying device are improved.

Drawings

FIG. 1 is a schematic structural diagram of a small-capacity heat-transfer vacuum drying apparatus according to an embodiment of the present invention;

FIG. 2 is a schematic cross-sectional view of a small-capacity heat-transfer vacuum drying apparatus according to an embodiment of the present application;

FIG. 3 is an enlarged partial schematic view of portion A of FIG. 2;

FIG. 4 is another schematic cross-sectional view of a small-capacity heat-transfer vacuum drying apparatus according to an embodiment of the present application;

FIG. 5 is a schematic structural diagram of an intelligent drying system according to an embodiment of the present application;

fig. 6 is a schematic view illustrating installation of the elastic member and the damper spring in fig. 5.

Description of reference numerals: 1. a base; 11. a heating tank; 12. a chute; 2. a support plate; 3. a closing plate; 31. a slider; 4. a vacuum pumping assembly; 5. a heating assembly; 51. a thermally conductive sleeve; 511. installing a folded edge; 52. an electric heating tube; 6. a drive assembly; 61. a drive motor; 7. a pushing assembly; 71. pushing the plate; 72. a cylinder; 8. a support frame; 9. a collection assembly; 91. a blanking pipeline; 92. a collection box; 921. an elastic member; 922. a shock absorbing spring.

Detailed Description

The present application is described in further detail below with reference to figures 1-6.

The embodiment of the application discloses a small-capacity heat conduction type vacuum drying device. Referring to fig. 1, the small-capacity heat-conduction vacuum drying apparatus includes a base 1, a support plate 2 installed in the base 1, a closing plate 3 installed on the base 1, a vacuum pumping assembly 4, and a heating assembly 5. When using the heat-conduction formula vacuum drying device of small capacity, place lithium battery material in backup pad 2, seal base 1 with closing plate 3 afterwards, start evacuation subassembly 4 and heating element 5, just can dry the lithium battery material in the base 1.

Referring to fig. 1 and 2, specifically, base 1 is the cuboid type, has the cavity in the base 1, and backup pad 2 installs in the cavity of base 1, and backup pad 2 is the cuboid type, and backup pad 2 specifically can be installed in the cavity of base 1 through the welded mode, and backup pad 2 specifically can be the copper, and backup pad 2 specifically also can be silver board, and backup pad 2 specifically also can be diamond plate, as long as backup pad 2 can quick heat conduction can. Through setting up backup pad 2, can place lithium battery material in backup pad 2, be convenient for then follow-up heating and drying, it needs to explain that 2 width direction's of backup pad both ends butt is on the inner wall of base 1 to be convenient for heat conduction. The closing plate 3 is used for closing the cavity of the base 1. The sealing plate 3 is in a cuboid shape, in order to be installed on the base 1, two sliding blocks 31 are arranged on the sealing plate 3, the sliding blocks 31 are in a T shape, correspondingly, two sliding grooves 12 are formed in the base 1, the sliding grooves 12 are T-shaped grooves and are matched with the sliding blocks 31, and the sliding blocks 31 are in sliding connection with the sliding grooves 12. Therefore, the closing plate 3 can be driven to slide on the base 1 by applying a pushing force or a pulling force to the closing plate 3, and then the opening and closing of the cavity of the base 1 are controlled by the closing plate 3.

In order to drive the sealing plate 3 to slide on the base 1, a driving assembly 6 is installed on the base 1, the driving assembly 6 comprises a driving motor 61 and a threaded rod, the driving motor 61 and the threaded rod are installed on the base 1, the threaded rod is cylindrical, the axis of the threaded rod is horizontally arranged, and one end of the threaded rod is coaxially installed with the output shaft of the driving motor 61. Correspondingly, a threaded hole is formed in one of the sliding blocks 31 of the closing plate 3, and the threaded rod is in threaded connection with the threaded hole of the sliding block 31. Therefore, by starting the driving motor 61, the driving motor 61 drives the threaded rod to rotate, and the rotating threaded rod drives the sliding block 31 to slide in the sliding groove 12, that is, the sealing plate 3 is driven to slide on the base 1.

Referring to fig. 2 and 3, the vacuum pumping assembly 4 is used to evacuate the cavity of the base 1. Specifically, a through hole is formed above the base 1, and the vacuum pumping assembly 4 comprises a conduit and a vacuum pump which are arranged in the through hole of the base 1. One end of the conduit is arranged on the through hole of the base 1, and the other end of the conduit is arranged on the vacuum pump. By activating the vacuum pump, the vacuum pump will evacuate the cavity of the base 1. The specific structure and the working principle of the vacuum pump are related technologies, and are not described in detail.

The heating assembly 5 is used for heating the cavity of the base 1. Specifically, heating tank 11 has been seted up on base 1, and heating tank 11 has two, and heating tank 11's vertical cross-section is rectangle, and two heating tank 11 are located base 1 width direction's both ends respectively, and heating tank 11 intussuseption is filled with heating oil, has still seted up the through-hole on the base 1, through-hole intercommunication heating tank 11 on the base 1. Heating element 5 includes heat conduction sleeve 51 and electrothermal tube 52, and heat conduction sleeve 51 is the cuboid type, and heat conduction sleeve 51 installs on base 1, is equipped with installation hem 511 on the heat conduction sleeve 51, has seted up the through-hole on the installation hem 511, and is corresponding, the last screw hole of having seted up of base 1, installs the screw of threaded connection in base 1 screw hole in the through-hole of installation hem 511, and the nut butt of screw is in the one side that base 1 was kept away from to installation hem 511. The heat conducting sleeve 51 is installed in the heating tank 11 after the base 1 is installed, the heat conducting sleeve 51 is immersed in the heating oil, the electric heating tube 52 is installed in the heat conducting sleeve 51, the electric heating tube 52 can be installed in the heat conducting sleeve 51 by welding, and the electric heating tube 52 is electrically connected with an external power supply (not shown). When the electric heating tube 52 is energized, the electric heating tube 52 will heat up, and then the heating oil in the heating tank 11 will be heated.

In order to increase the temperature rising speed of the heating oil, in the present embodiment, the heating assemblies 5 have four groups, and the four groups of heating assemblies 5 are respectively located on four corners of the base 1. Through setting up four group heating element 5, can accelerate the programming rate of heating oil, and make the heating to heating oil more even. The specific structure and operation principle of the electrical heating tube 52 are related technologies and will not be described in detail.

Referring to fig. 4, in addition, a push assembly 7 is installed in the base 1. The pushing assembly 7 comprises an air cylinder 72 mounted on the base 1 and a pushing plate 71 mounted on the air cylinder 72, wherein the air cylinder 72 is used for applying a pushing force or a pulling force to the pushing plate 71. Which in turn causes the push plate 71 to be pushed out of or retracted into the cavity of the base 1. Through setting up pushing assembly 7, after the lithium battery material in base 1 is dry, open closing plate 3, start pushing assembly 7, pushing assembly 7 just can release the lithium battery material of placing in backup pad 2 from base 1, need not the manual work and takes lithium battery material.

The embodiment of the application also discloses an intelligent drying system. Referring to fig. 5, the intelligent drying system includes a support frame 8 and a small-capacity heat conduction type vacuum drying device installed on the support frame 8, wherein the small-capacity heat conduction type vacuum drying device is the small-capacity heat conduction type vacuum drying device. In this embodiment, the number of the small-capacity heat conduction type vacuum drying devices is six, every three small-capacity heat conduction type vacuum drying devices form one set, and the two sets of the small-capacity heat conduction type vacuum drying devices are respectively located at two sides of the width direction of the supporting frame 8.

Collecting assemblies 9 are further arranged on two sides of the support frame in the width direction, and each collecting assembly 9 comprises a blanking pipeline 91 and a collecting box 92. Specifically, the lower surface at support frame 8 is installed to unloading pipeline 91, and unloading pipeline 91 specifically can be installed on support frame 8 through the welded mode, and unloading pipeline 91 width direction's both ends have the barricade, and when the lithium battery material after promotion subassembly 7 in the base 1 will dry was released, lithium battery material can drop to in the unloading pipeline 91, then slides down along unloading pipeline 91.

Collecting box 92 and unloading pipeline 91 intercommunication, collecting box 92 are the cuboid type, and collecting box 92 has the cavity, and the one end of unloading pipeline 91 is located collecting box 92 directly over, and when lithium battery material slided down from unloading pipeline 91, lithium battery material can fall into and collect and deposit in collecting box 92.

Referring to fig. 6, it is worth mentioning that, since damage may occur when the lithium battery material falls from the blanking pipe 91 into the collection box 92, a damping spring 922 and an elastic member 921 are further installed in the collection box 92. Specifically, the damping spring 922 has a plurality of, and a plurality of damping spring 922 installs in the cavity of collecting box 92, and elastic component 921 is the cuboid type, and elastic component 921 specifically can be rubber. One end of the damping spring 922 is fixedly connected with the collecting box 92, and the other end of the damping spring 922 is fixedly connected with the elastic piece 921. Therefore, when lithium battery material slides down from the discharging pipe 91 and falls into the collecting box 92, the elastic piece 921 and the damping spring 922 can buffer the lithium battery material, and then the occurrence of damage of the lithium battery material caused by the lithium battery material directly falling into the collecting box 92 is reduced.

The implementation principle of the small-capacity heat conduction type vacuum drying device and the intelligent drying system in the embodiment of the application is as follows: heating oil is filled into the heating tank 11 in the base 1, and the heating unit 5 is mounted on the base 1. Open closing plate 3, place lithium battery material in backup pad 2, close closing plate 3, start evacuation subassembly 4 and carry out the evacuation to base 1, start heating element 5 afterwards and heat to refueling heat, carry out the drying to lithium battery material promptly. After the lithium battery material is dried, the closing plate 3 is opened, the pushing assembly 7 is operated to push the lithium battery material out of the base 1, and then the lithium battery material is collected for further processing. The pushing assembly 7 pushes the lithium battery material out of the base 1, and the pushed lithium battery material falls into the discharging pipeline 91 and then slides into the collecting box 92 along the discharging pipeline 91 to be collected.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (10)

1. A small capacity heat conduction formula vacuum drying device which characterized in that: including base (1), install closing plate (3), evacuation subassembly (4) and heating element (5) on base (1), base (1) has the cavity, install backup pad (2) in the cavity of base (1), lithium battery material place in on backup pad (2), closing plate (3) are used for sealing the cavity of base (1), evacuation subassembly (4) intercommunication base (1), heating element (5) are used for right the cavity of base (1) heats.

2. The small-capacity heat-conductive vacuum drying apparatus according to claim 1, wherein: set up heating tank (11) in base (1), heating tank (11) intussuseption is filled with heating oil, heating element (5) are including heat conduction sleeve (51) and electrothermal tube (52), heat conduction sleeve (51) are installed base (1) is gone up and the submergence is in heating oil, electrothermal tube (52) are installed in heat conduction sleeve (51), backup pad (2) width direction's both sides with the inner wall laminating of base (1).

3. The small-capacity heat-conductive vacuum drying apparatus according to claim 2, wherein: the heat conducting sleeve (51) is provided with an installation folding edge (511), and the installation folding edge (511) is in threaded connection with the base (1).

4. The small-capacity heat-conductive vacuum drying apparatus according to claim 1, wherein: the sealing plate (3) is provided with a sliding block (31), the base (1) is provided with a sliding groove (12), and the sliding block (31) is in sliding connection with the sliding groove (12).

5. The small-capacity heat-conductive vacuum drying apparatus according to claim 4, wherein: the sliding groove (12) is a T-shaped groove, and the shape of the sliding block (31) is matched with that of the sliding groove (12).

6. The small-capacity heat-conductive vacuum drying apparatus according to claim 4, wherein: install drive assembly (6) on base (1), drive assembly (6) are including installing driving motor (61) and threaded rod on base (1), set up threaded hole on slider (31), the threaded rod with the screw hole threaded connection of slider (31), the one end of threaded rod with the output coaxial arrangement of driving motor (61).

7. The small-capacity heat-conductive vacuum drying apparatus according to claim 1, wherein: install in base (1) and promote subassembly (7), promote subassembly (7) including installing cylinder (72) and installing on base (1) push pedal (71) on cylinder (72), promote subassembly (7) be used for with lithium battery material on backup pad (2) is released from base (1).

8. An intelligence drying system which characterized in that: the drying device comprises a support frame (8) and at least two small-capacity heat conduction type vacuum drying devices installed on the support frame (8), wherein the small-capacity heat conduction type vacuum drying devices are the small-capacity heat conduction type vacuum drying devices as claimed in any one of claims 1 to 7.

9. The intelligent drying system of claim 8, wherein: the lithium battery material collecting device is characterized by further comprising a collecting assembly (9), wherein the collecting assembly (9) comprises a blanking pipeline (91) and a collecting box (92), the blanking pipeline (91) is communicated with the collecting box (92), the blanking pipeline (91) is located on one side of the supporting frame (8), and lithium battery materials can enter the blanking pipeline (91) after being taken out of the base (1).

10. The intelligent drying system of claim 9, wherein: a plurality of damping springs (922) and elastic pieces (921) are installed in the collecting box (92), one ends of the damping springs (922) are installed in the collecting box (92), and the other ends of the damping springs (922) are fixedly connected with the elastic pieces (921).

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