JP2000043713A - Carriage for porter lift and porter lift using it - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a carriage for a porter lift and the porter lift using it which can carry a snow boarder safely in the case carrying a snow boarder by the porter lift. SOLUTION: This carriage for a porter lift 20 provided on a ski slope and installed on a cable 14 hung across between pulleies and driven is provided with a plate shape slide plate 22 for loading a snow boarder while standing as mounting a board and carrying a snow boarder by sliding on a snow surface and a suspending means 29 for suspending the slide plate 22 from the cable 14.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a porter lift transporter attached to a cable driven between pulleys provided on a slope and a porter lift using the same.

[0002]

2. Description of the Related Art There are many ski resorts in which a half-pipe for snowboarding is built on a slope, reflecting the popularity of snowboarding. The half pipe is formed by excavating the ground into a shape obtained by cutting a cylinder having a length of about 20 m and a diameter of about 10 m in half in the axial direction, and is provided so that the axial direction of the cylinder is along the slope of the slope. (Not shown). The snowboarder slides along the circumference of the half pipe, and gradually descends due to the slope of the slope while repeatedly jumping at both ends of the half pipe. However, since the length of the half pipe itself is considerably shorter than the normal slope, no lift dedicated to the half pipe has been built, and the snowboarder who has finished sliding on the half pipe removes the snowboard, walks and walks the half pipe It is the present condition that it climbs to the summit of. For this reason, it is desired that a short-distance lift necessary only for the snowboarder to slide on the half pipe be installed near the half pipe. In general, when installing a lift with a short distance, it is difficult to install a lift that suspends the transporter from the cable as used for ordinary ski slopes because the equipment is too large and it is difficult Even if the facilities described above are prepared, since users cannot be considered except for snowboarders who slide on half pipes, simpler facilities are desired.

As a simple equipment lift, a so-called porter lift 10 as shown in FIG. 11, which slides and pulls a skier, can be considered. In this drawing, only the up side of the porter lift is shown, and the down side is omitted. Here, a so-called T-bar lift is described as an example of the porter lift. The porter lift 10 has pulleys 12a and 12b installed on pillars 13a and 13b at two places, that is, the top and the bottom of a slope, and an endless cable 14 is routed between the pulleys 12a and 12b. I have. A driving device 1 for rotating the pulley 12b is provided on the pulley 12b at the foot of the mountain.
6 are provided. When the driving device 16 rotates the pulley 12b, the cable 14 is driven between the two pulleys 12a and 12b. Also, the cable 14
So that the pulleys remain parallel to the slope.
The rotors 18a and 18b are provided between a and 12b.

A plurality of porter lift transporters 15 for towing the skier 11 are attached to the cable 14 at predetermined intervals. Transporter for porter lift 15
Includes a wire 19 connecting the cable 14 and the skier 11, and a T-shaped member 17 (hereinafter, referred to as a T-bar) attached to the tip of the wire 19. The skier 11 is pulled by the wire 19 by turning the T-bar 17 around the waist or grasping it by hand, and climbs in the direction of the mountaintop indicated by the arrow A. As described above, the porter lift 10 can transport the skier only by the traction force without suspending the transporter having the seat on the cable 14, so that the number of rotors for supporting the cable 14 is small, and Since the installation height of the cable 14 is lower than that of the hanging type of the seat, the support column may be low, so that the cable 14 can be installed without much labor and at low cost. In addition, there is no need to newly construct a skier's getting on / off section, and the existing slope can be used as it is.

[0005]

However, if a porter lift for a snowboarder is installed as a lift connecting short sections such as a half pipe as described above, the following inconveniences can be considered. That is, the foot of the snowboard is mounted obliquely to the sliding direction of the board.
For this reason, when the snowboarder is transported by the porter lift, the snowboarder being transported must always face diagonally, especially for beginners, it is difficult to slide straight and there is a risk of falling etc. is there.
Furthermore, since the snowboard has both feet mounted on a single board, remove the foot located on the back side of the board from the board except when gliding, and kick the snow surface with this removed foot and move it I have. Even when transported by a porter lift, it is necessary to kick the snow surface with one foot to approach the porter lift before being transported by the porter lift, and after transporting it is necessary to kick the snow surface with one foot and leave the porter lift, so snowboarders Must remove one foot from the board. As described above, there is a problem that transporting by a porter lift with one foot removed from the board is extremely dangerous because of the risk of falling over.

Accordingly, the present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide a porter lift transporter capable of safely transporting a snowboarder when the snowboarder is transported by the porter lift. To provide a porter lift using

[0007]

The present invention has the following arrangement to achieve the above object. That is, according to the porter lift transporter according to the present invention, a porter lift transporter that is attached to a cable that is driven by being stretched between pulleys provided on a slope, wherein the snowboarder stands while the board is mounted. It is characterized by comprising a plate-shaped sliding board to be mounted, and suspension means for suspending the sliding board from a cable that is driven from the foot of the mountain to the top of the mountain. By adopting this configuration, the snowboarder is transported while riding on the sliding board while wearing the board, so that the snowboarder can be transported safely without skew. In addition, since the unevenness is formed on the sliding surface of the sliding plate along the sliding direction, straight running stability can be improved, and skewing can be further prevented. Further, since the surface on which the snowboarder rides is covered with rubber, the sliding board increases the frictional resistance between the snowboarder and the sliding board, and the snowboarder slides off the sliding board during transportation. Can be prevented.

[0008] Since the bends are formed in the front and rear portions with respect to the sliding direction of the sliding board, even if there are irregularities on the snow surface on which the sliding board slides, it is possible to get over well. Further, the suspension means is provided with an urging means for urging the sliding board upward, and when the snowboarder is not on board, the sliding board is urged upward by the urging member, so that the sliding board becomes snowy. By moving away from the surface, the resistance is lower than when it is always in contact with the snow surface, the driving efficiency is improved, and there is no need to maintain the snow surface on downhill lines. The suspension means includes a fixed arm extending a predetermined distance from the cable, and a rotating arm attached to the fixed arm via a joint that is rotatable about an axis parallel to an axis of the cable. Therefore, even when the groove of the pulley is deep, the fixed arm is turned to the side opposite to the pulley and fitted into the groove, and the rotating arm through the joint is extended downward, so that the fixed arm is well fitted to the pulley. It can be a transporter for a porter lift that fits. Further, in a normal traveling state in which a snowboarder is mounted, the sliding board is attached to the suspension means so that the cable is not located immediately above the sliding board, and the fixed arm is twisted from the normal traveling state. At the same time, since the joint limits the range of rotation between the fixed arm and the rotating arm in order to prevent the cable from rotating toward the pulley, a cable that is not positioned above the occupant's head during normal running is used. The twisting of the cable prevents the pivot arm from being positioned above the occupant's head, and reduces the risk that the cable will fall onto the occupant's head when the cable comes off the pulley.

According to the porter lift of the present invention, 2
Endless cable passed between two pulleys,
Driving means for driving the cable between the two pulleys by rotating the pulleys,
Claim 1, Claim 2, Claim 3, Claim 4, Claim 5,
The porter lift transporter according to claim 6 or 7 is attached to the cable. By adopting this configuration, even if a cheap and simple porter lift is installed at a short distance such as next to a half pipe to transport the snowboarder, there is no danger such as falling down of the snowboarder, and the transport is safe. can do. A guide for twisting the cable so that the fixed arm of the porter lift transporter according to claim 6 or 7 is brought into contact with a position lowered by a predetermined distance from the groove of each of the pulleys, and the fixed arm rotates to the side opposite to the pulley. Is provided, the suspension means can be smoothly inserted into the pulley, and the guide is brought into contact with the lower side of the fixed arm as much as possible. Damage can be prevented.

[0010]

Preferred embodiments of the present invention will be described below in detail with reference to the accompanying drawings. The same components as those described in the related art are denoted by the same reference numerals, and description thereof will be omitted. 1 to 3 show a first embodiment of a porter lift transporter. The porter lift transporter 20 includes a sliding plate 22 on which a snowboarder rides and slides on a snow surface, and suspension means 29 for suspending the sliding plate 22 from the cable 14. The cable 14 is wound between two pulleys on the slope and driven in the direction of arrow A to transport the porter lift transporter 20 between the two pulleys. The sliding plate 22 is formed in a rectangular plate shape that is slightly larger than the size of the board 27 so that the snowboarder 23 can stably ride when the snowboarder 23 rides, and the front and rear ends 22a in the sliding direction. , 22b are formed with a bend that warps to the surface side. Since the bend is formed in the sliding plate 22 in this manner, even when the snow surface is not flat and has unevenness, the front and rear ends of the sliding plate 22 are caught by the unevenness of the snow surface. Without any trouble, it is possible to easily get over the unevenness on the snow surface and perform good sliding.

A sliding surface 24 is formed on the bottom surface of the sliding plate 22 so that the sliding plate 22 can slide smoothly on a snow surface. The sliding surface 24 is formed with irregularities along the sliding direction. In the present embodiment, the unevenness is a member different from that on the sliding surface 24, and a plurality of ridges 28 projecting toward the snow surface side are provided. Since the sliding stability of the sliding plate 22 is improved by forming the unevenness on the sliding surface 24 in this way, skewing and the like can be prevented, and the snowboarder 23 can be safely towed. A rubber pad 2 is provided on the surface side of the sliding plate 22.
5 is pasted. The pad 25 can increase the friction between the snowboarder 23 and the sliding surface of the board 27 so that the board 27 and the sliding board 22 do not slip when the snowboarder 23 rides. It is possible to prevent the vehicle from slipping on the slide plate 22 and falling. The rubber pad 25 also has a function of protecting the sliding surface of the board 27 from being damaged by the surface of the sliding plate 22. The sliding surface 24 is also suitable for being subjected to special processing such that friction on a snow surface is extremely small, such as a ski or snowboard.

The suspension means 29 comprises a towing arm 26, a biasing means 40, a rotating arm 36, and a fixed arm 37. The lower portion of the towing arm 26 is divided into two forks, and the distal ends of the divided forks are attached to the side surfaces of the sliding plate 22 by bolts or the like (not shown). The attachment may be performed by a method such as welding. In addition,
It is desirable that the attachment portion between the suspension means 29 and the slide plate 22 is such that the slide plate 22 is completely fixed to the suspension means 29. If the attachment portion is rotatably provided by the traction force of the cable 14 or the like, if the traction force is suddenly applied to the cable 14, the suspension means 29 will be inclined, and the snowboarder being conveyed while gripping the suspension means 29 will be described. This is because there is a danger that the balance 23 may lose the balance. In addition, since the suspension means 29 is attached to the side surface of the sliding plate 22, the suspension means 29 in a normal traveling state where the occupant is riding is in a straight line shape (a joint 34 described later rotates). If not, the cable 14 is not positioned directly above the slide plate 22, and safety when the cable 14 comes off can be ensured. A cylinder 40 as an example of the urging means 40 is attached to an upper portion of the towing arm 26. The cylinder 40 has a rod 40 a directed upward and a rod end connected to the lower end of the rotating arm 36. The lower end of the cylinder body 40b is connected to the upper end of the traction arm 26. This cylinder 4
0 is provided to normally urge upward.
That is, when the snowboarder 23 does not board, the sliding board 22 is lifted up so that the sliding board 22 does not touch the snow surface. Forty rods 40a extend and the sliding plate 2
2 is grounded on the snow surface.

As described above, the biasing means 40 is provided on the upper part of the towing arm 26, so that when the snowboarder 23 does not board, even if the snow surface has large irregularities, the sliding plate 22 collides with the irregularities. In particular, it is not necessary to level the snow surface on which the sliding plate 22 slides, particularly when the porter lift descends. In addition, the outer periphery of the cylinder 40 is covered with a cover 41 having a hollow inside,
It covers the cylinder 40. The surface of the cover 41 is made of a material such as rubber. For this reason, the snowboarder may grab the cover 41 during boarding. Further, since the cover 41 is provided, even when the rod 40a of the cylinder 40 expands and contracts, the hand is not pinched between the cylinder 40. The upper end surface of the cover 41 is penetrated by the turning arm 36, and the turning arm 36
Are slidably provided. On the other hand, the lower end surface of the cover 41 is fixedly attached to the upper end of the traction arm 26 and the lower end of the cylinder body 40b. Thus, even when the distance between the cable 14 and the snow surface is changed and the cylinder 40 is operated while the snowboarder 23 is holding the cover 41 and riding, the user can grasp the snowboarder 23 with his / her hand. Since the lower distance does not change, the snowboarder 23 can be safely towed.

A joint 34 is provided at the upper end of the rotating arm 36. The joint 34 is rotatable only in one direction, that is, in a direction parallel to the traveling direction (axial line) of the cable 14. The joint 34 is a limited joint and has a limited movable range, and is provided so as to rotate on the arrow B side but not on the broken arrow side. At the upper part of the joint 34, a fixed arm 37 having the grip portion 30 at the distal end is provided. The grip portion 30 is formed in a C-shaped cross section. The cable 14 is gripped by inserting the cable 14 into the center of the C shape, and the porter lift transporter 20 is securely fixed to the cable 14. By connecting the fixed arm 37 and the rotating arm 36 via the joint 34 in this manner, the cable 14 is twisted when the porter lift transporter 20 enters the pulley, as described later, so that the fixed arm 37 Is rotated in a direction away from the pulleys 12a and 12b in a direction opposite to the pulley, so that the porter lift transporter 20 can favorably enter the pulley. The reason for using the limited joint is as follows. That is, during normal traveling with a snowboarder on board, the sliding plate 22 is in contact with the snow surface and does not move laterally in the traveling direction due to the contact resistance.
Although rotation of the cable 4 is not considered, if the cable 14 is detached from the pulley, the cable 14 goes around the occupant's head when the joint 34 rotates to the side opposite to the pulley, which is dangerous. Are provided so as not to rotate in the direction of the dashed arrow with respect to the rotating arm 36.

FIGS. 4 and 5 show a second embodiment of the porter lift transporter. The same components as those in the above-described embodiment are denoted by the same reference numerals, and description thereof will be omitted. The sliding surface 46 which is the back surface of the sliding plate 44 has irregularities. The unevenness is formed by the same member along the sliding direction. Thereby, the straight running stability of the sliding plate 44 during sliding is improved, and skewing and the like can be prevented. The sliding plate 44 is connected to the cable 1 by the suspension means 51.
Hanged from 4. The suspension means 51 includes the towing arm 4.
8, a biasing means 40, a rotating arm 36, and a fixed arm 37. The lower end of the towing arm 48 is fitted into a mounting hole (not shown) formed in the sliding plate 44 and attached. In addition, the towing arm 48 is provided with a bent portion 48a that is bent in the middle portion in the outward direction of the slide plate 44. Since the towing arm 48 is provided with the bent portion 48a, the distance between the body of the snowboarder 23 and the suspension means 51 can be sufficiently separated when the snowboarder 23 rides.

The upper end of the towing arm 48 is attached to a rod 40a, which is the lower end of the biasing means 40. The upper end of the biasing means 40 is connected to the lower end of the rotating arm 36 via a joint 38. The joint 38 is connected to the pivot arm 36 about a direction orthogonal to the sliding direction.
4 and the urging means 40 can be rotated in the direction of arrow C in FIG. In this manner, the suspension means 51 can be bent back and forth with respect to the sliding direction, so that even when the traction force of the cable 14 is suddenly applied to the rotating arm 36, the joint 38 is once rotated and turned. Then, the tractive force is transmitted to the sliding plate 44, so that the shock at the time of transmitting the tractive force can be reduced. The joint 38 is not a universal joint, but can be rotated only in one direction, that is, only rotated about a direction orthogonal to the sliding direction. That is,
Even if the joint 38 is rotatable around a direction parallel to the axial direction of the cable 14, there is no point in rotating the joint 38 in such a direction because the joint 34 is provided. It is dangerous to bend. Further, if the joint 38 is limited and the rotation range is limited so that the sliding plate 44 is not rotated in the direction of the dashed arrow in FIG. Since the rotation arm 36 cannot be bent in the direction in which the rotation is performed, safety can be further improved.

Next, the porter lift 45 using the porter lift transporter 20 of the first embodiment will be described.
FIG. 6 shows a state where the cable 14 is wound around the pulley 12a at the top of the porter lift 45, FIG. 7 is a sectional view of the pulley 12a, and FIG. 8 is a plan view of the pulley 12a. Since the structure of the pulley 12b at the foot of the mountain is the same as the structure of the pulley 12a at the top of the mountain, it is omitted and the description is omitted. The porter lift 45 is connected to the porter lift transporter 2 by rotation of the pulley 12b between the pulley 12a at the top of the slope and the pulley 12b at the foot of the mountain 12b.
0 is being transferred. Further, as shown in FIG. 7, the pulley 12a is provided with a groove 55 into which the cable 14 enters, but if the suspension means 29 is provided so as to extend directly below the cable 14, the suspension means 29 will be an obstacle. Accordingly, the cable 14 cannot be fitted into the groove 55. Therefore,
Conventionally, the pulley 12a is provided with a guide 54 that directs the upper part of the suspension means 29, that is, the fixed arm 37 in the direction opposite to the pulley, that is, in the direction away from the pulley.
The guide 54 is a frustoconical member provided below the pulley 12a. The fixed arm 37 of the porter lift transporter 20 abuts on the guide 54 and twists the cable 14 to rotate the fixed arm 37 toward the anti-pulley side. You can get inside well.

However, in the porter lift 45, the porter lift transporter 20 is replaced by the conventional porter lift transporter 15.
Since the suspension means 29, which is heavier than that of FIG. 11 and extends from the cable 14, abuts on the edge of the guide 54 at a substantially upper portion thereof, the suspension means 29 has a strong impact when contacting the guide 54 due to the principle of leverage. However, there is a problem that the fixed arm 37 is overloaded. So Guide 5
A guide 56 for guiding the suspension means 29 below the position 4 may be provided. The guide 56 is attached to the column 13a below the guide 54 by a mounting arm 57 so as not to rotate, and protrudes outward with a smooth curve from the lower part to the upper part, and from the upstream side to the downstream side. Are formed so as to project outward with a smooth curve. Also, this guide 56
Is provided so as to protrude upstream from the edge of the conventional guide 54, and causes the suspension means 29 to abut before the edge of the guide 54 abuts. With the provision of the guide 56, the fixed arm 37 can be positioned at a lower position than the guide 56 as compared with the conventional case.
Therefore, the impact at the time of contact is weakened by the principle of leverage, and as the cable 14 advances, the fixed arm 37 gradually faces the side opposite to the pulley 12a along the curved surface of the guide 56 (FIG. 7 dashed line). This makes it possible to smoothly enter the suspension means 29 into the groove 55 and prevent the suspension means 29 in the pulley 12a from being deformed or damaged.

Next, as shown in FIGS. 9 and 10, a method for a snowboarder to board a porter lift according to the present embodiment will be described. Here, there are two types of directions in which the feet are fixed on the snowboard: a regular stance that is mounted on the board with the right foot behind and a goofy stance that is mounted on the board with the left foot behind.
According to the transporter for a porter lift according to the present embodiment, the suspension means 29 is provided on the right side in the traveling direction with respect to the sliding direction A. Therefore, in the case of the regular stance shown in FIG. The right foot 31 may approach the sliding board 22 while kicking the snow surface, and the board 27 mounted on the left foot may be lifted while riding on the sliding board 22 while being gripped by the suspension means 40. On the other hand, in the case of the goofy stance in FIG. 10, from the opposite direction to the sliding direction A, approach the sliding plate 22 while kicking the snow surface with the left foot 33 detached from the board 27, and grasp the suspension means 40 from the right foot. It is to be mounted on the sliding board 22. In this case, the front-back direction of the board 27 is opposite to the sliding direction A, but since the suspension means 40 is located in front of the body, there is a place where it can be gripped by hand, so that it is safely towed.

Although various preferred embodiments of the present invention have been described above, the present invention is not limited to these embodiments, and many modifications can be made without departing from the spirit of the invention. Of course.

[0021]

According to the transporter for a porter lift according to the present invention, a plate-like sliding board on which a snowboarder is mounted while standing with a board mounted thereon, and the sliding board is hung from the foot of the mountain to the top of the mountain. Since the snowboarder is provided with the suspension means for suspending from the driving cable, the snowboarder is transported on the sliding board while wearing the board, so that the snowboarder can be transported safely without skewing. In addition, since the unevenness is provided on the sliding surface of the sliding plate, straight running stability can be improved. Furthermore, since the surface on which the snowboarder rides is covered with rubber, the frictional resistance between the snowboarder and the slideboard increases, and the snowboarder slides off the slideboard during transportation. Can be prevented. In addition, since the bends are formed in the front and rear portions with respect to the sliding direction of the sliding board, even if there are irregularities on the snow surface on which the sliding board slides, it is possible to get over well. Further, the suspension means is provided with an urging means for urging the sliding board upward, and when the snowboarder is not on board, the sliding board is urged upward by the urging member, so that the sliding board is snow-covered. The driving efficiency is improved because the resistance is reduced as compared to being constantly in contact with the snow surface at a distance from the surface, and there is no need to maintain the snow surface on a down line. The suspension means includes a fixed arm extending a predetermined distance from the cable, and a fixed arm,
A pivot arm attached via a joint that is pivotable about an axis parallel to the axis of the cable, so that even if the groove of the pulley is deep, the suspension means does not hinder It is put on the pulley. Also, in the normal running state where the snowboarder is mounted, the sliding board is attached to the suspension means so that the cable is not located directly above the sliding board, and the fixed arm is twisted from the normal running state to the pulley side together with the twist of the cable. The joint limits the rotation range between the fixed arm and the rotation arm to prevent rotation, so that the cable that is not positioned above the occupant's head during normal travel is twisted by the cable to allow the rotation arm to ride Therefore, when the cable is detached from the pulley, the risk that the cable falls on the occupant's head can be reduced.

According to the porter lift according to the present invention, 2
Endless cable passed between two pulleys,
A drive means for driving the cable between the two pulleys by rotating the pulleys, and the porter lift transporter is attached to the cable, so that an inexpensive and simple porter lift can be shortened, for example, next to a half pipe. Even when the snowboarder is transported by being installed at a distance, the risk of falling down of the snowboarder can be eliminated and the snowboarder can be transported safely. In addition, since the fixed arm of the transporter for the porter lift is brought into contact with the guide and the cable is twisted so that the fixed arm rotates toward the pulley side, the suspension means can be smoothly inserted into the pulley. Further, since the guide is brought into contact with the lower side of the fixed arm as much as possible, it is possible to prevent the suspension means from being deformed or damaged without giving a strong impact.

[Brief description of the drawings]

FIG. 1 is a side view of a porter lift transporter.

FIG. 2 is a front view of the porter lift transporter shown in FIG.

FIG. 3 is a plan view of a porter lift transporter.

FIG. 4 is a side view of a second embodiment of the porter lift transporter.

FIG. 5 is a front view of the porter lift transporter shown in FIG. 4;

FIG. 6 is a perspective view showing a part of a porter lift using the porter lift transporter.

FIG. 7 is a sectional view of a pulley of the porter lift shown in FIG. 6;

FIG. 8 is a plan view of a pulley of the porter lift shown in FIG.

FIG. 9 is an explanatory view showing a method of boarding on a porter lift in the case of regular stance.

FIG. 10 is an explanatory diagram showing a boarding method on a porter lift in the case of goofy stance.

FIG. 11 is an explanatory view showing a conventional porter lift.

[Explanation of symbols]

 Reference Signs List 20 transporter for porter lift 22 sliding board 23 snowboarder 24 running surface 25 pad 26 traction arm 27 board 29 suspension means 30 gripping part 34 joint 36 rotating arm 37 fixed arm 38 joint 40 biasing member 41 cover 44 sliding plate 45 porter lift 46 Running surface 48 Towing arm 50 Porter lift transporter of second embodiment 51 Suspension means 54 Guide 55 Groove 56 Guide 57 Mounting arm

Claims (9)

[Claims] 1. A porter lift transporter attached to a cable driven between pulleys provided on a slope, wherein the snowboarder is mounted on a snowboard while standing on a board, and slides on a snow surface. A transporter for a porter lift, comprising: a plate-like sliding plate for transporting a snowboarder by means of a cable; and suspension means for suspending the sliding plate from the cable. 2. The transporter for a porter lift according to claim 1, wherein the sliding surface of the sliding plate is formed with irregularities along the sliding direction. 3. The porter lift transporter according to claim 1, wherein a surface of the sliding board on which the snowboarder rides is covered with rubber. 4. A bend is formed at a front and rear portion with respect to a sliding direction of the sliding plate.
4. The transporter for a porter lift according to 2 or 3. 5. The suspension means is provided with an urging means for urging the sliding board upward, and when the snowboarder is not on board, the sliding board is urged upward by the urging member to slide. 5. The transporter for a porter lift according to claim 1, wherein the plate is separated from the snow surface. 6. The suspension means comprises: a fixed arm extending a predetermined distance from the cable; and a pivot attached to the fixed arm via a joint rotatable about an axis parallel to an axis of the cable. 6. The transporter for a porter lift according to claim 1, further comprising an arm. 7. In a normal traveling state in which a snowboarder is mounted, the sliding board is attached to the suspension means so that a cable is not positioned directly above the sliding board, and the fixed arm is moved from the normal traveling state to the suspension means. 7. The porter lift for a porter lift according to claim 6, wherein the joint limits a rotation range between the fixed arm and the rotation arm so as to prevent the cable from being twisted toward the pulley when the cable is twisted. Transporter. 8. An endless cable spanned between two pulleys, and driving means for driving the cable between the two pulleys by rotating the pulley, wherein: Claim 2, Claim 3, Claim 4, Claim 5,
A porter lift, wherein the porter lift carrier according to claim 6 or 7 is attached to the cable. 9. The fixed arm of the porter lift transporter according to claim 6 or 7 is brought into contact with a position lowered by a predetermined distance from a groove of each of the pulleys, so that the fixed arm rotates to the side opposite to the pulley. 9. The porter lift according to claim 8, further comprising a guide for twisting the cable.