TWI792802B - Water removal method for battery device and water removal device for battery device - Google Patents

Abstract

The present invention relates to a method for removing water from a battery device and its device. The method for removing water from a battery device in the present invention includes: selecting a soft metal packaged battery device with at least one unsealed end, moving the battery device into an airtight cavity, In the airtight cavity, a predetermined temperature and pressure are applied to the upper and lower ends of the battery device, and the moisture inside the battery is removed by applying pressure while heating, and finally the soft metal unsealed side of the battery device is sealed tightly. It has the effect of quickly removing moisture inside the battery device; the invention also includes a method of removing released moisture and supplementing dry gas with negative pressure to improve the efficiency of water removal; and multiple sets of continuous hot pressing In the method, the moisture inside the battery device is sequentially reduced. In addition to continuously and quickly removing the moisture inside the battery device, it also has the effect of uniform dryness inside the battery device and uniform quality.

Description

Water removal method for battery device and water removal device for battery device

The invention belongs to the technical field of secondary battery devices, and in particular refers to a method for removing water from a battery device and a new design of a water removal device for a battery device. In addition to achieving continuous and rapid removal of moisture inside the battery device, it also has the ability to dry the inside of the battery device. Uniformity, to achieve the effect of uniform quality.

Due to the vigorous development of the 3C product market, various high-performance devices used in various products are moving towards the goal of being light, thin, short, and small. In order to increase the battery life and increase the energy density of the battery, the primary battery that could not be reused before can no longer meet the needs of today's electronic information products, and the batteries currently used in electronic information products are mostly secondary batteries that can be recharged and discharged. The secondary battery system is the mainstream. Such as: lithium batteries, fuel cells, solar cells...etc. However, the existing lithium-ion secondary batteries mainly use liquid electrolytes as the lithium ion transmission medium. However, the volatile characteristics of liquid electrolytes will cause adverse effects on the human body and the environment; That being said, it is also a huge security risk. Furthermore, one of the reasons for the unstable performance of lithium batteries at present is mainly because the electrode surface activity is relatively large (negative electrode) and the voltage is relatively high (positive electrode). Stability, and then produce the so-called exothermic reaction to form a passive protective film on the contact interface of the two. These reactions will consume the liquid electrolyte and lithium ions, and will also generate heat. Once a local short circuit occurs, the local temperature rises rapidly, and the passive protective film will become unstable at this time, and heat will be released at the same time; and this exothermic reaction can be accumulated, thus making the overall temperature of the battery continue to rise. one Once the temperature of the battery increases to the initial temperature (or trigger temp) of the thermal runaway, thermal runaway will occur, which will cause damage to the battery, such as explosion or fire. Cause sizable safety concerns (my country's patent No. I676316 prior art reference). In recent years, solid-state electrolytes have become another research focus. They have ionic conductivity similar to liquid electrolytes, but they do not have the properties of easy evaporation and combustion of liquid electrolytes. At the same time, the interface with the surface of active materials is relatively stable (whether chemical properties or electrochemical properties).

China Patent Publication No. I655304 "Manufacture of High-capacity Solid-State Battery" patent discloses a method for manufacturing a thin-film solid-state battery device using a closed-loop process to build multiple stacks to obtain a high capacity greater than 0.1mAh, wherein the method Including a processing step on a thin substrate (0.1 μm to 100 μm), the closed loop process comprises the steps of performing a plurality of processes to form one on the substrate by sequentially depositing a plurality of materials obtained from deposition sources. To create a single stack of resulting electrochemical cells, the plurality of processes includes at least one of: depositing a first current collector on the substrate; depositing a first electrode layer capable of interacting with the current collector The ions on the device perform an electrochemical reaction; deposit a solid electrolyte material on the first electrode layer; deposit a second electrode layer on the solid electrolyte material; deposit a second current collector on the second electrode layer ; moving the substrate, followed by the resulting electrochemical cell forming a second electrochemical cell on the substrate on the resulting electrochemical cell stack; and repeating the cell stack deposition sequence until having a value equal to or greater than 0.1 A multi-stack battery with a high capacity of mAh is formed on the substrate, wherein the substrate further comprises a release material selected from at least one of the following: fluoropolymers, monomers, oligomers, conductive materials, or combinations , dual-function release layer, desiccant, depolymerization layer, thermal release material, polyimide, polydimethylsiloxane (PDMS), semiorganosiloxane, hydrophobic layer, epitaxial release material, amorphous Fluoropolymers, Radiation stripping materials (refer to the materials announced by Yanli on April 1, 2019). Patent Publication No. I646713 "Manufacture of Solid State Battery Pack" discloses a method for manufacturing a solid state battery pack, comprising the following steps: providing a green sheet of positive electrode material; providing a green sheet of separator material; combining the green sheet of positive electrode material with the Laminating the separator material green sheets together to form a laminated green stack; sintering the laminated green stack to form a sintered stack comprising a positive electrode and a separator; and laminating a negative electrode to the On the sintered stack (refer to the patent announcement data on January 1, 2019). Patent Announcement No. I624976 "Method for Manufacturing Solid State Batteries" patent discloses a method for manufacturing solid state batteries, which includes the following steps: a. Provide a battery unit, which includes a positive electrode sheet, a solid electrolyte layer and A negative electrode sheet, the positive electrode sheet includes a first collector layer and positive electrode material layers respectively bonded to both sides of the first collector layer; b. positioning the battery unit on a carrier plate in a pressure chamber, the There is a fluid medium in the pressure chamber; and c. Provide the medium temperature control of 20~200°C and the medium pressure control of 5~100000PSI, so that the joint surfaces of the positive electrode sheet, the solid electrolyte layer and the negative electrode sheet are softened Joining (refer to the patent announcement data on May 21, 2018).

Conventional battery packaging structure, whether it is a primary battery system or a secondary battery system, most of the conventional battery packaging is presented in the appearance of a hard metal shell (including traditional cylindrical and square), such as: currently widely used in notebooks The 18650 type lithium battery (cylindrical lithium battery) in the small computer or the 383562 type lithium battery (square lithium battery) used in a large number of portable communication devices are all packaged with a hard metal shell. Preventing the battery core from being damaged by external stress can also reduce the impact of external factors (such as moisture, oxygen, etc.) on the internal chemical system of the battery. Therefore, for terminal electronic products, although the secondary lithium battery system can provide better electrical performance and service life, due to its fixed size design and hard shell material, most electronic products are not suitable for circuit design. system is considerably restricted. So there are secondary batteries The device has developed a soft metal package (such as aluminum foil) structure to replace the conventional hard metal package packaging technology, so it can reduce the difficulty of the secondary battery system in the application of electronic products. In particular, the solid-state battery device stacked in sheet form has the advantage of greatly reducing the volume of the battery device compared to the cylindrical battery device. As such, this battery can be used in a variety of applications such as portable electronic devices (mobile phones, personal digital assistants, music players, video recorders, and the like), power tools, power supplies for military use (communications, lighting , imaging, and the like), power supplies for aerospace applications (power for satellites), and power supplies for vehicular applications (hybrid electric vehicles, plug-in hybrid electric vehicles, and all-electric vehicles).

However, the above-mentioned stacked solid-state battery device packaged with soft metal (such as aluminum foil) must have a moisture content of less than 200ppm due to the internal sheet-shaped battery device, otherwise the battery device will be damaged after packaging, and the life of the battery device will be reduced. missing. In the prior art, when packaged with soft metal, one side is left unsealed, and then the battery device is baked and dried in an oven. Since the materials inside the battery device are not resistant to high temperatures, they cannot be baked and dried at high temperatures, so drying It will take a long time. Furthermore, because the inside of the battery device is a stacked structure, the more layers are stacked, the more difficult it is to dry. In addition to taking a long time, it is more likely to cause deformation and damage to the battery device, and the degree of internal drying is uneven, which cannot achieve consistent quality. demand. Furthermore, the conventional technology is to place the battery device inside the oven to dry. Since there is no pressure to release the water inside the battery device, the internal water can only be evaporated slowly by temperature, and the evaporated water is not easy to be discharged from the inside. Therefore, the drying process will take a long time, and the internal temperature of the conventional battery device is not uniform, and its moisture content is also not uniform, resulting in poor quality. The lack of drying and water removal technology of the aforementioned conventional battery devices has become a problem that the industry needs to overcome urgently.

In view of the lack of conventional technology, the inventor of the present invention has accumulated his professional knowledge in the design and manufacture of high-tech industrial products such as precision ceramics, biotechnology and environmental protection for many years. After continuous research and improvement, the present invention has been successfully developed and made public to the world. .

The reason is that the main purpose of the present invention is to provide a method for removing water from a battery device. The method for removing water from a battery device of the present invention includes: selecting a soft metal packaged battery device with at least one unsealed end, and moving the battery device to an airtight chamber Inside the body, apply a predetermined temperature and pressure to the upper and lower ends of the battery device in the airtight cavity, remove the moisture inside the battery by applying pressure while heating, and finally seal the soft metal unsealed side of the battery device Closely sealed, it has the effect of quickly removing moisture inside the battery device.

The present invention also includes a method of removing released water and supplementing drying gas with negative pressure suction to improve water removal efficiency.

The present invention also includes a method of vacuumizing the aforementioned airtight cavity to remove the released water, and the vacuum environment is used to improve the water removal efficiency.

The present invention also includes a predetermined number of times of hot pressing and displacement, and multiple sets of continuous hot pressing methods to sequentially reduce the moisture inside the battery device. In addition to achieving continuous and rapid removal of moisture inside the battery device, It also has the effect of uniform dryness inside the battery device and uniform quality.

Another main purpose of the present invention is to provide a water removal device for a battery device. The water removal device of the present invention mainly includes an airtight cavity, and a carrier plate is arranged in the airtight cavity to place the battery device. There is an upper hot-pressing device, and a lower hot-pressing plate is provided below the carrier plate. The aforementioned upper hot-pressing device is composed of a lifting system and an upper hot-pressing plate located below the lifting system. The aforementioned upper hot-pressing plate and the lower hot-pressing The plates have heating elements to heat the upper and lower heat press plates to a predetermined temperature. In addition, it includes a battery device, the battery device is packaged with soft metal, and at least one end of the battery device is not sealed to form an unsealed end, the battery device is placed on the carrier plate in the aforementioned airtight cavity, and the aforementioned lifting system moves down, The upper hot-pressing plate is pressed down, and a predetermined temperature and pressure are applied to the upper and lower end surfaces of the battery device with the lower hot-pressing plate in the airtight cavity, and the internal parts of the battery device are heated and pressed. Moisture removal, has the effect of quickly removing moisture inside the battery device.

The present invention also includes a negative pressure system and a source gas intake system. The aforementioned negative pressure system includes a negative pressure buffer tank connected with a negative pressure piping connected to the aforementioned airtight cavity. The source gas intake system includes a drying and dewatering device, which is used to dry the source gas. The drying and dehydrating device is connected to the intake shunt pipe arranged at the bottom of the aforementioned airtight cavity, and the negative pressure system is used to Negative pressure removes the released moisture inside the battery device and supplements dry gas with the source gas intake system to improve the water removal efficiency.

The above-mentioned negative pressure system of the present invention, the negative pressure piping connected to it, is provided with a negative pressure gas collection cover inside the airtight cavity relative to the battery device to be heated, so as to improve the efficiency of negative pressure water removal .

The aforementioned source gas intake system of the present invention is additionally provided with an intake flow adjustment device, so as to adjust the diversion flow of the intake air.

The aforementioned source gas intake system of the present invention is additionally equipped with a moisture sampling device, which is installed in the aforementioned airtight cavity, so as to analyze the amount of water in the aforementioned airtight cavity, so as to adjust the flow rate of air intake and negative pressure , to achieve the best effect.

The present invention also includes a closed furnace body, the outer two ends of the furnace body are provided with an exchange system, the exchange system is connected with a conveying channel, the aforementioned airtight cavity system is set inside the furnace body, and the aforementioned airtight cavity is provided with an internal conveying system. Road, the inner conveying road is connected to the two-end exchange system of the aforementioned furnace body for It is the track for the moving of the aforementioned carrier boards. The aforementioned carrier boards are continuously pushed in sequentially by the exchange system on the top of the aforementioned inner conveyor. A predetermined number of the above-mentioned upper hot-pressing devices are provided, each of the upper hot-pressing devices has the aforementioned carrier plate opposite to each other, and each of the carrier plates has the aforementioned lower hot-pressing plate opposite to each other, and the aforementioned lower hot-pressing plate is arranged on the inner conveying path , each of the aforementioned upper hot pressing devices can set the time and pressure of hot pressing, and each of the aforementioned upper hot pressing plates and lower hot pressing plates can be set at a predetermined temperature, so as to perform hot pressing for a predetermined number of times and cooperate with the displacement of the carrier plate. Multiple sets of continuous hot pressing methods reduce the moisture inside the battery device to be dewatered in sequence. In addition to achieving continuous and rapid removal of moisture inside the battery device, it also has a uniform dryness inside the battery device and uniform quality effect.

The present invention also includes a soft metal sealing device, the soft metal sealing device is located at the tail end of the airtight cavity, which includes an upper sealing device and a lower sealing device, so that the soft metal of the battery device that has been dewatered is not sealed. The end is sealed by heat pressing.

Another main purpose of the present invention is to provide a water removal device for a battery device. The water removal device of the present invention mainly includes a vacuum airtight cavity, and a conveying track is arranged in the vacuum airtight cavity, and the conveying track is used to place a load plate, the carrier plate is used to place at least one set of heat-pressing layer racks, the heat-pressing layer frame is composed of a predetermined number of heating plates and connecting mechanisms, and the aforementioned heating plates have heating elements to heat each heating plate to a predetermined temperature, each heating plate is used to place the battery device, the above-mentioned connecting mechanism includes a connecting piece useful for connecting the adjacent heating plates, one end of each connecting piece is fixed at the predetermined position of the adjacent lower heating plate, and the other end is The heating plate extending from the adjacent upper part has a chute as the distance between each heating plate, and the heating plate adjacent to the upper part is provided with a pin relative to the chute of the connecting sheet. In the state, it is located at the lower end of the aforementioned chute to connect and support the upper and lower adjacent heating plates, and the upper heating plate is Use another connecting piece to connect the other heating plate on the top, so that the heat-pressing layer rack with a predetermined number of layers is connected in series; The lifting system is composed of a pressing plate below, and also includes a battery device, the battery device is packaged with soft metal, and at least one end of the battery device is unsealed to form an unsealed end, and the battery device is placed between the heating plates of the aforementioned heat-pressing layer frame, Use the aforesaid lifting system to move down, so that the pressure plate is pressed down, and then in the vacuum airtight cavity, each heating plate of the hot-pressing layer frame is placed between the upper and lower end surfaces of the battery device to apply a predetermined temperature and pressure, so as to The method of heating while applying pressure removes the moisture inside the battery device, which has the effect of quickly and efficiently removing the moisture inside the battery device.

The present invention also includes a vacuum system, the vacuum system is connected with a vacuum pipe, and the vacuum pipe is communicated with the aforementioned vacuum airtight chamber, and the vacuum system is used to evacuate the vacuum airtight chamber to accelerate the removal of the released gas from the inside of the aforementioned battery device. water, to improve the efficiency of water removal.

The present invention also includes a closed furnace body, the outer two ends of the furnace body are provided with an exchange system, the aforementioned vacuum airtight chamber system is set inside the furnace body, and the conveying track provided in the aforementioned vacuum airtight chamber connects the two ends of the aforementioned furnace body. The exchange system at the end is used as the track for the moving of the aforementioned carrier board. The aforementioned carrier board is continuously pushed in order by the exchange system on the aforementioned conveying track. A battery device to be hot-pressed to remove water is placed between each heating plate. The aforementioned vacuum airtight cavity is provided with a predetermined number of the aforementioned hot-pressing devices. The device can set the time and pressure of hot pressing. The heating plates of each of the aforementioned hot pressing shelves can be set to a predetermined temperature, so that a predetermined number of hot pressing can be carried out, and in conjunction with the displacement of the carrier plate, multiple sets of continuous hot pressing can be performed. In this way, the moisture inside the battery device to be dewatered is sequentially reduced. In addition to achieving continuous and rapid removal of moisture inside the battery device, it also has the effect of uniform dryness inside the battery device and uniform quality.

A: Battery device

B: soft metal

C: Unsealed end

1: airtight cavity

10: carrier board

11: Lower hot plate

110: heating element

12: Inner conveyor

13: Vacuum airtight cavity

14: Conveyor track

15: Loading board

16:Hot pressing shelf

160: heating plate

161: Link mechanism

162: connecting piece

163: Chute

164:pin

17: Heating element

2: Upper heat press device

20: Lifting system

21: Upper hot plate

210: heating element

22:Hot pressing device

220: Lifting system

221: Platen

3: Negative pressure system

30: Negative pressure buffer tank

31: Negative pressure piping

32: Negative pressure gas collection hood

33: Vacuum system

330: vacuum piping

4: Source gas intake system

40: Drying and water removal device

41: Intake manifold

42: Air intake flow adjustment device

43:Moisture sampling device

5: furnace body

51: Outer conveyor

6: Exchange system

60: inner airtight door

61: Outer airtight door

62: airtight space

7: Soft metal sealing device

70: Upper sealing device

71: Bottom sealing device

8: furnace body

80: Exchange system

81: inner airtight door

82: Feed system

83:Discharging system

84: Outer airtight door

85: Vacuum transfer chamber

[Fig. 1] is the front sectional view of the water removal device of the battery device of the present invention; [Fig. 2] is the upper end sectional view of the water removal device of the battery device of the present invention; [Fig. 3] is the heat removal device of the battery device of the present invention [Fig. 4] is a sectional view of the upper end of the water removal device of the battery device in another embodiment of the present invention; [Fig. 5] is a hot pressure removal of the water removal device of the battery device in another embodiment of the present invention. Sectional view of the water part; (Fig. 6) is a partial enlarged view of the heat-pressed shelf of the embodiment of the present invention.

In order to achieve the technical means of the above-mentioned purpose of the present invention, hereby cite an embodiment, and describe it with the drawings as follows, so that your review committee can gain a better understanding of the method, structure, characteristics and achieved effects of the present invention.

The water removal method and the water removal device of the battery device of the present invention are aimed at the water removal method and the water removal device of the stacked solid state battery device (hereinafter referred to as the battery device) packaged with soft metal (such as aluminum foil). The stacked solid-state battery device with flexible metal packaging has at least one unsealed end. In order to increase its water removal efficiency, two unsealed ends can also be selected.

The water removal method of the battery device of the present invention includes: selecting a soft metal packaged battery device with at least one end unsealed, moving the battery device into an airtight cavity, and applying water to the upper and lower ends of the battery device in the airtight cavity. Predetermined temperature and pressure, remove the moisture inside the battery by applying pressure while heating, and finally seal the soft metal unsealed side of the battery device, so as to achieve the effect of quickly removing the moisture inside the battery device. Compared with the conventional technology, the present invention applies pressure while heating to pressurize the water inside the battery and release it from the unsealed part. The effect of removing moisture inside the battery device.

The present invention also includes the method of removing the released moisture and replenishing dry gas with negative pressure pumping, continuously discharging the released moisture with negative pressure pumping, and then replenishing the dried fresh external air, due to the reduced The water content in the airtight cavity can effectively improve the water removal efficiency.

The present invention also includes a method of vacuumizing the aforementioned airtight cavity to remove the released water, and the vacuum environment is used to improve the water removal efficiency.

The present invention also includes a predetermined number of times of hot pressing and displacement, and multiple sets of continuous hot pressing methods to sequentially reduce the moisture inside the battery device. In addition to achieving continuous and rapid removal of moisture inside the battery device, It also has the effect of uniform dryness inside the battery device and uniform quality.

Please refer to FIG. 3 , which is a cross-sectional view of the hot-press dewatering part of the dewatering device of the battery device of the present invention. It can be seen from the figure that the dewatering device of the battery device of the present invention mainly includes an airtight cavity 1, and a carrier plate 10 is arranged in the airtight cavity 1 to place the battery device A, and an upper Hot pressing device 2, the bottom of the carrier plate 10 is provided with a lower hot pressing plate 11, the aforementioned upper hot pressing device 2 is composed of a lifting system 20 and an upper hot pressing plate 21 located below the lifting system 20, the aforementioned upper hot pressing The plate 21 and the lower heat press plate 11 have heating elements 210, 110 to heat the upper heat press plate 21 and the lower heat press plate 11 to a predetermined temperature, and also include a battery device A, which is packaged with a soft metal B , and at least one end of it is unsealed to form an unsealed end C, the battery device A is placed on the carrier plate 10 in the aforementioned airtight cavity 1, the aforementioned lifting system 20 moves down, and the upper hot platen 21 is pressed down , and apply a predetermined temperature and pressure to the upper and lower ends of the battery device A in the airtight cavity 1 with the lower hot pressing plate 11, and remove the moisture inside the battery device A by applying pressure while heating , and then seal the unsealed end C of the soft metal B of the battery device A, so as to achieve the effect of quickly removing the moisture inside the battery device. compared to customary Technology, the present invention pressurizes the moisture inside the battery device A by applying pressure while heating, and releases it from the unsealed part, which has the effect of quickly removing the moisture inside the battery device. The present invention removes the moisture inside the battery device A by means of hot pressing, because the hot pressing will pressurize the moisture inside the battery device A and release it from the unsealed part, so that the dryness of the inside of the battery device A can be made uniform, The quality is relatively stable.

Please refer to the front sectional view of the water removal device of the battery device of the present invention in FIG. 1 and the upper sectional view of the water removal device of the battery device of the present invention in FIG. 2 . The present invention also includes a negative pressure system 3 and a source gas intake system 4. The aforementioned negative pressure system 3 includes a negative pressure buffer tank 30, which is connected with a negative pressure piping 31, and the negative pressure piping 31 communicates with the In the aforementioned airtight cavity 1, the aforementioned source gas intake system 4 includes a drying and dewatering device 40, which is used to dry the source gas, and the drying and dehydrating device 40 is connected to the aforementioned airtight cavity 1. The air intake distribution pipe 41 at the bottom of the interior uses the negative pressure system 3 to remove the moisture released from the interior of the aforementioned battery device A, and uses the source gas intake system 4 to supplement the dry gas. The present invention uses negative pressure to pump air Excluding the released water and supplementing the dry gas, continuously exhausting the released water with negative pressure pumping, and then replenishing the dried fresh external air, because the moisture content in the airtight cavity 1 is reduced, Therefore, the water removal efficiency can be effectively improved.

The aforementioned negative pressure system 3 of the present invention, the negative pressure piping 31 connected to it, is provided with a negative pressure gas collecting cover 32 on the inside of the airtight cavity 1 relative to the battery device A to be heated, so as to improve the negative pressure. Water removal efficiency under pressure.

Please refer to FIG. 3 , the aforementioned source gas intake system 4 of the present invention is further provided with an intake flow adjusting device 42 for adjusting the split flow of intake air.

Please refer to shown in Figure 3, the aforementioned source gas intake system 4 of the present invention is provided with moisture sampling device 43 in addition, and this moisture sampling device 43 is arranged in the aforementioned airtight chamber 1, so as to take and analyze the aforementioned airtight chamber 1 The amount of water inside is used to adjust the flow of air intake and negative pressure to achieve the best effect.

The present invention also includes a closed furnace body 5, the outer two ends of the furnace body 5 are provided with an exchange system 6, the exchange system 6 is connected with a conveying channel 51, the aforementioned airtight chamber 1 is arranged inside the furnace body 5, and the aforementioned The airtight cavity 1 is provided with an inner conveying channel 12, which is connected to the exchange system 6 at the two ends of the furnace body to serve as a track for the movement of the aforementioned carrier plate 10. Above the aforementioned inner conveying channel 12, there is an exchange system 6 The above-mentioned carrier plates 10 that are continuously pushed in order, each of the carrier plates 10 is placed on the battery device A to be hot-pressed to remove water, and a predetermined number of the aforementioned upper hot-pressing devices 2 are arranged inside the airtight cavity 1, and each of the The above-mentioned carrier plate 10 is opposite to the bottom of the upper hot-pressing device 2, and the aforementioned lower hot-pressing plate 11 is oppositely arranged below each of the carrier plates 10. The device 2 can set the time and pressure of hot pressing. The above-mentioned upper hot pressing plate 21 and lower hot pressing plate 11 can be set at a predetermined temperature, so as to perform hot pressing for a predetermined number of times and cooperate with the displacement of the carrier plate 10. The method of continuous hot pressing sequentially reduces the moisture inside the battery device A to be dewatered. In addition to achieving continuous and rapid removal of water inside the battery device A, it also has a uniform dryness inside the battery device A and uniform quality effect.

The present invention also includes a soft metal sealing device 7, the soft metal sealing device 7 is arranged at the tail end of the aforementioned airtight cavity 1 to seal the unsealed end C of the battery device A after water removal. The aforementioned soft metal sealing device 7 of the present invention includes an upper sealing device 70 and a lower sealing device 71, which seal the soft metal B by hot pressing.

Please refer to shown in Fig. 2, the aforementioned exchanging systems 6 arranged on both sides of the body of furnace 5 of the present invention, each exchanging system 6 includes an airtight door 60 disposed on the side of the body of furnace 5 and disposed outside the side of the outer conveyor 51 The airtight door 61, the inner airtight door 60 and the outer airtight door 61 form an airtight space 62. When the carrier plate 10 is sent into the furnace body 5, the inner airtight door 60 at the head end of the furnace body 5 and the outer airtight The door 61 is closed, and after the airtight space 62 is evacuated (or negatively pressured) to the same environment as the airtight chamber 1, the airtight door 60 on the side of the furnace is opened to push the carrier plate 10 into the airtight chamber 1, before the carrier plate 10 is sent out of the airtight chamber 1, the airtight door 60 in the rear end of the furnace body And the outer airtight door 61 is closed, and the airtight space 62 has been evacuated (or negative pressure) to the same environment as in the airtight cavity 1, and the inner airtight door 60 on the side of the furnace body is opened to push the carrier plate 10 into In the airtight space 62, this has the effect of preventing the airtight cavity 1 from mixing with the air outside the furnace and achieving uniform quality.

Please refer to FIG. 5 , which is a cross-sectional view of the hot-press dewatering part of the dewatering device of the battery device according to another embodiment of the present invention. As can be seen from the figure, the dewatering device of the present invention mainly includes a vacuum airtight cavity 13, and the vacuum airtight cavity 13 is provided with a conveying track 14, and the conveying track 14 is used to place a carrying plate 15, and the carrying plate 15 is used to place at least one group of heat-pressing layer frames 16. Please refer to Fig. 6 again. The element 17 is used to heat each of the heating plates 160 to a predetermined temperature, and the battery device A is placed between each heating plate 160. The aforementioned connecting mechanism 161 includes a connecting sheet 162 useful for connecting the adjacent heating plates 160, and each of the connecting One end of the sheet 162 is fixed at the predetermined position of the adjacent lower heating plate 160, and the other end extends out of the adjacent upper heating plate 160, and has a chute 163 as the distance between each of the heating plates 160. The heating plate 160 above is provided with a pin 164 with respect to the above-mentioned linking piece chute 163, and this pin 164 is positioned at the lower end of the aforementioned chute 163 when in normal state, to link and support each of the adjacent heating plates up and down. plate 160, and the heating plate 160 on the top is connected to another heating plate 160 on the top with another connecting piece 162, so that it is connected in series to form a predetermined number of layers of heat-pressing shelf 16; There is a hot pressing device 22, which can be a constant pressure type, and the hot pressing device 22 is composed of a lifting system 220 and a pressing plate 221 located at the bottom of the lifting system 220, and also includes a battery device A, the battery Device A is packaged with soft metal B, and at least one end of it is unsealed to form an unsealed end C. The battery device A is placed between the heating plates 160 of the aforementioned heat-pressing layer frame 16, and is lowered by the aforementioned lifting system 220 to make the pressing plate 221 to press down, and then in the vacuum airtight cavity 13, each heating plate 160 of the hot-pressing layer frame 16 applies a predetermined temperature and pressure to the upper and lower end surfaces of the battery device A placed therebetween, so as to Applying pressure while heating removes the moisture inside the battery device A, which has the effect of quickly and efficiently removing the moisture inside the battery device. Compared with the conventional technology, the present invention compresses the moisture inside the battery device A by applying pressure while heating, and releases it from the unsealed part, which has the effect of quickly removing the moisture inside the battery device. The present invention removes the moisture inside the battery device A by means of hot pressing, because the hot pressing will pressurize the moisture inside the battery device A and release it from the unsealed part, so that the dryness of the inside of the battery device A can be made uniform, The quality is relatively stable. In addition, in this embodiment, a predetermined number of battery devices A can be hot-pressed at the same time by using the multi-layer and simultaneous hot-pressing method of the hot-pressing layer frame 16 at one time. In addition to taking into account high quality, the production efficiency can be effectively improved.

The present invention also includes a vacuum system 33, the vacuum system 33 is connected with a vacuum pipe 330, and the vacuum pipe 330 is communicated with the aforementioned vacuum airtight cavity 13, and the vacuum system 33 is used to evacuate the vacuum airtight cavity 13 to accelerate Eliminate the released water inside the battery device A to improve the water removal efficiency.

The present invention also includes a closed furnace body 8, the outer two ends of the furnace body 8 are provided with an exchange system 80, the aforementioned vacuum airtight chamber 13 is set inside the furnace body 8, and the aforementioned vacuum airtight chamber 13 is provided with The conveying track 14 connects the exchange system 80 at the two ends of the aforementioned furnace body 8 to serve as a track for the movement of the aforementioned carrier plate 15. The aforementioned carrier plate 15 is placed on the aforementioned transport track 14 and continuously pushed in by the exchange system 80 sequentially. The aforementioned hot-pressing layer frame 16 is placed on the plate 15, and the battery device A to be hot-pressed to remove water is placed between each heating plate 160 of the hot-pressing layer frame 16. The aforementioned vacuum airtight cavity 13 is provided with a predetermined number of the aforementioned hot-pressing devices. 22. The above-mentioned heat-pressing layer frame 16 is opposite to the bottom of each of the heat-pressing devices 22. The time and pressure of the heat-pressing can be set for each of the aforementioned heat-pressing devices 22. The heating plates 160 of each of the aforementioned heat-pressing layer frames 16 can be Set a predetermined temperature, use a predetermined number of hot pressing, and cooperate with the displacement of the carrier plate 15, in order to reduce the moisture inside the battery device A to be dehydrated sequentially by means of multiple sets of continuous hot pressing, in addition to achieving continuous In addition to quickly removing moisture inside the battery device A, it also has the effect of uniform dryness inside the battery device A and uniform quality.

Please refer to Fig. 4, the exchange system 80 of the present invention is located at the two sides of the body of furnace 8, each exchange system 80 includes an inner airtight door 81 located at the side of the body of furnace 8 and a feed system 82 connected to the outside or Connecting the outer airtight door 84 of the discharge system 83, the inner airtight door 81 and the outer airtight door 84 form a vacuum transfer chamber 85. When the carrier plate 15 is sent into the furnace body 8, the inside of the furnace body 8 The airtight door 81 and the outer airtight door 84 are closed. After the vacuum transfer chamber 85 is evacuated to the same environment as the vacuum airtight chamber 13, the inner airtight door 81 on the side of the furnace is opened to push the carrier plate 15 into the vacuum airtight chamber 13, before the carrier plate 15 is sent out of the vacuum airtight chamber 13, the inner airtight door 81 and the outer airtight door 84 at the rear end of the furnace body are closed, and the vacuum transfer chamber 85 is finished Vacuumize to the same environment as the vacuum airtight chamber 13, open the airtight door 81 on the side of the furnace body and push the carrier plate 15 into the vacuum transfer chamber 85, so as to prevent the vacuum airtight chamber 13 from being mixed with the outside of the furnace Air, to achieve the effect of uniform quality.

In summary, the present invention discloses a "water removal method for a battery device and a water removal device for a battery device" that have never been seen in the past, nor have they been published in publications at home and abroad, so they already have novelty patent requirements. In addition, this invention clearly eliminates the deficiencies of conventional technology and achieves the design purpose. It also fully meets the patent requirements. I file an application in accordance with the law. I would like to ask your review committee to review and grant this case a patent. I really appreciate it.

But what is described above is only one of the preferred feasible embodiments of the present invention, and is not intended to limit the scope of the present invention. For those who are familiar with this art, they can use the description of the present invention and the alternative method or method made by the scope of the patent application. Equivalent structural changes should be included in the patent scope of the present invention.

A: Battery device

1: airtight cavity

10: carrier board

11: Lower hot plate

110: heating element

12: Inner conveyor

2: Upper heat press device

20: Lifting system

21: Upper hot plate

210: heating element

3: Negative pressure system

30: Negative pressure buffer tank

31: Negative pressure piping

32: Negative pressure gas collection hood

40: Drying and water removal device

41: Intake manifold

42: Air intake flow adjustment device

43:Moisture sampling device

5: furnace body

Claims (15)

A method for removing water from a battery device, which mainly includes: selecting a soft metal packaged battery device with at least one unsealed end, moving the battery device into an airtight cavity, and applying water to the upper and lower ends of the battery device in the airtight cavity Predetermined temperature and pressure, remove the moisture inside the battery by applying pressure while heating, and finally seal the soft metal unsealed side of the battery device, which has the effect of quickly removing moisture inside the battery device. A method for removing water from a battery device as described in Claim 1, which further includes a method of removing released water and replenishing dry gas by negative pressure pumping to improve water removal efficiency. A method for removing water from a battery device as described in claim 1, further comprising a method of vacuumizing the airtight cavity to remove released water, and using a vacuum environment to improve water removal efficiency. The water removal method of the battery device as described in claim 2 or claim 3, which further includes a predetermined number of heat-press fit displacements, and multiple sets of continuous heat-press methods to sequentially reduce the water content of the battery device. Moisture, in addition to achieving continuous and rapid removal of moisture inside the battery device, it also has the effect of uniform dryness inside the battery device and uniform quality. A water removal device for a battery device, which mainly includes an airtight cavity, a carrier plate is arranged in the airtight cavity for placing the battery device, an upper heat pressing device is arranged above the carrier plate, and a lower plate is arranged below the carrier plate. The hot pressing plate, the aforementioned upper hot pressing device is composed of a lifting system and an upper hot pressing plate located below the lifting system, the aforementioned upper hot pressing plate and the lower hot pressing plate have heating elements to make the upper hot pressing plate and the lower The hot press plate is heated to a predetermined temperature, and further includes a battery device, the battery device is packaged with soft metal, and at least one end of the battery device is not sealed to form an unsealed end, and the battery device is placed on the carrier plate in the aforementioned airtight cavity, The aforesaid lifting system moves down, so that the upper hot platen is pressed down, and with the lower The hot pressing plate applies predetermined temperature and pressure to the upper and lower end surfaces of the battery device in the airtight cavity, and removes the moisture inside the battery device by applying pressure while heating. The dewatering device of the battery device as described in claim 5, which further includes a negative pressure system and a source gas intake system, the aforementioned negative pressure system includes a negative pressure buffer tank, and the negative pressure buffer tank is connected with a negative pressure pipe, The negative pressure piping is connected to the aforementioned airtight cavity, and the aforementioned source gas intake system includes a drying and dehydrating device, which is used to dry the source gas, and the drying and dehydrating device is connected to the aforementioned airtight cavity The air intake distribution pipe under the part uses the negative pressure system to remove the water released from the inside of the battery device and supplements the dry gas with the source gas intake system to improve the water removal efficiency. The water removal device of the battery device as described in claim 6, wherein, the negative pressure system connected with the negative pressure piping is provided in the airtight cavity above the battery device to be heated. Negative pressure gas collection hood to improve the efficiency of negative pressure to remove moisture. The water removal device for a battery device as described in claim 6, wherein the source gas intake system is further provided with an intake air flow adjustment device to adjust the split flow of the intake air. The water removal device of the battery device as described in Claim 6, wherein the aforementioned source gas intake system is additionally provided with a moisture sampling device, and the moisture sampling device is installed in the aforementioned airtight chamber to analyze the aforementioned airtight The amount of water in the cavity is used to adjust the flow of air intake and negative pressure. The dewatering device for a battery device as described in claim 5 or claim 6, which further includes a closed furnace body, two ends of the furnace body are provided with an exchange system, and the exchange system is connected to an external conveying channel, and the aforementioned airtight chamber The system is set inside the furnace body, and an inner conveying channel is provided in the aforementioned airtight cavity, and the inner conveying channel is connected to the exchanging system at the two ends of the aforementioned furnace body to serve as a track for the moving of the aforementioned carrier plate. The aforementioned carrier boards pushed in sequentially by the system, and each carrier board is placed on For the battery device to be hot-pressed to remove water, a predetermined number of the above-mentioned upper hot-pressing devices are arranged inside the airtight cavity, and the aforementioned carrier plates are placed opposite each of the upper hot-pressing devices, and the aforementioned carrier plates are arranged oppositely below each of the carrier plates. The lower hot-pressing plate, the aforementioned lower hot-pressing plate is set on the inner conveying path, the time and pressure of hot-pressing can be set for each of the aforementioned upper hot-pressing devices, and the predetermined temperature can be set for each of the aforementioned upper and lower hot-pressing plates , by means of a predetermined number of heat presses and in conjunction with the displacement of the carrier plate, the water in the battery device to be dewatered is sequentially reduced by means of multiple sets of continuous heat presses. The battery device dewatering device as described in claim 5 or claim 6, which further includes a soft metal sealing device, the soft metal sealing device is located at the tail end of the aforementioned airtight cavity, and it includes an upper sealing device and The lower sealing device seals the soft metal by hot pressing. A water removal device for a battery device, mainly comprising a vacuum airtight cavity, the vacuum airtight cavity is provided with a conveying track, the conveying track is used to place a carrying plate, and the carrying plate is used to place at least one set of heat Lamination frame, the heat-pressing layer frame is composed of a predetermined number of heating plates and a connecting mechanism, the aforementioned heating plates have heating elements to heat each heating plate to a predetermined temperature, each heating plate is used to place a battery device, the aforementioned The connecting mechanism is used to connect the adjacent heating plates to form the heat-pressing layer frame with a predetermined number of layers in series. A heat-pressing device is arranged above the heat-pressing layer frame. It is composed of the pressing plate below the lifting system, and also includes a battery device. The battery device is packaged with soft metal, and at least one end of it is not sealed to form an unsealed end. The aforesaid lifting system moves down to make the pressure plate press down, and then in the vacuum airtight cavity, each heating plate of the hot-pressing layer frame is placed between the upper and lower end surfaces of the battery device to apply a predetermined temperature and pressure to heat. The method of applying pressure while removing the moisture inside the battery device has the effect of quickly and efficiently removing the moisture inside the battery device. The water-removing device for a battery device as described in claim 12, wherein the connecting mechanism includes a connecting piece useful for connecting the adjacent heating plates, and one end of each connecting piece is fixed at a predetermined position of the adjacent lower heating plate, The other end extends out of the adjacent upper heating plate, and has a chute as the distance between the pressing down of each heating plate. The adjacent upper heating plate is provided with a pin relative to the aforementioned connecting piece chute. The part is located at the lower end of the aforementioned chute in normal state to connect and support the upper and lower adjacent heating plates, and the upper heating plate is connected to another upper heating plate with another connecting piece. It is a heat-pressed shelf that is connected in series to form a predetermined number of layers. The water-removing device for a battery device as described in Claim 12 further includes a vacuum system, the vacuum system is connected to a vacuum pipe, and the vacuum pipe is connected to the aforementioned vacuum airtight chamber, and the vacuum airtight chamber is connected to the vacuum airtight chamber by the vacuum system Vacuuming is used to expedite the removal of the released moisture inside the aforementioned battery device to improve the efficiency of water removal. The water removal device for battery devices as described in claim 12 further includes a closed furnace body, and an exchange system is provided at both ends of the furnace body. The vacuum airtight cavity system is set inside the furnace body. The conveying track provided in the chamber connects the exchanging system at the two ends of the aforementioned furnace body as a track for the moving of the aforementioned carrying plate. Place the aforementioned hot-pressing layer frame, the battery device to be hot-pressed to remove water is placed between each heating plate of the hot-pressing layer frame, the aforementioned vacuum airtight cavity is provided with a predetermined number of the aforementioned hot-pressing devices, and the bottom of each of the hot-pressing devices is opposite to each other. The above-mentioned heat-pressing layer frame is installed, and the time and pressure of the heat-pressing can be set for each of the above-mentioned heat-pressing devices. The displacement of the bearing plate, in the way of multiple sets of continuous hot pressing, sequentially reduces the moisture inside the battery device to be dewatered. In addition to achieving continuous and rapid removal of moisture inside the battery device, it also has the function of drying the inside of the battery device. Uniform degree, uniform quality One effect.

Images