The present invention relates to a foreign matter removing apparatus for removing foreign matters in the vicinity of a track branch of a railway through air injection, and to a nozzle used in this apparatus. Particularly, the present invention relates to a foreign matter removing apparatus at a track branch for removing foreign matters in the vicinity of a tongue rail through air injection, and to a nozzle used in this apparatus.
There has been known such a conventional problem that, when vehicles pass through a track branch, frozen snow drops down due to vibrations of the vehicles, or dropping frozen snow hits ballast, so that the ballast jumps up as scattered stones or the like; and thus the dropping frozen snow or the scattered stones may be caught between a stock rail and a tongue rail, which hinders switching of the tongue rail. Hence, various developments and studies have been conducted on foreign matter removing apparatuses for use at a track branch.
For example, Patent Literature 1 discloses a foreign matter removing apparatus at a track branch that removes foreign matters between a stock rail and a tongue rail so as to prevent switching of the track branch from being disable due to dropping frozen snow or scattered stones.
The foreign matter removing apparatus at a track branch described in Patent Literature 1 is a foreign matter removing apparatus at a track branch that removes foreign matters having dropped between the stock rail and the tongue rail at the track branch, wherein each piping unit is installed to a side surface of the stock rail opposing the tongue rail in accordance with a length of the branch track, air injection nozzle units each having multiple injection ports are disposed at multiple positions with intervals in the longitudinal direction of this piping unit such that the injection orientation of each nozzle unit is slightly directed to the tongue rail, a pressured air source device is provided in the vicinity of the track branch, and the pressured air source device is connected to each pressured air supply passage through an opening/closing switching mechanism thereof so as to supply the pressured air to each piping unit.
Patent Literature 2 discloses a foreign matter removing apparatus at a track branch capable of removing foreign matters between rails at a crossing section of the track branch.
The foreign matter removing apparatus at a track branch described in Patent Literature 2 is installed at a track branch including stock rails, and tongue rails that can come into contact with or apart from the stock rails, and removes foreign matters having dropped between the rails by injecting compressed air, wherein this foreign matter removing apparatus is disposed at a crossing section where rails intersect each other, which is located at a backward position opposite to a frontward position of the track branch where the stock rail and the tongue rail are able to come into contact with each other, and the foreign matter removing apparatus includes a nozzle unit for injecting compressed air, and an air supply device for supplying the compressed air to the nozzle unit, wherein the nozzle unit is disposed in the frontward position in the crossing section, and includes injection ports having apertures for injecting the compressed air backward in the crossing section.
Both the foreign matter removing apparatuses of Patent Literature 1 and Patent Literature 2 at the track branches are very useful for removing dropping frozen snow and scattered stones.
Patent Literature 1 discloses an injection port having a round hole as an air injection port 17 of the nozzle unit 3, and Patent Literature 2 discloses a large-diameter injection port 22 and a small-diameter injection port 23 at the crossing section.
In both cases of using the air injection port 17 of Patent Literature 1 and the small-diameter injection port 23 of Patent Literature 2, there is such a problem that these injection ports are difficult to be installed at locations near private houses in the neighbor because of noises caused by injecting the compressed air. Consequently, although installation of these apparatuses has been desired in many areas and many places, progress in installation of the apparatuses is still insufficient in these places.
The nozzle unit of the foreign matter removing apparatus described in Patent Literature 2 includes a number of small-diameter injection ports and three large-diameter injection ports, as shown in FIG. 4 of Patent Literature 2. There is such a problem that this apparatus is difficult to be installed at a place in the vicinity of private houses in the neighbor because of noises caused at the time of injecting the compressed air from these many small-diameter injection ports. As a result, although installation of this apparatus has been desired in many areas and in many places, progress in installation of this apparatus is still insufficient in these places.
An object of the present invention is to provide a foreign matter removing apparatus at a track branch, and a nozzle used in this apparatus which are capable of sufficiently securing foreign matter removing performance as well as significantly reducing generated noises.
(1)
A foreign matter removing apparatus at a track branch according to one aspect of the present invention is a foreign matter removing apparatus at a track branch for removing foreign matters having dropped between a stock rail and a tongue rail at the track branch, the foreign matter removing apparatus including: a piping unit for supplying compressed air; and at least one injection nozzle element for injecting the compressed air supplied from the piping unit; wherein the injection nozzle element includes: a cylindrical housing disposed on an opposite side of the injection nozzle element to the tongue rail, and having a sloped portion approaching more closely to the stock rail toward a nozzle front end of the injection nozzle element; and slits extending through an inside of the cylindrical housing in a central axis direction thereof so as to inject the compressed air, at least some of the slits opening in the sloped portion, and none of the slits opening toward the stock rail, and a central axis of the injection nozzle element is oriented from a direction along the stock rail toward the tongue rail at a predetermined angle.
In the foreign matter removing apparatus at a track section, the compressed air supplied from the piping unit is injected from the slits extending through the inside in the central axis direction, and at least some of the slits open in the sloped portion, and none of the slits open toward the stock rail. The cross sectional shape of each slit may be oval in addition to rectangular.
The present inventors have found that noises are caused because of the air injection port 17 of Patent Literature 1 and the small-diameter injection port 23 of Patent Literature 2 both having simple round holes.
In addition, it has been confirmed through an experiment that, if configuring a nozzle to have a conical shape, and also configuring each injection port supplying the compressed air to have a slit shape that opens in its conical side surface, it is possible to sufficiently secure the injection pressure while greatly reducing the noises, compared with the case of using the injection ports injecting the compressed air each having a simple round hole. Despite this, if this finding is directly applied to the foreign matter removing apparatus at a track branch, the injected compressed air collides with the stock rail, which causes the noises.
By using such slits that extend through the inside in the central axis direction, at least some of which open in the sloped portion, but none of which open in the surface thereof facing the stock rail, the slits or some of the slits opening in the sloped portion attain the same foreign matter removing effect as that of the slits opening in the conical side surface, as well as the injection pressure can be sufficiently secured while greatly reducing the noises.
On the other hand, because no slits open in the surface thereof opposite to the stock rail, the same effect as that of the slits opening in the conical side surface cannot be attained, but the injected compressed air is prevented from colliding with the stock rail, thereby reducing the noises caused by the collision.
The sloped portion may be a plane surface or a curved surface, and the cross sectional shape of each slit may be rectangular, oval, or polygonal including′ triangle.
(2)
In the foreign matter removing apparatus at a track branch, the sloped portion may be formed by a plane surface extending from a top surface of the columnar housing toward a circumferential side surface thereof.
In this case, since only beveling is required at the time of machining the injection nozzle element, it is possible to reduce generation of the noises while significantly reducing production cost compared with the case of machining of a curved surface such as a conical shaped side surface. Specifically, the position and the dimension of each slit opening in the sloped portion become changed through the beveling, but the slits are obliquely cut, which is similar to the case of the curved surface, so that it is possible to sufficiently secure the injection pressure while significantly reducing the noises,
(3)
In the foreign matter removing apparatus at a track branch, the piping unit may include a rectangular tube disposed on a side surface of the stock rail opposite to the tongue rail, the injection nozzle element may be disposed to one or both of an upper side and a lower side of the piping unit, and the plane surface of the sloped portion may be provided within a projected area on an upper surface or on a bottom surface of the piping unit.
In this case, it is possible to prevent, interference with the tongue rail while securing installation space for the injection nozzle element,
(4)
In the foreign matter removing apparatus at a track branch, the slits may be radially arranged at multiple positions around an axial center of the cylindrical housing.
In this case, it is possible to secure a greater distance between the two adjacent slits compared with the case of arranging the slits in the top surface of the cylindrical housing in a grid form. As a result, the compressed air injected from each slit hardly interferes each other, and the air flow can be prevented from being disturbed, thereby further reducing the noises. Each slit may have a cross sectional shape of a rectangle or an oval alone, or in combination thereof.
(5)
In the foreign matter removing apparatus at a track branch, a plurality of the injection nozzle elements each having the same shape may be provided, and one of the injection nozzle elements may have an injection direction different from an injection direction of another of the injection nozzle elements.
In this case, by setting the injection direction of each injection nozzle element to be different from each other, it is possible to increase the injection area, to secure the removal of foreign matters in a wide range, and to commonly use the injection unit, which makes it easier to manage product components on the manufacturing basis.
(6)
A foreign matter removing apparatus at a track branch according to another aspect of the present invention is a nozzle for a foreign matter removing apparatus at a track branch mounted at a track branch of rails so as to remove foreign matters having dropped between rails by injecting compressed air, the nozzle for a foreign matter removing apparatus at a track branch including: an injection housing of a conical trapezoid disposed at a front position of a crossing section where the rails intersect, each other; one or multiple slits formed in a side surface of the injection housing so as to inject the compressed air toward a back position of the crossing section; and a guide unit for guiding the compressed air from a compressed air introduction port of the injection housing through an inside of the injection housing to the one or multiple slits.
The present inventors have found that noises are caused because of the air injection port 17 of Patent Literature 1 and the small-diameter injection port 23 of Patent Literature 2 both having simple round holes.
In addition, it has been confirmed through an experiment that, if configuring a nozzle to have a conical shape, and also configuring each injection port supplying the compressed air to have a slit shape that opens in its conical side surface, it is possible to sufficiently secure the injection pressure while greatly reducing the noises, compared with the case of using the injection ports injecting the compressed air each having a simple round hole. Based on this finding, further improvement has been made which has disposed a guide unit inside the injection housing. Specifically, it is possible to allow the compressed air to flow along the guide unit, thereby reducing abrupt collision of the compressed air with the inner wall of the injection housing, and suppressing disturbance of the air flow injected from the slits. Accordingly, it is possible to significantly reduce the noises caused by injecting the compressed air while maintaining the pressure at the time of injecting the compressed air.
The cross sectional shape of each slit may be an oval, or a polygon including a triangle other than a rectangle.
(7)
In the foreign matter removing apparatus at a track branch, the guide unit may have a conical shape.
The guide unit may be formed in a pyramid shape, a simple sloped surface, or a curved slope surface other than a conical shape. If a number of slits are provided, and each slit has a conical shape, it is possible to more uniformly flow the compressed air to each slit along the conical portion compared with the case of using a guide unit having a pyramid shape or the like, so that abrupt collision of the compressed air with the inner wall of the injection housing can be reduced, thereby suppressing disturbance of the air flow injected from each slit formed in the side surface. Accordingly, it is possible to greatly reduce the noises caused by injecting the compressed air.
(8)
A nozzle used in a foreign matter removing apparatus at a track branch according to another aspect of the present invention is a nozzle used in a foreign matter removing apparatus at a track branch for removing foreign matters having dropped between a stock rail and a tongue rail at the track branch, the nozzle including: a piping unit for supplying compressed air; and at least one injection nozzle element for injecting the compressed air supplied from the piping unit; wherein the injection nozzle element includes: a cylindrical housing disposed on an opposite side of the injection nozzle element to the tongue rail, and having a sloped portion approaching more closely to the stock rail toward a nozzle front end of the injection nozzle element; and slits extending through an inside of the cylindrical housing in a central axis direction thereof so as to inject the compressed air, at least some of the slits opening in the sloped portion, and none of the slits opening toward the stock rail, and a central axis of the injection nozzle element is oriented from a direction along the stock rail toward the tongue rail at a predetermined angle.
In the nozzle used in the foreign matter removing apparatus at the track branch, the compressed air supplied from the piping unit is injected from the slits extending through the inside in the central axis direction, and at least some of the slits open in the sloped portion, and none of the slits open toward the stock rail. The cross sectional shape of each slit may be oval in addition to rectangular.
The present inventors have found that noises are caused because of the air injection port 17 of Patent Literature 1 and the small-diameter injection port 23 of Patent Literature 2 both having simple round holes.
In addition, it has been confirmed through an experiment that, if configuring a nozzle to have a conical shape, and also configuring each injection port supplying the compressed air to have a slit shape that opens in its conical side surface, it is possible to sufficiently secure the injection pressure while greatly reducing the noises, compared with the case of using the injection ports injecting the compressed air each having a simple round hole. Despite this, if this finding is directly applied to the nozzle used in the foreign matter removing apparatus at a track branch, the injected compressed air collides with the stock rail, which causes the noises.
By using such slits that extend through the inside in the central axis direction, at least some of which open in the sloped portion, but none of which open in the surface facing the stock rail, the slits or some of the slits opening in the sloped portion attain the same foreign matter removing effect as that of the slits opening in the conical side surface, as well as the injection pressure can be sufficiently secured while greatly reducing the noises.
On the other hand, because no slits open in the surface facing the stock rail, the same effect as that of the slits opening in the conical side surface cannot be attained, but the injected compressed air is prevented from colliding with the stock rail, thereby reducing the noises caused by the collision.
The sloped portion may be a plane surface or a curved surface, and the cross sectional shape of each slit may be rectangular, oval, or polygonal including triangle.
Embodiments according to the present invention will be described with reference to drawings, hereinafter. In the first and second embodiments, a foreign matter removing apparatus at a track branch and a nozzle used in this apparatus will be described by using examples of applying them to a track for Shinkansen. The foreign matter removing apparatus at a track branch and the nozzle used in this apparatus may be applicable not only to a track for Shinkansen, but also to other tracks, such as tracks for existing railways, etc.
As shown in
The point section P of
The crossing section C is configured as a region where the wing rails 504, the movable rail 505, and the fixing member 506 are disposed at the back position of the track branch 500.
The lead section L is configured as a region between the point section P and the crossing section C where the lead rails 503 are disposed at a portion where the point section P and the crossing section C are connected to each other.
In the present embodiment, the point section P and the leading section L form a frontward section located at the front position of the track branch 500, and the crossing section C is located at a backward section of the track branch 500 opposite to the frontward section, and forms a region including a portion where the rails intersect each other.
As shown in
The stock rails 501 at the track branch 500 shown in
In general, at the track branch, a railway point (not shown) operates in accordance with an instruction from a controller (not shown) so that each tongue rail 502 moves in the direction of coming into contact with or apart from the stock rails 501, thereby carrying out a switching operation (point switching operation) on the traveling rails at the track branch 500. Accordingly, the railway vehicle can travel in the direction of the branch track line, or in the direction of the main track line.
A configuration of a foreign matter removing apparatus 300 equipped with a nozzle for the foreign matter removing apparatus 100 according to the first embodiment will be described hereinafter.
The nozzle for the foreign matter removing apparatus 100 is disposed between the stock rail 501 and the tongue rail 502 at the track branch 500, as described above. The foreign matter removing apparatus 300 equipped with the nozzle for the foreign matter removing apparatus 100 according to the present embodiment removes foreign matters such as snow and scattered stones having dropped between the stock rail 501 and the tongue rail 502 by injecting compressed air from the nozzle for the foreign matter removing apparatus 100.
As shown in
The air supply device 310 shown in
Specifically, the controller (not shown) transmits a switching instruction for the electromagnetic switching valve 340 based on operation instruction signals transmitted from various equipment such as an operation signal of the railway point (point switching signal), or based on detection results from various sensors, such as a fall sensor (not shown) for fall of snow and foreign matters and a snowfall sensor (not shown). As a result, compressed air is injected from the nozzle for the foreign matter removing apparatus 100 so as to remove the foreign matters. In response to the above point switching signal, a front end portion of each tongue rail 502 comes into contact with or apart from the stock rail 501, and the movable rail 505 comes into contact with or apart from the wing rail 504.
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In addition, as shown in a nozzle for the foreign matter removing apparatus 100e in
In the nozzle for the foreign matter removing apparatus 100, the sloped portion 130 is disposed on the side opposite to the tongue rail 502, and some of the multiple slits 140 open in the sloped portion 130; therefore, it is possible to significantly reduce the generation of the noises while securing pressure required for injecting the compressed air.
Specifically, a noise level can be reduced by half compared with the configuration of employing no sloped portion, and employing injection ports having simple round holes. Reduction in output of the compressed air is approximately 10% to 20%, and thus there is no practical problem, and there is almost no influence on the foreign matter removing performance.
As shown in
The nozzle elements 110 of the nozzle for the foreign matter removing apparatus 100 are configured to be commonly used by simply changing the title angle of each nozzle element 110 (θ1, θ2), alternately, which makes it easier to manage product components on the manufacturing basis.
In the present invention, the stock rail 501 is corresponding to a stock rail; the tongue rail 502 is corresponding to a tongue rail; the nozzles for the foreign matter removing apparatus 100, 100e are corresponding to a foreign matter removing apparatus at a track branch, and nozzles used in this apparatus; the compressed air PA is corresponding to compressed air; the piping 180 is corresponding to a piping unit; each of the nozzle element 110, the nozzle element 110a, the nozzle element 110b, the nozzle element 110c, the nozzle element 110d, and the nozzle element. 110e is corresponding to an injection nozzle element, respectively; the sloped portion 130 is corresponding to a sloped portion or a plane surface; the cylindrical body 161 is corresponding to a cylindrical housing; the slits 140, the slits 140a, the slits 140b, and the slits 140c are corresponding to slits, respectively; the angles θ1, θ2 are corresponding to a predetermined angle and also to an injection direction; the cylindrical body 161 is corresponding to a columnar housing; the top surface 120 is corresponding to a top surface; the slits 140a and 140b are corresponding to a rectangular shape and also to an oval shape; and the arrangement of the slits 140 is corresponding to radial arrangement of the multiple slits around the axial center,
As shown in
The point section P of
The crossing section C is configured as a region where the wing rails 504, the movable rail 505, and the fixing member 506 are disposed at the back position of the track branch 500.
The lead section L is configured as a region between the point section F and the crossing section C where the lead rails 503 are disposed at a portion where the point section P and the crossing section C are connected to each other.
In the present embodiment, the point section P and the leading section L form a frontward section located at the front position of the track branch 500, and the crossing section C is located at a backward section of the track branch 500 opposite to the frontward section, and forms a region including a portion where the rails intersect each other.
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The stock rails 501 at the track branch 500 shown in
It is configured that the movable rail 505 of the crossing section C is allowed to be displaced along with the movement of the tongue rail 502 in accordance with the operation of the railway point (not shown), and becomes oscillatingly displaced using the fixing portion as a fulcrum structure so that the front end portion of the movable rail 505 comes into contact with or apart from the wing rail 504.
In general, at the track branch, a railway point (not shown) operates in accordance with an instruction from a controller (not shown) so that each tongue rail 502 moves in the direction of coming into contact with or apart from the stock rails 501, and the movable rail 505 moves at the same time, thereby carrying out a switching operation (point switching operation) on the traveling rails at the track branch 500. Accordingly, the railway vehicle can travel in the direction of the branch track line, or in the direction of the main track line.
The foreign matter removing apparatus 300 equipped with a nozzle unit 110 for the foreign matter removing apparatus 300 according to the second embodiment will be described hereinafter. The foreign matter removing apparatus 300 is mounted to the wing rail 504 in the crossing section C at the track branch 500 as described above.
The foreign matter removing apparatus 300 equipped with the nozzle unit 110 for the foreign matter removing apparatus according to the present embodiment removes foreign matters such as snow and scattered stones having dropped to the wing rail 504, or to the wing rail 504 and the movable rail 505 by blowing the foreign matters away backward of the track branch 500, or by melting the snow through injection of the compressed air PA or the heated air HA from the nozzle unit 110. The present invention is not directed to sending the heated air HA; therefore description thereof will be omitted, hereinafter.
As shown in
The air supply device 310 shown in
Specifically, the controller (not shown) transmits a switching instruction for the electromagnetic switching valve 340 based on operation instruction signals transmitted from various equipment such as an operation signal of the railway point (point switching signal), or based on detection results from various sensors, such as a fall sensor (not shown) for fall of snow and foreign matters and a snowfall sensor (not shown). As a result, compressed air PA is injected from the nozzle unit 110 so as to remove the foreign matters. In response to the above point switching signal, a front end portion of each tongue rail 106 comes into contact with or apart from the stock rail 105 and the movable rail 109 comes into contact with or apart from the wing rail 108.
Not only in accordance with the aforementioned operation instruction signals and the detection results from the various sensors, but also during a time period such as vehicle operation time when the foreign matter removing operation is likely required, the controller (not shown) may be configured to transmit a switching instruction for the electromagnetic switching valve 340 so as to periodically inject the compressed air PA from the nozzle unit 110.
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Consequently, the compressed air PA is smoothly guided in the direction of the air flow PAP by the guide 210, and can be injected from the multiple slits 230. Hence, it is possible to smoothly flow the compressed air PA without disturbing the air flow PAF of the compressed air PA, thereby greatly reducing the noises caused by the nozzle 200. Compared with another example of the nozzle structure described later, the guide 210 having a conical shape can further smoothen the compressed air PA in the direction of the air flow PAF toward every slit 230; therefore it is possible to minimize the noises.
As a nozzle unit 110a shown in
As a nozzle unit 110b shown in
Each of the aforementioned nozzles may be formed by combining part of these nozzles. As another example of the nozzle structure, the guide is not limited to the guides 210, 210a, and 210b, and may also have a half-conical shape, a quadrangular pyramid shape or a part thereof, a circular truncated conical shape or a part thereof, and a truncated square pyramid shape or a part thereof other than a perfect conical shape.
In the present embodiment, the nozzle unit 110 is disposed at a single position, but the present invention is not limited to this, and any number of the nozzle units 110 may be provided.
The nozzle unit 110 is provided with a single nozzle 200, but the present invention is not limited to this, and the nozzle unit 110 may be provided with any number of the nozzles 200.
In the nozzle 200 of the foreign matter removing apparatus 300 according to the present embodiment, it is possible to flow the compressed air PA along the guide 210; therefore, abrupt collision of the compressed air PA with the inner wall of the injection housing can be suppressed, and disturbance of the air flow of the compressed air PA injected from the slits 230 can be reduced, as well. Accordingly, it is possible to significantly reduce the noises caused by injecting the compressed air PA while maintaining the pressure at the time of injecting the compressed air PA. In the other examples of the nozzle structure, it is possible to reduce the noises more than the prior art.
In the foreign matter removing apparatus 300 according to the present embodiment, the wing rail 504 is corresponding to a rail, the track branch 500 is corresponding to a track branch, the compressed air PA is corresponding to compressed air, the crossing section C is corresponding to a crossing section, the conical trapezoid. 201 is corresponding to an injection housing of a conical trapezoid, the slits 230 are corresponding to one or multiple slits, the introduction port. 141 is corresponding to a compressed air introduction port of the injection housing, each of the guides 210, 210a, and 210b is corresponding to a guide unit, respectively, and the nozzle 200 is corresponding to a nozzle for the foreign matter removing apparatus at a track branch.
One preferable embodiment of the present invention has been described as above, but the present invention is not limited thereto. It should be appreciated that other various embodiments can be accomplished without departing from the spirit and scope of the present invention. In addition, the operation and the effect attained by the configuration of the present invention have been described in the embodiments, but the above described operation and effect are examples thereof, and the present invention is not limited thereto.
Number | Date | Country | Kind |
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2011-163335 | Jul 2011 | JP | national |
2011-163601 | Jul 2011 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2012/004773 | 7/26/2012 | WO | 00 | 5/12/2014 |