JP2009215876A - Elevator type parking device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce weight and the number of parts, and to improve the use efficiency of a void space. <P>SOLUTION: A parking shelf 4 erectly disposed in a state of being separated from the wall surface 3a of the void space in the void space 3 has four main shelf columns 10 forming the square pole-shaped skeleton structure of a parking device 1 and separated from the wall surface and a plurality of beams 30 vertically and mutually separated and horizontally erected among the four main shelf columns along the plan-view rectangle of the skeleton structure. The parking shelf 4 further has a plurality of shelf members 12 erected among sub-shelf columns 11 adjacent to the main shelf columns to each of the main shelf columns and extended in the horizontal direction, respectively, while being vertically and mutually separated and disposed. An elevator 6 is configured so as to lift and lower a pallet 5 at the central section of the parking shelf as the internal region of the four sub-shelf columns, and the pallet lifted and lowered by the elevator can be traversed along a pair of the shelf members opposed in a fore-and-aft direction. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an elevator-type parking apparatus that is erected in a void space of a building housing in a state of being separated from a wall surface of the void space.

  A three-dimensional parking device (hereinafter referred to as a parking device) is divided into an independent steel tower type constructed as a building independent of a building in which a living space is provided, and a steel tower type in a building installed in a void space inside the building. Broadly divided.

  FIG. 8 is a perspective view showing the configuration of an independent tower type parking apparatus. As shown in FIG. 8, the independent tower type parking apparatus 101 includes a parking tower 104 in which an exterior plate (exterior panel) 103 is pasted on the outer surface of a steel tower 102 serving as a skeleton, and a parking tower 104 disposed inside the parking tower 104. An elevator 105 as a vehicle transport mechanism provided and a parking shelf 106 for housing the vehicle M are mainly configured. As shown in the figure, the steel tower 102 has a quadrangular prism shape as a whole, a main column 107 standing at the four corners, a beam 108 spanned between the main columns 107 at a predetermined interval in the vertical direction, and a reinforcing column. And a diagonal material (brace) 109.

  The elevator 105 is for raising and lowering the pallet 110 on which the vehicle M is mounted, and is configured to raise and lower the lateral central portion of the parking shelf 106. The elevator 105 is suspended by a wire (not shown), and the iron tower 102 is provided with a driving device 112 that raises or lowers the elevator 105 by winding or unwinding the wire. The elevator 105 is provided with a rail 105a (see FIG. 9) on which the pallet 110 can traverse, and the pallet 110 is placed on the rail 105a.

  FIG. 9 is a cross-sectional plan view showing the configuration of the independent tower type parking apparatus. The parking shelf 106 is erected inside the steel tower 102 and has a rectangular column shape slightly smaller than the steel tower 102. The parking shelf 106 includes four main shelf columns 115 a erected at the four corners of the parking shelf 106. Between the main shelf columns 115 a that are separated in the left-right direction, two parking shelves are provided on both sides of the elevator 105. The secondary shelf column 115b is erected. That is, a total of four sub shelf columns 115b are provided, two on the front side of the parking apparatus and two on the back side. A plurality of bar-shaped shelf members 116 spaced apart in the vertical direction are spanned between the main shelf column 115a and the sub shelf column 115b on both sides of the parking shelf 106 with the elevator 105 interposed therebetween. Yes. A rail on which the pallet 110 can traverse is formed on the top surface of the shelf member 116.

  When the vehicle M enters the vehicle, the vehicle M enters the pallet 110 on the elevator 105 from an entry / exit port (not shown) provided in the ground portion on the front side of the parking device 101, and the driving device 112 is connected to the wire. Is lifted until the elevator 105 reaches the required height, and the pallet 110 is further traversed until the pallet 110 is placed on the shelf member 116 along the rail 105a and the rail of the shelf member 116, and the warehousing is completed. Also, the delivery is achieved by the reverse process.

  On the other hand, in a conventional steel tower type parking device in a building, the exterior panel 103 of the independent steel tower type parking device 101 is removed in a void space provided inside a building frame such as a building. A parking device of the same form is erected. FIG. 10 is a cross-sectional plan view showing a configuration of a conventional in-building steel tower type parking apparatus. As shown in FIG. 10, an in-building steel tower type parking apparatus 117 includes a void space 119 provided in a void space 119 provided in a building housing 118 (hereinafter referred to as a building housing) such as an office building or an apartment house. It is erected from the wall surface 120 with a predetermined clearance (gap). This clearance is provided in order to prevent mechanical noise, vibration, and the like generated when the elevator 105 is operated from being transmitted to the living space of the building. Such a parking device is disclosed in Patent Document 1, for example.

  Further, by providing such a clearance, the building housing 118 and the parking device 117 having different vibration modes are each independently shaken when an earthquake occurs. The clearance is sufficient to avoid collision in consideration of the rigidity and height of the parking device 117 so that the building housing 118 and the parking device 117 do not collide due to such relative shaking. The size is set as much as possible.

  Therefore, a cushioning member is provided at the upper end of the parking device, and a collision portion is provided at the upper end of the void space so as to face the cushioning member in the horizontal direction, so that the parking device and the building frame are relatively shaken. In such a case, a collision mitigation structure is proposed in which the parking device and the building enclosure collide only at the top position of the parking device via the buffer member and the collision portion (see, for example, Patent Document 2). ).

Japanese Patent Laid-Open No. 10-46860 Japanese Patent No. 2972986

  However, since the conventional parking apparatus is heavy and has a large number of parts, it requires a lot of labor to manufacture the parking apparatus, and there has been a demand for weight reduction and a reduction in the number of parts. Especially in the steel tower type in a building, if the skeleton structure of the parking device is complicated and large as in the past, it is inevitable that the void space to be secured in the building housing will be increased, and the parking device is installed in the building housing. It will squeeze the space to be secured.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide an elevator type parking apparatus that can realize a reduction in weight and a reduction in the number of parts as compared with the prior art and has high use efficiency of void space.

  In the case of the collision mitigation structure as described above, in the event of an earthquake, etc., the parking device may swing so as to deform like a bow with the upper and lower ends as fulcrums, and the parking device and the building frame are Even when the collision occurs only at the top position of the parking device via the buffer member and the collision portion, the trunk of the parking device may collide with the wall surface of the void space. Moreover, in order to avoid such a collision, it is necessary to increase the clearance provided between the parking device and the building housing, which causes the use efficiency of the void space to deteriorate.

  Therefore, the present invention alleviates the collision between the parking device and the building frame even when the parking device is shaken so as to deform like a bow with the upper and lower ends as fulcrums, in the event of an earthquake, etc. It is another object of the present invention to provide an elevator parking apparatus having a small clearance provided between the parking apparatus and the building frame as compared with the conventional structure, and thus high use efficiency of the void space.

  In order to solve the above problems, an elevator parking apparatus according to the present invention is an elevator parking apparatus that stands in a void space having a rectangular shape in a plan view provided in a building housing. A parking shelf that is erected in a state of being separated from the wall surface of the void space, and an elevator that lifts and lowers a vehicle-mounted pallet supported by the parking shelf, wherein the parking shelf is a quadrangular prism shape of the parking device. 4 main shelf columns that are respectively provided upright at the four corners of the void space so as to form the four corners of a rectangular shape in plan view of the skeletal structure, and spaced apart from the wall surface, A plurality of beams that are spaced apart from each other and are horizontally laid between the four main shelf columns along a rectangular shape in plan view of the skeleton structure, and the left and right inner sides of each of the four main shelf columns Standing next to each other, the four main shelf columns are The four auxiliary shelf columns located on the sides of the rectangular in plan view, and each of the main shelf columns and the auxiliary shelf columns adjacent to the main shelf columns extend in the left-right direction. A plurality of shelf members disposed vertically apart from each other, and the elevator is configured to raise and lower the pallet at a central portion of the parking shelf that is an inner region of the four sub shelf columns. The pallet that is moved up and down by the elevator is traversable along a pair of the shelf members facing forward and backward.

  By adopting such a configuration, the main shelf column and the sub shelf column are not only used as components of a parking shelf for supporting a pallet and accommodating a vehicle, but also used as a skeleton structure of a parking device. Therefore, the steel main pillar (main pillar 107 in FIGS. 8 and 9), which has been necessary in the past, becomes unnecessary, and the parking device can be significantly reduced in weight compared to the conventional one and the number of parts can be reduced. . Even if the main steel pillar is abolished, since a beam is installed between the main shelf pillars, sufficient strength can be secured as a skeleton structure of the parking apparatus.

  As is clear from the configuration, the four sub shelf columns define a space in which the pallet that is raised and lowered by the elevator moves, and shelf members are provided separately on the left and right sides of the space. The shelf member extends from side to side by spanning a main shelf column forming four corners of the skeleton structure of the parking apparatus and a sub shelf column arranged on a rectangular side forming the four corners. By arranging the main shelf column and the sub shelf column in this way, the shelf member extending in the left and right directions is supported by the main shelf column and the sub shelf column, and the shelf member can be firmly supported.

And since a steel main pillar becomes unnecessary, the void space required for the parking apparatus which concerns on this invention can be reduced in space compared with the past. Therefore, the freedom degree of the architectural plan of a building can be improved compared with the past. In addition, the amount of fire extinguishing gas (CO ₂ ) that needs to be prepared in the space where the parking device is installed can be reduced.

  Diagonal squares formed by two beams arranged vertically in the plurality of beams and two sub shelf columns arranged in the left-right direction among the four sub shelf columns, and the plurality of beams A brace is provided so that square diagonals formed by two beams arranged vertically and two main shelf columns arranged in the front-rear direction among the four main shelf columns are connected to each other. It may be done. Thereby, when using a parking shelf as a skeleton structure of a parking apparatus, the intensity | strength can be ensured.

  A plurality of buffer members provided so as to face the wall surface are attached to each of a plurality of vertical positions including at least the trunk of the main shelf column, and the parking shelf and the building frame are relatively It is preferable that the parking shelf is configured to collide with the wall surface only through the buffer member when swaying. As a result, even when the parking device swings to deform like a bow with the upper and lower ends as fulcrums when an earthquake occurs, the buffer member provided on the trunk of the main shelf column is By colliding with the wall surface, the collision between the parking rack and the building frame is efficiently mitigated. In addition, when the parking rack and the building frame are relatively shaken, the parking rack collides with the wall surface of the void space only by the buffer member, so the clearance provided between the parking rack and the building frame is conventionally provided. It can be made smaller than that.

  At each of the plurality of locations, the first buffer member protrudes from the main shelf column so as to face the wall surface in the left-right direction, and the second buffer member protrudes from the main shelf column so as to face the wall surface in the front-rear direction. It is preferable that the front end surface of each of the buffer members is disposed so as to form a slight gap with the wall surface. Here, if the front end surface of the buffer member is always in contact with the building housing, the sound and vibration generated during operation of the parking device are transmitted via the buffer member. Regardless of the operation of the parking device, the buffer member can collide with the wall surface only when the parking rack and the building frame are relatively shaken.

  It is preferable that the buffer member is disposed corresponding to the beam of the building frame. As described above, by arranging the buffer member in accordance with a particularly high strength portion of the building enclosure, there is no possibility of the building enclosure being damaged at the time of collision with the parking rack.

  According to the elevator parking device according to the present invention, the main shelf column and the sub shelf column on which the shelf members are installed are used as the skeleton structure of the parking device, and the conventional steel main column can be abolished. The void space to be secured can be reduced.

  Furthermore, even when the parking device swings to deform like a bow with the upper and lower ends as fulcrums in the event of an earthquake, etc., the cushioning member provided on the trunk of the main shelf column is the wall surface of the void space. The collision between the parking shelf and the building frame is efficiently mitigated. In addition, when the parking rack and the building housing are relatively shaken, the parking device collides with the wall surface of the void space only by the buffer member, so the clearance provided between the parking device and the building housing is conventionally reduced. There are excellent effects such as being able to be made smaller than the above.

It is a front view which shows the structure of the parking apparatus provided with the collision mitigation structure which concerns on embodiment of this invention. It is a side view which shows the structure of the parking apparatus provided with the collision mitigation structure which concerns on embodiment of this invention. It is a cross-sectional arrow view by the III-III line in FIG. It is a partial expanded plan view which shows the detailed structure of the buffer member which concerns on embodiment of this invention. It is an arrow line view in the VV line shown in FIG. It is a typical front view which shows the arrangement position of the buffer member in the parking apparatus provided with the collision mitigation structure which concerns on embodiment of this invention. It is a partial expanded side view which shows the attachment structure of the breathing apparatus of the parking apparatus which concerns on embodiment of this invention. It is a perspective view which shows the structure of the conventional independent tower type parking apparatus. It is a plane sectional view showing the composition of the conventional independent tower type parking device. It is plane sectional drawing which shows the structure of the conventional steel tower type parking apparatus in a building.

  Hereinafter, a collision mitigation structure according to an embodiment of the present invention will be specifically described with reference to the drawings. FIG. 1 is a front view showing a configuration of a parking apparatus provided with a collision mitigation structure according to an embodiment of the present invention, and FIG. 2 is a side view thereof. A three-dimensional parking apparatus (hereinafter referred to as a parking apparatus) 1 according to the present embodiment is a so-called steel tower type building, and is a building structure 2 of a building in which a living space (residential part, office, etc.) is provided (see FIG. 3), and is erected in the void space 3 provided in FIG. The parking apparatus 1 is mainly composed of a parking shelf 4, a pallet 5, and an elevator 6. The parking shelf 4 is a skeleton structure of the parking device 1 and has a rectangular column shape slightly smaller than the void space 3. The elevator 6 is for raising and lowering the pallet 5 on which the vehicle M is mounted, and refers to the left-right direction of the parking rack 4 (here, the left-right direction when facing the front from the inside of the parking device 1. .) It is configured to be able to move up and down at the central portion. The elevator 6 is suspended by a wire 7, and a driving device 8 that raises or lowers the elevator 6 by winding or unwinding the wire 7 is provided at the upper end of the parking apparatus 1. As will be described later, the elevator 6 is provided with a rail 9 (see FIG. 3) on which the pallet 5 can traverse, and the pallet 5 is placed on the rail 9.

  3 is a sectional view taken along line III-III in FIG. As shown in FIG. 3, the parking shelf 4 has main shelf columns 10 made of H-shaped steel standing upright at the four corners. Two sub-shelf columns 11 are erected between the main shelf columns 10 separated in the left-right direction and on both sides of the elevator 6. That is, a total of four sub shelf columns 11 are provided, two on the front side of the parking apparatus and two on the back side. A plurality of bar-like shelf members 12 that are spaced apart in the vertical direction are stretched over the main shelf column 10 and the sub shelf column 11 on both sides of the parking shelf 4 across the elevator 6. A rail 13 on which the pallet 5 can traverse is formed on the top surface of the shelf member 12.

  In addition, buffer members 14 and 15 are attached to several locations of the main shelf columns 10 that are spaced apart in the vertical direction. FIG. 4 is a partially enlarged plan view showing a detailed configuration of the buffer members 14 and 15, and FIG. 5 is a view taken along the line VV shown in FIG. 4. As shown in FIG. 4, the buffer members 14, 15 are elastic buffer rubbers (elastic rubber portions) 20, 21 on one end face of the steel brackets 16, 17 via a liner 18 and a fixing plate 19. The other end of the bracket 16 is fixed to the main shelf column 10 by welding or the like, and is attached to the main shelf column 10. The brackets 16 and 17 are configured such that three plate members are fixed to each other so as to form a substantially channel shape in plan view, and ribs 22 and 23 for reinforcement are provided at the center in the vertical direction. ing. The brackets 16 and 17 are integrally fixed to the main shelf column 10 with the channel-shaped opening side facing the main shelf column 10. The liner 18, the fixing plate 19, and the buffer rubbers 20 and 21 are attached to the channel-like bottom plates of the brackets 16 and 17, that is, the mounting plates 24 and 25 that are plates on the side away from the main shelf column 10.

  As shown in FIG. 5, the mounting plate 25 (24) is a square plate having a substantially square shape when viewed from the front, and mounting holes (not shown) are provided at two positions vertically separated on the center line in the width direction. It has been. The liner 18 is configured by stacking a plurality of square plates having substantially the same vertical length as the vertical length of the mounting plate 25 (24). The length in the width direction of the liner 18 is slightly smaller than the length in the width direction of the mounting plate 25. An attachment hole (not shown) is also provided on the center line in the width direction of the liner 18 at a location that matches the attachment hole of the attachment plate 25. Further, a fixing plate 19 is disposed on the front side of the liner 18. The fixed plate 19 has the same shape as the liner 18 in a front view, and is provided with an attachment hole (not shown) at the same location. Both the mounting hole of the mounting plate 25, the mounting hole of the liner 18, and the mounting hole of the fixing plate 19 are passed through the bolts 26 and tightened with nuts 27, whereby the liner 18 and the fixing plate 19 are fixed to the mounting plate 25. Has been.

  In addition, screw holes (not shown) are provided at two positions separated in the width direction on the vertical center line of the fixing plate 19. On the further front side of the fixed plate 19, a square plate-shaped buffer rubber 21 (20) is disposed. The shock absorbing rubber 21 has the same length in the width direction as the fixed plate 19, and the vertical length is shorter than the fixed plate 19 so as not to interfere with the head of the bolt 26. Further, the buffer rubber 21 is provided with an attachment hole (not shown) at a position corresponding to the screw hole of the fixing plate 19, and a bolt 28 is passed through the attachment hole, and the bolt 28 is attached to the fixing plate 19. The buffer rubber 21 is fixed to the fixing plate 19 by being screwed into the screw hole. The mounting hole of the buffer rubber 21 is provided with a counterbore (not shown). The head of the bolt 28 is accommodated in the counterbore and the head of the bolt 28 protrudes from the surface of the buffer rubber 21. It is configured not to.

  The buffer member 14 for mitigating the collision in the lateral direction between the parking device 1 and the building housing 2 is separated from the inner wall by a predetermined distance (for example, 20 mm) so that the buffer rubber 20 faces the inner wall of the void space 3. The buffer member 15 for mitigating the collision in the front-rear direction between the parking device 1 and the building housing 2 is arranged so that the buffer rubber 21 faces the wall surfaces 3 a before and after the void space 3. 3a and a predetermined distance (for example, 20 mm). The liner 18 is used for adjusting the separation distance between the wall surface 3 a of the void space and the buffer rubbers 20 and 21 by increasing or decreasing the thickness as appropriate.

  FIG. 6 is a schematic front view showing an arrangement position of the buffer member in the parking apparatus provided with the collision mitigation structure according to the embodiment of the present invention. As shown in FIG. 6, the buffer members 14 and 15 are respectively attached to a plurality of locations in the vertical direction of the main shelf column 10. The positions where the buffer members 14 and 15 are attached are set corresponding to the portion 29 having a particularly high strength even on the wall surface 3a of the void space 3, such as the position where the beam is provided in the inner portion (inside the building) of the building housing 2. Is done. Thereby, even if it is a case where the buffer members 14 and 15 collide with the wall surface 3a of the void space 3 as will be described later, the wall surface 3a is prevented from being damaged. In FIG. 6, for the sake of easy understanding, a state in which the high-strength portion 29 of the wall surface 3a of the void space 3 protrudes is shown. However, the present invention is not limited to this. The wall surface 3a of 3 may be comprised by the flat surface.

  In addition, as shown in FIGS. 1, 2 and 3, it is arranged on the right side between the two main shelf columns 10 arranged on the front side and between the two main shelf columns 10 arranged on the back side. Between each of the two main shelf columns 10 and between the two main shelf columns 10 arranged on the left side, a plurality of beams 30 are horizontally installed so as to be spaced apart in the vertical direction. Thereby, the bending of the parking rack 4 is prevented and strength against loads from the front and rear and the left and right directions is ensured. Such a beam 30 is provided at a location unrelated to the installation location of the shelf member 12.

  Further, as shown in FIG. 1, adjacent sub shelf columns 11 arranged side by side (that is, for example, two sub shelf columns 11 on the front side (rear side)) and the front side or rear surface of the parking shelf 4. In the quadrangle formed by the adjacent beams 30 arranged side by side on the side, two braces 31 connecting the diagonals of the quadrangle are provided to intersect. Further, adjacent main shelf columns 10 arranged in parallel in the front and rear (that is, for example, two main shelf columns 10 on the right side (left side)) and adjacent beams arranged in parallel up and down on the right side or left side of the parking shelf 4. In the quadrangle formed by 30, two braces 32 that connect the diagonals of the quadrangle are crossed.

  FIG. 7 is a partially enlarged side view showing the attachment structure of the brace 32. As shown in FIG. 7, in the middle of the main shelf column 10, a brace mounting plate 33 extending toward the main shelf column 10 adjacent to the front and rear is fixed by fastening with bolts. That is, a breath mounting plate 33 extending rearward is fixed to the front main shelf column 10, and a breath mounting plate 33 extending forward is fixed to the rear main shelf column 10. Yes. The beam 30 is fixed to the main shelf column 10 by bolting the end of the beam 30 to the brace mounting plate 33. Further, the end of the brace 32 is fixed to the brace mounting plate 33 by bolt fastening or welding, and the brace 32 is attached to the main shelf column 10 by this. The braces 31 and 32 are attached so that a predetermined tension acts, whereby the strength against the load from the front and rear and the left and right directions of the parking rack 4 is increased.

  The parking shelf 4 is configured so that there are a level where the braces 31 and 32 are provided and a level where the parking rack 4 is not provided in the vertical direction. Here, the “step” refers to a space surrounded by adjacent beams 30 arranged in parallel in the vertical direction. Referring to FIGS. 1 and 2, on the ground stage where the entrance / exit 34 of the vehicle M is provided, the braces 31 and 32 are provided on all four sides to secure the entrance / exit 34 of the vehicle M. The brace 31 is provided only on the front side and the back side of the step directly above (hereinafter referred to as the second step, the steps above the third step, the fourth step,... In this order). . Further, the third stage, the fifth stage and the seventh stage, which is the uppermost stage, are provided with braces 31, 32 on all four sides, and the fourth stage and the sixth stage are not provided with braces 31, 32 on all four sides. . Thus, by providing the portions (stages) without the breaths 31 and 32, the parking rack 4 is more flexible than in the conventional case where the breaths are provided over all stages except the ground level (see FIG. 8). It has a simple structure.

  With such a configuration, when an earthquake occurs, the parking device 1 and the building housing 2 vibrate independently because they have different natural vibration modes, and thus the parking device 1 and the building housing 2. A relative shaking occurs between the two. In such a case, when only the buffer members 14 and 15 of the parking apparatus 1 collide with the wall surface 3a of the void space 3, and the main shelf column 10, the auxiliary shelf column 11, the beam 30, etc. directly collide with the building housing 2. In comparison, the collision between the parking device 1 and the building housing 2 is alleviated. Further, even when the parking device 1 is swung so as to be deformed like a bow with the upper end and the lower end as fulcrums, the buffer members 14 and 15 are provided on the trunk of the parking device 1, so that the wall surface of the void space 3 3a and the buffer members 14 and 15 provided in the trunk portion collide with each other, whereby the collision between the parking device 1 and the building housing 2 is efficiently mitigated.

  In addition, since the collision between the parking device 1 and the building housing 2 is allowed, the clearance between the parking device 1 and the building housing 2 (that is, the wall surface 3a of the void space 3) can be reduced. Thus, the use efficiency of the void space can be improved.

  Furthermore, when the building housing 2 is greatly shaken due to an earthquake, strong wind, or the like, the void space 3 of the building housing 2 is deformed and buffered in the parking device 1. However, as described above, the void space 3 Since only the buffer members 14 and 15 collide with the wall surface 3a, the steel frame structure such as the main shelf column 10 does not directly collide with the building housing 2, and the parking rack 4 (parking device 1) as described above. Therefore, the parking device 1 is deformed following the deformation of the void space 3, and the damage to the parking device 1 and the building housing 2 due to the collision is prevented.

  Further, by attaching the beam 30 and the braces 31, 32 to the main shelf column 10 and the sub shelf column 11, not only the main shelf column 10 and the sub shelf column 11 are used as components of the parking shelf 4, but also a parking device. Since it is also used as a skeleton structure, the steel column (main column 107 in FIGS. 8 and 9), which has been necessary in the past, is unnecessary, and the parking device 1 is significantly lighter than the conventional one and the number of parts is reduced. It becomes possible to decrease.

This will be described using a simulation result performed by the present inventors. According to the simulation result, the parking apparatus according to the present embodiment has a breath diameter of about 30 mm, and there is no need to provide a brace on each floor. On the other hand, in the conventional parking apparatus having the same number of shelves and the same size, the diameter of the breath is about 90 mm to 140 mm, and a brace is required on each floor. In addition, the main pillar that was necessary in the past is no longer needed, so the total weight of the steel frame has been greatly reduced (about 20%) compared to the conventional steel, and the number of parts has also been reduced. It was. The number of breaths of the parking device according to the present embodiment was about half that of the conventional one. Moreover, the void space required for the parking apparatus according to the present embodiment can be reduced by about 2% compared to the conventional case. This means that if it is 5 stories, the living space of the building will increase by about 6m2. Thereby, the freedom degree of the architectural plan of a building can be improved compared with the past. In addition, the amount of digestion gas (CO ₂ ) that needs to be prepared in the space where the parking apparatus 1 is installed can be reduced.

  In addition, in this Embodiment, although the structure which attached the buffer members 14 and 15 to the main shelf column 10 was described, it is not limited to this, As the structure which attached the buffer members 14 and 15 to the beam 30 Also good. However, in this case, it is necessary to arrange the beam 30 in accordance with a portion having a high strength (such as a portion where the beam is provided) in the wall surface 3a of the void space 3 of the building housing 2, and the parking device 1 Due to the design, there are many manufacturing restrictions.

  Furthermore, the above-described embodiment is an embodiment, and various modifications can be made without departing from the scope of the present invention, and the present invention is not limited to the above-described embodiment.

  Elevator parking apparatus according to the present invention can realize a reduction in weight and a reduction in the number of parts as compared with the prior art, and has an effect of improving the use efficiency of void space. It is beneficial to apply it to the device.

DESCRIPTION OF SYMBOLS 1 Parking apparatus 2 Building housing 3 Void space 3a Wall surface 4 Parking shelf 5 Pallet 6 Elevator 7 Wire 8 Drive device 9 Rail 10 Main shelf column 11 Sub shelf column 12 Shelf member 13 Rail 14, 15 Buffer member 16, 17 Bracket 18 Liner 19 Fixed plate 20, 21 Buffer rubber 22, 23 Rib 24, 25 Mounting plate 26 Bolt 27 Nut 28 Bolt 30 Beam 31, 32 Breath 33 Breath mounting plate 34 Entry / exit port

Claims (5)

An elevator-type parking device that is erected in a void space having a rectangular shape in a plan view provided in a building housing,
A parking shelf standing in a state separated from the wall surface of the void space in the void space, and an elevator for raising and lowering a vehicle-mounted pallet supported by the parking shelf,
The parking shelf has a quadrangular columnar skeleton structure of the parking device,
Four main shelf columns that are respectively erected at the four corners in the void space so as to form the four corners of the rectangular structure in plan view of the skeleton structure, and are spaced apart from the wall surface;
A plurality of beams that are vertically spaced apart from each other, and are horizontally laid between the four main shelf columns along a rectangular plan view of the skeleton structure;
Four sub-shelf columns that are erected adjacent to the left and right inner sides of each of the four main shelf columns, and that are positioned on sides of a rectangle in plan view with the four main shelf columns as four corners;
A plurality of shelf members that are installed between each of the main shelf columns and the sub shelf columns adjacent to the main shelf columns and extend in the left-right direction, and are spaced apart from each other in the vertical direction. Prepared,
The elevator is configured to raise and lower the pallet at a central portion of the parking shelf that is an inner region of the four sub shelf columns, and the pair of shelf members facing the front and rear of the pallet that is raised and lowered by the elevator An elevator-type parking apparatus that can traverse along.   Diagonal squares formed by two beams arranged vertically in the plurality of beams and two sub shelf columns arranged in the left-right direction among the four sub shelf columns, and the plurality of beams The bracelet bridges the square diagonals formed by the two beams arranged vertically and the two main shelf columns arranged in the front-rear direction among the four main shelf columns. The elevator parking apparatus according to claim 1, wherein the elevator parking apparatus is provided.   A plurality of buffer members provided so as to face the wall surface are attached to each of a plurality of vertical positions including at least the trunk of the main shelf column, and the parking shelf and the building frame are relatively The elevator type parking apparatus according to claim 1 or 2, wherein the parking shelf is configured to collide with the wall surface only through the buffer member when swaying. At each of the plurality of locations, the first buffer member protrudes from the main shelf column so as to face the wall surface in the left-right direction, and the second buffer member protrudes from the main shelf column so as to face the wall surface in the front-rear direction. Established,
The elevator-type parking apparatus according to claim 3, wherein a tip end surface of each of the buffer members is disposed so as to form a slight gap with the wall surface.   The elevator-type parking apparatus according to claim 3 or 4, wherein the buffer member is arranged corresponding to a beam of the building frame.

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