The present disclosure relates to a sliding device for a drawer, and more particularly, to a sliding device for a drawer capable of reinforcing rigidity while reducing noise during operation by mixing and using a plurality of slide balls having different tensile strengths.
Generally, a sliding device for a drawer is provided between a main body and a storage body and is used so that the storage body is easily drawn out from or drawn into from the main body when the user opens and closes the storage body.
The sliding device for the drawer is provided in a double-fold folding type and a triple-fold folding type. Here, in the triple-fold folding type, a fixed rail is fastened to the inner surface of the main body, and a movable rail is fastened to the outer surface of the storage body. In addition, an intermediate rail is provided between the fixed rail and the movable rail, and a plurality of slide balls are disposed between the intermediate rail and the fixed rail and between the intermediate rail and the movable rail to perform a rolling motion. According to such a configuration, the intermediate rail and the movable rail are supported by the fixed rail to slide together with the storage body.
In addition, a conventional sliding device for a drawer uses slide balls made of the same materials. For example, the slide ball made of metal or plastic is used.
However, if the slide ball made of metal is used, there are problems in that loud noise is generated when the storage body is moved, which causes discomfort to the user, and if the slide ball made of plastic is used, the slide ball is easily broken.
The present disclosure is intended to solve the above problems, and an object of the present disclosure is to provide a sliding device for a drawer capable of reinforcing rigidity while reducing noise during operation by mixing and using a plurality of slide balls having different tensile strengths.
In order to achieve the object, a sliding device for a drawer according to a preferred exemplary embodiment of the present disclosure includes: a fixed rail fastened and fixed to a main body; a movable rail fastened and fixed to a storage body, and sliding on the fixed rail; an intermediate rail disposed between the fixed rail and the movable rail to guide the sliding movement of the movable rail; and ball assemblies disposed between the intermediate rail and the fixed rail and between the intermediate rail and the movable rail, respectively to slide, and provided with a plurality of slide balls having different tensile strengths, the slide ball having a large tensile strength being disposed at the outermost side thereof.
The intermediate rail may include: a plate part disposed between the fixed rail and the movable rail; and contact parts provided at both sides of the plate part along the longitudinal direction, respectively, and formed with rolling surfaces so that the slide balls of the ball assembly are partially accommodated, and a plurality of rolling surfaces may be formed to be spaced apart from each other along the circumferential direction thereof at each of one side and the other side of the plate part.
The ball assembly may include: a retainer provided in a ‘¬’ shape, and formed with a plurality of through holes at regular intervals in the longitudinal direction at both ends and edges thereof; a first slide ball inserted into a first through hole formed in the end of one side of the retainer, and disposed on a first rolling surface formed to be curved at the edge of one side of the contact part; a second slide ball inserted into a second through hole formed in the edge of the retainer, and disposed on a second rolling surface formed to be curved at the edge of the other side of the contact part; and a third slide ball inserted into a third through hole formed in the end of the other side of the retainer, and disposed on a third rolling surface formed to be curved at the lower side of the second rolling surface.
Here, the retainer may have the first through hole and the third through hole which are provided on the same line, and also have the second through hole which is provided between the first through hole and the third through hole.
In addition, the first rolling surface, the second rolling surface, and the third rolling surface may be formed to be curved at the same diameters, and the first slide ball, the second slide ball, and the third slide ball may also be provided at the same diameters.
Alternatively, the first rolling surface and the second rolling surface may be formed to be curved at the same diameters, and the third rolling surface may be formed to be curved at a larger diameter than that of the second rolling surface, and the first slide ball and the second slide ball may be provided at the same diameters, and the third slide ball may also be provided at a larger diameter than that of the second slide ball.
In addition, the ball assembly may also have the slide balls disposed at both side ends which are larger in tensile strength than the slide balls located at the center side, among the plurality of first slide balls and third slide balls.
In addition, the ball assembly may also have the slide balls disposed at both side ends which are larger in tensile strength than the slide balls located at the center side, among the plurality of second slide balls.
Furthermore, the ball assembly may also have the slide balls having different tensile strengths whose difference is 400 MPa or more.
More specifically, the ball assembly may have the slide ball having a large tensile strength which is made of a material having the tensile strength of 405 to 2500 MPa, and also have the slide ball having a small tensile strength which is made of a material having the tensile strength of 5 to 150 MPa.
The fixed rail and the movable rail may further include: stoppers formed to protrude from the inner circumferential surfaces of the fixed rail and the movable rail, and limiting the movement so that the ball assembly slides only within a predetermined region.
In addition, the intermediate rail may further include: a stopper limiting the movement so that the ball assembly slides only within a predetermined region.
The sliding device for the drawer according to the present disclosure may reduce noise using the slide ball having the low tensile strength as a whole, and reinforce rigidity using the slide ball having the large tensile strength in the portion to which the shock load is applied.
In order to help the understanding of the features of the present disclosure, a sliding device for a drawer according to an exemplary embodiment of the present disclosure will be described in more detail below.
In adding the reference numerals to the components of each of the accompanying drawings in order to help the understanding of the exemplary embodiments described below, it is noted that the same components have the same reference numerals as possible even though they are displayed on different drawings. In addition, in the description of the present disclosure, if it is determined that detailed descriptions of related well-known structures or functions may obscure the gist of the present disclosure, detailed descriptions thereof will be omitted.
Hereinafter, specific exemplary embodiments of the present disclosure will be described with reference to the accompanying drawings.
In addition,
In addition,
Referring to
That is, the present disclosure may dispose a slide ball made of a material having a relatively small tensile strength at the center side of the sliding device, and a slide ball made of a material having a relatively large tensile strength at the outermost side thereof, thereby reducing noise during driving compared to a sliding device using only a slide ball made of a material having a large tensile strength, and reinforcing rigidity compared to a sliding device using only a slide ball made of a material having a small tensile strength.
The fixed rail 200 is fastened to the inner surface of the main body 10 and fixed in position, and the movable rail 300 is fastened to the outer surface of the storage body 20 and provided to move to be slidable on the fixed rail 200 to draw into or draw out the storage body 20.
In addition, the inner circumferential surfaces of the fixed rail 200 and the movable rail 300 are formed with a fixed rail stopper 210 and a movable rail stopper 310 which are formed to protrude inward, respectively to limit the movement so that the ball assembly 500 slides only within a predetermined region.
That is, as illustrated in
The intermediate rail 400 includes a plate part 410 disposed between the fixed rail 200 and the movable rail 300, and contact parts 420 provided at both sides of the plate part 410 along the longitudinal direction and formed with rolling surfaces so that the slide ball of the ball assembly 500 is partially accommodated. Here, three rolling surfaces are formed to be spaced apart from each other along the circumferential direction at each of one side and the other side of the plate part 410, and provided so that the plurality of slide balls roll and are in contact with the rolling surface.
More specifically, referring to
Here, referring to
In addition, the intermediate rail 400 is provided with an intermediate rail stopper 430 which limits the movement so that the ball assembly 500 slides only within a predetermined region.
More specifically, a pair of the intermediate rail stoppers 430 are provided and disposed to be spaced apart from each other at a regular interval, and formed to protrude from the plate part 410 toward the first rolling surface 421. That is, the intermediate rail stoppers 430 are formed to have a separation distance longer than the length of the ball assembly 500, so that the ball assembly 500 is provided to move to be slidable between the intermediate rail stoppers 430.
In addition, as illustrated in
The intermediate rail stopper 430 thus formed may limit the maximum drawn-out distance of the storage body by limiting the movement region of the ball assembly 500 together with the fixed rail stopper 210 and the movable rail stopper 310.
The ball assembly 500 includes a retainer 510 provided in a ‘¬’ shape and formed with a plurality of through holes at regular intervals in the longitudinal direction at both ends and edges, a first slide ball 520 inserted into a first through hole 511 formed in the end of one side of the retainer 510 and disposed on the first rolling surface 421, a second slide ball 530 inserted into a second through hole 512 formed at the edge of the retainer 510, provided at the same diameter as the first slide ball 520, and disposed on the second rolling surface 422, and a third slide ball 540 inserted into a third through hole 513 formed in the end of the other side of the retainer 510, provided to have a larger diameter than that of the second slide ball 530, and disposed on the third rolling surface 423.
More specifically, referring to
Here, the first through hole 511 and the third through hole 513 are provided on the same line, and the second through hole 512 is provided between the first through hole 511 and the third through hole 513. According to such a configuration, a load point may be dispersed and thus the load applied to the sliding device 100 for the drawer by the storage body may be dispersed, thereby reinforcing the rigidity of the sliding device for the drawer.
Referring to
When a storage object is stored in the storage body 20, as illustrated in
Accordingly, the third slide ball 540 and the third rolling surface 423 are provided to have a larger diameter than those of the first slide ball 520 and the first rolling surface 421, thereby increasing a rolling contact area of the third slide ball 540. Accordingly, the intensive load applied between the movable rail 300 and the third slide ball 540 and between the third slide ball 540 and the third rolling surface 423 may be dispersed, thereby reducing wear and damage of the third slide ball 540.
Referring to
In addition, the ball assembly 500 may also be provided with the slide balls 531 disposed at both side ends of the plurality of second slide balls 530 having the tensile length larger than that of the slide ball 532 located at the center side of the ball assembly 500.
That is, the ball assembly 500 may be configured so that only the first and third slide balls 520, 540 of the first to third slide balls 520, 530, 540 have the slide balls 521, 541 located at both side ends which are made of a material having a large tensile strength, or all of the first to third slide balls 520, 530, 540 have the slide balls 521, 531, 541 located at both side ends which are made of a large tensile strength. Accordingly, it is possible to select the number of slide balls used made of a material having a large tensile strength in consideration of the required rigidity according to the use of the storage body.
Here, a material having a difference in tensile strength of 400 MPa or more among the slide balls having different tensile strengths may be selected and applied to the ball assembly 500.
More specifically, the slide ball having the large tensile strength may be made of a material having the tensile strength of 405 to 2500 MPa, and the slide ball having the small tensile strength may be made of a material having a tensile strength of 5 to 150 MPa.
For example, a slide ball made of iron having a tensile strength of 600 MPa and a slide ball made of polyacetal resin (POM) having a tensile strength of 100 MPa are used, and a comparison of noises generated in the sliding device in the case of using only the slide ball made of iron and the case of mixing and using the slide ball made of iron and the slide ball made of polyacetal resin is shown in Table below.
In Table 1 below, a Comparative Example is a case where only the slide ball made of iron is used.
In addition, in Example 1, for all of the first to third slide balls 520, 530, 540, the slide balls 521, 531, 541 located both side ends thereof used the slide balls made of iron, and the slide balls 522, 532, 542 located at the center side thereof used the slide balls made of polyacetal resin.
In addition, in Example 2, for only the first and third slide balls 520, 540, the slide balls 521, 541 located at both side ends used the slide balls made of iron, and the slide balls 522, 542 located at the center side and the second slide ball 530 used the slide balls made of polyacetal resin.
As shown in Table 1, in the Comparative Example, a noise of 4.4 dB was generated during operation, and in Example 1, a noise of 3.9 dB was generated, thereby improving the noise by 11%. In addition, in Example 2, it may be seen that a noise of 2.5 dB was generated, thereby improving the noise by 56%.
Accordingly, the slide balls located at both side ends may use the slide ball made of a material having a relatively large tensile strength such as iron, thereby reinforcing rigidity, and the slide ball located at the center side may use the slide ball made of a material having a relatively low tensile strength such as polyacetal resin, thereby reducing the generation of noise, compared to the case where all of the slide balls use the slide balls made of iron.
Referring to
That is, the sliding device for the drawer according to another exemplary embodiment of the present disclosure is provided so that the first to third slide balls have the same diameters.
A sliding device for a drawer according to still another exemplary embodiment of the present disclosure is provided to have the same configuration as the sliding device for the drawer according to the exemplary embodiment of the present disclosure described with reference to
That is, as illustrated in
As described above, although the present disclosure has been described by the limited exemplary embodiments and drawings, it is natural that the present disclosure is not limited thereto and various modifications and changes are possible by those skilled in the art to which the present disclosure pertains without departing from the technical spirit of the present disclosure and the equivalent scope of the claims set forth below.
Number | Date | Country | Kind |
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10-2018-0003324 | Jan 2018 | KR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/KR2018/016806 | 12/28/2018 | WO | 00 |