THERMAL CONDUCTIVE ADHESIVE AND SECONDARY BATTERY CONTAINING THE SAME

Abstract

The embodiment of the present application relates to the field of Li-ion battery and, in particular, to a thermal conductive adhesive and a secondary battery containing the thermal conductive adhesive. The thermal conductive adhesive is prepared through adding thermal conductive filling material in the hot melt adhesive system, which performs good thermal conductivity and adhering property, and can stably adhere the safety component with the cell, meanwhile transferring, via the thermal conductive adhesive, heat of the cell to the safety component rapidly, so that the safety component cuts off the circuit to protect the cell during overcharge; the thermal conductive adhesive has high initial viscosity, which increases good contact between the protection device and the cell through the adhesion, thereby reduces situations that the thermal conductive adhesive is separated from the cell due to inflation and deformation of the cell.

Description

TECHNICAL FIELD

The present application relates to the field of Li-ion battery and, in particular, to a thermal conductive adhesive and a secondary battery containing the thermal conductive adhesive.

BACKGROUND

Li-ion battery has advantages such as high energy density, long cycle service life, environmental friendly and reproducible etc., which has been widely applied to various kinds of consumer electronic products. However, since the chemical systems of different Li-ion batteries are not the same, safety performance in abuse, in particular overcharge, becomes a great challenge of Li-ion battery. At present, the commonly adopted measure for improving safety performance in abuse is to connect an external protection device, such measure can significantly improve the safety performance of the Li-ion battery in abuse.

Currently, Li-ion battery for commercial use is generally welded with temperature fuse, circuit breaker, PTC and so on outside the battery as the safety protection device, when heat is generated due to abuse of the battery and then the temperature increases, the heat of the battery main body will be conducted to the temperature fuse, when the temperature is higher than the triggering temperature of the temperature fuse, the fuse will open and cut off the circuit, so as to guarantee safety of the battery.

Now in the market, the battery is mainly adhered by double faced adhesive tape, which performs poor thermal conductivity and insufficient adhesion. The present application is aiming at the defects and disadvantages existed in the prior art.

SUMMARY

A primary object of the present application is to provide a thermal conductive adhesive.

A second object of the present application is to provide an application of the thermal conductive adhesive.

A third object of the present application is to provide a Li-ion battery containing the thermal conductive adhesive.

A fourth object of the present application is to provide a method for preparing the Li-ion battery.

In order to achieve the objects of the present application, the technical solutions adopted are:

The present application relates to a thermal conductive adhesive, the thermal conductive adhesive contains hot melt adhesive and thermal conductive filling material.

Preferably, the hot melt adhesive is selected from at least one of EVA hot melt adhesive, polyamide hot melt adhesive, polyurethane hot melt adhesive, polyester hot melt adhesive, polyethylene hot melt adhesive, polyesteramide hot melt adhesive, styrene type thermoplastic elastomer; preferably, the polyurethane hot melt adhesive is selected from isocyanate polyurethane prepolymer; preferably, the styrene type thermoplastic elastomer is selected from styrene-butadiene-styrene block copolymer, styrene-isoprene-styrene block copolymer.

Preferably, the thermal conductive filling material is selected from at least one of metal, metallic oxide, carbon material, nitride, carbide, silicon material; the metal is preferably selected from at least one of silver, copper or tin; the metallic oxide is preferably selected from at least one of aluminium oxide, magnesium oxide, zinc oxide, titanium oxide, SnO_y; the carbon material is preferably selected from at least one of hard carbon, soft carbon, mesocarbon microbead, carbon nano tube, graphite, graphene; the nitride is preferably selected from at least one of silicon nitride, aluminium nitride, boron nitride, titanium nitride; the carbide is preferably selected from at least one of silicon carbide, tungsten carbide; the silicon material is preferably selected from at least one of Si, SiO_x, 0<x<=2, 0<y<=2.

Preferably, thermal conductive coefficient of the thermal conductive filling material is 1 W/mK˜10000 W/mK, preferably 20 W/mK˜6000 W/mK.

Preferably, particle size of the thermal conductive filling material is 1 nm˜100 μm, or, the thermal conductive filling material contains thermal conductive filling material particle with particle size larger than 1 nm but smaller than 1 μm, and thermal conductive filling material particle with particle size larger than 1 μm but smaller than 50 μm.

Preferably, the thermal conductive filling material occupies 1%˜99% weight of the thermal conductive adhesive, preferably 20%˜75%.

Preferably, melt viscosity of the thermal conductive adhesive is 1000˜1*10⁶ CPs, initial viscosity is 0.5˜100N, peeling strength is 0.1˜20N/3 mm, melting temperature is 120° C. 190° C., thermal conductive coefficient is 0.1˜10000 W/mK; preferably, the melt viscosity of the thermal conductive adhesive is 1000˜20000 CPs, the initial viscosity is 0.5˜60N, peeling strength is 0.5˜10N/3 mm, melting temperature is 160° C.˜180° C., thermal conductive coefficient is 0.1˜100 W/mK.

The present application further relates to an application of the thermal conductive adhesive in a secondary battery.

The present application further relates to a secondary battery, including a cell, a safety component fixed on the cell and thermal conductive adhesive provided between the cell and the safety component, the thermal conductive adhesive is the thermal conductive adhesive according to the present application.

Preferably, area of the thermal conductive adhesive is 1 mm²˜500 mm², thickness of the thermal conductive adhesive is 0.01˜10 mm.

The present application further relates to a method for preparing the battery, including: adding the thermal conductive adhesive on the safety component or the cell, applying a force of 0.1˜100N so that the safety component is tightly adhered with the cell.

The beneficial effect achieved by the present application is:

1. The present application, through adding thermal conductive filling material in the hot melt adhesive system so as to prepare thermal conductive adhesive with good thermal conductivity, preferably, the thermal conductive coefficient is within the range of 0.1˜100 W/mK, so that the heat in the cell is transferred to the safety component to keep its temperature the same with that of in the cell and that the circuit is cut off rapidly so as to protect the cell, and improve the safety performance during overcharge.

2. The thermal conductive adhesive of the present application has good initial viscosity, based on the good viscosity, the safety component is well connected with the cell, thereby avoid situations that the thermal conductive adhesive is separated from the cell due to inflation and deformation of the cell in abuse.

3. The thermal conductive adhesive of the present application can adopt coating process and is coated on the position of the cell for placing the safety component so as to adhere the safety component with the battery, thereby achieve quantified, positioned adhesive distribution, moreover, the viscosity of the thermal conductive adhesive of the present application increases production efficiency, the consecutive production process is reliable and meets the production process requirements.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 shows a principle diagram of a hot melt adhesive during solidification and adhesion;

FIG. 2 shows variation curves of temperature, voltage and current with respect to time and temperature during overcharging according to Embodiment 1.

FIG. 3 shows variation curves of temperature, voltage and current with respect to time and temperature during overcharging according to Comparison Example 2.

DESCRIPTION OF EMBODIMENTS

The present application will be further illustrated as follows in combination with specific embodiments. It should be understood that, these embodiments are only used to illustrate the present application, rather than limiting the scope of the present application.

The present application relates to a thermal conductive adhesive, which contains hot melt adhesive and thermal conductive filling material.

As an improvement of the thermal conductive adhesive of the present application, the thermal conductive filling material is selected from at least one of metal, metallic oxide, carbon material, nitride, carbide, silicon material.

Preferably, the metal is metal powder, which is selected from at least one of silver, copper or tin, preferably silver.

Preferably, the metallic oxide is selected from at least one of aluminium oxide, magnesium oxide, zinc oxide, titanium oxide, SnO_y, 0<y<=2.

Preferably, the carbon material is selected from at least one of hard carbon, soft carbon, mesocarbon microbead, carbon nano tube, graphite, graphene.

Preferably, the nitride is selected from at least one of silicon nitride, aluminium nitride, boron nitride, titanium nitride.

Preferably, the carbide is selected from at least one of silicon carbide, tungsten carbide.

Preferably, the silicon material is selected from at least one of Si, SiO_x, 0<x<=2.

The thermal conductive filling material of the present application can also be natural mineral containing the above compounds.

As an improvement of the thermal conductive adhesive of the present application, particle size of the thermal conductive filling material is 1 nm˜100 μm, the particle size in the present application refers to the median particle size of the filling material. Too large particle size will lead to insufficient filling degree of the thermal conductive filling material, thus the thermal conductivity is poor; too small particle size will lead to poor processability.

Or, the thermal conductive filling material contains thermal conductive filling material particle with particle size larger than 1 nm but smaller than 1 μm, and thermal conductive filling material particle with particle size larger than 1 μm but smaller than 50 μm, since selecting multiple particle sizes can increase the filling volume and improve thermal conducting effect.

As a thermal conductive filling material with uniform particle size, the particle size is preferably between 20 nm˜10 μm.

As an improvement of the thermal conductive adhesive of the present application, the thermal conductive filling material occupies 1%˜99% weight of the thermal conductive adhesive, preferably 20%˜75%. Filling too large amount will lead to poor adhering property, filling too small amount will not significantly improve the thermal conducting effect.

As an improvement of the thermal conductive adhesive of the present application, the thermal conductive coefficient of the thermal conductive filling material is 1 W/mK˜10000 W/mK (25° C.), preferably 20˜6000 W/mK (25° C.), more preferably 20˜5000 W/mK (25° C.).

For a thermal conductive filling material with thermal conductive coefficient of 25 W/mK˜500 W/mK, the weight occupied by the thermal conductive filling material in the thermal conductive adhesive is preferably 20%˜70%.

For a thermal conductive filling material with thermal conductive coefficient of 1000 W/mK˜5000 W/mK, the weight occupied by the thermal conductive filling material in the thermal conductive adhesive is preferably 1%˜10%.

The hot melt adhesive in the present application is a plastic binder, of which the physical status changes with respect to temperature, but with chemical property unchanged.

As an improvement of the thermal conductive adhesive of the present application, the hot melt adhesive is selected from at least one of EVA (ethylene-vinyl acetate copolymer) hot melt adhesive, polyamide hot melt adhesive, polyurethane hot melt adhesive, polyester hot melt adhesive, polyethylene hot melt adhesive, polyesteramide hot melt adhesive, styrene type thermoplastic elastomer.

As an improvement of the thermal conductive adhesive of the present application, the ethylene-vinyl acetate copolymer (also called as ethylene-acetic acid ethylene copolymer) is copolymerized by ethylene (E) and vinyl acetate (VA), abbreviated as EVA. In the present application, in order to guarantee adhering property and other properties of the thermal conductive adhesive, ethylene-vinyl acetate copolymer with vinyl acetate (VA) content of 30% is preferably adopted.

The polyamide (PA) in the present application is a high polymer containing amide group in the repeating unit of its macromolecule main chai. The polyamide can be prepared by open loop polymerizing of acid amide, or can be prepared by polycondensation of diamine and diacid, and so on. PA possesses good overall property, including mechanical property, heat-resisting property, wear-resisting property, chemical drug tolerant property and self-lubricating property. The PA can be selected from PA6, PA66, PA11, PA12, PA46, PA610, PA612, PA1010 etc. In order to adapt for the adhering property of the thermal conductive adhesive of the present application, PA12 is preferred.

The polyurethane of the present application is a macromolecular compound containing a repeating carbamate group in its main chain, which is formed by addition polymerization of organic diisocyanate or polyisocyanate with dihydroxyl or polyhydroxy-compound.

The polyethylene (PE) hot melt adhesive in the present application includes high density polyethylene (HDPE) hot melt adhesive and low density polyethylene (LDPE) hot melt adhesive. HDPE powder hot melt adhesive is a non-polar thermoplastic resin with high crystallinity, LDPE powder hot melt adhesive has low melting temperature and good fluidity after melting.

The polyesteramide in the present application is a polymer containing ester bond and amido bond in its molecular chain, which combines the advantages of polyester and polyamide, and includes linear polyesteramide and cross-linking polyesteramide. The present application preferably adopts cross-linking polyesteramide as the hot melt adhesive.

The polyester used by the hot melt adhesive of the present application is a thermoplastic product formed by esterification of diacid and dihydric alcohol. Generally, dimethyl terephthalate, isophthalic acid, ethylene glycol and butanediol etc are adopted as the raw material of the esterification. Similar to polyamide hot melt adhesive, polyester hot melt adhesive has high heat resistance, good waterproof property and elasticity.

As an improvement of the thermal conductive adhesive of the present application, the polyurethane hot melt adhesive is preferably isocyanate polyurethane prepolymer, the polymerization reaction formula is:

Compound of isocyanate polyurethane prepolymer with isocyanate group can be selected from: toluene diisocyanate, polymethylene polyphenyl isocyanate, 1,6-hexamethylene diisocyanate, diphenylmethane 4, 4′-diisocyanate, toluene diisocynate etc; compound of the isocyanate polyurethane prepolymer with hydroxyl group can be selected from: polypropylene oxide glycol, poly(ethylene glycol adipate) diol, poly(ethylene-diethylene glycol adipate) diol, poly(ethylene-glycol-propanediol adipate) diol, poly(ethylene glycol adipate) diol.

During the adhering process of the isocyanate polyurethane prepolymer, the solid adhesive is heated to melt as fluid, and then is coated on the surface of the base material, the active end group —NCO group reacts with the active hydrogen in the water absorbed by the surface of the base material, in the air and within the hydroxyl existed on the surface thereof, to form a polyurea structure. The polyurethane binder performs high activity and polarity, and also performs excellent chemical adhesion with base material containing active hydrogen such as porous material like foam, plastic, wood, leather, fabric, paper and ceramic etc, and material having smooth and clean surface such as metal, glass, rubber, plastic etc, which makes the such thermal conductive adhesive fixedly adhere the protection device with the battery.

The principle diagram during solidification and adhesion of the hot melt adhesive is as shown in FIG. 1, the reaction of the isocyanate polyurethane prepolymer during solidification and adhesion is:

1. Self-crosslinking reaction of the thermal conductive adhesive

2. Reaction between the thermal conductive adhesive and the base material

The styrene series thermoplastic elastomer is selected from styrene-butadiene-styrene block copolymer (SBS), styrene-isoprene-styrene block copolymer (SIS).

As an improvement of the thermal conductive adhesive of the present application, the thermal conductive adhesive can further be added with at least one of tackifier, antioxidant, catalyst, viscosity modifier, so as to adjust the performance of the thermal conductive adhesive.

As an improvement of the thermal conductive adhesive of the present application, melt viscosity of the thermal conductive adhesive is 1000˜1*10⁶ CPs (175° C.), initial viscosity is 0.5˜100N, peeling strength is 0.1˜20N/3 mm, melting temperature is 120° C.˜190° C., thermal conductive coefficient is 0.1˜10000 W/mK, preferably, the melt viscosity of the thermal conductive adhesive is 1000˜20000 CPs (175° C.), the initial viscosity is 0.5˜60N, peeling strength is 0.5˜10N/3 mm, melting temperature is 160° C.˜180° C., thermal conductive coefficient is 0.1˜100 W/mK.

More preferably, the thermal conductive coefficient of the thermal conductive adhesive is 0.2˜50 W/mK.

The preparing method of the thermal conductive adhesive of the present application is: in water-free inert gas environment, adding thermal conductive filling material after heating the raw material, stirring the mixture to be dispersed and uniform, then sealing.

The present application further relates to usage of the thermal conductive adhesive, the thermal conductive adhesive of the present application can be used in a secondary battery, and is adapted to any position of the secondary battery which needs to be adhered and, preferably, is provided between the cell and the safety component. The safety component includes circuit breaker, positive temperature coefficient (Positive Temperature Coefficient, PTC) and fuse.

The present application further relates to a secondary battery, including a cell, a safety component fixed on the cell and a thermal conductive adhesive provided between the cell and the safety component, the thermal conductive adhesive is the thermal conductive adhesive according to the present application.

As an improvement of the secondary battery of the present application, the area of the thermal conductive adhesive is 1 mm²˜500 mm², the thickness of the thermal conductive adhesive is 0.05˜5 mm.

The present application further relates to a method for preparing the secondary battery: adding thermal conductive adhesive on the safety component or the cell, applying a force of 0.1˜100N so that the safety component is tightly adhered with the cell. Preferably, the operating temperature of the thermal conductive adhesive after melting is 150° C.˜200° C.

The adding manner of the thermal conductive adhesive in the present application can be coating, depositing, adhering, placing etc; the coating manner can be achieved by dotting, coating line, spraying etc.

The isocyanate polyurethane prepolymer used in the embodiments of the present application is purchased from Guangzhou Yawei company.

The ethylene-vinyl acetate copolymer (EVA), polyamide (PA), low density polyethylene (LDPE), polyesteramide (PEA) used in the embodiments of the present application are purchased from Huagongbaichuan company.

The double faced adhesive tape 3M467, thermal conductive double faced adhesive tape 3M8805 used in the embodiments of the present application are purchased from 3M company.

The high density polyethylene (HDPE), styrene-butadiene-styrene block copolymer (SBS), styrene-isoprene-styrene block copolymer (SIS) used in the embodiments of the present application are purchased from Shenzhen Suyuanshiye Co, Ltd.

Embodiments 1˜9

Preparing thermal conductive adhesive according to the hot melt adhesive and thermal conductive filling material shown in Table 1, and coating the prepared thermal conductive adhesive between the cell and the safety component, detecting the performance of the cell.

The preparing method of the thermal conductive adhesive: in water-free inert gas environment, adding thermal conductive filling material after heating the raw material, stirring the mixture to be dispersed and uniform, then sealing.

The preparing method of the battery is: adding thermal conductive adhesive on the safety component or the cell, applying a force of 0.1˜100N so that the safety component is tightly adhered with the cell. Preferably, the operating temperature of the thermal conductive adhesive is 150˜200° C.

	TABLE 1
	Thermal conductive filling material
					Thermal
			Weight	Particle	conductive
			ratio	size	coefficient
No.	Hot melt adhesive	Type	(%)	(nm)	(W/mK)
Embodiment 1	polypropylene oxide glycol, toluene	aluminium	50%	5000	30
	diisocynate	oxide
Embodiment 2	polymethylene polyphenyl isocyanate,	graphite	50%	5000	151
	poly(ethylene glycol adipate) diol
Embodiment 3	1,6-hexamethylene diisocyanate,	SiC	40%	5000	83
	poly(ethylene-diethylene glycol adipate)
	diol
Embodiment 4	diphenylmethane4, 4′-diisocyanate,	Silver	20%	5000	420
	poly(ethylene-glycol-propanediol	powder
	adipate) diol
Embodiment 5	toluene diisocyanate, poly(ethylene	aluminium	65%	4000	30
	glycol adipate) diol	oxide
Embodiment 6	EVA (VA 30 wt %)	aluminium	50%	5000	30
		oxide
Embodiment 7	PA12	aluminium	50%	5000	30
		oxide
Embodiment 8	LDPE	aluminium	50%	5000	30
		oxide
Embodiment 9	PEA	aluminium	50%	5000	30
		oxide
Comparison	Double faced adhesive tape 3M467	—	—	—	—
example 1
Comparison	—	—	—	—	—
example 2
Comparison	Thermal conductive double faced	—	—	—	—
example 3	adhesive tape 3M8805

The detection method includes:

(i) initial viscosity testing method: preparing sample product with 0.03 mg/mm dispensing adhesive, cutting a sample product of 3 mm*20 mm, cementing TCO after dispensing adhesive, and testing tension under normal temperature within 2 minutes after completion of the sample product.

(ii) peeling strength testing method: preparing adhering sample product with 0.06 mg/mm dispensing adhesive, cutting a sample product with 3 mm width, cementing TCO after dispensing adhesive, then testing to acquire performance of the battery by peeling at 180° C.

(iii) overcharge testing method: charging using a constant current of 1 C to a voltage of 10V, maintain CV as 10V for 2 h or until the temperature of the cell is below 40° C., then stop testing. Variation curves of temperature, voltage and current at different time and under different temperature are shown in FIG. 2 and FIG. 3, respectively.

The performance of the thermal conductive adhesive in Embodiments 1˜9 and Comparison examples 1˜3 is as shown in Table 2 and Table 3:

	TABLE 2
						Thermal conductive
						coefficient of
	Melt	Operating			Peeling	thermal conductive
	viscosity/	temperature/	Initial	Setting	strength	adhesive/
	CPs	° C.	viscosity/N	time/h	N/3 mm	W/mK
Embodiment 1	6000	170	50	18	8	1.1
Embodiment 2	5000	180	60	20	7	1.5
Embodiment 3	5500	180	50	24	8.4	1.4
Embodiment 4	5000	175	45	20	7.9	2.5
Embodiment 5	6500	180	45	20	7.5	1.6
Embodiment 6	4800	180	60	10	10	1.1
Embodiment 7	5000	190	55	12	9	1.4
Embodiment 8	4400	185	45	10	7	1.2
Embodiment 9	4500	175	40	8	6	1.1
Comparison	—	—	8	—	2	0.12
example 1
Comparison	—	—	—	—	—	—
example 2
Comparison	—	—	5	—	—	0.7
example 3

	TABLE 3
	Safety	Testing result	Highest temperature
	component cut	of battery	on surface of safety	Highest temperature
	off or not	overcharge	component/° C.	on surface of cell/° C.
Embodiment 1	Yes	Nonignition	80	80
Embodiment 2	Yes	Nonignition	82	85
Embodiment 3	Yes	Nonignition	75	76
Embodiment 4	Yes	Nonignition	86	87
Embodiment 5	Yes	Nonignition	74	76
Embodiment 6	Yes	Nonignition	79	80
Embodiment 7	Yes	Nonignition	78	78
Embodiment 8	Yes	Nonignition	87	88
Embodiment 9	Yes	Nonignition	89	90
Comparison	No	Ignition	600	580
example 1
Comparison	None	Ignition	—	850
example 2
Comparison	Yes	Nonignition	80	94
example 3

Embodiment 2

Preparing thermal conductive adhesive according to the hot melt adhesive and thermal conductive filling material shown in Table 4, and coating the prepared thermal conductive adhesive between the cell and the safety component, detecting the performance of the cell. The preparing method is as the same with Embodiment 1.

	TABLE 4
	Thermal conductive filling material
	Thermal
	weight		conductive
			ratio	Particle	coefficient
	Hot melt adhesive	Type	(%)	size	(W/mK)
Embodiment 10	HDPE	graphene	1%	10	nm	4800
Embodiment 11	SBS	mesocarbon	50%	100	nm	200
		microbead
Embodiment 12	SIS	carbon	5%	50	nm	1500
		nano tube
Embodiment 13	EVA (VA 30 wt %)	SnO2	20%	6	μm	30
Embodiment 14	EVA (VA 30 wt %)	Si	65%	400	nm	100
Embodiment 15	polypropylene oxide glycol,	aluminium	50%	6 μm 25%	30
	toluene diisocynate	oxide		800 nm 25%
Embodiment 16	polyester hot melt adhesive	zinc oxide	50%	3 μm 25%	26
				500 nm 25%
Embodiment 17	HDPE	hard	50%	300	nm	100
		carbon
Embodiment 18	SBS	soft	50%	600	nm	86
		carbon
Embodiment 19	SIS	aluminium	20%	6	μm	30
		nitride
Embodiment 20	EVA (VA 30 wt %)	boron	65%	3	μm	125
		nitride
Embodiment 21	PA12	titanium	50%	4	μm	29
		nitride
Embodiment 22	LDPE	tungsten	50%	8	μm	72
		carbide
Embodiment 23	PEA	SiO2	50%	15	μm	5
Embodiment 24	1,6-hexamethylene	Si	50%	20	μm	100
	diisocyanate,
	poly(ethylene-diethylene
	glycol adipate) diol
Embodiment 25	diphenylmethane 4,	Si	50%	50	μm	100
	4′-diisocyanate,
	poly(ethylene glycol
	adipate) diol
Embodiment 26	toluene diisocyanate,	Si	50%	100	μm	100
	poly(ethylene glycol
	adipate) diol

The performance of the thermal conductive adhesive and that of the battery prepared by the thermal conductive adhesive in Embodiments 10˜26 is as shown in Table 5 and Table 6:

	TABLE 5
						Thermal conductive
	Melt	Operating			Peeling	coefficient of thermal
	viscosity/	temperature/	Initial	Setting	strength	conductive adhesive/
	CPs	° C.	viscosity/N	time/h	N/3 mm	W/mK
Embodiment	6500	170	45	12	6	3.5
10
Embodiment	5500	180	50	13	6.5	2.4
11
Embodiment	5500	180	42	15	7	1.5
12
Embodiment	4800	185	45	13	8	0.9
13
Embodiment	7000	170	35	12	5.5	1.9
14
Embodiment	5500	180	30	16	8	2.1
15
Embodiment	6000	180	28	12	4	0.4
16
Embodiment	5000	180	40	16	8	2.0
17
Embodiment	6000	180	26	16	6.5	1.6
18
Embodiment	4000	175	35	18	5	0.4
19
Embodiment	6000	180	20	16	4	1.3
20
Embodiment	6000	180	28	18	5	0.9
21
Embodiment	6500	180	30	16	4	1.3
22
Embodiment	7000	180	25	18	3	0.2
23
Embodiment	6500	180	16	18	4	1.2
24
Embodiment	5800	180	14	16	3.5	0.9
25
Embodiment	5000	180	9	12	1	0.6
26

	TABLE 6
	Safety	Testing result	Highest temperature
	component cut	of battery	on surface of safety	Highest temperature
	off or not	overcharge	component/° C.	on surface of cell/° C.
Embodiment 10	Yes	Nonignition	75	76
Embodiment 11	Yes	Nonignition	74	85
Embodiment 12	Yes	Nonignition	77	83
Embodiment 13	Yes	Nonignition	79	82
Embodiment 14	Yes	Nonignition	76	79
Embodiment 15	Yes	Nonignition	74	75
Embodiment 16	Yes	Nonignition	78	86
Embodiment 17	Yes	Nonignition	75	75
Embodiment 18	Yes	Nonignition	77	78
Embodiment 19	Yes	Nonignition	80	89
Embodiment 20	Yes	Nonignition	75	79
Embodiment 21	Yes	Nonignition	76	86
Embodiment 22	Yes	Nonignition	76	78
Embodiment 23	Yes	Nonignition	79	95
Embodiment 24	Yes	Nonignition	78	92
Embodiment 25	Yes	Nonignition	79	95
Embodiment 26	Yes	Nonignition	82	104

Comparison Examples 4˜12

Preparing thermal conductive adhesive according to the hot melt adhesive and thermal conductive filling material shown in Table 7, and coating the prepared thermal conductive adhesive between the cell and the safety component, detecting the performance of the cell. The preparing method is as the same with Embodiment 1.

The structural formula of the epoxy resin is:

	TABLE 7
	Thermal conductive filling material
	Thermal
	conductive
			Weight	Particle	coefficient
	Hot melt adhesive	Type	ratio(%)	size	(W/mK)
Comparison	polypropylene oxide glycol and	aluminium	50%	110	μm	30
example 4	toluene diisocynate	oxide
Comparison	polypropylene oxide glycol and	ABS	50%	500	nm	0.25
example 5	toluene diisocynate
Comparison	polypropylene oxide glycol and	—	—	—	—
example 6	toluene diisocynate
Comparison	polypropylene oxide glycol and	aluminium	1%	5	μm	30
example 7	toluene diisocynate	oxide
Comparison	polypropylene oxide glycol and	aluminium	80%	5	μm	30
example 8	toluene diisocynate	oxide
Comparison	polypropylene oxide glycol and	aluminium	95%	5	μm	30
example 9	toluene diisocynate	oxide
Comparison	Silica gel	SiC	50%	5	μm	83
example 10
Comparison	Epoxy resin: formula 1	silver	20%	5	μm	420
example 11		powder
Comparison	Epoxy resin: formula 2	SiC	50%	5	μm	83
example 12

The performance of the thermal conductive adhesive and the battery prepared by the thermal conductive adhesive according to Comparison examples 4˜12 is as shown in Table 8 and Table 9:

	TABLE 8
						Thermal
	Melt	Operating			Peeling	conductive
	viscosity/	temperature/	Initial		strength	coefficient/
	CPs	° C.	viscosity/N	Setting time/h	N/3 mm	W/mK
Comparison	7000	180	10	16	3	1.1
example 4
Comparison	5500	175	30	12	6	0.3
example 5
Comparison	4000	175	50	14	12	0.08
example 6
Comparison	4300	180	50	16	10	0.4
example 7
Comparison	4400	180	48	15	9.8	0.5
example 8
Comparison	8000	180	10	8	2	2.8
example 9
Comparison	—	25	2	72	12	2.5
example 10
Comparison	—	25	0.2	74	16	1.8
example 11
Comparison	—	25	0.15	78	14	2
example 12

	TABLE 9
	Safety	Testing result	Highest temperature
	component cut	of battery	on surface of safety	Highest temperature
	off or not	overcharge	component/° C.	on surface of cell/° C.
Comparison	Yes	Nonignition	79	102
example 4
Comparison	No	Ignition	520	580
example 5
Comparison	No	Ignition	630	700
example 6
Comparison	Yes	Nonignition	79	86
example 7
Comparison	Yes	Nonignition	75	76
example 8
Comparison	No	Ignition	600	750
example 9	(fall off)
Comparison	Yes	Nonignition	75	78
example 10
Comparison	Yes	Nonignition	75	79
example 11
Comparison	Yes	Nonignition	76	80
example 12

The experiment result of Comparison example 4 shows that if the particle size of the thermal conductive filling material is too large, the thermal conductive coefficient decreases.

The experiment results of Comparison examples 5 and 6 show that if the thermal conductive filling material is not added, or filling material with relative low thermal conductive coefficient is added, the thermal conductivity cannot be effectively improved.

The experiment results of Comparison examples 7˜9 show that when adopting thermal conductive filling material with suitable thermal conductivity, if too small amount is added, the thermal conductivity cannot be effectively improved, if too much is added, the physical property of the thermal conductive adhesive will be affected due to poor adhesion, thereby cannot form a stable connection between the battery and the safety component.

The experiment results of Comparison examples 10˜12 show that if other base material is adopted, the thermal conductive initial viscosity is relative small, which does not meet the actual application requirements, or the setting time is too long, resulting in low manufacturing efficiency.

Although the present application is illustrated by the preferred embodiments as above, however, they are not used to limit the claims; various modifications and variations can be made by those skilled in the art without departing from the concept of the present application, therefore, the protection scope of the present application shall be defined by the scope of the claims.

Claims

1. A thermal conductive adhesive, comprising: a hot melt adhesive and thermal conductive filling material.

2. The thermal conductive adhesive according to claim 1, wherein the hot melt adhesive is selected from at least one of EVA hot melt adhesive, polyamide hot melt adhesive, polyurethane hot melt adhesive, polyester hot melt adhesive, polyethylene hot melt adhesive, polyesteramide hot melt adhesive, styrene type thermoplastic elastomer; preferably, the polyurethane hot melt adhesive is selected from isocyanate polyurethane prepolymer; preferably, the styrene type thermoplastic elastomer is selected from styrene-butadiene-styrene block copolymer, styrene-isoprene-styrene block copolymer.

3. The thermal conductive adhesive according to claim 1, wherein the thermal conductive filling material is selected from at least one of metal, metallic oxide, carbon material, nitride, carbide, silicon material; the metal is preferably selected from at least one of silver, copper or tin; the metallic oxide is preferably selected from at least one of aluminium oxide, magnesium oxide, zinc oxide, titanium oxide, SnOy; the carbon material is preferably selected from at least one of hard carbon, soft carbon, mesocarbon microbead, carbon nano tube, graphite, graphene; the nitride is preferably selected from at least one of silicon nitride, aluminium nitride, boron nitride, titanium nitride; the carbide is preferably selected from at least one of silicon carbide, tungsten carbide; the silicon material is preferably selected from at least one of Si, SiOx; wherein, 0<x<=2, 0<y<=2.

4. The thermal conductive adhesive according to claim 1, wherein thermal conductive coefficient of the thermal conductive filling material is 1 W/mK˜10000 W/mK, preferably 20 W/mK˜6000 W/mK.

5. The thermal conductive adhesive according to claim 1, wherein particle size of the thermal conductive filling material is 1 nm˜100 μm, or, the thermal conductive filling material contains thermal conductive filling material particle with particle size larger than 1 nm but smaller than 1 μm, and thermal conductive filling material particle with particle size larger than 1 μm but smaller than 50 μm.

6. The thermal conductive adhesive according to claim 1, wherein the thermal conductive filling material occupies 1%˜99% weight of the thermal conductive adhesive, preferably 20%˜75%.

7. The thermal conductive adhesive according to claim 1, wherein melt viscosity of the thermal conductive adhesive is 1000˜1*106 CPs, initial viscosity is 0.5˜100N, peeling strength is 0.1˜20N/3 mm, melting temperature is 120° C.˜190° C., thermal conductive coefficient is 0.1˜10000 W/mK; preferably, the melt viscosity of the thermal conductive adhesive is 1000˜20000 CPs, the initial viscosity is 0.5˜60N, the peeling strength is 0.5˜10N/3 mm, the melting temperature is 160° C.˜180° C., the thermal conductive coefficient is 0.1˜100 W/mK.

8. An application of the thermal conductive adhesive according to claim 1 in a secondary battery.

9. A secondary battery, comprising a cell, a safety component fixed on the cell and thermal conductive adhesive provided between the cell and the safety component, characterized in that, the thermal conductive adhesive is the thermal conductive adhesive according to claim 1, preferably, area of the thermal conductive adhesive is 1 mm2˜500 mm2, thickness of the thermal conductive adhesive is 0.01˜10 mm.

10. A method for preparing the secondary battery according to claim 9, wherein comprising: adding the thermal conductive adhesive on the safety component or the cell, applying a force of 0.1˜100N so that the safety component is tightly adhered with the cell.