CN217823617U - Liquid cooling connector assembly and vehicle - Google Patents

Abstract

The utility model discloses a liquid cooling connector assembly and vehicle relates to car electric energy transmission technical field. Including at least one electricity connection skeleton and connector, include connecting terminal in the connector, it is connected with connecting terminal electricity respectively to connect the skeleton both ends, the protective housing that has shielding efficiency is cup jointed to electricity connection skeleton periphery, electricity connection skeleton periphery with form the cavity between the protective housing inner wall that has shielding efficiency, the insulating coolant liquid of cavity circulation. The utility model discloses can reduce the electricity and connect skeleton and connecting terminal because of the inefficacy that the circular telegram produced high temperature and leads to, reduce the diameter of electricity connection skeleton, prolong the life of connector assembly, improve whole car security, play shielding electromagnetic interference's effect simultaneously.

Description

Liquid cooling connector assembly and vehicle

Technical Field

The utility model relates to an automobile electric energy transmission technical field, more specifically relates to a liquid cooling connector assembly and a vehicle.

Background

With the increasing popularization of new energy automobiles, equipment and facilities for supplying power to the new energy automobiles are developed, the connector assemblies on the new energy automobiles have large transmission current due to the fact that the requirements for driving high-power motors are met, the diameters of high-voltage cables on the connector assemblies are increased, the connectors can be assembled on automobile bodies only by hand, and labor cost and time cost are wasted.

In addition, in the normal use process, the high-voltage cable can flow through very large current, so the high-voltage cable and the connecting joint can generate a large amount of heat, high temperature can be caused due to excessive heat, the connecting position of the high-voltage cable, the peripheral connecting pieces and the peripheral fixing pieces can be out of work due to high temperature, the normal use of the high-voltage device is influenced, short circuit and open circuit are generated, even electric shock hazard is generated, and the life is threatened.

High-voltage cable can produce very strong electromagnetic interference because the electric current is great, and in order to reduce electromagnetic interference's influence, high-voltage cable adopts the shielding net to carry out electromagnetic interference's shielding usually, and the shielding net of current commonly used adopts the wire to compile and forms, need increase the shielding braider in cable production facility, and equipment price is high, and area is big, and the shielding cable price that leads to the connector is high at all. At present, the shielding technology of the connector is not particularly perfect, and the electric appliances in the automobile are interfered and cannot be used.

At present, no practical solution is provided for the above problems, and therefore, a connector assembly which has a small wire diameter, a low cable heat productivity and can realize automatic production and assembly is urgently needed in the technical field of automobile electrical appliances.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a new technical scheme of liquid cooling connector assembly and vehicle. The utility model discloses a liquid cooling connector assembly can reduce the electricity and connect skeleton and connecting terminal because of the inefficacy that the circular telegram produced high temperature and leads to, reduces the diameter of electricity connection skeleton, and the life of extension connector improves whole car security, plays shielding electromagnetic interference's effect simultaneously.

According to the utility model discloses an aspect provides a liquid cooling connector assembly, connect skeleton and connector including an at least electricity, its characterized in that, include connecting terminal in the connector, the electricity is connected the skeleton both ends and is connected with connecting terminal electricity respectively, the protective housing that has shielding efficiency is cup jointed to the electricity connection skeleton periphery, the electricity connection skeleton periphery with form the cavity between the protective housing inner wall that has shielding efficiency, the cavity circulates the coolant liquid.

The cooling liquid is made of an insulating material.

The material of the electric connection framework is a rigid solid conductor material.

The cross-sectional area of the electric connection framework is 1.5mm ² -240mm ² 。

The electric connection framework is electrically connected with the connecting terminal in a welding or crimping mode.

The protective shell is made of rigid conductive materials.

The protective shell is made of metal or conductive plastic.

The connector further comprises a shielding inner shell, and the shielding inner shell is made of a conductive material.

The shielding inner shell is made of metal or conductive plastic.

The conductive plastic is a high polymer material containing conductive particles, and the conductive particle material contains one of metal, conductive ceramic, a carbon-containing conductor, solid electrolyte and a mixed conductor; the material of the high polymer material contains one of tetraphenyl ethylene, polyvinyl chloride, polyethylene, polyamide, polytetrafluoroethylene, tetrafluoroethylene/hexafluoropropylene copolymer, ethylene/tetrafluoroethylene copolymer, polypropylene, polyvinylidene fluoride, polyurethane, poly terephthalic acid, polyurethane elastomer, styrene block copolymer, perfluoroalkoxy alkane, chlorinated polyethylene, polyphenylene sulfide, polystyrene, crosslinked polyolefin, ethylene-propylene rubber, ethylene/vinyl acetate copolymer, chloroprene rubber, natural rubber, styrene-butadiene rubber, nitrile rubber, silicone rubber, butadiene rubber, isoprene rubber, ethylene-propylene rubber, chloroprene rubber, butyl rubber, fluorine rubber, polyurethane rubber, polyacrylate rubber, chlorosulfonated polyethylene rubber, epichlorohydrin rubber, chlorinated polyethylene rubber, chlorosulfonated sulfur rubber, styrene butadiene rubber, hydrogenated rubber, polysulfide rubber, crosslinked polyethylene, polycarbonate, polysulfone, polyphenylene oxide, polyester, phenolic resin, urea formaldehyde, styrene-acrylonitrile copolymer, polymethacrylate, and resin.

The metal material contains one of nickel, cadmium, zirconium, chromium, cobalt, manganese, aluminum, tin, titanium, zinc, copper, silver, gold, phosphorus, tellurium and beryllium.

The carbon-containing conductor contains one of graphite powder, a carbon nanotube material, graphite silver, graphene silver and a graphene material.

The protective shell is electrically connected with the shielding inner shell in a crimping or welding mode.

The impedance between the protective shell and the shielding inner shell is less than 80m omega.

The transfer impedance of the protective shell is less than 100m omega.

The transfer impedance of the shielding inner case is less than 100m omega.

The electric connection skeleton quantity is one, the connector is including connecting first connector and the second connector at electric connection skeleton both ends, first connector with the inside switching cavity that sets up of second connector, the switching cavity with cavity UNICOM, first connector sets up the UNICOM the induction pipe of switching cavity, the second connector sets up the UNICOM the contact tube of switching cavity.

The number of the electric connection frameworks is at least two, the connectors comprise a first connector and a second connector which are connected with two ends of the electric connection frameworks, communicated rotary cavities are arranged in the first connectors, and the rotary cavities are communicated with the cavities of the electric connection frameworks; the liquid inlet cavity and the liquid outlet cavity are isolated from each other and are respectively communicated with the cavity of the electric connection framework.

The side wall of the liquid inlet cavity is provided with a liquid inlet pipe communicated with the outside of the connector, and the side wall of the liquid outlet cavity is provided with a liquid outlet pipe communicated with the outside of the connector.

And a sealing structure is arranged between the connector and the protective shell.

At least one support ring is arranged inside the cavity, the inner wall of the support ring is in contact with the periphery of the electric connection framework, and the outer wall of the support ring is in contact with the inner wall of the protective shell.

The support ring is in the electricity is connected skeleton axial direction and is set up at least one through-hole.

The sum of the sectional areas of the through holes accounts for 23% -90% of the sectional area of the cavity.

The electric connection framework is provided with at least one bending position, and support rings are respectively arranged at two ends and the middle position of the bending position.

The cross section of the electric connection framework is in one or more of a round shape, an oval shape, a rectangular shape, a polygonal shape, an A shape, a B shape, a D shape, an M shape, an N shape, an O shape, an S shape, an E shape, an F shape, an H shape, a K shape, an L shape, a P shape, a T shape, a U shape, a V shape, a W shape, an X shape, a Y shape, a Z shape, a semi-arc shape, an arc shape and a wave shape.

The cross section of the electric connection framework is a polygon, and corners of the polygon are rounded or chamfered.

At least partial region of the electric connection framework is a flexible body.

The thickness of the protective shell accounts for 1% -15% of the outer diameter of the protective shell.

The outer diameter of the cavity is 1.02-1.3 times of the outer diameter of the electric connection framework.

The boiling point of the cooling liquid is more than or equal to 100 ℃.

The cooling fluid comprises water, ethylene glycol, silicone oil, fluorinated fluids, castor oil, coconut oil, corn oil, cottonseed oil, linseed oil, olive oil, palm oil, peanut oil, grapeseed oil, rapeseed oil, safflower oil, sunflower oil, soybean oil, high oleic variants of various vegetable oils, decene-4-acid, decenoic acid, myrcenic acid, nervonic acid, tetradecenoic acid, sperm whale acid, crude leased acid, palmitoleic acid, petroselic acid, oleic acid, octadecenoic acid, gadoleic acid, macrocephalic acid, cetenoic acid, erucic acid, and one of nervonic acid, glycerol, transformer oil, axle oil, internal combustion engine oil, or compressor oil.

The cooling rate of the cooling liquid to the electric connection framework is 0.05K/s-5K/s.

One of the connectors is a charging cradle.

The utility model also provides a vehicle, include as above liquid cooling connector assembly, circulating pump and cooling device, the cavity with the circulating pump with cooling device UNICOM.

The inlet pipe is communicated with a liquid inlet of the circulating pump, a liquid outlet of the circulating pump is communicated with a liquid inlet of the cooling device, and a liquid outlet of the cooling device is communicated with the delivery pipe.

The liquid inlet pipe is communicated with a liquid inlet of the circulating pump, a liquid outlet of the circulating pump is communicated with a liquid inlet of the cooling device, and a liquid outlet of the cooling device is communicated with the liquid outlet pipe.

The utility model has the advantages that:

1. the problem of present high-voltage wire harness wire footpath thick is solved, uses the liquid cooling technique, reduces the calorific capacity of electricity connection skeleton, makes the electricity connect the skeleton can switch on great electric current with less wire footpath.

2. The problem of present high-pressure pencil use flexible cable, can't realize automated production and assembly is solved, use the electric connection skeleton of at least part stereoplasm, can realize the automatic assembly and the equipment of pencil.

3. The problem of solving present liquid cooling pencil cooling efficiency low, present liquid cooling pencil all cools off through the liquid cooling pipe, the utility model discloses a skeleton contact is connected with the electricity to the coolant liquid is direct, can reduce the temperature of electricity connection skeleton rapidly, realizes that the heavy current switches on.

4. The problem of flexible cable and hull contact friction, lead to the damaged short circuit of insulating layer is solved, the electric connection skeleton can follow the automobile body shape and arrange, but also can have the certain distance with the automobile body, can guarantee not rub with the hull to guarantee the life of electric connection skeleton.

5. The connector is internally provided with the shielding inner shell, electromagnetic interference generated by a terminal of the connector can be effectively prevented, the shielding inner shell made of conductive plastic can be integrally formed with the connector in an integral injection molding mode, processing time is saved, production efficiency is improved, and production cost is reduced.

6. The electric connection framework is further provided with a flexible part and a bending part, so that the structure of the connector assembly can be reasonably designed according to the installation environment of the automobile body, the connector assembly is easier to install on the automobile body, and the assembly time is saved.

7. The sealing ring can prevent revealing of junction coolant liquid, and the support ring can support the cavity, prevents that it from receiving the circulation that external force extrusion deformation influences the coolant liquid.

8. Adopt the protective housing to cup joint the form of electricity connection skeleton, the protective housing has both played the effect of building the cavity, can play the effect of shielding layer again, and the electromagnetic interference that skeleton circular telegram produced is connected to effectual shielding electricity.

Other features of the present invention and advantages thereof will become apparent from the following detailed description of exemplary embodiments of the invention, which proceeds with reference to the accompanying drawings.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate embodiments of the invention and together with the description, serve to explain the principles of the invention.

Fig. 1 is a schematic structural view of the liquid-cooled connector assembly of the present invention.

Fig. 2 is a schematic structural view of the shielding inner shell of the liquid-cooled connector assembly of the present invention.

Fig. 3 is a cross-sectional view of the electrical connection frame of the liquid-cooled connector assembly of the present invention.

Fig. 4 is a schematic view of the structure of the rotary cavity of the liquid-cooled connector assembly of the present invention.

Fig. 5 is the schematic structural diagram of the liquid inlet cavity and the liquid return cavity of the liquid cooling connector assembly of the present invention.

Fig. 6 is a schematic structural view of the support ring of the liquid-cooled connector assembly of the present invention.

Fig. 7 is a schematic structural view of the through hole of the liquid-cooled connector assembly of the present invention.

Fig. 8 is a schematic structural view of the adapting cavity of the liquid-cooled connector assembly of the present invention.

Fig. 9 is the schematic structural diagram of the liquid inlet cavity and the liquid outlet cavity of the liquid cooling connector assembly of the present invention.

The figures are labeled as follows:

1-connector, 11-first connector, 12-second connector, 2-electric connection framework, 4-shielding inner shell, 5-protective shell, 6-cavity, 7-connecting terminal, 8-sealing structure, 91-rotary cavity, 92-liquid inlet cavity, 921-liquid inlet pipe, 93-liquid outlet cavity, 931-liquid outlet pipe, 94-switching cavity, 941-inlet pipe, 942-outlet pipe, 10-support ring, 101-through hole, 111-circulating pump and 112-cooling device.

Detailed Description

Various exemplary embodiments of the present invention will now be described in detail with reference to the accompanying drawings. It should be noted that: unless specifically stated otherwise, the relative arrangement of parts and steps, numerical expressions, and numerical values set forth in these embodiments do not limit the scope of the present invention.

The following description of at least one exemplary embodiment is merely illustrative in nature and is in no way intended to limit the invention, its application, or uses.

Techniques, methods, and apparatus known to one of ordinary skill in the relevant art may not be discussed in detail but are intended to be part of the specification where appropriate.

In all examples shown and discussed herein, any particular value should be construed as merely illustrative, and not limiting. Thus, other examples of the exemplary embodiments may have different values.

The utility model provides a liquid cooling connector assembly, as shown in fig. 1-7, includes that skeleton 2 and connector 1 are connected to at least one electricity, include connecting terminal 7 in the connector 1, 2 both ends of electricity connection skeleton are connected with connecting terminal 7 electricity respectively, 2 peripheries of electricity connection skeleton are cup jointed the protective housing 5 that has shielding efficiency, 2 peripheries of electricity connection skeleton with form cavity 6 between the protective housing 5 inner walls that have shielding efficiency, 6 insulating coolant liquids of circulation of cavity.

At present, multi-core copper cables are used for high-voltage cables on most connector assemblies, so that the high-voltage cables are heavy in weight and high in price and become obstacles for limiting the popularization of new energy automobiles. In addition, although the multi-core cable is soft, the multi-core cable can be conveniently processed and wired, due to the fact that the cable is too thick in diameter and large in weight, the cable can frequently rub against a car shell in the driving process of a car, an insulating layer of the cable is damaged, high-voltage discharge is caused, the car is damaged slightly, and serious traffic accidents are caused seriously. Therefore, the cable form of the electric connection framework 2 can be used for replacing a multi-core cable structure, so that the cable can be fixed on a car shell, the friction between the cable and the car shell along with the vibration of the car is avoided, the service life of the connector assembly is prolonged, and the accident rate is reduced. When the car charges, the electric current of connecting skeleton 2 very greatly through the electricity, and the temperature of connecting skeleton 2 risees fast, has shielding effect's protective housing 5 and 6 circulation coolants of cavity between the electricity connection skeleton 2 and plays the cooling effect to the electricity connection skeleton to cooling down the electricity connection skeleton 2 that generates heat, making the connector assembly work under safe temperature.

In some embodiments, the material of the connection terminal 7 is copper or copper alloy. Copper or copper alloy conductivity are high to antifriction, and most of power consumption device connect the electric part material all be copper at present moreover, consequently need use the material to carry out plug connection for connecting terminal 7 of copper or copper alloy, and connecting terminal 7 can wide application in various electric transmission scenes.

In some embodiments, the cooling fluid is made of an insulating material. Like insulating oil, the insulating oil can quickly conduct the high temperature of the electric connection framework 2 to the outside, and the purpose of quick cooling is achieved. And the electric connection framework 2 and the protective shell are not electrically connected, so that the electric connection framework and the protective shell realize the electric conduction functions of different loops.

In some embodiments, the material of the electrical connection framework 2 is a rigid solid conductor material. The conductor is composed of a conducting wire, and the specific material can be copper or copper alloy with excellent conductivity, aluminum or aluminum alloy.

In some embodiments, the material of the electrical connection frame 2 is aluminum or aluminum alloy. The electric connection framework 2 made of aluminum or aluminum alloy has the advantages of good rigidity, light weight and high transmission efficiency, and is particularly suitable for large current transmission.

In some embodiments, the cross-sectional area of the electrical connection backbone 2 is 1.5mm ² -240mm ² . The cross-sectional area of the electrical connection frame 2 determines the current that the electrical connection frame 2 can conduct, generally, the electrical connection frame 2 that realizes signal conduction has a smaller current and the cross-sectional area of the electrical connection frame 2 is smaller, for example, the minimum cross-sectional area of the electrical connection frame 2 for transmitting signals can reach 1.5mm ² And the electric connection framework 2 for realizing the power supply conduction has larger current, and the sectional area of the electric connection framework 2 is also larger, for example, a wire harness of an automobile storage battery, and the maximum sectional area of the electric connection framework 2 reaches 240mm ² 。

In some embodiments, the electrical connection framework 2 is electrically connected with the connection terminal 7 by welding or crimping. The material of connecting terminal 7 is copper or copper alloy, 2 materials of electricity connection skeleton are aluminium or aluminum alloy, and copper or copper alloy conductivity is high to antifriction, most of power consumption device connect the partial material all to be copper moreover at present, consequently need use the material to carry out the plug connection for connecting terminal 7 of copper or copper alloy, connecting terminal 7 can wide application in various electronic transmission scenes. The electric connection framework 2 made of aluminum or aluminum alloy has the advantages of good rigidity, light weight and high transmission efficiency, and is particularly suitable for large current transmission. The connecting terminal 7 and the electric connection framework 2 are connected through welding, and the adopted welding modes comprise one or more of resistance welding, friction welding, ultrasonic welding, arc welding, laser welding, electron beam welding, pressure diffusion welding and magnetic induction welding, so that the contact positions of the connecting terminal 7 and the electric connection framework 2 are in fusion connection by adopting concentrated heat energy or pressure, and the welding modes are stable in connection.

In addition, the metal inertia of copper is larger than that of aluminum, the electrode potential difference between copper and aluminum is 1.9997V, the two metals can generate electrochemical reaction after being connected and electrified, the aluminum wire is gradually oxidized, the mechanical strength and the conductivity of the aluminum wire are reduced, the connection of dissimilar materials can be realized by adopting a welding mode, and the conductive effect is better because the contact positions are mutually fused.

The resistance welding method is a method of welding by using a strong current to pass through a contact point between an electrode and a workpiece and generating heat by a contact resistance.

The friction welding method is a method of welding by plastically deforming a workpiece under pressure using heat generated by friction of a contact surface of the workpiece as a heat source.

The ultrasonic welding method is a method in which a high-frequency vibration wave is transmitted to the surfaces of two objects to be welded, and the surfaces of the two objects are rubbed against each other under pressure to form fusion between molecular layers.

The arc welding method is a method of connecting metals by converting electric energy into thermal energy and mechanical energy required for welding using an electric arc as a heat source and utilizing a physical phenomenon of air discharge, and the main methods include shielded metal arc welding, submerged arc welding, gas shielded welding, and the like.

The laser welding method is an efficient and precise welding method using a laser beam with high energy density as a heat source.

The friction welding method is a method of welding by plastically deforming a workpiece under pressure using heat generated by friction of a contact surface of the workpiece as a heat source.

The electron beam welding mode is that accelerated and focused electron beams are used to bombard the welding surface in vacuum or non-vacuum to melt the workpiece to be welded for welding.

The pressure welding method is a method of applying pressure to a workpiece to bring the joining surfaces into close contact with each other to generate a certain plastic deformation, thereby completing welding.

The magnetic induction welding mode is that two workpieces to be welded produce instantaneous high-speed collision under the action of strong pulse magnetic field, and the surface layer of the material makes the atoms of the two materials meet in the interatomic distance under the action of very high pressure wave, so that stable metallurgical bonding is formed on the interface. Is one type of solid state cold welding that can weld together conductive metals that may or may not have similar properties.

And the compression joint mode is a production process for punching and pressing the electric connection framework and the connecting terminal into a whole by using a compression joint machine after the electric connection framework and the connecting terminal are assembled. The crimping has an advantage of mass productivity, and a product of stable quality can be rapidly manufactured in a large quantity by using an automatic crimping machine.

In some embodiments, the protective casing 5 is made of a rigid conductive material. The rigid conductor material has unchanged shape and size, unchanged relative position of each point inside, stable physical performance and stable electric energy transmission efficiency.

In some embodiments, the protective shell 5 is made of metal or conductive plastic. The conductive plastic is conductive plastic or conductive rubber containing metal particles. The conductive plastic has the advantages that the conductive plastic is convenient to be injection molded, and the conductive plastic can obtain better strength by adopting a metal material and has a protection effect on the cavity 5. The user can select the protective housing 5 of suitable material as required.

In some embodiments, the connector further includes a shielding inner housing 4 inside, and the material of the shielding inner housing 4 is a conductive material. The shielding inner shell 4 is electrically connected with the protective shell 5 with shielding effect to form a complete shielding device. The shielding layer can play a role in effectively shielding electromagnetic interference generated by electrifying the electric connection framework 2 and the connecting terminal 7, the use of a shielding net is saved, and the cost of the connector assembly is reduced.

Furthermore, the material of the shielding inner case 4 is metal or conductive plastic. The conductive plastic is conductive plastic or conductive rubber containing metal particles. The conductive plastic has the advantage of being convenient for injection molding, and a user can select the shielding inner shell 4 with proper material according to the requirement.

In some embodiments, the conductive plastic is a polymer material containing conductive particles, and the conductive particles comprise one of metal, conductive ceramic, carbon-containing conductor, solid electrolyte and mixed conductor; the material of the high polymer material contains one of tetraphenyl ethylene, polyvinyl chloride, polyethylene, polyamide, polytetrafluoroethylene, tetrafluoroethylene/hexafluoropropylene copolymer, ethylene/tetrafluoroethylene copolymer, polypropylene, polyvinylidene fluoride, polyurethane, poly terephthalic acid, polyurethane elastomer, styrene block copolymer, perfluoroalkoxy alkane, chlorinated polyethylene, polyphenylene sulfide, polystyrene, crosslinked polyolefin, ethylene-propylene rubber, ethylene/vinyl acetate copolymer, chloroprene rubber, natural rubber, styrene-butadiene rubber, nitrile rubber, silicone rubber, butadiene rubber, isoprene rubber, ethylene-propylene rubber, chloroprene rubber, butyl rubber, fluorine rubber, polyurethane rubber, polyacrylate rubber, chlorosulfonated polyethylene rubber, epichlorohydrin rubber, chlorinated polyethylene rubber, chlorosulfonated sulfur rubber, styrene butadiene rubber, hydrogenated rubber, polysulfide rubber, crosslinked polyethylene, polycarbonate, polysulfone, polyphenylene oxide, polyester, phenolic resin, urea formaldehyde, styrene-acrylonitrile copolymer, polymethacrylate, and resin. The conductive plastics containing different conductive particles can be selected according to requirements.

In some embodiments, the metal material includes one of nickel, cadmium, zirconium, chromium, cobalt, manganese, aluminum, tin, titanium, zinc, copper, silver, gold, phosphorus, tellurium, and beryllium. In order to demonstrate the influence of different metal materials on the conductivity of the shielding inner shell 4, the inventor performed an experiment to manufacture a sample of the shielding inner shell 4 using metal particles with the same specification and size and different materials, and respectively test the conductivity of the shielding inner shell 4, and the experimental result is shown in table 1 below, in this embodiment, the conductivity of the shielding inner shell 4 is greater than 99% as an ideal value.

Table 1: influence of metallic particles of different materials on the conductivity of the shielded inner shell 4

As can be seen from table 1 above, the conductivity of the conductive plastic made of different metal particles is within the ideal value range, and in addition, phosphorus is a non-metal material, which cannot be directly used as a material of the conductive plating layer, but can be added to other metals to form an alloy, so as to improve the conductivity and mechanical properties of the metal itself. Therefore, the inventors set the material of the metal particles to contain one of nickel, cadmium, zirconium, chromium, cobalt, manganese, aluminum, tin, titanium, zinc, copper, silver, gold, phosphorus, tellurium, and beryllium

In some embodiments, the carbon-containing conductor comprises one of graphite powder, carbon nanotube material, graphite silver, graphene material. The graphite powder is mineral powder, and the main components are carbon simple substance, soft and black gray; graphite powder is a good non-metallic conductive substance. The carbon nano tube has good electric conductivity, and the structure of the carbon nano tube is the same as the lamellar structure of graphite, so the carbon nano tube has good electric property. The graphene has extremely high electrical properties, and the carbon-containing conductor containing the three materials has high conductivity and good shielding property, so that the electromagnetic shielding of the electric connection framework 2 can be well realized.

In some embodiments, the protective shell 5 is electrically connected to the shield inner shell 4 by crimping or welding. The aluminum or aluminum alloy material has good conductivity, light weight and low price. The shielding inner shell 4 is made of aluminum or aluminum alloy, so that a good shielding effect can be achieved, and the connection terminal 7 and the electromagnetic radiation of the electric connection framework 2 are prevented from affecting other equipment.

The crimping is a production process of assembling the shielding inner shell 4 and the protective shell 5 with shielding effectiveness and then punching the two into a whole by using a crimping machine. The crimping has an advantage of mass productivity, and a product of stable quality can be rapidly manufactured in a large quantity by using an automatic crimping machine.

The welding mode is basically the same as that of the connecting terminal 7 and the electric connection framework 2, and the description is omitted.

In some embodiments, the impedance between the protective shell 5 and the shielded inner shell 4 is less than 80m Ω.

The impedance between the protective shell 5 and the inner shielding shell 4 is as small as possible, so that the current generated by the inner shielding shell 4 flows back to the energy source or the ground without hindrance, and if the impedance between the protective shell 5 and the inner shielding shell 4 is large, a large current is generated between the protective shell 5 and the inner shielding shell 4, so that a large radiation is generated at the cable connection.

In order to verify the influence of the impedance value between the protective shell 5 and the shielding inner shell 4 on the shielding effect, the inventor selects the electrical connection framework 2, the connector 1 and the connection terminal 7 with the same specification, selects the impedance between different protective shells 5 and shielding inner shells 4, manufactures a series of samples, and respectively tests the shielding effect, and the experimental result is shown in table 2 below, in this embodiment, the shielding performance value is greater than 40dB, which is an ideal value.

The method for testing the shielding performance value comprises the following steps: the testing instrument outputs a signal value (the value is a testing value 2) to the electric connection framework 2, and a detecting device is arranged on the outer side of the electric connection framework 2 and detects a signal value (the value is a testing value 1). Shielding performance value = test value 2-test value 1.

Table 2: influence of impedance between the protective case 5 and the shield inner case 4 on the shielding performance

As can be seen from table 2, when the impedance value between the protective case 5 and the shield inner case 4 is 80m Ω or more, the shielding performance value is less than 40dB, which is not satisfactory as the ideal value, and when the impedance value between the protective case 5 and the shield inner case 4 is less than 80m Ω, the shielding performance values all are satisfactory as the ideal value, and the trend is better and better, and therefore, the inventors set the impedance between the protective case 5 and the shield inner case 4 to be less than 80m Ω.

In some embodiments, the transfer impedance of the protective shell 5 is less than 100m Ω. The shielding material generally represents the shielding effect of the protective shell 5 by the transfer impedance, and the smaller the transfer impedance, the better the shielding effect. The transfer impedance of the protective shell 5 Is defined as the ratio of the differential mode voltage U induced by the shield per unit length to the current Is passing through the surface of the shield, namely:

Z _T ＝U/I _S it can therefore be understood that the transfer impedance of the protective case 5 converts the protective case 5 current into differential mode interference. The smaller the transfer impedance, the better, namely, the differential mode interference conversion is reduced, and the better shielding performance can be obtained.

In order to verify the influence of the protective cases 5 with different transfer impedance values on the shielding effect, the inventor selects the electrical connection framework 2, the connector 1 and the connection terminal 7 with the same specification, adopts the protective cases 5 with different transfer impedance values, manufactures a series of samples, respectively tests the shielding effect, and the experimental result is shown in the following table 3, wherein in the embodiment, the shielding performance value is greater than 40dB, which is an ideal value.

The shielding performance value test method comprises the following steps: the test instrument outputs a signal value (the value is a test value 2) to the electric connection framework 2, and a detection device is arranged on the outer side of the electric connection framework 2 and detects a signal value (the value is a test value 1). Shielding performance value = test value 2-test value 1.

Table 3: influence of transfer resistance of protective case 5 on shielding performance

As can be seen from table 3 above, when the transfer resistance value of the protective case 5 is equal to or greater than 100m Ω, the shielding performance value of the protective case 5 is less than 40dB, which is not satisfactory for the desired value, and when the transfer resistance value of the protective case 5 is less than 100m Ω, the shielding performance value of the protective case 5 is all satisfactory for the desired value, and the trend is better and better, so the inventors set the transfer resistance of the protective case 5 to be less than 100m Ω.

In some embodiments, the transfer impedance of the shielding inner housing 4 is less than 100m Ω. In order to verify the influence of the shielding inner housings 4 with different transfer impedance values on the shielding effect, the inventor selects the electrical connection framework 2, the connector 1 and the connection terminal 7 with the same specification, adopts the shielding inner housings 4 with different transfer impedance values, manufactures a series of samples, respectively tests the shielding effect, and the experimental result is shown in the following table 4, in this embodiment, the shielding performance value is greater than 40dB, which is an ideal value.

The shielding performance value test method comprises the following steps: the testing instrument outputs a signal value (the value is a testing value 2) to the electric connection framework 2, and a detecting device is arranged on the outer side of the shielding inner shell 4 and detects a signal value (the value is a testing value 1). Shielding performance value = test value 2-test value 1.

Table 4: influence of transfer impedance of the shield inner case 4 on the shield performance

As can be seen from table 4 above, when the transfer impedance value of the shield inner case 4 is equal to or greater than 100m Ω, the shielding performance value of the shield inner case 4 is less than 40dB, which does not meet the requirement of the ideal value, and when the transfer impedance value of the shield inner case 4 is less than 100m Ω, the shielding performance values of the shield inner case 4 all meet the requirement of the ideal value, and the trend is better, and therefore, the inventors set the transfer impedance of the shield inner case 4 to be less than 100m Ω.

In some embodiments, the number of the electrical connection frame 2 is one, the connector 1 includes a first connector 11 and a second connector 12 connected to two ends of the electrical connection frame 2, the first connector 11 and the second connector 12 are internally provided with an adapter cavity 94, the adapter cavity 94 is communicated with the cavity 6, the first connector 11 is provided with an inlet 941 communicated with the adapter cavity 94, and the second connector 12 is provided with an outlet 942 communicated with the adapter cavity. As shown in fig. 2 and 8, the cooling fluid is driven by the driving device to enter the adapting cavity 94 of the first connector 11 through the inlet pipe 941, enter the rotating cavity 94 of the second connector 12 through the cavity 6 of the electrically connected frame 2, and then exit from the exit pipe 942 of the second connector 12, and then enter the first connector 11 through the driving device, so as to form a complete cooling cycle.

In some embodiments, the number of the electrical connection skeletons 2 is at least two, the connector 1 includes a first connector 11 and a second connector 12 connected to two ends of the electrical connection skeleton 2, a communicating rotary cavity 91 is disposed inside the first connector 11, and the rotary cavity 91 is communicated with the cavity 6 of each electrical connection skeleton 2; the second connector 12 is internally provided with an isolated liquid inlet cavity 92 and an isolated liquid outlet cavity 93, and the liquid inlet cavity 92 and the liquid outlet cavity 93 are respectively communicated with the cavities 6 of the electric connection framework 2. As shown in fig. 4, fig. 5 and fig. 9, different from the previous embodiment, in the present embodiment, the cooling circuit includes two electrically connected frameworks 2, and the cooling liquid enters the liquid inlet cavity 92 of the second connector 12 under the driving of the driving device, enters the rotary cavity 91 of the first connector 11 from the cavity 6 of one electrically connected framework 2, enters the cavity 6 of the other electrically connected framework 2, and enters the liquid outlet cavity 93, and after cooling, enters the liquid inlet cavity 92 from the driving device, so as to form a complete cooling cycle.

In some embodiments, the side wall of the liquid inlet cavity 92 is provided with a liquid inlet pipe 921 communicating with the outside of the connector 1, and the side wall of the liquid outlet cavity 93 is provided with a liquid outlet pipe 931 communicating with the outside of the connector 1. As shown in fig. 5, the cooling liquid enters liquid inlet cavity 92 through liquid inlet pipe 921 and flows out of liquid outlet cavity 93 through liquid outlet pipe 931.

In some embodiments, a sealing structure 8 is provided between the connector 1 and the protective shell 5. As shown in fig. 4, the sealing structure 8 seals the joint. The seal structure 8 can prevent the coolant from leaking from the joint between the connector 1 and the protective case 5. The sealing structure 8 may be a sealing ring.

In some embodiments, at least one supporting ring 10 is disposed inside the cavity 6, as shown in fig. 6, an inner wall of the supporting ring 10 is in contact with an outer periphery of the electrical connection skeleton 2, and an outer wall of the supporting ring 10 is in contact with an inner wall of the protective shell 5. The support ring 10 can support the cavity 6, prevent the cavity 6 from being narrowed due to external extrusion, so as to reduce the cooling efficiency of the connector assembly, and simultaneously avoid short circuit caused by contact between the electrical connection framework 2 and the protective shell 5. The number of the support rings 10 can be set to be a plurality of, the support rings can be firstly fixed on the electric connection framework 2 during processing, then the protective shell 5 is sleeved, and the outer wall of each support ring 10 is in contact with the inner wall of the protective shell 5 by extruding the protective shell 5.

Further, the support ring 10 is provided with at least one through hole 101 in the axial direction of the electrical connection bobbin 2. As shown in fig. 7, in order to prevent the support ring 10 from blocking the flow of the cooling liquid and reducing the cooling efficiency of the connector assembly, the support ring 10 is provided with at least one through hole 101 in the axial direction of the electrical connection frame 2, so that the cooling liquid can smoothly pass through the support ring 10 and the cooling effect can be obtained.

Furthermore, the sum of the sectional areas of the through holes 101 accounts for 23% -90% of the sectional area of the cavity 6. If the sum of the sectional areas of the through holes 101 is too large, the supporting force of the supporting ring 10 is insufficient, if the sum of the sectional areas of the through holes 101 is too small, the cooling efficiency is insufficient, and in order to select a reasonable sum of the sectional areas of the through holes 101, the inventor has carried out relevant tests by selecting the same electrically connecting framework 2 with the same cavity 6, arranging the supporting rings 10 with different through holes 101 in the cavity 6, applying a force of 80N, observing whether the cavity 6 is deformed, and if the deformation is unqualified. In a closed environment, the same current is conducted to the electric connection framework 2 with different through holes 101, and the temperature rise is less than 50K, which is a qualified value. The results are shown in Table 5.

Table 5: the influence of the sum of the sectional areas of the through holes 101 on the temperature rise of the cooling cavity 6 supporting and electrically connecting framework 2 in comparison with the sectional area of the cavity 6

As can be seen from the above table 5, when the sum of the cross-sectional areas of the through holes 101 accounts for less than 23% of the cross-sectional area of the cavity 6, the temperature rise of the electrically connecting skeleton 2 is greater than 50.2K, which is not qualified, and when the sum of the cross-sectional areas of the through holes 101 accounts for more than 90% of the cross-sectional area of the cavity 6, the cavity 6 deforms under the action of 80N, which easily causes the cooling rate to decrease, and even the cooling liquid leaks, so the inventor prefers that the sum of the cross-sectional areas of the through holes 101 accounts for 23% -90% of the cross-sectional area of the cavity 6.

In some embodiments, the electrical connection backbone 2 has at least one bending position having an arc shape, and the support rings 10 are respectively disposed at least at two ends and at a middle position of the arc shape. As shown in fig. 6, the arc shape formed by the bending position of the electrical connection framework 2 is more easily pressed, so that the support rings 10 arranged at the two ends and in the middle of the arc shape can play a better role in supporting.

In some embodiments, the cross-sectional shape of the electrical connection frame 2 is one or more of circular, oval, rectangular, polygonal, a-shaped, B-shaped, D-shaped, M-shaped, N-shaped, O-shaped, S-shaped, E-shaped, F-shaped, H-shaped, K-shaped, L-shaped, T-shaped, P-shaped, U-shaped, V-shaped, W-shaped, X-shaped, Y-shaped, Z-shaped, semi-arc-shaped, and wave-shaped. In practical use, the electrical connection framework 2 with different sections can be adopted according to requirements.

In some embodiments, the cross-sectional shape of the electrical connection backbone 2 is a polygon, the corners of which are all rounded or chamfered. Preventing the sharp part from damaging the insulating layer or the shielding layer.

In some embodiments, at least a partial region of the electrical connection backbone 2 is a flexible body. The flexible body can ensure that the electric connection framework 2 can be bent to a larger angle so as to be conveniently arranged in a vehicle body with a larger corner.

In some embodiments, the electrical connection backbone 2 includes at least one bend. So as to meet the requirement of the installation of the vehicle inner body.

In some embodiments, the thickness of the protective shell 5 is 1% to 15% of the outer diameter of the protective shell 5. If the thickness of the protective case 5 is too small, the electric conductivity is insufficient, and the shielding effect cannot be satisfied. If the thickness of the protective case 5 is too large, material is wasted to increase the weight of the vehicle body. In order to demonstrate the influence of the ratio of the different protective cases 5 occupying the outer diameter of the protective case 5 on the conductivity of the protective case 5, the inventors manufactured samples of the protective cases 5 with different thicknesses and the same material, and tested the conductivity, respectively, and the experimental results are shown in table 6.

Table 6: the influence of different thicknesses of the protective shell 5 on the conductivity of the ratio of the outer diameter of the protective shell 5

As can be seen from table 6, when the thickness of the protective shell 5 accounts for less than 1% of the outer diameter of the protective shell 5 having shielding effectiveness, the electrical conductivity of the protective shell 5 is less than 99%, which is not acceptable, and when the thickness of the protective shell 5 accounts for more than 15% of the outer diameter of the protective shell 5, the electrical conductivity has not been significantly increased, the shielding effect is not further enhanced, and the thicker protective shell 5 increases the cost and the weight of the vehicle body, so the inventors prefer the thickness of the protective shell 5 to account for 1% -15% of the outer diameter of the protective shell 5 having shielding effectiveness.

In some embodiments, the outer diameter of the cavity 6 is 1.02 times to 1.3 times the outer diameter of the electrical connection backbone 2. The outer diameter of the cavity 6 is too small, the cooling efficiency is insufficient if the flowing cooling liquid is insufficient, in order to find the relation between the outer diameter of the cavity 6 and the outer diameter of the electric connection framework 2, the inventor conducts relevant tests, the test method is that the same electric connection framework 2 and the cavities 6 with different outer diameters are selected, the same cooling liquid with the same speed flows in, after the electric connection framework 2 is electrified, the temperature rise is measured, and the temperature rise is lower than 50K and is a qualified value. The results are shown in Table 7.

Table 7: the external diameter of the cavity 6 and the influence of the temperature rise of the electric connection framework compared with the external diameter of the electric connection framework 2

As can be seen from table 7 above, when the ratio of the outer diameter of the cavity 6 to the outer diameter of the electrically connecting frame 2 is less than 1.02, the temperature rise of the electrically connecting frame 2 is greater than 50K, which is not acceptable, and when the ratio of the outer diameter of the cavity 6 to the outer diameter of the electrically connecting frame 2 is greater than 1.3, the temperature rise of the electrically connecting frame 2 is not significantly changed, and the thicker cavity 6 increases the cost and the weight of the vehicle body, so the inventor prefers that the outer diameter of the cavity 6 is 1.02 times to 1.3 times the outer diameter of the electrically connecting frame 2.

In some embodiments, the cooling fluid has a boiling point of 100 ℃ or higher. Different cooling liquids have different boiling points under the same external pressure, and the boiling points of the cooling liquids are different due to the characteristics and the components of the cooling liquids. At present, the boiling point of the cooling liquid is more than 100 ℃, and the phenomenon of boiling is not easy to generate. Since a large amount of vapor and a large amount of bubbles are generated when the coolant reaches the boiling point, and a part of the area of the cooling system occupied by the bubbles obstructs the flow of the coolant, thereby lowering the cooling efficiency, the inventors prefer that the boiling point of the coolant is 100 ℃.

In some embodiments, the cooling fluid comprises one or more of purified water, silicone oil, fluorinated fluids, ethylene glycol, castor oil, coconut oil, corn oil, cottonseed oil, linseed oil, olive oil, palm oil, peanut oil, grapeseed oil, rapeseed oil, safflower oil, sunflower oil, soybean oil, various high oleic variants of vegetable oils, decene-4-acid, decenoic acid, myrcenic acid, gardenic acid, tetradecenoic acid, sperm whale acid, hirsutic acid, palmitoleic acid, petroselinic acid, oleic acid, octadecenoic acid, gadoleic acid, macrocephalic acid, cetoleic acid, erucic acid, and nervonic acid, glycerol, transformer oil, axle oil, internal combustion engine oil, or compressor oil. Additives selected from one of antioxidants, pour point depressants, corrosion inhibitors, antimicrobial agents, viscosity modifiers may also be added to the cooling fluid. The cooling liquid has the advantages of sensitive heat balance capability, super strong heat conduction capability, super wide working temperature range, stopping boiling and boiling, and the like.

In some embodiments, the cooling rate of the cooling fluid to the electrical connection backbone 2 is between 0.05K/s and 5K/s. In order to verify the influence of the cooling rate of the cooling liquid on the temperature rise of the electrically-connected framework 2, the inventor selects 10 electrically-connected frameworks 2 with the same cross section, the same material and the same length, applies the same current, adopts cooling liquids with different cooling rates to cool the electrically-connected frameworks 2, reads the temperature rise value of each electrically-connected framework 2, and records the temperature rise value in table 8.

The experimental method is that in a closed environment, the same current is conducted to the electric connection framework 2 adopting cooling liquid with different cooling rates, the temperature before electrifying and the temperature after electrifying are stable are recorded, and the absolute value is obtained by taking the difference. In this embodiment, a temperature rise of less than 50K is a qualified value.

Table 8: influence of cooling liquid with different cooling rates on temperature rise of electric connection framework 2

As can be seen from table 8 above, when the cooling rate of the coolant is less than 0.05K/s, the temperature rise value of the electrically connecting bobbin 2 is not qualified, and the larger the cooling rate of the coolant, the smaller the temperature rise value of the electrically connecting bobbin 2. However, when the cooling rate of the cooling liquid is more than 5K/s, the temperature rise of the electrically connecting frame 2 is not significantly reduced, and a higher cooling rate means a higher price and a more complicated process, and therefore, the inventors set the cooling rate of the cooling liquid to 0.05K/s to 5K/s.

In some embodiments, one of the connectors is a cradle. One end of the electric connection framework 2 is connected with a connecting terminal 7 in the charging seat, and the other end is connected with a vehicle-mounted battery through the connecting terminal 7 to form a charging circuit of the automobile.

The utility model also provides a vehicle, include as above connector assembly, circulating pump 111 and cooling device 112 that have the liquid cooling function, cavity 6 with circulating pump 111 with cooling device 112 UNICOM. The circulating pump 111 sends the cooling liquid into the cavity 6 to cool the electrical connection framework 2, the cooling liquid flows out of the cavity 6, the temperature of the cooling liquid at the moment is higher, and after the cooling liquid enters the cooling device 112, the temperature of the cooling liquid is reduced and sent into the cavity 6 by the circulating pump 111 again, so that a complete cooling cycle is formed.

In some embodiments, the inlet 941 is in communication with an inlet of the circulation pump 111, an outlet of the circulation pump 111 is in communication with an inlet of the cooling device 112, and an outlet of the cooling device 112 is in communication with the outlet 942. The circulating pump 111 drives the cooling liquid to enter the cooling device 112, and then enters the delivery pipe 942 through the liquid outlet of the cooling device 112, and then enters the circulating pump 111 from the inlet pipe 941 after cooling the electrically connected frame 2 through the cavity 6, so as to form a complete cooling cycle.

In some embodiments, the liquid inlet pipe 921 communicates with an liquid inlet of the circulation pump 111, a liquid outlet of the circulation pump 111 communicates with a liquid inlet of the cooling device 112, and a liquid outlet of the cooling device 112 communicates with the liquid outlet pipe 931. The circulating pump 111 drives the cooling liquid to enter the cooling device 112, and then enters the liquid outlet cavity 93 through the liquid outlet pipe 931, and further enters the cavity 6 electrically connected with the framework 2, enters the rotary cavity 91, enters the other cavity 6 electrically connected with the framework 2, and finally enters the circulating pump 111 through the liquid inlet pipe 921 of the second connector 12, so as to form a complete cooling cycle. Of course, the circulation may be reversed, that is, the circulation pump 111 drives the cooling liquid to enter the liquid inlet pipe 921 and finally enter the cooling device 111, and the cooling circulation may be completed.

Although certain specific embodiments of the present invention have been described in detail by way of example, it should be understood by those skilled in the art that the foregoing examples are for purposes of illustration only and are not intended to limit the scope of the invention. It will be appreciated by those skilled in the art that modifications may be made to the above embodiments without departing from the scope and spirit of the invention. The scope of the invention is defined by the appended claims.

Claims (32)

1. The utility model provides a liquid cooling connector assembly, includes that skeleton and connector are connected to an at least electricity, its characterized in that, include connecting terminal in the connector, it is connected with connecting terminal electricity respectively to connect the skeleton both ends electrically, the protective housing that has shielding efficiency is cup jointed to the skeleton periphery of electricity, the skeleton periphery of electricity connect with form the cavity between the protective housing inner wall that has shielding efficiency, the cavity circulates the coolant liquid.

2. The liquid-cooled connector assembly of claim 1, wherein the cooling liquid is an insulating material.

3. The liquid-cooled connector assembly of claim 1, wherein the electrical connection backbone is formed from a rigid solid conductor material.

4. The liquid-cooled connector assembly of claim 1, wherein the cross-sectional area of the electrical connection backbone is 1.5mm ² -240mm ² 。

5. The liquid-cooled connector assembly of claim 1, wherein the electrical connection frame is electrically connected to the connection terminals by soldering or crimping.

6. The liquid-cooled connector assembly of claim 1, wherein the protective housing is made of a rigid, electrically conductive material.

7. The liquid cooled connector assembly of claim 6, wherein the protective housing is made of metal or conductive plastic.

8. The liquid-cooled connector assembly of claim 1, wherein the connector further comprises an inner shielding shell formed of an electrically conductive material.

9. The liquid cooled connector assembly of claim 8, wherein the shielding inner housing is made of metal or conductive plastic.

10. The liquid cooled connector assembly of claim 8, wherein the protective housing is electrically connected to the inner shielding shell by crimping or welding.

11. The liquid cooled connector assembly of claim 8, wherein an impedance between the protective housing and the shielded inner housing is less than 80m Ω.

12. The liquid cooled connector assembly of claim 1, wherein the protective shell has a transfer impedance of less than 100m Ω.

13. The liquid-cooled connector assembly of claim 8, wherein the transfer impedance of the inner shielding shell is less than 100m Ω.

14. The liquid-cooled connector assembly of claim 1, wherein the number of the electrically connecting frames is one, the connector comprises a first connector and a second connector which are connected with two ends of the electrically connecting frames, a switching cavity is arranged inside the first connector and the second connector, the switching cavity is communicated with the cavity, the first connector is provided with an inlet pipe communicated with the switching cavity, and the second connector is provided with an outlet pipe communicated with the switching cavity.

15. The liquid-cooled connector assembly of claim 1, wherein the number of the electrically connecting frames is at least two, the connectors include a first connector and a second connector connected to two ends of the electrically connecting frames, a communicating rotary cavity is arranged in the first connector, and the rotary cavity is communicated with the cavity of each electrically connecting frame; the second connector is internally provided with an isolated liquid inlet cavity and an isolated liquid outlet cavity, and the liquid inlet cavity and the liquid outlet cavity are respectively communicated with the cavities of the electric connection frameworks.

16. The liquid-cooled connector assembly of claim 15, wherein the inlet cavity sidewall is configured to communicate with an inlet pipe outside the connector, and the outlet cavity sidewall is configured to communicate with an outlet pipe outside the connector.

17. The liquid-cooled connector assembly of claim 1, wherein a seal is provided between the connector and the protective housing.

18. The liquid cooled connector assembly of claim 1, wherein at least one support ring is disposed within the cavity, an inner wall of the support ring is in contact with an outer periphery of the electrical connection frame, and an outer wall of the support ring is in contact with an inner wall of the protective housing.

19. The liquid-cooled connector assembly of claim 18, wherein the support ring is provided with at least one through hole in an axial direction of the electrical connection backbone.

20. The fluid-cooled connector assembly of claim 19, wherein a sum of cross-sectional areas of the through-holes is between 23% and 90% of a cross-sectional area of the chamber.

21. The liquid-cooled connector assembly of claim 18, wherein the electrical connection frame has at least one bend location, and wherein the support ring is disposed at least at each end and at a middle of the bend location.

22. The liquid-cooled connector assembly of claim 1, wherein the cross-sectional shape of the electrical connection backbone is one or more of circular, oval, rectangular, polygonal, A-shaped, B-shaped, D-shaped, M-shaped, N-shaped, 0-shaped, S-shaped, E-shaped, F-shaped, H-shaped, K-shaped, L-shaped, T-shaped, P-shaped, U-shaped, V-shaped, W-shaped, X-shaped, Y-shaped, Z-shaped, semi-arc-shaped, and wave-shaped.

23. The liquid-cooled connector assembly of claim 1, wherein the electrical connection backbone has a polygonal cross-section, and wherein corners of the polygon are rounded or chamfered.

24. The liquid-cooled connector assembly of claim 1, wherein at least a portion of the electrical connection backbone is a flexible body.

25. The liquid cooled connector assembly of claim 1, wherein the protective shell has a thickness that is between 1% and 15% of an outer diameter of the protective shell.

26. The liquid cooled connector assembly of claim 1, wherein the cavity has an outer diameter that is between 1.02 and 1.3 times an outer diameter of the electrical connection backbone.

27. The liquid-cooled connector assembly of claim 1, wherein the cooling liquid has a boiling point of 100 ℃ or greater.

28. The liquid-cooled connector assembly of claim 1, wherein the cooling rate of the cooling liquid to the electrical connection backbone is 0.05K/s to 5K/s.

29. The liquid-cooled connector assembly of claim 1, wherein one of said connectors is a charging dock.

30. A vehicle comprising the liquid-cooled connector assembly of any of claims 1-29, a circulation pump, and a cooling device, said chamber being in communication with said circulation pump and said cooling device.

31. The vehicle of claim 30, wherein the number of the electrical connection frames is one, the connector includes a first connector and a second connector that connect two ends of the electrical connection frames, a connection cavity is disposed inside the first connector and the second connector, the connection cavity is communicated with the cavity, the first connector is provided with an inlet pipe communicated with the connection cavity, the second connector is provided with an outlet pipe communicated with the connection cavity, the inlet pipe is communicated with a liquid inlet of the circulation pump, a liquid outlet of the circulation pump is communicated with a liquid inlet of the cooling device, and a liquid outlet of the cooling device is communicated with the outlet pipe.

32. The vehicle of claim 30, wherein the number of the electrical connection frames is at least two, the connector comprises a first connector and a second connector which are connected with two ends of the electrical connection frames, a communicated rotary cavity is arranged in the first connector, and the rotary cavity is communicated with the cavity of each electrical connection frame; the inside isolated feed liquor cavity and the play liquid cavity of setting up of second connector, the feed liquor cavity with go out the liquid cavity respectively with each the cavity UNICOM of electricity connection skeleton, feed liquor cavity lateral wall sets up the UNICOM the external feed liquor pipe of connector, it sets up the UNICOM to go out the liquid cavity lateral wall the external drain pipe of connector, the feed liquor pipe with the inlet UNICOM of circulating pump, the liquid outlet of circulating pump with cooling device's inlet UNICOM, cooling device's liquid outlet with drain pipe UNICOM.

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