KR101278901B1 - Double plate type seat back frame - Google Patents

Abstract

The present invention relates to a seat back frame comprising: a back frame made of fiber-reinforced thermoplastic resin, the back frame including ribs for strength reinforcement, and a shell plate bonded to the back frame; The shell plate may be formed in a plate shape, and a part of the recess part may be directly contacted with the back frame without intervening the rib. The edge of the shell plate is fixed to the edge of the back frame with a plurality of plate fixing screws, the portion of the shell plate seated on the rib intersecting the rib portion of the double sheet seat back frame, characterized in that the screw is screwed to the boss. To provide.
According to the present invention, it is possible to secure the rigidity more than specified without significantly increasing the weight, and at the same time can be modified according to the impact to prevent damage through energy absorption or breakage in a sharp form that threatens the occupant, more safe and comfortable high quality A seat back frame can be obtained.

Description

Double seat back frame {DOUBLE PLATE TYPE SEAT BACK FRAME}

TECHNICAL FIELD The present invention relates to a double sheet back frame, and more particularly, to a double sheet back frame improved to satisfy both strength and emotional quality.

In general, the seat back of the vehicle is a means for providing a comfortable and comfortable riding environment by supporting the back of the passenger connected to the seat cushion that supports the passenger's hips.

Such a seat back is usually formed of a plastic material and forms ribs 12 or channels 14 on the seat back frame 10 as shown in FIG. 1 to maintain strength. Doing.

However, this structure helps to maintain an appropriate level of strength, but there is a limit to sufficiently increasing the stiffness of the product.

In addition, there is an example of further reinforcing the strength by using a steel-like reinforcement bracket or a plate-like reinforcement, but in this case, the weight increases rapidly, which is very disadvantageous in terms of competitiveness and disadvantageous in terms of rigidity.

In other words, the stiffness of the seat back frame is not the same as that of the strength. The strength of the seat back frame refers to the strength of the object, that is, the deformation resistance until the material is destroyed when the material is loaded. Stiffness refers to the hardness or rigidity of the material. In the case of the seat back frame, the concept includes emotional quality.

For example, when passengers sit down, when seats are folded down, and when the armrest is pressed, the seat back frame lacks the rigidity. It is difficult to quantify the criteria, but it needs to be minimized.

Therefore, although the product strength that satisfies the international performance regulations is secured through the strength reinforcement as described above, such a lack of rigidity still occurs.

In order to solve this problem, fiber reinforced plastic resins (GMT, LFT, etc.) are used to reduce the weight of the seat back frame while improving both strength and rigidity to absorb static or dynamic impact energy to secure vehicle safety functions. Efforts have been raced.

For example, in connection with the seat back frame, Patent Publication No. 2008-100499 discloses a technique for improving strength and rigidity by vibrating two plates in a sandwich structure, and Patent Publication No. 2010-0097776. A technique for achieving both the purpose of weight reduction and strength and rigidity improvement by providing a sandwich structure in the form of joining through two ribs through a rib is disclosed.

However, when stiffness increases with sufficient strength, the deformation energy due to impact decreases, so it is difficult to secure the emotional quality due to the low impact absorption ability.On the contrary, when the impact absorption power is increased by having the appropriate deformation energy to secure sufficient emotional quality, It is very difficult to find an alternative that satisfies both of these properties due to the conflicting stiffness and difficult specification.

In other words, if the stiffness is increased, there is a problem in the legal performance of absorbing energy through deformation, and if the energy absorption structure is made to have a proper deformation, a problem of insufficient product rigidity occurs.

In this regard, in the disclosed prior patents, a sandwich structure is formed by interposing a core 24 between two plates 20 and 22, as shown in FIG. 2, and then, between the core 24 and the plates 20 and 22. Are bonded to each other by heat fusion or adhesive bonding, or vibration welding, which form a hollow portion in which the two plates 20 and 22 are entirely spaced apart, and the core 24 is interposed therebetween. ) Is an intervening form, so the shock absorbing performance due to impact is excellent, but the strength is low, and it has a limitation that it is difficult to satisfy the rigidity requirements as described above.

The present invention was made in view of the above-described problems in the prior art, and was created to solve this problem. Its main purpose is to provide a one-dimensional high quality seat back frame that satisfies all.

The present invention provides a means for achieving the above object, a seat back frame made of a fiber-reinforced thermoplastic resin, a back frame comprising a rib for strength reinforcement, and a shell plate bonded to the back frame; The shell plate may be formed in a plate shape, and a part of the recess part may be directly contacted with the back frame without interposing the rib, and the part except the recess part may be seated on the rib, and a boss may protrude from the part where the rib intersects. The edge of the shell plate is fixed to the edge of the back frame with a plurality of plate fixing screws, the portion of the shell plate seated on the rib intersecting the rib portion of the double sheet seat back frame, characterized in that the screw is screwed to the boss. To provide.

In addition, the present invention is a seat back frame made of a fiber-reinforced thermoplastic resin, a back frame comprising a rib for strength reinforcement, and a shell plate bonded to the back frame as a means for achieving the above object ; The shell plate is formed in a plate shape is seated on the rib, the boss intersects the portion where the rib intersects, the edge of the shell plate is fixed to the edge of the back frame with a plurality of plate fixing screws, the shell plate on the rib The portion of the seated portion where the ribs cross is provided with a double seat back frame, characterized in that the screw is screwed to the boss.

In this case, the shell plate is also characterized in that it is formed in a smaller size than the back frame.

According to the present invention, while securing a strength greater than the specified amount without significantly increasing the weight and receiving a shock or force above a certain level, the locally screwed portion falls and absorbs energy, thereby absorbing the front plate (shell plate). It also prevents damage to the rear plate (mainframe) and prevents sharp edges, reducing the threat of occupants, resulting in a safer and more comfortable high quality seat back frame.

In addition, it is possible to obtain the effect of satisfying both the stiffness and the energy absorption due to deformation, without modifying or redesigning a mold for manufacturing an existing seat back frame.

In addition, the effect of assembly is improved and the installation is easy.

1 is an exemplary view of a seat back frame according to the prior art.
2 is a cross-sectional view illustrating main parts of an example of a seat back frame according to the related art.
3 and 4 are exemplary views of the double sheet back frame according to the present invention.
5 is a sectional view of principal parts of the double sheet back frame according to the present invention;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figure 3, according to one preferred embodiment of the present invention, the seat back frame 100 is made of a fiber-reinforced thermoplastic resin which is an improved material as in the prior art described above.

Here, the fiber-reinforced thermoplastic resin includes both glass fiber mat thermoplastics (GMT), including long fiber thermoplastics (LFT).

The seat back frame 100 has a plate shape in which the shell plate S is partially screwed to one surface of the back frame 110, which is a base, and the back frame 110 and the shell plate S are formed in two layers. .

At this time, the shell plate (S) is partially installed on one surface of the back frame 110, and the shell plate (S) is not partially screwed in whole, but rather a plurality of ribs (as shown in Figs. It is preferred to have the form of screwing 102 at the point where they cross each other, ie partially screwing.

Of course, the basic fixing structure for fixing the shell plate (S) to the back frame 110 has a screw fastened to the back frame 110 at intervals along the edge of the shell plate (S), but this screw, that is, Plate fixing screw (B1) is a means for simply holding the shell plate (S) to the back frame 110, the joining screw for achieving the desired purpose of the present invention is the rib 102 and rib 102 intersect. Joining screw (B2) is fastened to the point to be obtained, the shell plate (S) in the portion joined by the joining screw (B2) to obtain the effect of the partial joining so as to satisfactorily meet both the strength and the emotional quality during the collision. It will work.

Accordingly, the back frame 110 includes the rib 102 or the channel 104, which is a conventional structure provided for strength reinforcement, as it is in the present invention.

In addition, the shell plate (S) is preferably formed in a form that is formed in accordance with the shape of the back frame 110 to be installed in the plate-like member, the shell plate (S) itself may have a multi-layer sandwich panel form, After tens to hundreds of actual vehicle tests, the back frame 110 is provided to be bonded only to the weakest emotional quality.

That is, the shell plate S is partially bonded to the back frame 110 while including a specific point (a portion having a poor quality of emotion) rather than the entire surface of the back frame 110.

This form is as shown in (a) of Figure 5, the shell plate (S) of the recessed portion 120 and the back frame 110 of the recessed downward to match the shape of the back frame 110 Corresponding portions are arranged to be in surface contact with each other, wherein the remaining portion of the shell plate (S) has a form that is mounted on the rib 102 as shown.

Then, at the portion where the ribs 102 cross each other, the joining screw B2 is fastened, and the edge of the shell plate S is fixed to the plate fixing screw B1 on the ribs 102 formed at the edge of the back frame 110. Is fixed.

Here, a boss 112 having a '+' shape protrudes from a portion where the rib 102 intersects to fasten the joining screw B2, as illustrated in FIG. 4, and has a center of the boss 112. The screw hole 114 is formed to fasten the joint screw (B2).

In addition, in some cases, when a space for installing the armrest fixing hinge bracket is required on a portion of the shell plate S, a portion of the shell plate S may be cut and removed by a corresponding size, or the shell plate may be removed at all. (S) From the molding step may be pre-designed and molded to fit the back frame 110 having an armrest.

In addition, the shell plate S is formed to have a smaller size than the back frame 110, because the shell plate S is not overlapped over the entire surface of the back frame 110 but overlaps only a part thereof.

In addition, a part, in particular, a part of which strength is reduced through testing, when partially bonded is formed in such a manner that the back frame 110 and the shell plate S directly contact each other and partially form two layers of plates, that is, a double plate. By having the hollow portion disposed inside the furnace, it is possible to fundamentally block local degradation of strength that may occur as a counterpart due to the improvement of rigidity.

To this end, the shell plate (S), as described above, a part is recessed downward to conform to the shape of the back frame 110, the surface contact with the back frame 110 to form a two-ply plate, that is, a double plate As shown in FIG. 5A, at least a plurality of recesses 120 are provided.

In this case, if the general welding method of completely welding the shell plate S over the entire surface of the back frame 110 is selected, desired characteristics, that is, desired rigidity cannot be obtained.

This is because welding is usually the main concept of perfectly integrating the two materials so that they do not easily fall off, so in this case the strength is strengthened, but the ability to absorb deformation due to impact is reduced, so during the crash collision test (ECE R17). This joining method is very disadvantageous, as sharp edges appear in the same way as in the conventional fault model, which poses a threat to the occupants.

Therefore, in the present invention, a partial screw fastening double joining structure capable of local bonding and absorbing the impact of a collision is applied.

By using the joint structure of the double plate structure through such local screwing, the screwing parts are separated from each other when a certain amount of external force is applied while easily achieving local bonding, and the structure can absorb the impact.

In other words, during the luggage collision test (ECE R17), the same sharp damage area as the existing fault model is not generated, thereby minimizing the threat of occupants.

According to the present invention, such a local screwing part is made at the point where it is determined to be vulnerable through a test (analyzes the waveform of impact energy at the time of collision) as mentioned above.

As another example, as shown in (b) of FIG. 5, instead of forming the concave portion 120 in the shell plate S, the convex portion 120 is formed in a simple plate shape, and then the rib 102 protrudes on the back frame 110. It may be deformed to form a fastening using the plate fixing screw (B1) and the bonding screw (B2) immediately.

This structure also falls within the scope of the preferred embodiment according to the present invention has a sufficient effect in terms of ease of molding, ease of assembly and installation.

Of course, the rib 102 is excessively protruded for convenience of description, but the lower the height of protrusion of the rib 102, the effect can be even higher.

As described above, the seat back frame according to the present invention allows the shell plate to be partially screwed into the back frame to achieve a rigid reinforcement of shock energy absorption, which is the opposite concept, while minimizing the weight added for strength reinforcement. This makes it possible to manufacture even higher quality seat back frames.

In particular, the shell plate (S) screwed to the back frame 110 can be modified in the form of a sandwich panel of a multi-layer structure to ensure excellent shock absorbing power and stability of post-shock behavior obtained by the structural characteristics of the sandwich panel rigidity It is possible to more fully meet the requirements of the contradictory concepts of increased strength and shock absorption.

This has allowed us to successfully build a higher level of seat back frame, with actual vehicle baseline testing showing a 23% weight increase over the total weight of the previous seat back frame when steel was added to meet the required performance of the seat back frame. Although the occurrence of the shell plate (S) according to the present invention was successful in increasing the stiffness of the product only with an additional weight of 15%.

100: seat back frame 102: rib
110: frame 112: boss
114: screw hole 120: recessed part
B1: Plate fixing screw B2: Joining screw
S: shell plate

Claims (3)

A seat back frame made of fiber-reinforced thermoplastic resin and comprising a back frame (110) including ribs (102) for strength reinforcement and a shell plate (S) bonded to the back frame (110);
The shell plate (S) is formed in a plate shape, the recess portion 120 which is in direct contact with the back frame 110 is formed in part without the rib 102,
Portions other than the concave inlet 120 is seated on the rib 102,
A boss 112 protrudes at a portion where the ribs 102 cross each other,
The edge of the shell plate (S) is fixed to the edge of the back frame 110 by a plurality of plate fixing screws (B1), the rib 102 of the portion where the shell plate (S) is seated on the rib (102) The intersecting part is screwed to the boss 112 with a bonding screw (B2) characterized in that the double seat back frame.
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