JP2571967B2 - Water discharge device - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a water discharge device, and more particularly to a water discharge device used for an indoor or outdoor fire hydrant or the like.

The fire hydrant, which has been widely used in the past, is a fire hose type hose with rubber lining on the inner surface of a tubular woven fabric, folded in a zigzag and stored in a fire hydrant box. When you do this, you must take out the entire length from the fire hydrant box and use it, and if the hose is bent, it will not be possible to pass water, making it difficult for inexperienced people to pass water satisfactorily. there were.

Therefore, in recent years, there has been a demand for a fire hydrant which can be housed in a fire hydrant box in a state in which the hose is wound around a winder, and can be passed through the wind while being wound on the winder.

Fire hydrants of this type are generally wound around a hose that always keeps a circular cross section, such as a rubber hose.
The hose is heavy, and the thickness of the hose is large, making it difficult to handle, and the fire hydrant becomes large, which is not preferable.

Therefore, if a conventional fire hose type hose can be wound around a winder and stored in a fire hydrant box, it will be light and easy to handle, and the fire hydrant will also be compact. Hose-type hoses are usually folded flat, and cannot be swollen even if you try to pass water while wound around the winder,
Can not be used.

As a solution to this problem, Japanese Patent Application No. 62-271500 (Japanese Patent Application Laid-Open No. 1-117184) previously filed by the applicant and Japanese Patent Application No.
No. 317152 (JP-A-1-156285), Japanese Patent Application No. 62-317153.
(JP-A-1-156286) and Japanese Patent Application No. 62-331771 (JP-A-1-172188).

In these devices, the winding frame of the winder can be radially reduced, and the water pressure applied to the hose during water flow causes the winding frame to shrink radially, thereby expanding the hose into a cylindrical shape. It is designed to forgive.

In recent years, as a hose with a special form of fire hose type that can be wound on a normal reel, weaving metal wire or synthetic resin bristle into the weft of the tubular woven fabric to prevent it from flattening, A hose with an inner lining has been proposed and attracted attention.

According to these inventions, it is possible to use a hose of the fire hose type, which has not been able to pass water while being wound on a reel, and to pass water while being wound on a reel. Although it became compact and allowed water to be discharged at high pressure, new problems have arisen here.

In other words, a problem has arisen in that the reels are inadvertently rotated during use, and the hoses more than necessary are naturally drawn out.

Since the hose of the fire hose type is provided with a lining on the inner surface of a tubular woven fabric as described above, and the tubular woven fabric is formed by weaving a warp yarn and a weft yarn having high strength in a tubular shape. When the hose is inflated into a cylindrical shape, it is difficult to bend, and tends to extend linearly when an internal pressure is applied. However, since the hose wound on the reel is curved, water flows through this hose and the internal pressure acts,
When a force is applied to the hose to extend in a straight line, the force acts to rotate the hose in the direction in which the hose is extended, and the reel starts rotating in the direction in which the hose is extended.

Therefore, when the water is discharged, the hose may be unreeled from the reel, and the hose may come off the outer periphery of the reel, or the hose may be entangled or bend locally to cause a kink phenomenon, thereby preventing water from flowing. is there.

This tendency also exists in ordinary rubber hoses and the like, but is particularly remarkable in fire hose types.

2. Description of the Related Art As means for solving these problems, Japanese Patent Application No. 63-47827 (JP-A-1-220686) filed by the applicant earlier,
Japanese Patent Application No. 63-73008 (JP-A-1-247375), Japanese Patent Application No. 63-73008
No. 301640 (Japanese Patent Application Laid-Open No. 2-147573).

The invention of Japanese Patent Application No. 63-47827 applies a resistance to the rotation of the reel by a brake means to prevent the reel from rotating carelessly. Application for Japanese Patent Application No. 63-73008 and Japanese Patent Application No.
In the invention of Japanese Patent Application No. 3-301640, the brake resistance acting on the rotation of the reel is adjusted by the water pressure applied to the hose.

Problems to be Solved by the Invention However, the rotating force applied to the reel is extremely complicated, and the mechanism as described above cannot reliably prevent the rotating force, or draws out or winds the hose. It is heavy and difficult to operate.

In other words, the rotational force applied to the reel is not limited to the case where the hose is pulled out in the direction in which the hose is extended so as to extend linearly when water pressure is applied to the hose as described above. Even if the pull-out force is stopped after the desired length has been drawn out, the reel may continue to rotate due to inertia and the hose may be drawn out. Further, since the drawn-out hose is filled with water, the hose is heavy and the hose may be drawn out carelessly due to its weight.

Rotational force due to the force that the hose tries to extend linearly,
In FIG. 3, as shown by the straight line a, the pressure changes almost in proportion to the water pressure applied to the hose, but the latter two are almost constant irrespective of the magnitude of the water pressure, as shown by the straight line b. Then, when a rotational force due to the force of the hose extending and a force to rotate the reel due to inertia or gravity are applied, a substantially straight line c is obtained.

Thus, it is necessary to prevent the reel from rotating and the hose from being unintentionally extended by these actions.
The operator must be able to easily pull the hose out of the reel as desired and wind the hose around the reel after use. Also when used in indoor or outdoor fire hydrant is not necessarily the pressure of the water source of the fire hydrant is constant, typically about 3 kg / cm ² from 7 kg / cm ²
Range. Therefore, it must be able to be used without any problem within these pressure ranges.

Incidentally, in the invention of Japanese Patent Application No. 63-47827, the frictional resistance applied to the reel is, as shown by a broken line d in FIG.
If the frictional resistance is small because it is almost constant regardless of the water pressure, the reel may start to rotate due to the force that the hose tries to extend linearly when used under high pressure. If it is large, it is difficult to extend the hose when used under low pressure, which may hinder fire fighting activities.

In the applications of Japanese Patent Application Nos. 63-73008 and 63-301640, the magnitude of the frictional resistance is almost proportional to the water pressure as indicated by the broken line e. It is effective against the rotational force due to the force
It has little effect on the inertia of the hose when it is extended or on the extension of the weight of the hose.

It is also possible to increase the coefficient of increase in frictional resistance due to water pressure, as shown by the dashed line f in FIG. 3. In addition, at high pressures, the frictional resistance becomes too large, making it difficult to operate the hose for feeding and winding.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and when used, reliably prevents the reel from being carelessly rotated and the hose being fed out, and easily winds the hose when not in use. It is an object to provide a water discharge device that can be taken.

Means for Solving the Problems In the water discharge device of the present invention, a reel is rotatably mounted on a support, and water is passed through a hose wound around the reel through a shaft of the reel. A fixed-side friction member and a rotation-side friction member are provided on a support and a reel, respectively, and the fixed-side friction member and the rotation-side friction member are constantly pressed against each other by a spring force to frictionally engage with each other, and fluid applied to the hose The pressure contact force of the friction member is increased by pressure.

As a specific structure, a rotating shaft is rotatably and axially slidably fitted to a fixed shaft fixed to the support so as to be watertight, and the reel is fixed to the rotating shaft. A disk-shaped fixed friction member is fixedly connected to the fixed shaft, a disk-shaped rotating friction member is rotatably provided on a side surface of the fixed friction member, and the rotation friction member is connected to the reel. Then, the rotating friction member is constantly pressed against the fixed friction member by a spring means, and a part of the reel is made to face a side surface of the rotating friction member, and the rotating friction member is moved by sliding the reel. It is suitable to press against the fixed-side friction member.

Further, in the present invention, one of the fixed-side friction member and the rotation-side friction member is fixedly connected to the support or the reel, and the other is connected to the reel or the support by a reel having a hose. It is preferable that they are connected indirectly so that they are connected only when rotating in the feeding direction.

Further, the structure is such that the support or the reel and the friction member indirectly connected thereto are relatively fixed to the hose against the spring force over a predetermined range while maintaining the connected state. Suitably, it is rotatable in the rotation direction at the time of feeding.

As a more specific structure, a vortex spring is attached to a shaft attached to the support or the reel so that the outer end thereof can be pulled out, and the vortex spring is attached to the outer end of the vortex spring only when the reel is rotated in the feeding direction of the hose. By providing an engaging member capable of engaging with the friction member, and by pulling out the spiral spring, the reel can be rotated only in a predetermined range in the hose feeding direction with respect to the rotation-side friction member. it can.

An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 shows an embodiment of the water discharge device of the present invention. Reference numeral 1 denotes a support, and a fixed shaft 2 is fixed to the support 1, and a hollow rotary shaft 3 is fitted to a tip of the fixed shaft 2 so as to be rotatable and slidable in the axial direction. , An O-ring 4 for watertight sealing. A rear end of the fixed shaft 2 is connected to a tip of a water pipe 5, and a water pipe 6 is integrally attached to a tip of the rotating shaft 3.

A reel 7 is rotatably supported on the rotating shaft 3. This reel 7 has a pair of flanges 8, 9
And one flange 8 is integrally attached to a rotating plate 10 fixed to the water pipe 6, and the other flange 9 is a rotating member 11 rotatably and slidably supported by the fixed shaft 2. It is integrally attached to.

A wound bed 12 is suspended between the flanges 8 and 9, and a hose 13 is wound around the wound bed 12. Thus, water is passed from the water supply pipe 5 to the hose 13 via the fixed shaft 2, the rotating shaft 3, and the water distribution pipe 6.

A plurality of (three in the drawing) shafts 14 are suspended between the rotating plate 10 and the rotating member 11, and flanges 8, 9 are connected by the shafts 14 and the winding floor 12, It behaves as one.

A disk-shaped fixed-side friction member 15 is attached to the outer periphery of the distal end of the fixed shaft 2. Rotation-side friction members 16 and 17 are rotatably provided on both surfaces of the fixed-side friction member 15. The outer peripheral portions of the rotation-side friction members 16, 17 are connected by a plurality of pins 18a, 18b. In the pin 18a, the rotating friction members 16, 17 are urged in a direction approaching each other by a spring means 19, and the pin 18a and the pin 18b simply connecting the two are alternately provided. The fixed-side friction member 15 is sandwiched between the rotation-side friction members 16 and 17 by the spring means 19 to frictionally engage the two.

The tip of the rotating member 11 is closely opposed to the side of the rotating friction member 16, and a sheet 20 having a small friction coefficient is adhered to the opposed surface of the rotating friction member 16. When the rotating member 11 slides rightward in the figure with respect to the fixed shaft 2, the leading end surface of the rotating member 11
The rotation-side friction member 16 is pressed via 20.

One of the shafts 14a has the friction member group 15, 1
A sleeve 21 is fitted at a position corresponding to the outer side of 6, 17 and a spiral spring 22 is wound around the outer periphery of the sleeve 21 so that the outer end thereof can be pulled out. And the spiral spring
An engagement member 24 is attached to a tip end of the arm 22 via an arm 23. The engaging member 24 can be engaged with the pin 18. Reference numeral 25 denotes a torsion coil spring that urges the engaging member 24 toward the center of the reel 7.

Thus, when no water pressure is applied to the hose 13, the reel 7 is biased to the left in the drawing, and the rotating member 11 does not press the rotating friction member 16. In this state, the fixed-side friction member 15 and the rotation-side friction members 16, 17 are pressed against each other only by the spring force of the spring means 19.

Here, when the hose 13 is wound around the reel 7, the reel 7 rotates clockwise in FIG. In this rotating direction, the engaging member 24 is in the non-engaging direction with respect to the pin 18, so that there is no resistance to the rotation of the reel 7, and the hose 13 can be easily wound with a small force.

Next, when the hose 13 is pulled out from the reel 7, the reel 7 rotates counterclockwise in the drawing. At this time, the engaging member 24 engages with any one of the pins 18, but since the elastic force of the spiral spring 22 is smaller than the frictional resistance of the friction members 15, 16, 17, the rotation-side friction members 16, 17 rotate. 2, the spiral spring 22 is pulled out with the rotation of the reel 7, and wound around the outer circumferences of the rotation-side friction members 16 and 17, as indicated by a chain line A in FIG. When the reel 7 rotates nearly one rotation, the reel 7 moves to the position shown by the chain line B, and the spiral spring 22 is
Contact 24.

At this stage, the rotation resistance of the reel 7 is only the elasticity of the spiral spring 22, and the reel 13 can be rotated by only the force required to pull out the spiral spring 22, and the hose 13 can be pulled out. If the pulling force of the hose 13 is released in the middle, the reel 7 rotates clockwise by the elastic force of the spiral spring 22, and the fed hose 13 can be wound again.

When the hose 13 is further pulled out after the shaft 14a has reached the position of the chain line B in FIG. 2 and the reel 7 is rotated, the spiral spring 22 comes into contact with and pushes the engaging member 24, and the engaging member 24 is pressed.
Is engaged with the pin 18, the reel 7 cannot rotate with respect to the rotating friction members 16 and 17, and the rotating friction members 16 and 17 start rotating together with the reel 7. Since the rotation-side friction members 16 and 17 are pressed against the fixed-side friction member 15 by the elastic force of the spring means 19, the rotation-side friction members 16, 1
The rotation of the reel 7 has a resistance, and the reel 7 is rotated against the frictional resistance.

Then, when the hose 13 is pulled out to a desired length and the drawing operation of the hose 13 is stopped, the reel 7 continues to rotate due to inertia, but the rotating side friction members 16 and 17 and the fixed side friction member 1
Due to the frictional resistance with 5, the rotation stops immediately. Then, the reel 7 rotates clockwise by the resilience of the spiral spring 22, and the excessively fed hose 13 is caught and slack is removed. There is no resistance to the rotation of the reel 7 with respect to the rotation of the hose 13 in the winding direction.

Next, when water pressure is applied to the hose 13, the water pressure causes the rotary shaft 3 to slightly slide in the direction in which it extends with respect to the fixed shaft 2, that is, rightward in the drawing. As a result, the reel 7 also moves to the right in the figure as a whole, and the leading end surface of the rotating member 11 presses the rotating friction member 16 via the sheet 20,
The rotation-side friction member 16 is a spring means with respect to the fixed-side friction member 15.
The elastic force of the reel 19 and the biasing force of the reel 7 caused by the water pressure make the reel 7 more tightly pressed.

Therefore, the resistance to rotation of the rotation-side friction members 16, 17 is
A pressing force is applied to the elasticity of the spring means 19 by water pressure, and the frictional resistance increases as the water pressure increases.

When a water pressure is applied to the hose 13, a force is applied to the hose 13 to extend the hose 13 in a straight line due to the water pressure, as described above. Direction rotational force acts. However, as described above, the rotating member is proportional to the magnitude of the water pressure.
The pressing force by 11 acts, and the frictional resistance between the fixed-side friction member 15 and the rotation-side friction members 16 and 17 increases, so that the reel 7 rotates in the hose feeding direction due to the force of the hose 13 trying to extend linearly. However, the hose 13 is not inadvertently extended.

Since the rotation resistance is frictional resistance, it is possible to rotate the reel 7 against this resistance.
13 can be pulled out as needed by pulling. And the frictional resistance increased by the water pressure is offset by the rotational force of the reel 7 based on the force of the hose 13 trying to extend linearly,
Fixed-side friction member 15 and rotation-side friction member 1 by spring means 19
Since the hose 13 is extended only against the frictional resistance based on the pressure contact force with the hoses 6, 17, the force required to pull out the hose 13 does not become unnecessarily large.

Therefore, even in the state where the water pressure is applied to the hose 13, the operation can be performed in exactly the same manner as the above-described state where the water pressure is not applied, and the operability does not differ depending on the magnitude of the water pressure, and also carelessly. The hose 13 is not extended.

The present invention is not limited to the structure of the above embodiment. In the embodiment, the engaging member 24 is engaged with the pin 18 via the spiral spring 22 on the reel 7, but the engaging member 24 is directly connected to the reel 7, and is always engaged when the reel 7 rotates in the hose feeding direction. The reel 7 and the rotation-side friction members 16 and 17 can be indirectly connected by engaging the joining member 24 with the pin 18.

In the embodiment, the fixed-side friction member 15 is directly connected to the fixed shaft 2 and the rotating-side friction members 16 and 17 are indirectly connected to the reel 7 via the engaging member 24. The side friction member 15 and the fixed shaft 2 may be indirectly connected, and the rotation side friction members 16 and 17 and the reel 7 may be directly connected.

In the present invention, when the hose 13 is not under water pressure, the fixed-side friction member 15 and the rotation-side friction member 1
6 and 17 are frictionally engaged only by the elastic force of the spring means 19, and the frictional resistance prevents the hose 13 from being excessively extended by the inertia of the rotation-side friction member 17. When water pressure is applied to the hose 13, the action of the water pressure causes the fixed-side friction member 15 to move.
The pressing force between the rotating members 16 and 17 is increased in proportion to the magnitude of the water pressure, so that the frictional resistance increases, and the frictional resistance becomes a state shown by a broken line g in FIG. The extension of the hose 13 due to the rotation of the reel 7 due to the force of the hose 13 to which the water pressure has been applied tends to extend linearly is prevented.

In addition, the force required to pull out the hose 13 and rotate the reel 7 is the fixed-side friction member 15 increased by water pressure.
The frictional resistance between the rotating friction members 16 and 17 is offset by the rotating force of the reel 7 due to the force of the hose 13 extending linearly, and the elastic force of the spring means 19 causes the fixed friction member 15 and the rotating friction. A force that resists frictional resistance with the members 16 and 17 remains. This force is almost constant regardless of the water pressure.

In the invention of claim 2, when water is passed through the hose, first, water pressure is applied to the fixed shaft 2 and the rotating shaft 3,
Due to the water pressure, the rotating shaft 3 slightly slides in a direction (rightward in FIG. 1) extending with respect to the fixed shaft 2. Due to this sliding, a part of the reel 7 is turned into the rotation side friction member 16.
, And the pressing force between the fixed-side friction member 15 and the rotation-side friction members 16 and 17 is increased, and the rotation resistance of the reel 7 is increased.

Then, when the reel 7 is rotated in the hose winding direction to store the hose 13 on the reel 7 after use, no water pressure is applied to the hose 13 at this time. The hose 13 can be wound by rotating the reel 7 against only the pressure contact with the members 16 and 17.

According to the third aspect of the present invention, when the reel 7 rotates in the hose winding direction, the reel 7 does not engage with the fixed-side friction member 15, so that no rotational resistance acts on the reel 7.

Further, in the invention of claim 4, in the initial stage of drawing out of the hose 13, the reel 7 rotates over a predetermined range against the spring force, and in this range, the rotating side friction members 16, 1 are rotated.
7 does not rotate with respect to the fixed-side friction member 15. When the reel 7 rotates beyond the predetermined range, the rotation-side friction members 16 and 17 rotate with the reel 7, and the rotation of the reel 7 causes the fixed-side friction member 15 and the rotation-side friction member 1 to rotate.
Friction with 6,17 becomes resistance. When the drawing of the hose 13 is stopped and the hose 13 becomes slack, the reel 7 is rotated without resistance in the hose winding direction by the spring force, and the slack is taken up by winding the hose 13.

Thus, according to the present invention, the rotating friction members 16 and 17 connected to the reel 7 and the fixed friction member 1 connected to the support 1 are provided.
5 and frictional resistance occurs. And the frictional resistance is
When the water pressure is not applied, the pressure is applied only by the pressing force of the spring means 19, but when the water pressure is applied, the rotating member 11 presses the rotating friction member 16 so that the pressure is almost proportional to the magnitude of the water pressure. As the water pressure increases, the rotational resistance of the reel 7 gradually increases.

However, when water is passed through the hose 13, a force is applied to the hose 13 to extend linearly due to the internal pressure, and the force applies a rotational force to the reel 7 in the hose feeding direction, and the rotational force is applied to the hose 13. It is almost proportional to water pressure. Therefore, the rotational force applied to the reel 7 and the rotational resistance of the reel 7 increased by the water pressure almost cancel each other, and the force required to actually pull out the hose 13 and rotate the reel 7 is substantially independent of the magnitude of the water pressure. It will be constant.

Therefore, the hose 13 can be pulled out by rotating the reel 7 against the substantially constant rotational resistance, and the hose 13 can be pulled out.
The rotation of the reel 7 due to inertia and the rotation of the reel 7 caused by the weight of the hose 13 when the drawing of the reel 7 is stopped can be stopped quickly by the substantially constant rotational resistance applied to the reel 7.

Therefore, various kinds of rotational force applied to the reel 7 are effectively suppressed, and the reel does not rotate carelessly to feed out the hose, so that the hose does not become entangled or kinked.

According to the third aspect of the present invention, the reel 7 and the rotation-side friction members 16 and 17 are coupled only when the reel 7 rotates in the hose feeding direction, and the reel 7 moves in the hose winding direction.
Is rotated, the reel 7 and the rotation-side friction members 16 and 17 are rotated.
Is not combined with Therefore, although the above-described action is provided for rotation in the hose unwinding direction, no rotation resistance is generated on the reel 7 for rotation in the hose winding direction. Therefore, when the hose 13 is stored after use, the reel 13 can be freely rotated to wind the hose 13.

In the invention of claim 4, in the initial stage when the reel 7 rotates in the hose feeding direction, the reel 7 is pulled out against the spring force, and thereafter, the fixed-side friction member 15 and the rotation-side friction members 16 and 17 are pulled out.
When the hose 13 becomes slack after the desired amount has been drawn out, the hose force is applied by the spring force.
13 slack can be wound up. Accordingly, it is possible to more effectively prevent the hose 13 that has been excessively pulled out from becoming loose and entangled or causing a kink phenomenon.

[Brief description of the drawings]

FIG. 1 is a central longitudinal sectional view showing one embodiment of the present invention,
FIG. 2 is a cross-sectional view taken along the line II-II in FIG. FIG. 3 is a graph showing the relationship between the change in the rotation force or the rotation resistance of the reel due to the change in the water pressure in the present invention and the conventional water discharge device. DESCRIPTION OF SYMBOLS 1 ... Support body 2, ... Fixed shaft 3 ... Rotating shaft, 7 ... Reel 11 ... Rotating member, 13 ... Hose 14 ... Shaft, 15 ... Fixed side friction member 16, 17 ... Rotation side Friction member 19: Spring means, 22: Spiral spring 24: Engaging member

Claims (5)

(57) [Claims] 1. A reel (7) rotatably mounted on a support (1), and a hose (13) wound around the reel (7) through a shaft (2, 3) of the reel (7). The support (1) and the reel (7)
Are provided with a fixed-side friction member (15) and a rotation-side friction member (16, 17), respectively. The fixed-side friction member (15) and the rotation-side friction member (16, 17) are constantly pressed against each other by a spring force. And a fluid pressure applied to the hose (13) to increase the pressure contact force of the friction members (15, 16, 17). 2. A rotating shaft (3) is rotatably and axially slidably fitted to a fixed shaft (2) fixed to the support (1) so as to be watertight, and the rotating shaft is The reel (7) is fixed to (3), a fixed friction member (15) having a disk shape is fixedly connected to the fixed shaft (2), and a disk-shaped friction member (15) is attached to a side surface of the fixed friction member (15). The rotation side friction members (16, 17) are rotatably provided, and the rotation side friction members (16, 17) are connected to the reel (7),
The rotating friction members (16, 17) are constantly pressed against the fixed friction members (15) by spring means (19), and a part of the reel (7) is attached to the side surface of the rotating friction members (16, 17). The rotating friction member (16, 17) is pressed against the fixed friction member (15) by sliding the reel (7). Water discharge device 3. One of the fixed-side friction member (15) and the rotation-side friction member (16, 17) is fixedly connected to the support (1) or the reel (7). The other is the reel (7) or the reel (7) with respect to the support (1).
2. The coupling according to claim 1, wherein the couplings are indirectly connected only when the hoses rotate in the direction in which the hose is extended.
Water discharge device described in 4. The support (1) or the reel (7) and the friction members (15, 16, 17) connected indirectly to the support (1) or the reel (7) over a predetermined range while maintaining the connected state. The water discharge device according to claim 3, wherein the water discharge device is rotatable relative to a spring force in a rotation direction when the hose (13) is extended. 5. A spiral spring (22) is attached to a shaft (14) attached to the support (1) or the reel (7) so that an outer end thereof can be pulled out, and an outer end of the spiral spring (22). And an engagement member (24) that can be engaged with the friction member (15, 16, 17) only when the reel (7) is rotated in the extension direction of the hose (13), and pulls out the spiral spring (22). The reel according to claim 4, characterized in that the reel (7) is rotatable only in a predetermined range with respect to the rotation side friction member (16, 17) in a direction in which the hose (13) is extended. Water discharge device