JP2012006529A - Air condition system of railway vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain uniform wind speed distribution from an outlet member of air condition wind from a center to an edge section in a vehicle where an air condition device is equipped.SOLUTION: An air condition duct 3 includes a single air path 3a of a rectangle cross section surrounded by a duct wall faces, and a plate form wind amount adjusting member 5 is provided in the middle of the ventilation path 3a. The plate form wind amount adjusting member 5 is constituted with a mesh member arranged so as to cross a longitudinal direction of the ventilation path 3a, with a wind adjusting effect. The outlet member 4 of the air condition wind provided at a bottom face of the air condition duct 3 at vehicle outer side via a sponge 7, includes an upper member 8 including slit form outlet holes for restricting an extended wind amount, which extend to a front and a backward direction; and a lower member 9 of a louver form, including a plurality of vertical plate sections 9B for adjusting wind direction, which extend to a vertical direction in parallel with a cross direction of the vehicle.

Description

  The present invention relates to an air conditioning system for a railway vehicle such as a commuting suburban vehicle.

  For example, in an air conditioning system for a railway vehicle such as a commuter suburban vehicle, there is an example in which about four air conditioners are distributed on the roof. However, in recent years, a centralized type in which one normal air conditioner is installed near the center of the vehicle body. Or, there are many centralized decentralized systems that are mounted around the center of the vehicle. And, for example, air is distributed from the air conditioner at the center of the vehicle body to the air conditioning duct provided in the ceiling of the passenger compartment, and the conditioned air is blown out from the outlet member attached to the air conditioning duct over the entire length of the passenger compartment, while the indoor air is below the air conditioner It is a flow (circulation flow) of returning from the return port provided to the air conditioner (see, for example, Patent Documents 1, 2, and 3).

  By the way, in the case of such a commuting suburban vehicle, the space requiring air conditioning is usually about 18 to 20 m in length, about 2.2 to 2.4 m in height, and about 2.6 m in width. It is an elongated rectangular parallelepiped cabin space with a length-to-height ratio of approximately 9: 1 and a length-to-width ratio of approximately 7: 1 at ˜3.0 m. In such a space, in a full state, passengers having a height of a certain value or more exist over the entire cabin space, so the difference between the passenger's height and the ceiling height is small (substantially 0. 0 above the passenger's head). There is only a space of about 5m to 0.8m in the height direction), and there is little space on the ceiling side in the cabin space where air-conditioning air is evenly diffused. In the subway between stations, the vehicle stops every 2 to 3 minutes and the door is opened for passengers getting on and off for about 1 minute to 1 minute 30 seconds. The wind is required to spread.

  For example, as shown in FIG. 5A, the air conditioner 101 is generally provided on the upper side of a roof structure 102 extending in the vehicle front-rear direction. There is a sufficient distance to the part, and the wind speed (air volume) blown out from the outlet member varies. That is, in the vicinity of the portion where the air conditioner 101 is provided, the conditioned air is blown from the air conditioner 101 into the air conditioning duct 103, so that the wind speed increases, but the wind speed gradually decreases toward the end. In the vicinity of the end portion, the flow of the conditioned air is blocked by the end portion, so that the pressure in the air conditioning duct 103 (wind tunnel) increases, and the wind speed from the outlet member tends to increase again (FIG. 5). (See line L1 in (b)).

  Therefore, conventionally, as shown in FIGS. 6 (a) and 6 (b), air conditioning disposed in the roof structure 102 so as to obtain a substantially uniform wind speed distribution (see line L2 in FIG. 5 (b)) over the entire length of the vehicle. The duct 103 has a so-called plenum chamber type structure in which the partition wall 104 divides the duct 103 into a main duct 103A near the center of the vehicle and a sub-duct 103B that becomes an air reservoir near the outside of the vehicle. From the vehicle front-rear direction in the duct 103A, the flow is changed to a horizontal flow by the partition wall portion 104, and the flow is changed downward in the sub-duct 103B, and finally the customer is passed through the blowout port member 105 (upper blowout hole portion 105A, lower blowout portion 105B). It blows out indoors. As a result, the flow of conditioned air that tends to flow in the longitudinal direction of the vehicle is changed to the flow of wind in the vertical direction of the vehicle (floor direction) or in the lateral direction of the vehicle (direction of sleepers). Therefore, for example, as described in Patent Document 1, an air volume adjusting plate is installed in the left and right direction of the vehicle in the sub duct 103B, or a partition provided between the main duct 103A and the sub duct 103B as shown in FIG. The height of the wall portion 104 is adjusted to be the highest at the position of the center of the vehicle body corresponding to the air conditioner 101 and gradually lower toward the end of the vehicle in a straight line. I am doing so. In FIG. 6C, 104 a is the upper end portion of the partition wall portion 104.

  The air-conditioning duct 103 is provided on both the left and right sides of the cross-flow fan 111 for agitating the air in the cabin. It is designed to be supplied indoors. A fluorescent lamp 114 is provided outside the air conditioning duct 103, and the outside is a side ceiling plate 115.

  In order to achieve the above object, the cross-sectional area / volume ratio of the main duct 103A and the sub duct 103B with respect to the rated air volume of the air conditioner 101, the size of the gap between the main duct 103A and the sub duct 103B, etc. It is an important factor.

Japanese Patent Laid-Open No. 62-96169 JP 2002-37061 A JP 2008-213580 A

  However, the relational expression for determining the optimal volume ratio, gap size, etc. has not been established mathematically yet, after creating a full-scale test duct and confirming in advance with the test duct, The current situation is that the wind speed distribution in the longitudinal direction of the vehicle is finally confirmed by a ventilation test in the state of being designed and manufactured and actually mounted on the vehicle. When the wind speed distribution is not as expected, it is very difficult to add an air volume adjusting plate in the ceiling wind tunnel or to correct the shape of the partition wall between the main duct and the sub duct.

  In addition, the flow of the conditioned air from the main duct 103A directly under the air conditioner 101 to the sub duct 103B is changed from the vertical direction to the horizontal direction, so that the turbulent state and the wind speed are high. A reverse flow phenomenon may occur in which the air in the cabin is sucked from the air outlet member 105 provided in the lower part of 103B. In general, immediately below the air conditioner 101, the wind speed distribution is unstable, and the air volume tends to be excessive or excessive.

  Therefore, in order to review the structure of the air-conditioning duct in such a vehicle air-conditioning system, the inventor first examined the necessity of a partition wall portion between the main duct and the sub-duct, For the wind speed at each outlet member, 43 measurement points # 1 to # 43 are provided between the vehicle end and the vehicle center, and the conditioned air at each measurement point is provided. The wind speed of was measured. The measurement results are indicated by white bars in FIG. In other words, a rectangular cylindrical air conditioning duct with the partition wall between the main duct and sub-duct removed is manufactured, and the wind speed (air volume) is measured using an anemometer when no air volume adjusting member is used. The results are shown by white bars in FIG.

  From this result, the wind speed from the outlet member 105 is considerably increased at the site (measurement points # 43 and # 42) in the vicinity of the center of the vehicle where the conditioned air is blown from the air conditioner into the air conditioning duct. On the other hand, the wind speed from the outlet member 105 is considerably slow at the part (measurement points # 41 to # 39), and turbulence is generated in the duct from the part near the center to this part. It can be made. Thereafter, the wind speed of the outlet member 105 is stabilized, but gradually decreases toward the vehicle end. And since the edge part of the air-conditioning duct was closed, it was confirmed that the air pressure in the air-conditioning duct becomes high near the edge part, and the wind speed from the outlet member 105 tends to increase again.

  Therefore, the inventor has a range in which the inside of the air conditioning duct directly under the air conditioner is assumed to be in a turbulent state because the variation in the wind speed between the end of the vehicle and the center of the vehicle is not as great as expected. When the temperature exceeds the point where the wind speed from the blowout member is the lowest (measurement point # 36), the vehicle is substantially cross-sectionally oriented between the measurement point # 34 and the measurement point # 35 in the vicinity (right and left sides of the vehicle). If the air volume adjustment member having a high opening ratio is arranged so as to be substantially perpendicular to the vehicle longitudinal direction along the direction), the air volume adjustment member becomes a resistance without hindering the smooth flow of the air-conditioning air in the air-conditioning duct. As a result, the pressure in the duct on the center side of the airflow adjustment member is increased, the turbulent flow in the duct on the center side of the vehicle body is stabilized, the air speed from the outlet is leveled, and the airflow adjustment is also performed on the downstream side of the airflow adjustment member. Material Because air flow is reduced to the next downstream conceived that it is possible to suppress an increase in wind speed from the blowing mouth, in which none of the present invention.

  Actually, the air volume adjusting member having a high opening ratio that is substantially vertical in the left-right direction of the vehicle is substantially arranged in the left-right direction of the vehicle on the downstream side (between # 34 and # 35) in the vicinity of the portion where the wind speed from the air-conditioning wind blowing portion is the lowest. When the air speed adjustment member (specifically, the aperture ratio 83%) was arranged vertically and the wind speed was measured, as shown by the black bar in FIG. 7, the air-conditioning wind blown from the blowing member was measured. It was confirmed that fluctuations in wind speed could be improved.

  It is an object of the present invention to provide an air conditioning system for a railway vehicle that can obtain a uniform wind speed distribution from an outlet member of conditioned air from a vehicle central portion where an air conditioning device is provided to a vehicle end portion. To do.

  According to the first aspect of the present invention, an air conditioner is provided in a central portion on the roof of the vehicle, and air-conditioning air is sent in the vehicle front-rear direction through an air-conditioning duct arranged in the vehicle front-rear direction, and communicates with the air-conditioning duct. The air conditioning system of the railway vehicle is supplied with conditioned air into the passenger compartment through the air conditioning duct, and the air conditioning duct forms a single air passage having a rectangular cross section surrounded by the duct wall surface. An air volume adjusting member having a high opening ratio that adjusts the conditioned air from the air conditioner is provided at each of the front and rear sides of the vehicle center portion in the middle of the vehicle. Here, the air volume adjusting member provides a function of adjusting the air volume (air velocity) of the conditioned air blown out through the air outlet member by being provided in the middle of the ventilation path. Here, a high aperture ratio means that the aperture ratio exceeds 80%.

  If it does in this way, the partition wall part between a main duct and a sub duct will be abolished, and an air conditioning duct can be made into the simple structure which has the cross-sectional rectangular shape enclosed by a duct wall surface, and has a single ventilation path. At the same time, the partition wall between the main duct and the sub-duct is eliminated, so the duct area can be effectively expanded, and an air volume adjusting member is provided in the middle of the ventilation path to blow the conditioned air directly from the air-conditioning duct. By doing so, a uniform wind speed distribution (air volume distribution) from the outlet member can be obtained from the center of the vehicle to the end of the vehicle.

  In addition, by removing the partition wall (plenum chamber) between the main duct and the sub-duct, which requires a substantially full length of the vehicle body shown in FIG. Since the structure is simplified, the manufacturing is easy, the cost is low, the weight can be reduced, and at the same time, the inspection and cleaning work in the duct at the time of maintenance can be facilitated.

  In particular, instead of the conventional partition wall portion between the main duct and the sub duct that is long in the longitudinal direction of the vehicle, the air volume adjusting member is arranged in the substantially vertical direction of the vehicle in the substantially cross-sectional direction of the vehicle (the left-right direction of the vehicle). Since the center of the vehicle is sandwiched between the front and rear of the vehicle, the speed of the conditioned air blown from the air outlet member is adjusted to simplify the structure and reduce the weight. It is advantageous in planning.

  According to a second aspect of the present invention, it is desirable that the air volume adjusting member is a plate-like net member having a wind adjusting effect.

  In this way, when the air volume adjusting member is formed of a punching plate, the aperture ratio is 50% even if a punching plate having a high aperture ratio is adopted, and in the case of a louvered air conditioning plate, the aperture ratio is Some are higher than the punching plate, but the opening ratio is not as high as the mesh member, and the structure is complicated and heavy. If it is a net-like member, the aperture ratio is higher than 80%, and the weight is light, and the air volume adjustment member has the purpose of only giving some resistance to the conditioned air flowing in the air conditioning duct. suitable. Another advantage is that it is relatively easy to select a suitable air flow rate adjusting member by changing the density of the wire constituting the mesh portion of the mesh member and the thickness of the wire.

  According to a third aspect of the present invention, the air-conditioning duct has a rectangular cylindrical shape, and an inspection port that can be opened and closed by an inspection lid is provided on the lower surface portion corresponding to the position where the air volume adjusting member is provided. It is desirable that

  If it does in this way, an air volume adjustment member can be attached or removed through an inspection opening, and inspection and cleaning work in a duct will also become easy work by adjusting the size of an inspection opening.

  According to a fourth aspect of the present invention, the outlet member includes a first member having a slit-like outlet hole extending in the vehicle front-rear direction and restricting the air volume, and a plurality of members extending in the vehicle left-right direction and extending in the vertical direction. A louver-shaped second member that has a vertical plate portion and adjusts the wind direction, and the second member communicates with the blowing hole between the adjacent vertical plate portions from the blowing hole in the vehicle left-right direction. It is desirable to have a wide blow hole.

  If it does in this way, the function which changes the flow of the air-conditioning wind in the air-conditioning duct which goes to the direction of vehicles front and rear to a horizontal direction and a downward direction can be given to an outlet member by simple structure.

  According to a fifth aspect of the present invention, the air outlet member includes a board portion that extends in a horizontal direction and covers a lower side of the air conditioning duct, and a plurality of vertical plates that extend parallel to the vehicle left-right direction and extend in the vertical direction on the board portion. And a slit-like blowout extending in the vehicle front-rear direction to the board portion. It can be set as the structure by which the hole is provided.

  If it does in this way, it is possible to make the lower surface of an air-conditioning duct into a concealment part completely, and the inspection port for the cleaning in a duct can be chosen freely suitably. Therefore, it can contribute to the improvement of cleanability.

  According to a sixth aspect of the present invention, the outlet member includes a first member extending in the vehicle front-rear direction and having a slit-like outlet hole, and a louver-like second member provided above the first member, The second member includes a side plate portion located on both left and right sides of the blowing hole and extending in parallel with the vehicle front-rear direction, and a plurality of vertical plates provided between the side plate portions and extending in the vehicle left-right direction and extending in the vertical direction. It can also be set as the structure which has a part.

  In this way, similarly to the fourth aspect, with a simple structure, the outlet member can have a function of changing the flow of the conditioned air in the air-conditioning duct in the longitudinal direction of the vehicle to the lateral direction and the downward direction.

  As described in claim 7, the first and second members are made of a light alloy shape, and the slit-shaped blowing holes of the first member cut the light alloy shape. It can be set as the structure formed by.

  In this way, the structure can be simplified because the blowout port member can be manufactured simply by cutting the light alloy profile.

  According to an eighth aspect of the present invention, the first and second members may be configured by FRP and coupled by bonding or fastening by screws.

  In this way, since the first and second members that are separate members are configured by FRP, the color and the like can be changed for each.

  As described above, the present invention eliminates the partition wall portion between the main duct and the sub duct, and converts the air conditioning duct from the air conditioning duct having a rectangular cross section surrounded by the duct wall surface and having a single ventilation path. It can be a simple structure that blows out directly. In addition, since an air volume adjustment member is provided in the middle of the ventilation path, the center of the vehicle can be adjusted without using a sub-duct that has the role of adjusting the flow rate of the blown air by changing the flow of the conditioned air from the vehicle longitudinal direction to the sideways or downward in the air conditioning duct. A uniform wind speed distribution from the outlet can be obtained from the outlet to the end of the vehicle. In particular, instead of the partition wall between the main duct and the sub duct, it is only necessary to provide an air volume adjusting member with a high opening ratio at each one front and rear of the vehicle for adjusting the wind speed, so that the structure is simplified (simplified) and lightweight. Can also be achieved.

1 shows a schematic configuration (right half) of an air conditioning system for a railway vehicle according to the present invention, where (a) is a cross-sectional view, (b) is a view in the direction of arrow A in FIG. 1 (a), and (c) and (d) are balloons. It is a perspective view of a mouth member. The other embodiment about the air conditioning system of the railway vehicle which concerns on this invention is shown, (a) is sectional drawing, (b) is a B direction arrow line view of FIG. 2 (a), (c) is a ceiling center grille. It is a perspective view. The site | part which attached the plate-shaped air volume adjustment member in the air-conditioning duct is shown, (a) is sectional drawing, (b) is a C direction arrow line view of Fig.3 (a). The other embodiment about the air-conditioning system of the railway vehicle which concerns on this invention is shown, (a) is sectional drawing, (b) is a D direction arrow line view of Fig.4 (a), (c) is an outlet member. The figure seen from the upper side, (d) is the figure which looked at the outlet member from the lower side. (A) The figure which shows schematic structure of the conventional air conditioning system of a railway vehicle, (b) is explanatory drawing which shows the relationship between the partition wall and wind speed distribution in the system. The schematic structure (right side half) of the conventional air conditioning system of a rail vehicle is shown, (a) is sectional drawing, (b) is an E direction arrow view of FIG. 6 (a), (c) is explanatory drawing of a partition wall part It is. It is a figure which shows the wind speed distribution measured about embodiment shown to Fig.1 (a) (b).

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  As shown in FIG. 1, an air conditioning system for a railway vehicle according to an embodiment of the present invention is provided with an air conditioner (not shown) on a roof structure 2 of the railway vehicle 1, and air conditioning from the air conditioning apparatus. Wind is sent in the longitudinal direction of the vehicle through a rectangular cylindrical air conditioning duct 3 arranged in the longitudinal direction of the vehicle, and the conditioned air is supplied into the passenger compartment 6 through the outlet member 4 communicating with the air conditioning duct 3.

  This air conditioning duct 3 has a rectangular cross section (square tube shape) surrounded by the duct wall surface, and has a single ventilation path 3a, and in the middle of the ventilation path 3a, the flow of the conditioned air is blocked. A plate-like air volume adjusting member 5 is provided at each of the front and rear positions with the vehicle central portion interposed therebetween.

  The air volume adjusting member 5 is arranged to be orthogonal to the longitudinal direction (vehicle longitudinal direction) of the ventilation path 3a, and is made of, for example, a net-like member having a wind adjusting effect so as not to hinder ventilation. That is, the air velocity (air volume) of the air-conditioning air blown out through the air outlet member 4 is adjusted by providing a certain amount of resistance without interfering with ventilation. The air volume adjusting member 5 is provided because the air-conditioning air is excessively emitted in the vicinity immediately below the air-conditioning apparatus, and the air-conditioning air is hardly emitted in the area adjacent to the area (see the white bar in FIG. 7). This is because air conditioned air is also emitted from the part. The reason why the air-conditioning air is less likely to come out is considered as follows. It is considered that the conditioned air coming out of the air conditioner hits the lower plate of the duct and bounces once and proceeds toward the vehicle end while facing upward, so that the direction of the conditioned air is upward in the region adjacent to the air conditioner.

  The position at which the air volume adjusting member 5 is provided is determined by measuring the air speed of the conditioned air blown from each air outlet member 4 at a plurality of measurement points, and the air outlet at a position corresponding to the measurement point at which the air speed tends to decrease. It is provided on the downstream side of the member 4. Specifically, after providing the downstream side of the outlet member 4 at the position corresponding to the measurement point where the wind speed tends to decrease, fine adjustment of the position to be provided is performed while measuring the wind speed.

  As a result, the air volume adjusting member 5 acts as a resistance without impeding the smooth flow of the air-conditioning air by the air volume adjusting member 5, and the wind speed at the portion where the air speed from the outlet member 4 is reduced increases. A uniform wind speed distribution (and hence an air volume distribution) is obtained from the vehicle center to the vehicle end (see the black bar in FIG. 7).

  Further, it is considered that the portion where the wind speed is lowered is a turbulent flow area near the air conditioner, and by providing the air volume adjusting member 5, the excess or deficiency of the wind speed near the air conditioner can be easily adjusted.

  The outlet member 4 is provided on the lower surface side of the air-conditioning duct 3 on the outer side of the vehicle via a sponge 7, and extends in the vehicle front-rear direction to form a slit-like upper outlet hole 8a that restricts the air volume (first member 8). 1) and a louver-like lower member 9 (second member) provided on the lower side of the upper member 8 and forming a lower blowing hole 9a wider in the vehicle left-right direction than the upper blowing hole 8a. It has a two-layer structure that is arranged one above the other.

  The upper member 8 includes a horizontal plate portion 8A in which an upper blowing hole 8a is formed, a pair of vertical plate portions 8B and 8B extending vertically downward from both side edges of the horizontal plate portion 8A, and the vertical plate portions 8B and 8B. And flange portions 8C and 8C extending in opposite directions from the lower edge. On the other hand, the lower member 9 includes a horizontal plate portion 9A joined to the lower surface of the horizontal plate portion 8A, and a plurality of lower members 9 provided on the lower surface of the horizontal plate portion 9A at a constant interval and extending in the vehicle left-right direction and extending in the vertical direction. The horizontal plate portion 9A is notched with a width corresponding to the width of the upper blowing hole 8a in the horizontal plate portion 9A at a predetermined interval in the vehicle front-rear direction. A space between the vertical plate portions 9B (a space surrounded by the two vertical plate portions 9B and the vertical plate portions 8B and 8B) communicates with the upper blowing hole 8a communicating with the inside. In other words, only the portion where the notch is formed is a blowout port portion for blowing the conditioned air through the space between the vertical plate portions 9B. Thereby, the function equivalent to a plenum chamber structure can be given.

  A fluorescent lamp 11 is provided next to the outlet member 4 so as to extend in the vehicle front-rear direction, and a side ceiling 12 is disposed outside the fluorescent lamp 11. Further, a cross flow fan 21 is provided at the center of the vehicle, and the wind from the cross flow fan 21 has the same shape as the lower member 9 when blown out through the blowing window portion 22 corresponding to the upper blowing hole 8a. The air is rectified by the air conditioning member 23.

  According to said structure, the airflow adjustment member 5 becomes resistance, without arrange | positioning the plate-shaped airflow adjustment member 5 in the downstream of the site | part where the wind speed has fallen, without disturbing the flow of air-conditioning wind. The wind speed of the part where the wind speed is reduced can be increased, and the change in the wind speed from the vehicle center to the vehicle end can be reduced (see the black bar in FIG. 7). As a result, if the flow of the conditioned air is changed from the longitudinal direction of the ventilation path 3a to the vertical direction using the air outlet member 4, the air volume of the air conditioned air blown from the air conditioned air outlet in the vehicle longitudinal direction is It becomes almost constant over the vehicle longitudinal direction.

  In the above embodiment, the lower member 9 of the outlet member 4 and the air conditioning plate 23 of the cross flow fan 21 are configured separately, but as shown in FIG. The upper member 8 may be omitted. In this case, the ceiling center grille 31 has a horizontal plate portion 31A and a vertical plate portion 31B provided at regular intervals on the lower surface of the horizontal plate portion 31A. , A notch 31 a having a width corresponding to the width of the slit-like upper blowing hole 3 b of the blowing window portion 22 and the air conditioning duct 3 is provided at a predetermined interval, and the notch 31 a of the ceiling center grill 31 is formed. Only in the portion, it is a blow-off port portion that blows out air-conditioned air through the space between the vertical plate portions 31B.

  In the above-described embodiment (see FIG. 1), since the inspection port serves as a finding surface of the cabin, its position and size cannot be freely determined. The horizontal plate portion 31A of 31 can be used as a completely concealing portion, and a portion where the inspection port 41 for cleaning the inside of the duct is provided can be appropriately selected. Therefore, it can contribute to the improvement of cleanability. Further, in this case, as shown in FIG. 3, an inspection port 41 that can be opened and closed by an inspection lid 42 is formed on the lower surface portion of the air conditioning duct 3 corresponding to the position where the plate-like air volume adjusting member 5 is provided. It can also be provided.

  As shown in FIGS. 4A to 4D, the upper member 52 (second member) and the lower member 53 (first member) constituting the outlet member 51 are light alloy shapes. It is also possible to have a structure in which a slit-like blowing hole 53a extending in the vehicle front-rear direction is formed by cutting the lower member 53. The upper member 52 has side plate portions 52A, 52A whose upper ends are in contact with the air conditioning duct 3 and extend parallel to the vehicle longitudinal direction, and vertical plate portions 52B, 52B,... The space surrounded by the side plate portions 52A and 52A and the vertical plate portions 52B and 52B is a louver-like member that functions as the air-conditioning air outlet 53a. In this way, the structure can be simplified because the light alloy profile can be manufactured simply by cutting.

  Instead of the light alloy profile, it is also possible to configure the outlet member by FRP so that the upper member 52 and the lower member 53 are joined by bonding or fastening with screws. By comprising in this way, since the upper member 52 and the lower member 53 are FRP with another part, it becomes possible to change a color etc. easily, respectively by the contact using an adhesive, or a screw Both members can be coupled by fastening. Thus, the degree of design freedom can be increased.

DESCRIPTION OF SYMBOLS 1 Rail vehicle 2 Roof structure 3 Air-conditioning duct 3a Ventilation path 4 Outlet member 5 Air volume adjustment member 6 Car compartment 7 Sponge 8 Upper member (1st member)
8a Upper blowing hole 9 Lower member (second member)
9a Lower blowing hole 9B Vertical plate portion 11 Fluorescent lamp 12 Side ceiling 21 Cross flow fan 22 Blowing window portion 23 Air conditioning plate 31 Ceiling central grill 31B Vertical plate portion 42 Inspection lid 52 Upper member 52A Side plate portion 52B Vertical plate portion 53 Lower member 53a Slit-shaped blowout hole

Claims (8)

An air conditioner is provided in the central part on the roof of the vehicle, air conditioned air is sent in the vehicle front-rear direction through an air-conditioning duct arranged in the vehicle front-rear direction, and air conditioned air is blown into the vehicle interior through a blowout member that communicates with the air-conditioning duct. An air conditioning system for a railway vehicle to be supplied,
The air-conditioning duct forms a single ventilation path having a rectangular cross-section surrounded by the duct wall surface. An air conditioning system for a railway vehicle, characterized in that an air volume adjusting member having a high opening ratio for adjusting conditioned air from an air conditioner is provided.
2. The air conditioning system for a railway vehicle according to claim 1, wherein the air volume adjusting member is a plate-like net-like member having a wind adjusting effect.
The air-conditioning duct has a rectangular cylindrical shape, and an inspection port that is closed by an inspection lid so as to be openable and closable is provided on a lower surface portion corresponding to a position where the air volume adjusting member is provided. The railway vehicle air conditioning system according to 1 or 2.
The air outlet member has a first member having a slit-like air outlet hole extending in the vehicle front-rear direction and restricting the air volume, and a plurality of vertical plate portions extending in the vertical direction in parallel with the vehicle left-right direction and adjusting the wind direction. A louver-shaped second member that
4. The second member according to claim 1, wherein a space between adjacent vertical plate portions is a blowout hole that communicates with the blowout hole and is wider in the vehicle left-right direction than the blowout hole. The air conditioning system for a railway vehicle according to any one of the above.
The blowout member is formed by a substrate portion extending in the horizontal direction and covering the lower side of the air conditioning duct, and a plurality of vertical plate portions extending parallel to the vehicle left-right direction and vertically extending on the substrate portion. It is configured to function as an air conditioning plate portion of a crossflow fan located on the center side in the left-right direction,
The air conditioning system for a railway vehicle according to any one of claims 1 to 3, wherein the board portion is provided with a slit-like blowing hole extending in the vehicle front-rear direction.
The outlet member includes a first member extending in the vehicle front-rear direction and having a slit-like outlet hole, and a louver-like second member provided on the upper side thereof,
The second member includes a side plate portion located on both left and right sides of the blowing hole and extending in parallel with the vehicle front-rear direction, and a plurality of vertical plates provided between the side plate portions and extending in the vehicle left-right direction and extending in the vertical direction. The air conditioning system for a railway vehicle according to any one of claims 1 to 3, further comprising a unit.
The first and second members are made of a light alloy shape, and the slit-shaped blowout holes of the first member are formed by cutting the light alloy shape. The air conditioning system for a railway vehicle according to claim 6.
  The railway vehicle air conditioning system according to claim 6, wherein the first and second members are made of FRP and are joined by bonding or fastening with screws.

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