JP3244123B2 - Evacuation equipment for high places - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an evacuation device for high places, and more particularly, to an evacuation device for high places that can safely and safely descend from the upper floor of a building or an apartment, for example, in the event of a fire.

[0002]

2. Description of the Related Art Recently, high-rise buildings and high-rise condominiums have been actively built in cities and the like. If a fire occurs on the upper floor of this high-rise building, etc., if it escapes, it will obstruct the destination and safety measures at the time of emergency evacuation will be a problem. Therefore, in order to safely evacuate from such a high place to the ground, many evacuation devices have been developed. As one example, Japanese Patent Application Laid-Open No. Hei 4-250176, filed by the applicant of the present invention, discloses an "evacuation escape device in a hotel fire". This conventional device is a device of a portable size, and the main device configuration is as follows. That is, a drum on which a steel tape having a length up to the ground is wound, a pair of crankshaft portions provided at eccentric positions on both end surfaces of the drum, and a first cylinder in which a piston is connected to each crankshaft portion And a second cylinder, wherein the interior of both cylinders is partitioned into a first chamber on the back side of the piston and a second chamber on the front side of the piston filled with hydraulic oil for operating the piston. The second chambers are communicated with each other by a flow control flow path,
In addition, the apparatus is provided with a flow control valve for controlling the flow rate of the hydraulic oil in the middle of the flow control flow path. The steel tape referred to here is a metal tape having a thickness of 0.2 mm and a width of 16 mm that is obtained by rolling and chamfering a JIS-standard piano wire type B as a material. Steel tape cutting load is 576k
g.

At the time of evacuation, an evacuation escape device is worn by an evacuee, and the tip of a steel tape is fixed to, for example, a window of a high-rise building. The evacuees then go out of the window and tape their weight. This causes the tape to be pulled and the drum to rotate, but since the flow control valve is closed in advance, there is no flow of hydraulic oil between the two hydraulic cylinders, and there is no rotation of the drum. Thereafter, when the flow control valve is gradually opened, the pressure gradually increases from the second chamber of the first cylinder to the second chamber of the second cylinder in a depressurized state via the hydraulic pressure adjustment passage. Hydraulic oil flows in, and then the movement direction of each piston is reversed, so that the flow of hydraulic oil to both chambers repeats reversing, while the drum rotates at low speed and the steel tape is gradually fed out . As a result, the evacuees can safely descend to the ground.

[0004]

However, in this conventional evacuation escape device, for example, in order to support the weight of an adult male, usually, the pressure receiving area of the piston, specifically, the piston surface in contact with the hydraulic oil The area of 13-14cm
^{About two} hydraulic cylinders were required. For example, when operating under a basic condition of a body weight of 100 kg, a height of 100 m (diameter of a drum around which a steel tape is wound 17 cm), and a piston stroke of 3 cm, the maximum oil pressure at the time of use within 45 kg / cm ² is 13 kg. ~ 14cm
^{2 are} required. As a result, there has been a problem that the evacuation escape device that the evacuee must bind to the upper body becomes large, and when worn by a woman or an elderly person, it feels heavy. Therefore, it is conceivable to make the device compact by making the hydraulic cylinder thin. However, as the diameter of the cylinder is reduced, the adjustment of the opening of the flow control valve by manual operation by the evacuee becomes more delicate and the operation becomes more difficult. This is because the pressure receiving area of the piston is small, for example, even if the flow control valve is slightly opened too much, the resistance in the hydraulic cylinder is significantly reduced, and the steel tape supporting the weight of the evacuee is faster than the drum. It is paid out. In the conventional apparatus, the adjustment of the descending speed is performed only by the flow control valve. As a result, in the event of a fire,
The evacuees who have fallen into panic will be required to have calm valve adjustment power.

[0005]

SUMMARY OF THE INVENTION It is an object of the present invention to provide an evacuation device for high places, which can reduce the size of the device and can easily adjust the descent speed. Another object of the present invention is to provide a high-place evacuation device capable of setting the descending speed arbitrarily according to the weight of the evacuees.

[0006]

According to a first aspect of the present invention, there is provided a drum on which a strip of a predetermined length is wound, and a pair of crankshafts provided at eccentric positions on both end surfaces of the drum. A first cylinder having a piston connected to the one crankshaft portion, a second cylinder having a piston connected to the other crankshaft portion, and the first cylinder and / or the second cylinder A flow control flow path provided in the middle of the flow path and provided with flow control means for controlling the flow rate of the working fluid for operating the piston, the inside of the first cylinder and the second cylinder The inside of the first chamber is formed by a corresponding piston, and the first chamber on the back side of the piston and the second chamber on the front side of the piston.
A first chamber of the first cylinder and a second chamber of the second cylinder are communicated by a first communication flow path, and a second chamber of the first cylinder; This is a high-place evacuation device that is connected to the first chamber of the second cylinder by the second communication channel.

Examples of the strip include metal wires such as piano wire, steel tape, rope, and the like. Also,
The material of the strip is not limited. Further, the thickness, thickness, width, length, and the like of the strip are not limited. The crankshaft portion may be one bent long crankshaft or a pair of short shafts protruding from both end surfaces of the drum. The sizes of the first cylinder and the second cylinder are not limited. For example, a cylinder having a diameter of 3 to 4 cm (cross-sectional area of 7 to 13 cm ² ) can be employed. The piston diameter (pressure receiving area) and the maximum oil pressure are correlated and inversely proportional.

[0008] The flow control flow path may be provided in the first cylinder, in the second cylinder, or in both. The flow rate adjusting means is not limited. For example, a manual valve or an electromagnetic valve for opening and closing the flow control flow path may be used. The shapes of the cross sections of the first communication channel and the second communication channel are not limited. For example, the cross section may be circular, and the cross section may be triangular or rectangular. Also,
The cross-sectional area of the two communication channels is not limited. Further, the length of these communication flow paths, the number of the formed communication flow paths, and the like are not limited. However, the cross-sectional area of the flow path needs to be such that the flow velocity of the oil is 4.5 m / sec or less.

According to a second aspect of the present invention, the flow rate adjusting flow path is a flow path for communicating the second chamber of the first cylinder with the second chamber of the second cylinder. It is an evacuation device for high places described in 3.

According to a third aspect of the present invention, the flow rate adjusting means is provided with a safe descent speed setting means for setting a speed at which the evacuee can safely descend according to the weight of the evacuee. An evacuation device for high places according to claim 2. The safe descent speed of the evacuees is 0.7 to 1.1 m / sec, preferably 0.9 to 1 m / sec. If it is less than 0.7 m / sec, the flight time becomes longer, and the probability of being damaged by fire or smoke increases. If the speed exceeds 1.1 m / sec, it is difficult to deal with obstacles in the middle of descending, and at the same time, there is a disadvantage that a large impact is applied to the foot when landing. The configuration of the safe descent speed setting means is not limited as long as the speed at which the evacuees can be safely lowered according to the weight of the evacuees can be set. For example, the maximum descent speed may be set in advance in accordance with the weight of the refugee by applying a mechanical stopper structure, an electric limit switch structure, or the like.

[0011]

According to the present invention, the first chamber of the first cylinder and the second chamber of the second cylinder are connected by the first communication passage, and the second chamber of the first cylinder is connected to the second chamber by the second communication passage. And the first chamber of the cylinder is communicated in a crossing manner by a second communication channel. As a result, the pressure receiving areas of the pistons of the two hydraulic cylinders are the sum of the pressure receiving areas of the two pistons, and the increase in the pressure receiving area enables downsizing of the pistons and, consequently, downsizing of the hydraulic cylinders as compared with the conventional means.

Here, the two cylinders inserted into the two cylinders communicated by the first communication channel or the second communication channel.
Assuming that the sum of the pressure receiving areas of the pistons is A, this A is obtained by the following equation. ^{A = πD 2/4 + π} (D 2 -d 2) / 4 Note, D is diameter piston, d is the diameter of the piston rod. As described above, by securing a large pressure receiving area of the piston, the accuracy of adjusting the flow rate of the working oil flowing through the flow rate adjustment flow path by the flow rate adjustment means can be reduced as compared with the conventional means. As a result, for example, even if the evacuee falls into a panic during an emergency evacuation and the operation of adjusting the flow rate by the flow rate adjusting means becomes slightly rough, the descent speed does not suddenly change unlike the conventional case.

[0013] In particular, according to the invention of claim 3, since the flow rate adjusting means is provided with the safe descent speed setting means, for example,
The speed at which the evacuees are safely lowered can be set in advance according to the weight of the evacuees. As a result, even if a refugee encountering a disaster makes a large mistake in operating the flow rate adjusting means, the maximum speed of the descent speed is set in advance in this way, so the refugee is at a speed that feels fearful Descent is avoided, and descent can always be performed within a safe speed range.

[0014]

Embodiments of the present invention will be described below with reference to the drawings. The interiors of the first cylinder and the second cylinder are divided into a first chamber on the back side of the piston, whose volume changes when the corresponding piston moves, and a second chamber on the front side of the piston. FIG. 1 is a longitudinal sectional view of an evacuation device for high places according to an embodiment of the present invention.
FIG. 2 is a side view including a partial cross-sectional view of the evacuation device for high places according to one embodiment of the present invention. FIG. 3 is a front view of a high-place evacuation device according to one embodiment of the present invention. FIG. 4 is an explanatory diagram of a use state of the evacuation device for high places according to one embodiment of the present invention. FIG. 5 is an explanatory view showing a state in which a steel tape of the evacuation device for high places according to one embodiment of the present invention is hooked to a building. FIG. 6 is an explanatory diagram showing another state in which the evacuation equipment for high places according to one embodiment of the present invention is hooked to a building.

In FIG. 1 to FIG. 3, reference numeral 10 denotes an evacuation device for high places according to an embodiment of the present invention. A drum 12 on which a steel tape (strip) 11 having a length is wound, and a pair of crankshaft portions 13A, 13 provided at eccentric positions of both end surfaces of the drum 12
B and the piston 14 on one of the crankshaft portions 13A.
A, the first cylinder 15 to which the piston 14B is connected to the other crankshaft portion 13B, and the second cylinder 16 on the piston surface side partitioned inside the first cylinder 15. Chamber 15b and the second
A flow control flow path 18 provided with a flow control valve 17 for adjusting the flow rate of hydraulic oil in the middle of the flow path by connecting a second chamber 16 b on the piston surface side partitioned inside the cylinder 16.
And a housing 19.

The feature of the high-place evacuation device 10 of the present invention is that the base end of the first cylinder 15 and the front end of the second cylinder 16 are connected to a communication passage for hydraulic oil. The first
While the front end of the first cylinder 15 and the base end of the second cylinder 16 are communicated by the second communication passage 20B, and the flow rate is adjusted. A safe descent speed setting means 21 for setting the speed at which the evacuees are safely lowered according to the weight of the evacuees at the valve 17
Is provided. Hereinafter, these will be described in detail.

The housing 19 mainly includes a drum housing portion 19a arranged at an upper portion and a cylinder housing portion 1 arranged at a lower portion.
9b. The two storage portions 19a and 19b are joined in a block manner by three joining plates 22 each having a predetermined shape, and are fixed by a large fastening force using a number of hexagon socket head bolts 23. With such a housing structure, an evacuation device for high places that can withstand a large pressure of hydraulic oil is provided. Drum storage unit 19
An outlet for the steel tape 11 is formed at the upper end side of the portion a. A pair of left and right safety hooks 30 are pivotally supported on both sides of the outlet forming portion via connecting members 31. An annular shackle 11 a is fixed to the tip of the steel tape 11. A flow rate adjusting flow path 18 is provided in a lower portion of the cylinder housing portion 19b. Inside this channel, a cone-like shape (abacus ball shape)
Is accommodated. Since the valve shape is set as described above, the flow rate of the hydraulic oil passing through the flow rate control valve 17 can be finely controlled. Moreover, this valve 17
The occurrence of turbulent flow of hydraulic oil passing through can be prevented.

A pair of small tires 32, which are applied to the outer wall of the building during descent and roll on the wall, are supported on one side of the lower portion of the cylinder housing 19b.
At the time of descending, the small tire 32 can be brought down by hitting the outer wall. The drum 12 has a slit 12a for inserting the steel tape 11 at an intermediate portion in the longitudinal direction.
Is a short cylindrical body perforated. A flange 12b and an outer gear 24, which are spaced apart from each other in parallel by a predetermined distance, are provided around an intermediate portion of the drum 12 in the axial direction. There is a winding area of the steel tape 11 between the flange 12b and the outer gear 24. The outer gear 24 is meshed with a small-diameter tape winding gear 25 disposed in a lower portion of the drum housing 19a. At the time of winding the steel tape 11 around the drum 12, a hexagon wrench (not shown) is inserted into a tape winding operation hole 2 formed at a lower portion of the drum housing portion 19a.
6, the drum 12 is rotated by rotating the tape winding gear 25, and the steel tape 11 is rotated.
Is wound. At this time, the flow control valve 17 is fully opened, and after this winding, the valve is closed.

The crankshaft portions 13A, 13B
Are provided on both end surfaces of the drum 12 with a positional shift of 180 degrees from each other. In addition, the piston 14
Transformers 14a are fixed to the base portions (the distal ends of the piston rods) of A and 14B, respectively. Both pistons 14
A and 14B of the transformer portion 14a have crankshaft portions 13A and 1A protruding from both end surfaces of the drum 12, respectively.
3B is pivotally supported. In addition, each piston 14A, 14
The area of the front and back surfaces of B (pressure receiving area) is 7 cm on the front surface
² , the back surface is 6 cm ² , and the sum (sum of the pressure receiving areas)
Is 13 cm ² . The first cylinder 15 and the second cylinder 15
Each of the cylinders 16 has a diameter of 3 cm, which is smaller than a conventional 4 cm hydraulic cylinder. These hydraulic cylinders 15 and 16 are arranged in parallel on both sides of the lower cylinder storage portion 19b.

The first communication passage 20A and the second communication passage 20B have a diameter of 8 provided inside a steel pipe.
mm flow path. The first communication channel 20A allows the first
The first chamber 15a on the piston rear surface side of the cylinder 15 and the second chamber 16b on the piston front surface side of the second cylinder 16 communicate with each other. As a result, the back surface of the piston 14A and the surface of the piston 14B act like a working surface (one surface) of one piston having a pressure receiving area of 13 cm ² . In addition, the second communication channel 20 </ b> B connects the second chamber 15 b on the piston front surface side of the first cylinder 15 and the first chamber 16 a on the piston back surface side of the second cylinder 16. As a result, the front surface of the piston 14A and the back surface of the piston 14B act as a working surface (one surface) of one piston having a pressure receiving area of 13 cm ² . Although not shown, both hydraulic cylinders 15, 1
A large number of air-cooling fins are protruded from the outer peripheral surfaces of the communication passage 6 and the communication passages 20A and 20B. The fins suppress heat generation of the hydraulic system during use of the device.

Next, the safe descent speed setting means 21 will be described in detail. The safe descent speed setting means 21 is for previously setting the amount of movement of the flow regulating valve 17 in the axial direction, and is assembled to a cylindrical casing 19c provided at one lower side of the cylinder housing portion 19b. The axial direction of the cylindrical casing 19c is perpendicular to the axial direction of each of the hydraulic cylinders 15, 16. The flow regulating valve 17 is housed in the central part of the cylindrical casing 19c. A pair of valve shafts 17a and 17b, which extend in the axial direction of the cylindrical casing 19c, protrude from central portions of both ends of the flow control valve 17, respectively.
A hexagonal wrench hole 17c extending in the axial direction is formed in the distal end surface of the valve shaft 17a. In addition, the valve shaft 17
A bolt portion 17d having an external thread is integrally formed on the tip end surface of b.

The distal end of the valve shaft 17a is
9c is engraved on the inner surface of one end of the cylindrical casing 19c.
c is inserted into a valve shaft slide hole 19d extending in the axial direction of c. The valve shaft slide hole 19d communicates with the center of one end surface of the cylindrical casing 19c by a screw hole 19e. A screw shaft 33a of a valve moving amount setting handle 33 serving as an operation unit when setting the maximum moving amount of the flow rate adjusting valve 17 is screwed into the screw hole 19e. A short hexagonal wrench portion 33b inserted into the hexagonal wrench hole 17c is coaxially formed integrally with the distal end surface of the screw shaft 33a. A stop ring 34 for securing the set value after the maximum movement amount of the flow control valve 17 is set to the base of the screw shaft 33a. The stop ring 34 is connected to a screw shaft 33a via a screw 34a.
Fixed to On the other hand, a descent speed adjusting handle 35 for controlling the descent speed of the high-place evacuation device 10 is pivotally supported at the other end of the cylindrical casing 19c via a nut portion 35a also serving as a handle rotation shaft. This nut part 35
The bolt portion 17d of the valve shaft 17b is screwed into a. The control valve configured as described above is capable of changing the volume of the hydraulic oil sealed in the hydraulic mechanism even if the valve is opened and closed by moving the flow control valve 17 to the left and right. Has a characteristic that does not increase or decrease.

Next, a method of using the high-place evacuation device 10 according to this embodiment will be described. This evacuation device for high places 10
Before an emergency such as a fire occurs, a user who uses the evacuation device 10 for high places (for convenience, also referred to as an evacuee) sets a safe descent speed according to his / her weight. Do a descent test for. Note that this descent test is performed on a wall having a height of about 2.5 to 3 m in order to avoid a danger of falling. In the actual descent test, first, the shackle 11a of the steel tape 11 is hooked on the swivel hook 37 directly attached to the wall surface of the building via the fixing bracket 36 (see FIG. 5). Thereafter, the evacuee wears the evacuation tool for high places 10 via the suspension belt 36 for rock climbing hooked on the safety hook 30, and then with the weight on the steel tape 11, removes the weight of the building. Go outside. At this time, it is assumed that a special handle operation for starting the descent test is performed on the flow regulating valve 17 and the valve is in a closed state. The length of the steel tape 11 used at this time is 2.5 to
3.0 m. That is, as shown in FIG. 1, this valve closing operation means that the descending speed adjusting handle 35 is first operated to move the flow rate adjusting valve 17 to the maximum valve opening position, and then the valve moving amount setting handle 33 is operated. This is an operation of pushing the flow control valve 17 back to the original valve closing position. Thus, the hex wrench 33b is inserted into the hex wrench hole 17c to the maximum extent.

In place of the swivel hook 37 , FIG.
May be used. This eccentric mount hook 40 is usually installed on the side of the window forming portion of the building outer wall, and mainly includes a fixed base 41 attached to the wall surface, and is supported by the fixed base 41 so as to be higher than a horizontal plane. It has a right-angled triangular hanging triangular arm 42 that can pivot in a slightly inclined state. The fixing base 41 has a vertically long and thick wall-mounted main body plate 41a. A relatively long upper piece 41b whose tip is bent slightly downward is integrally formed at the upper end of the main body plate 41a, and a relatively short lower piece is formed at the lower end of the main body plate 41a. 41c is integrally formed. The suspension triangular arm 42 includes a short horizontal frame 42a and the horizontal frame 42a.
And an inclined frame 42c that is gradually inclined upward toward the vertical frame 42b.
Note that a thin hanging frame 42d parallel to the vertical frame 42b is provided between the ends of the horizontal frame 42a and the inclined frame 42c on the vertical frame 42b side.
Is spanned. Also, the inclined frame 42 of the horizontal frame 42a
At the end on the c side, a shackle 1 of steel tape 11 is used.
A hanging hook 44 to which 1a is hooked is connected. Further, inside the vertical frame 42b, a swing rod 45 serving as a swing center of the suspension triangular arm 42 is loosely inserted with its upper end and lower end protruding outward. Swivel rod 4
5 is fixed to the upper piece 41b, and the pivot rod 45
Is fixed to the lower piece 41c.

A pair of coil springs 46 are loosely inserted in the center of the vertical frame 42b. One end of each coil spring 46 is hooked to both ends of the hook frame 42d, while the other end of each coil spring 46 is connected to a spring strength adjusting jig 47 provided at an intermediate portion of the main body plate 41a. It is fixed to a T-shaped hook 48. The spring strength adjusting jig 47 rotates the spring force adjusting bolt 49 to adjust the drawing width of the other end of the coil spring 46 hooked on the T-shaped hook 48, so that the spring strength of each coil spring 46 is adjusted. Is a jig to change. In the normal state (when not in use) of the eccentric mount hook 40, the lower end of the suspension triangular arm 42 (the suspension hook 4
4) is pressed by the spring force of the coil spring 46 near the window forming portion of the wall surface of the building, and this state is held by locking means (not shown). On the other hand, during use, that is, when the refugee evacuates from the window,
After the evacuee unlocks the locking means (not shown), the evacuee goes out of the window and places his weight on the hanging hook 44. Thereby, against the spring force,
The suspension triangular arm 42 pivots about the inclined pivot rod 45, and the suspension hook 44 automatically separates from the building wall. As a result, the suspended position when the refugee goes out of the window moves to the side of the window. Therefore, the evacuees can safely descend while avoiding fire or smoke blown out from the window.

When the height of the use floor of the high-place evacuation device 10 is 10 m or less, a swing seat plate is used instead of the suspension belt 36, so that the method of using the high-place evacuation device 10 is simplified. become. Thereafter, the evacuee, while being suspended by the steel tape 11, gradually rotates the valve moving amount setting handle 33 in the valve opening direction to a position where a safe descent speed of 0.9 to 1 m / sec is reached. The flow control valve 17 is moved. Then, while maintaining this state, the stop ring 34 is pressed against the end face of the cylindrical casing 19c and fixed with the screw 34a. As a result, a safe descent speed is set according to the weight of the refugee. After that, in preparation for an actual emergency, the flow rate adjusting valve 17 rotates the descent speed adjusting handle 35 in the valve closing direction, and presses the flow rate adjusting valve 17 against the valve seat to close the valve.

Next, with reference to FIGS. 4 and 5, a method of using the evacuation device 10 for high places in an emergency such as an actual fire will be described. First, the shackle 11a of the steel tape 11 is hooked on the swivel hook 37 fixed to the window of the room of the high-rise building. Thereafter, the evacuee wears the evacuation device for high places 10 on the upper body using the suspension belt 36, and leaves the weight on the steel tape 11 and goes out of the window in this state. At this time, since the flow control valve 17 is held in the closed state immediately after the descent test, the first cylinder 1
No hydraulic oil flows between the fifth and second cylinders 16. Thus, the steel tape 11 is not fed from the drum 12.

After that, the evacuee moves the descent speed adjusting handle 3
5 is gradually rotated in the valve opening direction so that the flow control valve 1
The gap between the valve 7 and the valve seat gradually increases, and the flow rate of the working oil between the first cylinder 15 and the second cylinder 16 via the flow rate adjustment flow path 18 gradually increases.
As a result, the force for controlling the rotation of the drum 12 gradually decreases, and the descending speed of the evacuees gradually stops. However, the increase in the descent speed does not stop at a speed higher than the safety speed set in advance in the descent test. That is, the screw shaft 3 is previously set by the stopper ring 34.
Since the amount of projection of 3a into the flow control flow path 18 is determined, no matter how aggressively rotating the descending speed control handle 35 to move the flow control valve 17 in the valve opening direction (speed increasing direction), The maximum descent speed is maintained within a preset safe descent speed of 0.9 to 1 m / sec. As a result, even if the evacuee who panicked due to a fire or the like rotates the descent speed adjustment handle 35 in the valve opening direction at the same time, the evacuee cannot descend at such a speed as to cause fear. Absent. After arriving on the ground, if the evacuee walks from the place with the high-place evacuation device 10 attached, the length of the steel tape 11 is only the length from the evacuee's room to the ground, and this tape 11
Is simply inserted into the slit 12a of the drum 12, so that the steel tape 11 naturally
Break away from

As described above, the chambers 15a and 15b of the first cylinder 15 and the chambers 16a of the second cylinder 16 are formed by the first communication channel 20A or the second communication channel 20B.
a and 16b are communicated in a crossing manner, so that the piston 14 that operates the hydraulic oil of both hydraulic cylinders 15 and 16 is operated.
The pressure receiving areas of A and 14B are the sum of the front and back surfaces of the pistons 14A and 14B in the communicating state, respectively. As described above, the size of both hydraulic cylinders 15 and 16 can be reduced by the increased pressure receiving area as compared with the conventional cylinder.
In addition, since a large piston pressure receiving area is ensured while using the small hydraulic cylinders 15 and 16 in this manner, the hydraulic oil flowing through the flow control flow path 18 by the flow control valve 17 is compared with the conventional means. The accuracy of adjusting the flow rate becomes gentle. As a result, even if the operation of adjusting the flow rate of the hydraulic oil by the flow rate adjustment valve 17 at the time of evacuation becomes somewhat less likely, the descent speed of the evacuee during descent does not significantly increase. In addition, since a belt for rock climbing is adopted as the suspension belt 36, both feet can be used freely,
You can descend along this surface while walking on the wall. Therefore, for example, even if there is an obstacle on the way, it is possible to safely descend.

If the evacuees fall into the large heat-resistant protective bag together with the evacuation equipment 10 at the time of evacuation, the evacuees falling can be exposed to toxic gas generated by the fire. Or the risk of burning. When there is a child other than the evacuee, the child can be safely lowered by putting the child in a safety bag (not shown) hooked on the safety hook 30. In addition, this evacuation device for high places 1
If 0 is fixed to the upper floor of a high-rise building and the steel tape 11 is slowly led out, for example, a child can be safely evacuated to the ground. That is, instead of the safety hook 30, a wiring (not shown) having a diameter of, for example, about 25 cm is attached, and this is hooked on a swivel hook installed on the outer wall of a high-rise building.
The rescue basket is hung on the shackle 11a of the steel tape 11.

Then, two or three children are put on the rescue basket, and thereafter, a person on the upper floor of the building gradually turns the descent speed adjusting handle 35 in the valve opening direction to safely keep the children. You can evacuate to the ground. Thus, the thickness of the steel tape 11 is extremely thin, 0.2 mm. For this reason, for example, even when the steel tape 11 having a length of 100 m is wound on the drum 12 having a diameter of 6 cm, the outer diameter of the wound portion is about 17 cm. Thereby, it is convenient for storage and can be widely applied from a high-rise building to which a ladder car cannot reach to a general house, and becomes a very effective evacuation device for high places as a third evacuation route.

[0032]

According to the present invention, since the two chambers of the first cylinder and the two chambers of the second cylinder are communicated in a crossing manner, the pressure receiving area of the piston is increased. Can be reduced in size, and the adjustment of the descending speed can be facilitated.

In particular, according to the third aspect of the present invention, since the safe descent speed setting means is provided in the flow rate adjusting means, the maximum descent speed can be determined in advance according to the weight of the evacuees. it can.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view of an evacuation device for high places according to an embodiment of the present invention.

FIG. 2 is a side view including a partial cross-sectional view of a high-place evacuation device according to one embodiment of the present invention.

FIG. 3 is a front view of the evacuation device for high places according to one embodiment of the present invention.

FIG. 4 is an explanatory diagram of a use state of the high-place evacuation device according to one embodiment of the present invention.

FIG. 5 is an explanatory view showing a state in which a steel tape of the evacuation device for high places according to one embodiment of the present invention is hooked to a building.

FIG. 6 is an explanatory diagram showing another state in which the evacuation device for high places according to one embodiment of the present invention is hooked to a building.

[Explanation of symbols]

10 evacuation equipment for high places, 11 steel tape (strip), 12 drums, 13A, 13B Crankshaft part, 14A, 14B piston, 15 first cylinder, 16 second cylinder, 17 flow control valve (flow control means), 18 flow control flow path, 19 housing, 2
0A first communication channel, 20B second communication channel, 21
Safe descent speed setting means.

Continued on the front page (72) Inventor Toshimasa Kohara 1 of 745, Tazu, Oji, Bungotakada City, Oita Prefecture (72) Inventor Yuji Tsuchiya 127, Tajima, Oji, Bungotakada City, Oita Prefecture (72) Inventor Tohru Kohara Bungo, Oita Prefecture Ryoichi Kohara, 744, Tazu, Oda-shi, Takada City Inventor: Ryoichi Kohara 745-2, Tazu, Oaza, Bungotakada-shi, Oita Prefecture (56) References JP-A-7-31686 (JP, A) JP-A-61-58674 ( JP, A) (58) Field surveyed (Int. Cl. ⁷ , DB name) A62B 1/06 A62B 1/00 F15B 15/00

Claims (3)

(57) [Claims] 1. A drum on which a strip of a predetermined length is wound, a pair of crankshaft portions provided at eccentric positions on both end surfaces of the drum, and a piston connected to the one crankshaft portion A first cylinder, a second cylinder in which a piston is connected to the other crankshaft portion, and a second cylinder provided in the first cylinder and / or the second cylinder. A flow control flow path provided with flow control means for controlling a flow rate of a working fluid to be operated, wherein the inside of the first cylinder and the inside of the second cylinder are respectively formed by corresponding pistons on the back side of the piston. And a second chamber on the piston surface side, wherein the first chamber of the first cylinder and the second chamber of the second cylinder are communicated by a first communication channel. The first
The evacuation device for high places, wherein the second chamber of the cylinder and the first chamber of the second cylinder are communicated by the second communication channel. 2. The evacuation device for high places according to claim 1, wherein the flow control flow path is a flow path that connects the second chamber of the first cylinder to the second chamber of the second cylinder. . 3. The high flow according to claim 1, wherein said flow rate adjusting means is provided with a safe descent speed setting means for setting a speed at which the evacuees can safely descend according to the weight of the evacuees. Evacuation equipment required.