KR20140006268A - Fixing structure for battery mount of electric vehicle - Google Patents

Abstract

The present invention relates to a fixing structure for absorbing impact in a battery mounting unit of an electric vehicle and, more specifically, to the fixing structure for structurally reinforcing the battery mounting unit, in which a battery is mounted, of the electric vehicle capable of absorbing an external force such as an inertial force. The fixing structure for absorbing the impact and for reinforcing the battery mounting unit of the electric vehicle according to the present invention comprises a main frame for forming a frame of the electric vehicle; the battery mounting unit installed in the main frame; and a plurality of buffering units installed between the battery mounting unit and the main frame to execute a buffering effect or to apply tension to the battery mounting unit. The battery mounting unit stably supports the weights of the battery mounting unit including the battery by fixing the battery mounting unit on the main frame using the buffering units according to the fixing structure for absorbing the battery mounting unit of the electric vehicle based on the present invention. Especially, the present invention relates to the fixing structure for absorbing impact and for reinforcing the battery mounting unit of the electric vehicle having an effect capable of improving the durability and safety of the vehicle by supporting the inertial force of the battery mounting unit including the battery when the electric vehicle is rapidly moved or stopped.

Description

FIXING STRUCTURE FOR BATTERY MOUNT OF ELECTRIC VEHICLE}

The present invention relates to a fixing structure for reinforcing and shock absorbing the battery mounting portion of an electric vehicle, and more particularly, to structurally reinforce the battery mounting portion on which the battery is mounted and to be absorbed and buffered when an external force such as an inertial force is applied. The present invention relates to a fixing structure for reinforcing and shock absorbing battery mounting parts of an electric vehicle.

In general, automobiles which are widely used as transportation means use fossil energy such as petroleum as energy source. However, fossil energy is a depleted resource, and is depleted over time, and its price is continuously rising.

In addition, since fossil energy is not only exhausting various exhaust gases that pollute the atmospheric environment during its use, but also discharging a large amount of carbon dioxide, which is a major cause of global warming, an electric vehicle Is being developed.

Unlike electric vehicles that use oil (petrol, diesel, etc.) or natural gas, electric vehicles are plug-in type to charge the battery, resulting in inconvenience of consumers due to long standby time and lack of economics of charging facility operators. There was a problem. Accordingly, a method of exchanging a fully charged battery itself by charging a battery in advance without directly charging power to a battery of an electric vehicle (hereinafter, referred to as a battery replacement method) is disclosed.

The battery for an electric vehicle includes a plurality of battery cells in which electricity is charged and a battery case for storing and storing the battery cells, and are installed in a battery seating portion provided in the electric vehicle.

On the other hand, a battery mounting portion in which the battery is mounted is disclosed a mounting device of a battery module for an electric vehicle as described in the prior art document.

The prior art document is installed so as to be able to rotate in each of the positions facing each other in the frame 10 located on the lower part of the vehicle body as shown in Figure 1 and a plurality of support brackets 21 are integrally located at a predetermined interval, respectively A pair of rotating shafts 20 provided; The battery module 30 is provided with a mounting groove 41 is fixed to the seat and is inserted into the space between the rotating shaft 20 from the lower portion of the frame 10 and the bottom surface is supported by the support bracket (21) A battery case 40 installed; A power providing means fixed to the battery case 40 to provide power to rotate the pair of rotation shafts 20; The battery case 40 and the pair of rotating shafts 20 are provided to have a structure including a power transmitting means for transmitting the power of the power providing means to the pair of rotating shafts 20.

The above-described conventional battery mounting apparatus can effectively fix the battery, but when the electric vehicle is quickly stopped or stopped in a stopped state in the process of driving at a high speed, the heavy weight of the battery is moved forward or backward by the inertia force, which is stable. Not only can't support it, but because of the sudden movement of the battery itself will cause serious adverse effects on safe operation.

In particular, in the case of an electric bus equipped with a large battery, the weight of the battery is very heavy and bulky, so a large inertial force is applied during sudden stops and start-ups. Therefore, in order to use the electric bus for public transportation, the battery seat or the inertia force is absorbed. There is an urgent need for a fixed structure that can be buffered.

Republic of Korea Patent No. 10-1080930

SUMMARY OF THE INVENTION The present invention has been proposed in view of the above, and a structure for reinforcing a battery mounting part in which a battery is mounted and fixing structure for reinforcing and shock absorbing a battery mounting part of an electric vehicle that can absorb and buffer when an external force such as an inertial force is applied. The purpose is to provide.

In order to achieve the above object, the fixing structure for reinforcing and shock-absorbing the battery mounting portion of the electric vehicle according to the present invention includes a main frame forming a skeleton of the electric vehicle; And a battery mounting part installed on the main frame to mount the battery, wherein the battery mounting part is connected to and installed between the battery mounting part and the main frame to apply a tension to the battery mounting part and to perform a buffering operation. It is characterized by including.

In particular, the buffer means is characterized in that consisting of a tie rod of the length adjustable structure to enable the adjustment of the tension.

The tie rod may include: a first rod having one end fixed to the main frame; A second rod having one end fixed to the battery mounting part; A tension adjusting member which is fastened to the other side of the first and second rods and adjusts tension through tightening or loosening operation; And an anti-loosening nut fastened to the first and second rods to prevent loosening of the tension adjusting member.

In addition, the tie rod may be interposed with an elastic member to absorb and cushion the external force acting on the battery mounting portion.

In addition, the tie rod, a rod is installed between the main frame and the battery mounting portion and the head portion formed on one side; A fixing nut fastened to the other side of the rod; And an elastic member inserted into the rod and coalesced in at least one of the inside of the head and the inside of the fixing nut.

According to the fixing structure for reinforcing and shock-absorbing the battery mounting portion of the electric vehicle according to the present invention, since the structural rigidity is reinforced as the battery mounting portion is fixed to the main frame by a plurality of shock absorbing means, the battery mounting portion including the battery There is an effect that can support the load stably.

Particularly, according to the fixing structure for reinforcing and shock absorbing the battery mounting portion of the electric vehicle according to the present invention, while supporting the inertial force of the battery mounting portion including the battery at the time of sudden stop, sudden start, and sudden turning of the electric vehicle while absorbing, cushioning Since it is possible to drive safely and the riding comfort is improved, the durability and safety of the vehicle is improved.

1 is a view for explaining a conventional electric vehicle battery charger;
Figure 2 is a perspective view showing the external structure of the battery mounting portion of the electric vehicle according to the invention,
3 is a perspective view for explaining a fixing structure for reinforcing and shock absorbing the battery mounting portion of an electric vehicle according to an embodiment of the present invention;
4 is an enlarged perspective view of main parts of a fixing structure for reinforcing and shock absorbing a battery mounting part of an electric vehicle according to an embodiment of the present invention;
5 is an exploded perspective view showing a shock absorbing means applied to a fixing structure for reinforcing and shock absorbing a battery mounting portion of an electric vehicle according to an embodiment of the present invention;
6 is an exploded perspective view showing another example of the shock absorbing means applied to the fixing structure for reinforcing and shock absorbing the battery mounting portion of the electric vehicle according to an embodiment of the present invention;
Figure 7 is an exploded perspective view showing another example of the shock absorbing means applied to the fixing structure for reinforcing and shock absorbing the battery mounting portion of the electric vehicle according to an embodiment of the present invention.

Hereinafter, a preferred embodiment of a fixing structure for reinforcing and shock absorbing a battery mounting portion of an electric vehicle according to the present invention will be described in detail with reference to the accompanying drawings. For reference, the present invention will be described taking an electric bus provided in a battery mounting portion of an electric vehicle as an example.

Figure 2 is a perspective view showing the external structure of the battery mounting portion of the electric vehicle according to the invention, Figure 3 is a perspective view for explaining a fixing structure for reinforcing and shock absorbing the battery mounting portion of the electric vehicle according to an embodiment of the present invention, 4 is an enlarged perspective view of main parts of a fixing structure for reinforcing and mounting a battery compartment of an electric vehicle according to an exemplary embodiment of the present invention.

Referring to FIG. 2, an outer panel 2 supported by an internal main frame 1 is installed at a ceiling portion of an electric vehicle, and an air conditioner (not shown) is built in front of the outer panel 2. The air conditioner installation part 3 protrudes, and the battery mounting part 6 which opens and closes by the door 4 and which the battery 5 is seated in the back which contacted this air conditioner installation part 3 is provided.

As shown in FIG. 3, the main frame 1 includes a plurality of longitudinal bars 11 arranged in the longitudinal direction of the electric vehicle, and a plurality of horizontal bars 12 arranged in a direction orthogonal to the longitudinal bars 11. Consists of.

The battery mounting portion 6 is provided with a clamping device including a seating plate 61 for holding the battery 5 and a holding holder 62 for holding a battery seated on the seating plate 61. The blower apparatus 63 which supplies cooling air to the inside of the 51 is provided.

On the other hand, the fixing structure for reinforcing and shock-absorbing the battery mounting portion of the electric vehicle according to the present invention is the main frame (1) and the battery which is installed in the main frame (1) so that the battery 5 is mounted to form a skeleton of the electric vehicle It is configured in the mounting portion 6, it is configured to be provided between the battery mounting portion 6 and the main frame 1, a plurality of shock absorbing means 7 configured to apply tension to the battery mounting portion.

The shock absorbing means 7 is not limited in structure and shape as long as it can apply tension to the battery mounting portion 6, but in this embodiment the length can be adjusted to adjust the tension applied to the battery mounting portion (6) It consists of a tie rod. At this time, the rod body portion of the tie rod is a concept including not only formed in a rod-like structure, but also formed in the form of a cable.

And, the arrangement form and the number of arrangement of the shock absorbing means 7 can be configured in various ways as long as it can reinforce the rigidity of the battery mounting portion 6 and can absorb and cushion the external force. It is comprised in the form arrange | positioned so that two pieces may respectively face a front part and a both side part mutually.

Figure 5 is an exploded perspective view showing a buffer means applied to the fixing structure for reinforcing and shock absorbing the battery mounting portion of the electric vehicle according to an embodiment of the present invention.

Referring to FIG. 5, the tie rod 7 (buffering means) has a first rod 71 and one side of the battery mounting part 6 having one side fixed to the longitudinal bar 11 and the side bar 12 of the main frame 1. It is composed of a second rod 72 is fixed, and the tension adjusting member 73 is fastened to the other side of the first and second rods (71, 72) to adjust the tension through the tightening or loosening operation.

First and second rods (71, 72) is a fixing nut 74 is fastened to maintain a fixed state on one side of the rod body mounted to the main frame (1) and the battery mounting portion 6, the rod The other side of the body is provided with an anti-loosening nut 75 which is fastened to prevent loosening of the tension adjusting member 73.

The first rod 71 has a right screw portion formed on an outer circumferential surface of the rod body, and the second rod 72 has a left screw portion formed thereon, and the fixing nut 74 and the loosening nut 75 are fastened to each other. The right hand thread and the left hand thread are formed to fit the thread shape of the first and second rods 71 and 72.

In addition, the second rod 72 may be installed at various positions such as the outer plate 65 or the seating plate 61 of the battery mounting part 6 if it can effectively support the inertia force of the battery 5 generated during rapid braking and sudden start. Can be. In this embodiment, since it is installed on the outer plate 65, which is relatively weak in rigidity, a separate fixing bracket 67 is mounted to configure the rigidity. In addition, insertion holes 13 and 66 for inserting the first and second rods 71 and 72 are drilled in the main frame 1 and the battery mounting part 6.

The tension adjusting member 73 is a member which is generally referred to as a turn buckle and has a fastening hole formed with a right screw on one side inner circumferential surface of the body having a substantially hexagonal bar shape so that the first and second rods 71 and 72 can be fastened. The fastening hole in which the left side thread was formed in the other inner peripheral surface is formed.

On the other hand, the tie rod 7 is coupled to each other by the first and second rods 71 and 72 by the tension adjusting member 73 in order to absorb and buffer the external force applied to the battery mounting portion 6, In the installed state is provided with an elastic member 76 fitted to be located on the outer surface.

The elastic member 76 is elastically interposed between the main frame 1 and the battery mounting portion 6 so as to absorb the inertial force of the battery due to sudden braking or sudden start of the electric vehicle, and at the same time absorbs the main frame 1 And it is composed of a compression coil spring to perform a function that can prevent the deformation of the battery mounting portion (6).

Hereinafter, the operation of the fixing structure for reinforcing and shock absorbing the battery mounting portion of the electric vehicle according to an embodiment of the present invention will be described briefly.

As shown in FIG. 5, the fastening prevention nuts 75 are fastened to the first and second rods 71 and 72, respectively, and the first rod 71 is inserted into the insertion hole 13 of the main frame 1. Then, the fixing nut 74 is fastened and fixed, and the second rod 72 is inserted into the battery mounting part 6 and then fastened using the fixing nut 74. Thereafter, the elastic member 76 is inserted into the first rod 71 and the second rod 72 and the tension adjusting member 73 is fastened to adjust the proper tension while performing the tightening operation. When the tension adjustment is completed, the tightening force is applied to the loosening prevention nuts 75 of the first and second rods 71 and 72 to prevent the loosening of the tension adjusting member 73.

In this manner, as shown in FIG. 3, a plurality of shock absorbing means 7 are installed to be connected to the main frame 1 in the front-back direction and the left-right direction of the battery mounting part 6 on which the battery 5 is mounted.

As described above, when the battery mounting portion 6 is fixed to the main frame 1 by the plurality of shock absorbing means 7, structural rigidity is first reinforced, so that the load of the battery mounting portion 6 including the battery 5 is increased. I can support it stably.

Then, when sudden stop and sudden braking in the process of driving the electric vehicle, the load of the battery mounting portion 6 including the battery 5 is moved forward by the inertial force, at this time buffer located in the rear of the battery mounting portion (6) The means 7 support the forward moment of inertia while exerting a pulling force, and the first rod 71 and the second rod 72 of the shock absorbing means 7 located in front of the battery compartment 6 are also forward. It blocks the inertia. At this time, the elastic member 76 of the buffer means (7) located in the front serves to absorb the inertial force while elastically deformed between the main frame (1) and the battery mounting portion (6).

On the contrary, when the electric vehicle starts and stops in a stopped state, the load of the battery mounting part 6 including the battery is pulled backward by the inertia force, and the shock absorbing means 7 located in front of the battery mounting part 6 is While supporting a pulling force to support the rear inertia force, the first rod 71 and the second rod 72 of the shock absorbing means (7) located in the rear of the battery mounting portion 6 also to support the inertial force toward the rear do. At this time, the elastic member 76 of the shock absorbing means 7 located at the rear serves to absorb the rear inertia force while being elastically deformed between the main frame 1 and the battery mounting part 6.

In addition, when the electric vehicle passes through the sharper part while driving, the load of the battery mounting part 6 including the battery is swayed to either side according to the turning direction of the electric vehicle due to the sharp turn, wherein the side of the battery mounting part 6 is located The shock absorbing means 7 carries out a role of absorbing and absorbing the shock while simultaneously supporting the load by a similar action to the shock absorbing means 7 positioned in front and behind the battery compartment.

Figure 6 is an exploded perspective view showing another example of the shock absorbing means applied to the fixing structure for reinforcing and shock absorbing the battery mounting portion of the electric vehicle according to an embodiment of the present invention, the same reference numerals as the configuration shown in Figure 5 The explanation will be given.

Referring to FIG. 6, the tie rod 7 ′ has a first rod 71 having one side fixed to the longitudinal bar 11 and the side bar 12 of the main frame 1 and one side fixed to the battery mounting part 6. The second rod 72 and the first and second rods 71 and 72 is fastened to the other side of the tension adjusting member 73 to adjust the tension through the tightening or loosening operation, the first rod 71 And engaging hooks 71c and 72c at the end of the second rod 72.

The first rod 71 has a right screw portion formed on the outer circumferential surface of the rod body, and the second rod 72 has a left screw portion formed thereon, and a tension adjusting member to which the first rod and the second rods 71 and 72 are fastened. In 73, a fastening hole in which a right hand thread is formed and a fastening hole in which a left hand thread is formed are formed.

In addition, the hook rings 14 and 68 protrude from the main frame 1 and the battery mounting part 6 so that the hooks 71c and 72c of the first rod and the second rod 71 and 72 are engaged. .

Figure 7 is an exploded perspective view showing another example of the shock absorbing means applied to the fixing structure for reinforcing and shock absorbing the battery mounting portion of the electric vehicle according to an embodiment of the present invention.

Referring to FIG. 7, the tie rod 7 ″ is provided between the main frame 1 and the battery mounting portion 6 and has a rod 77 having a head 77a formed at one side thereof, and the other side of the rod 77. Fixing nut 78 is fastened to, and an elastic member 79 for absorbing and buffering the external force acting on the battery mounting portion (6) is provided.

The elastic member 79 is inserted through the rod 77 and is interposed between the inside of the head 77a (between the head and the battery mounting part) and the inside of the fixing nut 78 (between the fixing nut and the horizontal bar). It is elastically installed and consists of a compression coil spring. At this time, the elastic member 79 may be configured only on the inner side of the head, but it is preferable that both the main frame 1 and the battery mounting portion 6 are installed as shown in FIG.

In addition, the fixing nut 78 has a structure in which the release preventing plate 78a is integrally formed to prevent the elastic member 79 from being separated, and the outer diameter of the head 77a is the diameter of the elastic member 79. It is formed to have a large outer diameter.

Although not shown in detail, the tie rod 7 ″ shown in FIG. 7 also has an elastic member (see FIGS. 5 and 6) between the main frame 1 and the battery mounting portion 6 as shown in FIGS. 5 and 6. When the reference numeral 76 is installed, the inertia force of the battery can be more effectively absorbed and buffered, and deformation of the main frame and the battery compartment can be prevented.

On the other hand, although not shown in detail, in the tie rods 7 and 7 'shown in Figs. 5 and 6, elastic members 79 provided in the tie rods 7 "of Fig. 7 at both ends of the first and second rods, respectively. Similar to), the additional installation can more effectively absorb the inertia of the battery.

What has been described above is just one embodiment for implementing a fixing structure for reinforcing and shock absorbing the battery mounting portion of the electric vehicle according to the present invention, the present invention is not limited to the above-described embodiment, the following claims As claimed in the present invention, those skilled in the art to which the present invention pertains without departing from the gist of the present invention will have the technical idea of the present invention to the extent that various modifications can be made.

1: main frame 11
12: horizontal bar 13, 66: insertion hole
2: Outer panel 3: Air conditioner mounting section
4: door 5: battery
6: Battery compartment 7: Shock-absorbing means
71: first load 72: second load
73: tension adjusting member 74, 78: fixing nut
75: Loosening prevention nut 76, 79: Elastic member
77: load

Claims (6)

A main frame forming a skeleton of the electric vehicle; And
It includes a battery mounting portion installed on the main frame so that the battery is mounted,
The battery mounting part of the electric vehicle for reinforcing and shock absorption, characterized in that it comprises a plurality of shock absorbing means connected to, and installed between the battery mounting portion and the main frame to perform a buffering action while applying the tension to the battery mounting portion. Fixed structure.
The method of claim 1,
The shock absorbing means is a fixed structure for reinforcing and shock absorbing the battery mounting portion of the electric vehicle, characterized in that consisting of a tie rod having a structure capable of adjusting the length of the tension control.
3. The method of claim 2,
The tie-
A first rod having one end fixed to the main frame;
A second rod having one end fixed to the battery mounting part;
A tension adjusting member which is fastened to the other side of the first and second rods and adjusts tension through tightening or loosening operation; And
A fixing structure for reinforcing and shock absorbing the battery mounting portion of the electric vehicle, characterized in that it comprises an anti-loosening nut fastened to the first and second rods to prevent loosening of the tension adjusting member.
3. The method of claim 2,
The tie rod is a fixing structure for reinforcing and shock absorption of the battery mounting portion of the electric vehicle, characterized in that the elastic member is interposed to absorb and buffer the external force acting on the battery mounting portion.
3. The method of claim 2,
The tie rod, the rod is installed between the main frame and the battery mounting portion and the head portion formed on one side; A fixing nut fastened to the other side of the rod; And an elastic member inserted into the rod and elasticized in at least one of the inside of the head and the inside of the fixing nut.
The method according to any one of claims 1 to 5,
The buffer means is a fixed structure for reinforcing and shock absorption of the battery mounting portion of the electric vehicle, characterized in that disposed in a plurality of opposed to the front and rear and both sides of the battery mounting portion.

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