The present invention relates to a bodyshell structure of a railcar, and particularly to a bodyshell structure configured to improve ride quality and be reduced in mass.
In recent years, a reduction in mass of railcars has been demanded with an increase in speed of the railcars, and railcars that are improved in comfort of passengers, such as ride quality, have been strongly demanded. In response to these, known is a railcar bodyshell that is improved in the ride quality by reducing the sizes of side windows to increase bending stiffness of the bodyshell.
Known as one of the structures of side bodyshells of railcars is a double skin structure using an aluminum alloy hollow extruded section constituted by two face plates and ribs each coupling these face plates to each other. The reduction in mass and the improvement in ride quality of the railcar having the above structure have also been demanded. In response to these, PTL 1 proposes a railcar bodyshell configured such that only the thickness of a face plate of a hollow section constituting a pier panel that is a portion between windows of the side bodyshell is uniformly increased in a railcar longitudinal direction as compared to the thickness of a face plate of the other hollow section constituting the side bodyshell. PTL 1 describes that the railcar bodyshell that is high in bending stiffness and light in mass can be provided by the above configuration.
However, if the sizes of the side windows are reduced, passengers' visions from the inside of the railcar are limited, so that open feeling decreases. In addition, in the railcar bodyshell described in PTL 1, since the thickness of the face plate of the hollow section constituting the pier panel is increased in the railcar longitudinal direction, the bending stiffness can be increased, but the problem is that the mass of the railcar increases.
Here, an object of the present invention is to provide a bodyshell structure of railcar, the bodyshell structure being increased in bending stiffness, improved in ride quality, and reduced in mass.
The present invention is a bodyshell structure of a railcar, the bodyshell structure including a side bodyshell including a plurality of side window opening portions formed along a railcar longitudinal direction, wherein the side window opening portions include a plurality of large window opening portions arranged on a railcar-longitudinal-direction center portion and a plurality of small window opening portions arranged on both railcar-longitudinal-direction sides of the large window opening portions and each having a smaller opening area than the large window opening portion.
According to this, the plurality of side window opening portions are formed by combining the plurality of large window opening portions arranged on the railcar-longitudinal-direction center portion and the plurality of small window opening portions arranged on both railcar-longitudinal-direction sides of the large window opening portions and each having a smaller opening area than the large window opening portion. Therefore, as compared to a case where the side window opening portions are formed only by the large window opening portions, the number of pier panel portions each between the side window opening portions can be increased, and the areas of the pier panel portions can be increased. On this account, the bending stiffness of the bodyshell can be increased, and the ride quality can be improved. In addition, since the plurality of large window opening portions each having a large opening area are arranged on the railcar-longitudinal-direction center portion, the passengers' visions from the inside of the railcar can be secured.
Hereinafter, a bodyshell structure of a railcar according to an embodiment of the present invention will be explained in reference to the drawings.
Each of
As shown in
The entrance opening portions 12A and 12B are respectively formed at front and rear side portions of the side bodyshell 11A. A plurality of side window opening portions 13 are formed between the entrance opening portions 12A and 12B at regular intervals along a railcar longitudinal direction. The side window opening portions 13 include four large window opening portions 13A having a substantially rectangular shape that is long in the railcar longitudinal direction, six small window opening portions 13B on the front side, and six small window opening portions 13B on the rear side, the small window opening portions 13B each having a shorter length than the large window opening portion 13A in the railcar longitudinal direction. A plurality of large window opening portions 13A are arranged at a railcar-longitudinal-direction center portion of the side bodyshell 11A, the small window opening portions 13B are formed between the large window opening portion 13A and the entrance opening portion 12A, and the small window opening portions 13B are also formed between the large window opening portion 13A and the entrance opening portion 12B. The load of the carbody is supported by the portions P1 and P2, and shear force larger than shear force acting on the center portion of the side bodyshell 11A acts on the portions P1 and P2. In order that the side bodyshell 11A withstands the shear force, the small window opening portions 13B are arranged on both sides of the large window opening portions 13A, that is, in the vicinities of the portions P1 and P2. Thus, the number of pier panel portions 14B is increased. Since the shear force is small at the center portion, providing the large window opening portions 13A at the center portion does not cause any problem.
Next, details of the side window opening portion 13 (the large window opening portion 13A and the small window opening portion 13B) will be explained.
As shown in
Although the small window opening portion 13B is different in size from the large window opening portion 13A, as with the large window opening portion 13A, the small window opening portions 13B include outside window openings 13Ba formed on the outside plate portion 11Aa and inside window openings 13Bb formed on the inside plate portion 11Ab, and the inside window opening 13Bb is formed by cutting off the inside plate portion 11Ab and the web portion 11Ac.
A length of a pier panel portion 14A between the large window opening portions 13A in the railcar longitudinal direction, a length of a pier panel portion 14B between the small window opening portions 13B in the railcar longitudinal direction, and a length of a pier panel portion 14C between the large window opening portion 13A and the small window opening portion 13B in the railcar longitudinal direction are equal to one another.
A height of the large window opening portion 13A (the outside window opening 13Aa) in a railcar vertical direction and a height of the small window opening portion 13B (the outside window opening 13Ba) in the railcar vertical direction are equal to each other. A length of the large window opening portion 13A in the railcar longitudinal direction is equal to a sum of lengths of two small window opening portions 13B in the railcar longitudinal direction and a length of the pier panel portion 14B between the two small window opening portions 13B in the railcar longitudinal direction.
In the carbody 11 shown in
Next, differences between the side window opening portion 13 of the present embodiment and a conventional side window opening portion 23 will be explained. Each of
A conventional carbody 21 includes entrance opening portions 22A and 22B respectively formed at front and rear side portions of a side bodyshell 21A. The side window opening portions 23 are formed between the entrance opening portions 22A and 22B at regular intervals along the railcar longitudinal direction. Each of the side window opening portions 23 is a large window opening portion having a substantially rectangular shape that is long in the railcar longitudinal direction. Ten side window opening portions 23 are provided.
This conventional case is the same as the above embodiment in that: the side bodyshell 21A has an aluminum alloy double skin structure including an outside plate portion, an inside plate portion, and a web portion (joint portion); and the side window opening portions 23 include outside window openings 23a formed on the outside plate portion of the side bodyshell 21A and inside window openings 23b formed on the inside plate portion of the side bodyshell 21A. Each of the outside window opening 23a and the inside window opening 23b has a rectangular shape that is long in the railcar longitudinal direction. A reference sign 21B denotes a roof bodyshell coupled to an upper portion of the side bodyshell 21A, and a reference sign 21C denotes an underframe connected to a lower portion of the side bodyshell 21A.
Each of
For example, the length of the large window opening portion 13A in the carbody longitudinal direction is set to 1,560 mm, that is, larger than the small window opening portion 13B having the length of 580 mm. With this, the wide vision from the inside of the railcar can be secured, the open feeling can be offered to the passengers, and the comfort can be improved. In addition, since the number of pier panel portions can be made larger than the number of conventional side window opening portions 23, and the areas of the pier panel portions can be made larger than those of the conventional side window opening portions 23, the bending stiffness of the bodyshell can be increased, and the ride quality can be improved.
As shown in
By adjusting the pitch between the seats and the length of the pier panel portion, one large window opening portion 13A is arranged for two seats, and one small window opening portion 13B is arranged for one seat. In a case where the railcar runs in any direction along the railcar longitudinal direction, the visions from the window opening portions 13A and 13B can be secured for the passengers on the seats.
As shown in
As above, in the present embodiment, the number of pier panel portions is made larger than that of the conventional structure, and the total area of the pier panel portions is made larger than that of the conventional structure. A bending load (shear force) acts on the carbody 11 by using the portions P1 and P2 of the truck bolsters of the truck frames as the fulcrums. However, by increasing the pier panel portions as above, the bodyshell structure whose bending stiffness is increased can be realized.
Next, an optimization analysis was carried out, which minimizes the mass of the bodyshell on condition that a design variable is the thickness of an extruded section of the aluminum alloy double skin structure, a limiting condition is the natural frequency of the carbody, and an objective function is the mass of the bodyshell. In order to secure satisfactory ride quality of the railcar, it is preferable that the natural frequency of the carbody be set to be higher than the natural frequency of a spring system of the truck by 1 Hz or more. Here, in the present embodiment, when the natural frequency of the spring system of the truck is N Hz, the natural frequency of the carbody that is the limiting condition is set to N+1.2 Hz. The natural frequency of the carbody having the conventional structure shown in
Each of
According to the above results, in order to increase the natural frequency of the carbody of the conventional bodyshell structure up to N+1.2 Hz, the thickness distribution becomes the thickness distribution shown in
As above, according to the bodyshell structure of the railcar of the present embodiment, the ride quality is improved, and the comfort is increased. In addition, the reduction in mass of the railcar can be realized.
Based on the sizes of the side window opening portions shown in
Therefore, in a case where the large window opening portions 13A are arranged in the range having the railcar-longitudinal-direction length V corresponding to 4/9 to 6/9 of the railcar-longitudinal-direction length W between the truck bolsters about the railcar-longitudinal-direction center portion X between the truck bolsters (P1 and P2) of the truck frames supporting the carbody 11 (see
The above embodiment may be modified as below to be carried out.
(i) The side bodyshell has the aluminum alloy double skin structure, but the present invention is not limited to this. The present invention may be applied to the single skin structure including only the outside plate portion. This is because since the number of pier panel portions can be increased, and the areas of the pier panel portions can be increased as with the above-described case, the bending stiffness can be increased, and the ride quality can be improved.
(ii) As shown in
(iii) Each of the opening shape of the large window opening portion and the opening shape of the small window opening portion is not limited to the above-described substantially rectangular shape. For example, the large window opening portion may have a substantially oval shape, and the small window opening portion may have a substantially circular shape (for example, a substantially perfect circular shape or a substantially elliptical shape).
Number | Date | Country | Kind |
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2010-157608 | Jul 2010 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2011/003984 | 7/12/2011 | WO | 00 | 2/6/2013 |
Publishing Document | Publishing Date | Country | Kind |
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WO2012/008147 | 1/19/2012 | WO | A |
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5595123 | Tao et al. | Jan 1997 | A |
7789020 | Li | Sep 2010 | B2 |
20090255437 | Hachet et al. | Oct 2009 | A1 |
Number | Date | Country |
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B1-40-6294 | Mar 1965 | JP |
Y1-40-33606 | Nov 1965 | JP |
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Entry |
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Oct. 11, 2011 Extended International Search Report issued in International Application No. PCT/JP2011/003984 (with translation). |
Number | Date | Country | |
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20130152820 A1 | Jun 2013 | US |