JP2012097440A - Gondola device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a gondola device which allows power source of the gondola to be supplied from other than an electric power company for energy cost reduction and a roof floor space to be effectively utilized.SOLUTION: A gondola device includes two parallel rails 3 which are arranged on a roof floor of a building 1, and a gondola 4 which is movably installed on the two rails 3. The gondola device further includes a plurality of solar cell modules 5 which are arranged side-by-side in movement direction of the gondola 4 between the two rails 3, and a power supply device 6 which is connected between the gondola 4 and the solar cell modules 5 and supplies energy generated by the solar cell modules 5 to the gondola 4.

Description

  The present invention relates to a gondola apparatus including a gondola for moving up and down a cage used for maintenance of a building outside a window and an outer wall surface.

  Conventionally, a gondola that moves the cage along the wall of the building is often used in order to safely and efficiently perform high-altitude work such as building walls, building repairs, and window cleaning. It is possible to perform a wide range of work by moving it in combination with being able to move up and down as well as moving up and down as needed as well as raising and lowering by installing a lifting mechanism I have to.

  As one of the gondola devices, for example, there is one configured by hanging and supporting a cage from a gondola provided on a rail laid on the roof of a building via a suspension wire. The gondola is equipped with a crane section that has a suspension wire operation / winding mechanism. The gondola lifts and lowers the cage by operating and winding the suspension wire using the operation / winding mechanism, and travels along the rail. Thus, the cage is moved in the horizontal direction. Furthermore, the conventional gondola device is not configured to install the solar cell module between the gondola rails. (See Patent Document 1)

JP 2000-320133 A

  The gondola apparatus as described above was supplied with all the power of the power source from the electric power company, so the cost of power consumption was high. In addition, when a gondola device is installed on the roof of a building, the space on the roof decreases, and when equipment such as air conditioning equipment is installed, the space further decreases, making it difficult to install solar cell modules. . For this reason, it has been desired to reduce the power cost and to effectively use the rooftop space of the building.

  It is an object of the present invention to provide a gondola apparatus that can supply electric power as a power source of a gondola from a company other than an electric power company to reduce the cost of electric power and effectively use the roof space of a building. .

  A gondola apparatus according to the present invention includes a gondola apparatus including two parallel rails provided on the roof of a building, and a gondola movably installed on the two rails. A plurality of solar cell modules installed side by side in the moving direction, and a power supply device that is connected between the gondola and the solar cell module and supplies the power generated by the solar cell module to the gondola. It is a feature.

  For example, the power supply device is connected to the gondola via a power supply box for supplying power to the gondola, and the power supply device is connected to the solar cell module via the connection box. One connection box may be provided for one solar cell module, or one connection box may be provided for a plurality of solar cell modules. One power supply box may be installed at a predetermined location on the roof, or a plurality of power supply boxes may be installed on the roof, for example, one on each side of the roof.

  The gondola is arranged on the rail in a state straddling the solar cell module. The solar cell modules straddling the gondola may not generate electric power because the sunlight is blocked by the gondola, but other solar cell modules generate electric power when irradiated with sunlight.

  Preferably, the solar cell module is arranged so as to face south and so as to form an angle of, for example, 20 degrees to 30 degrees with respect to the rooftop floor surface so that sunlight is irradiated at an angle close to a right angle.

  In the conventional gondola device, when equipment such as an air conditioner is installed on the roof of a building, there is no sufficient space for installing the solar cell module, and it is difficult to install the solar cell module. As a result, since all the power of the power source was supplied from the power company, the power cost was high.

  On the other hand, in the gondola apparatus according to the present invention, the solar cell module can be installed between the two rails, so that the solar cell module can be installed by effectively using the installation space on the roof. Thereby, a solar cell module can be installed not only in a new building but also in an existing building. Moreover, since all the electric power used for a gondola apparatus, or one part electric power can be generated with a solar cell module, the cost reduction of electric power can be achieved.

  In the gondola apparatus according to the present invention, it is preferable that a plurality of bases are arranged side by side on the rooftop surface, and two rails are provided across the plurality of bases.

  The foundation is manufactured to be strong so that a heavy gondola can travel, and the anchor portion of the foundation with respect to the rooftop floor is usually waterproofed.

  In recent years, buildings where solar cell modules are installed are increasing, and in order to install solar cell modules, a stand that takes into account wind pressure and earthquake load is necessary. When installing a solar cell module on the roof of an existing building, the solar cell module can be installed without producing a stand having a special strength other than the load of the gondola by using a base stand.

  For example, if the planar shape of the roof is a quadrangle, the plurality of bases are installed side by side so as to form a substantially square shape corresponding to the shape of the roof. In this case, the two rails are also bridged so as to have a substantially rectangular shape in accordance with the positions of the plurality of bases. The two rails are fixed to the foundation using anchor bolts. The solar cell module can also be installed at a corner portion of a rail installed in a substantially square shape.

  A plurality of bases installed on the roof may be provided with a walkway having a handrail extending vertically at the end in the circumferential direction, and the upper surface of the walkway provided at a predetermined position may be supplied with power. A box may be installed.

  The gondola is provided with an extended power cable for supplying power. The power supply box is installed at an interval shorter than the length of the power cable, and the plug of the power cable and the re-sectorable (plug receptacle) of the power supply box are connected.

  When moving the gondola, the power cable is disconnected from the power supply box before the gondola is moved, and the power supply box located nearest to the power supply box is connected after the movement.

  In the gondola apparatus according to the present invention, it is preferable that the support member is secured between the brackets integrated with the lower portions of the two rails, and the solar cell module is installed on the support member.

  For example, the rail has an I-shaped cross section. Brackets are respectively provided on the upper surfaces of the lower flanges of the two I-shaped rails, and support members are secured to the brackets by, for example, bolts. The bracket and the rail are attached by, for example, welding, and the support and the support member of the solar cell module are attached by, for example, welding or bolts.

  If it does in this way, it is not necessary to install a solar cell module in a rooftop floor surface or a base stand, and the installation work of a solar cell module is easy.

  However, the solar cell module may be installed on a support member such as a support fixed to a rooftop surface or a base. When the support member is fixed to the rooftop floor surface, the anchor portion is waterproofed.

  In the gondola device of the present invention, the power supply device is connected to the storage battery and the commercial power source for storing the power generated by the solar cell module, and can supply the power from the solar cell module, the storage battery and the commercial power source to the gondola. It is preferable that it is such.

  The power supply device, for example, converts the power generated by the solar cell module so that it can be used for the gondola, and the total amount of electric power that is connected to the power conditioner and converted so that it can be used for the gondola. Power distribution meter that combines the total power generation meter to be measured, and the earth leakage breaker (leakage breaker) and wiring breaker (safety breaker) that are connected to the total power generation meter and use the power safely. With a board.

  The power supply device is connected to the storage battery via a connection box. A required number of storage batteries are connected to the connection box, and are connected to a plurality of or one connection box. The gondola device of the present invention stores the electric power from the solar cell module in the storage battery and may supply it to the gondola, may supply the electric power to the gondola without storing it in the storage battery, and does not supply the electric power to the gondola. May be stored in a storage battery.

  When the power supply device is connected to the storage battery, the power generated by the solar battery module can be stored in the storage battery. Thereby, when the electric power from a solar cell module runs short by bad weather, electric power can be supplied from a storage battery and a gondola can be operated.

  In addition, when the power supply device is connected to a commercial power source, even if the power generated by the solar cell module is insufficient to operate the gondola or the power of the storage battery is insufficient, Since the insufficient power can be supplied to the gondola, the gondola can be operated.

  The power supply device may include a watt-hour meter for selling power and a watt-hour meter for purchasing power (general household energy meter). In this case, the distribution board and the watt-hour meter for power sale are connected, and the watt-hour meter for power sale and the watt-hour meter for power purchase are connected. The watt-hour meter for electric power sale and the watt-hour meter for electric power purchase are used when buying and selling the electric power generated by the solar cell module. Electricity sales are supplied in the order of a watt-hour meter for selling power from a distribution board, a watt-hour meter for buying power from a watt-hour meter for selling power, and an electric power company from the watt-hour meter for buying power. Purchase power is the reverse order of selling power, that is, watt-hour meter for power purchase from power company, watt-hour meter for power purchase from watt-hour meter for power purchase, and distribution board from watt-hour meter for power sale In the order of.

  According to the gondola device of the present invention, a plurality of solar cell modules installed side by side in the movement direction of the gondola between two rails, and the electric power generated by the solar cell module connected between the gondola and the solar cell module. Since the power supply device for supplying the gondolas to the gondola is provided, it is not necessary to supply all of the electric power for operating the gondola from the electric power company, and the power cost required for the operation of the gondola can be reduced. Further, since the solar cell module is installed between the two rails, it is possible to effectively use a space that has not been used conventionally and install the solar cell module on the roof of a new building or an existing building.

FIG. 1 is a side view showing a first embodiment of a gondola apparatus according to the present invention. FIG. 2 is a plan view showing a state in which the solar cell module is installed on the roof of a building. FIG. 3 is a side view showing the solar cell module taken along line III-III in FIG. FIG. 4 is a front view showing the solar cell module taken along line IV-IV in FIG. FIG. 5 is a side view showing the solar cell module taken along line VV of FIG. FIG. 6 is a block diagram showing a connection state of the gondola device. FIG. 7 is a block diagram illustrating a connection state of the power supply apparatus. FIG. 8 shows a different embodiment of the gondola apparatus according to the present invention, and is a side view showing a solar cell module located on the south side of the roof.

  Embodiments of the present invention will be described below with reference to the drawings.

In the following description, “upper and lower” means the upper and lower sides in FIG. 1, the back side of the paper in FIG. Further, the upper side of FIG. 2 is called north, the lower side is called south, the right side of the figure is east, and the left side is west.

  1 to 7 show a gondola apparatus according to the first embodiment.

  As shown in FIGS. 1, 3, and 6, the gondola device includes a plurality of bases (2) that are annularly installed on the roof surface of the building (1) at predetermined intervals, and a plurality of foundations. Two rails (3) made of parallel I-shaped steel that are stretched over the upper surface of the base (2) and endlessly provided, and a gondola that is horizontally movable on the two rails (3) (4), a plurality of solar cell modules (5) that generate power to operate the gondola (4), and a power supply device (6) that supplies the power generated by the solar cell module (5) to the gondola (4) And have.

  As shown in FIG. 1, the cross section of the base (2) has an inverted convex shape, and a handrail (7) extending vertically is provided at the protruding circumferential inner portion of the base (2). A walkway (8) provided in the section is provided, and a power supply box (9) for supplying power to the gondola (4) is installed on the upper surface of the walkway (8). A walkway (8) is provided on every base (2). The power supply box (9) is installed in a predetermined walkway (8). The anchor part of the foundation (2) with respect to the rooftop floor is waterproofed.

  The gondola (4) travels with a carriage traveling section (10) movably disposed on two rails (3), a traveling body section (11) coupled to the carriage traveling section (10), A crane part (13) connected to the main body part (11) and provided with a wire rope (12), and a cage (14) suspended from the roof of the building (1) by the crane part (13). It is configured.

  The carriage traveling section (10) includes a traveling base (15) on which the traveling main body section (11) is placed, and wheel legs (16) (left wheel legs extending in the front-rear direction on both the left and right sides of the traveling base (15). (16a) and the right wheel leg (16b)) are fixed, and driving wheel units (17) are mounted on the ends of both wheel legs (16a) and (16b).

  The driving wheel unit (17) includes a main wheel (19) rotatably accommodated by a horizontal rotating shaft inside a rectangular parallelepiped wheel accommodating body (18) opened to the lower surface side, and a wheel accommodating body (18 ) And a pair of side roller units (20) each having a side roller (20a) and a hook roller (20b) fixed on both front and rear sides.

  In the side roller unit (20), a pair of hook rollers (20b) are rotatably mounted around the horizontal axis so as to sandwich the vertical surface of the rail (3), and the hook roller (20b) is sandwiched between horizontal surfaces. A pair of side rollers (20a) are rotatably mounted around the vertical axis, and the upper flange (3a) is mounted on the side rollers with the main wheel on the upper surface of the upper flange (3a) of the rail (3). (20a) is sandwiched and the hook roller (20b) is positioned on the lower surface of the upper flange (3a) so that it can be engaged with the rail (3) so as not to fall off.

  The traveling main body (11) is configured to be able to turn around the vertical axis with respect to the carriage traveling unit (10). In addition, a power cable (21) connected to the feeding box (9) extends to the traveling main body (11), and the length of the power cable (21) is about 30 m. A plurality of power supply boxes (9) are installed on the roof, and are installed at intervals shorter than the length (30 m) of the power cable (21). The plug (21a) of the power cable (21) is connected to the re-stable (plug receptacle) (9a) of the power supply box (9).

  The cage (14) is structured such that an operator who performs maintenance of the outer wall of the building (1) and cleaning of the window glass can board. The cage (14) is moved up and down by winding and unwinding the wire rope (12) by a gondola lifting mechanism (not shown) provided inside the gondola (4).

  As shown in FIG. 2, two rails (3) are annularly mounted on a plurality of bases (2) arranged so as to be substantially square along the roof periphery of the building (1). It is arranged. A plurality of solar cell modules (5) are arranged between the two rails (3). As shown by the two-dot chain line in the figure, the gondola (4) is installed on the two rails (3) with the cage (14) positioned along the wall of the building (1). The gondola (4) can move horizontally on the rail (3).

  Although not shown, when moving the gondola (4), the power cable (21) is unplugged from the power supply box (9) before moving the gondola (4), and the power supply box ( Connect to 9).

  As shown in FIG. 3, the solar cell module (5) installed on the south side of the roof has two columns (23) provided at both ends on the south side, and two columns (23) provided at both ends on the north side ( 23) and is supported. This solar cell module (5) is arranged so as to face south and at an angle of 20 degrees to 30 degrees with respect to the rooftop surface so that sunlight is irradiated at an angle close to a right angle. . The angle of the solar cell module (5) can be freely adjusted.

  Since the solar cell module (5) is provided to be inclined to the south side, sunlight is irradiated almost perpendicularly to the solar cell module (5), and the power generation efficiency is improved.

  The solar cell module (5) installed on the north side of the roof shown in FIG. 2 is the same as the solar cell module (5) installed on the south side, and the description thereof is omitted.

  Two rails (3) made of I-shaped steel are installed on the base (2) via two iron plates (24), and the iron plate (24) is fixed by anchor bolts (25). ing. The iron plate (24) and the rail (3) are firmly fixed by welding or the like.

  Brackets (27) are respectively provided on the upper surfaces of the lower flanges of the two rails (3) so as to face each other. Between the two rails (3), the support member (28) having the same length as the distance between the brackets (27) is connected from the upper surface of the lower flange (3b) of one rail (3) to the other rail. (3) It is bridged on the upper surface of the lower flange (3b) and is fixed to the bracket (27) with bolts.

  The support column (23) and the support member (28) of the solar cell module (5) are joined by welding, and each rail (3) and the bracket (27) are joined by welding.

  In the support column (23) provided on one solar cell module (5), the support member (28) includes one short support column (23) on the south side and one long support column (23 on the north side). ) Is supported by one support member (28). Similarly, one short support column (23) on the south side and one long support column (23) on the north side are provided as one support member (28). ) Is supported.

  As shown in FIGS. 3 and 4, one end of the back side of the bracket (27) is formed to be inclined upward corresponding to the inclined upper surface of the lower flange (3b), and the bracket (27). The other end of the back side is inclined upward so as not to interfere with the nut (26) for fastening the anchor bolt (25).

  As shown in FIG. 5, the plurality of solar cell modules (5) installed on the east side of the roof are provided with four support columns (23) in the same manner as the solar cell module (5) installed on the south side shown in FIG. ) Is supported. The solar cell module (5) is arranged southward and at an angle of 20 degrees to 30 degrees with respect to the rooftop surface so that sunlight is irradiated at an angle close to a right angle. The angle of the solar cell module (5) can be freely adjusted. Since the solar cell module (5) is provided to be inclined, sunlight is applied to the solar cell module (5) almost vertically, and the power generation efficiency is improved. Since the plurality of solar cell modules (5) installed on the west side of the roof are the same as the plurality of solar cell modules (5) installed on the east side, description thereof is omitted.

  Further, as shown in the figure, the support member (28) has an L-shaped cross section, and is provided via a bracket (27) between the two rails (3) with the L-shaped inverted. ing. In the support member (28), in the support column (23) provided on one solar cell module (5), two short support columns (23) located on the south side are supported by one support member (28). The two long struts (23) located on the north side are provided so as to be supported by one support member (28).

  As shown in FIG. 6, the power supply device (6) includes a solar cell module (5) through a connection box (29), a gondola (4) through a power supply box (9), and a commercial power supply (30). Connected with. The power supply device (6) is configured to be able to supply power to the gondola (4) from any of the solar cell module (5), the gondola (4), and the commercial power supply (30).

  One connection box (29) is provided for one solar cell module (5). One storage battery (31) is connected to the plurality of junction boxes (29).

  As shown in FIG. 7, the power supply device (6) is connected to the connection box (29) and converts the power generated by the solar cell module (5) so that it can be used by the gondola (4) ( 32), a total power generation meter (33) connected to the power conditioner (32) and measuring the total power converted to be usable for the gondola (4), and a total power generation meter (33) And a distribution board (34) in which a leakage breaker (leakage breaker) and a wiring breaker (safety breaker) are combined into one in order to use power safely.

  The storage battery (31) stores the electric power generated by the solar cell module (5) on a sunny day, so that the stored electric power can be used even on bad weather days. As a result, the gondola (4) can be operated by supplying power from other than the commercial power source (30) regardless of the weather. When using the power of the storage battery (31), the power is discharged from the storage battery (31) to the junction box (29), and the power conditioner (32), total power generation meter (33), distribution board (34) and It goes around the power supply box (9) and is supplied to the gondola (4).

The distribution board (34) that constitutes the power supply device (6) is connected to the power supply box (9) in addition to the total watt-hour meter (33), and the power generated from the solar cell module (5) It is configured to supply from the power supply box (9) to the gondola (4).
In addition, the distribution board (34) is also connected to the commercial power supply (30), so that when the amount of power to operate the gondola (4) is insufficient, the necessary power can be used from the commercial power supply (30). ing. The electric power of the commercial power source (30) is supplied from the power supply device (6) to the gondola (4) through the power supply box (9).

  According to the above configuration, the gondola (4) can be operated using the electric power generated from the solar cell module (5), so all power necessary for the operation of the gondola (4) is obtained from the power company. There is no need to supply power, and power costs can be reduced. Furthermore, since the solar cell module (5) is installed between the two rails (3), the space can be used effectively. Further, by using the support member (28), it is not necessary to install the solar cell module on the rooftop surface or the base, and the installation work of the solar cell module becomes easy.

  Next explained is the second embodiment of the invention. The description of the same configuration as that of the first embodiment is omitted.

  As shown in FIG. 8, the solar cell module (5) is installed without using a support member, and the solar cell module (5) is provided with two rails (3) through four columns (23). Is directly attached to the foundation (2). The support (23) and the base (2) of the solar cell module (5) are firmly coupled by fastening the anchor bolt (25) with a nut (26).

  According to the above configuration, the gondola (4) can be operated using the electric power generated from the solar cell module (5), so it is not necessary to supply all the electric power from the electric power company, thereby reducing the power cost. Can be made. Furthermore, since the solar cell module (5) is installed between the two rails (3), the space can be used effectively. Further, by directly attaching the solar cell module (5) to the base stand (2), the support member is not required, so the number of parts of the gondola device can be reduced, and the cost can be further reduced.

(1) Building
(2) Foundation platform
(3) Rail
(4) Gondola
(5) Solar cell module
(6) Power supply device
(27) Bracket
(28) Support member
(30) Commercial power supply
(31) Storage battery

Claims (4)

In a gondola device comprising two parallel rails provided on the roof of a building, and a gondola movably installed on the two rails,
A plurality of solar cell modules installed side by side in the moving direction of the gondola between two rails, and a power supply device connected between the gondola and the solar cell module to supply the power generated by the solar cell module to the gondola And a gondola device.   2. The gondola apparatus according to claim 1, wherein a plurality of foundation stands are arranged side by side on the rooftop floor surface, and two rails are provided across the plurality of foundation stands.   The gondola apparatus according to claim 1 or 2, wherein a support member is secured between brackets respectively integrated with lower portions of the two rails, and a solar cell module is installed on the support member.   The power supply device is connected to a storage battery and a commercial power source for storing the power generated by the solar cell module, and can supply power from the solar cell module, the storage battery and the commercial power source to the gondola. The gondola apparatus in any one of 1-3.

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