JP2006181057A - Hydrant apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To facilitate assembling work and maintenance work and reduce the depth dimension of a casing in a door lowering opening type hydrant apparatus. <P>SOLUTION: This hydrant apparatus 1 is provided with a lowering door 19 opening a front opening part 20 of the casing 2 by its lowering, and a damper 25 elongated by the lowering of the lowering door 19 and giving a resistance to the lowering of the lowering door 19, between the casing 2 and the lowering door 19. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a fire hydrant device, and more particularly, to a fire hydrant device provided with a descending door that opens by lowering the front surface of a housing in which a fire hose or the like is stored.

  There are various types of door opening methods that open the front of the housing in the fire hydrant device, but as a conventionally known method, a door lowering and opening type that opens the front of the housing by lowering the door is known. There is something.

In JP-A-8-57075 (Patent Document 1), FIGS. 8 and 9 show that a hose outlet for raising and lowering the hose 51 and operating the fire hydrant valve 54 moves up and down within the height of the fire hydrant box 52. A fire hydrant device including a door 53 that can close or open 55 is disclosed. In the fire hydrant device, the door 53 is lowered to open the hose outlet 55. That is, Patent Document 1 discloses a fire hydrant device of a door lowering and opening type.
JP-A-8-57075

  According to the above-mentioned fire hydrant device of the door lowering and opening type, even when the door is opened, the door does not protrude in front of the fire hydrant device housing. Will not interfere with the traveling vehicle.

  Moreover, according to the door-opening open type fire hydrant device as described above, the force of the door falling due to its own weight can be used to open the door, so that the operation can be performed quickly and easily. .

  By the way, in the fire hydrant apparatus of the door lowering and opening type as described above, the casing has a stopper function for stopping the door at the open position, and for the purpose of preventing damage to the casing, the falling speed of the door is set. In order to control, generally, a mechanism in which the end of a wire with a weight suspended at the end is locked to a descending door via a pulley, and the weight becomes a counterweight with respect to the dropping operation of the descending door, that is, the descending A counterweight mechanism is provided on the door.

  In the conventional door-lowering open fire hydrant device, since the lower door is provided with a counterweight mechanism, the number of parts of the mechanism is large and assembly work is difficult, and the mechanism has many movable parts. Therefore, there are many objects to be maintained, maintenance work is difficult, and it is necessary to arrange the pulley and weight in the mechanism back and forth in the depth direction of the fire hydrant device. There are problems such as a large thickness in the depth direction, resulting in a large depth dimension of the fire hydrant housing.

  In view of the above circumstances, the present invention provides a door-lowering open fire hydrant device that allows easy assembly work, easy maintenance work, and the depth dimension of the housing. The purpose is to make it smaller.

  To describe the present invention that achieves the above object, the present invention relates to a fire hydrant device having a descending door that opens by lowering a front opening of a housing, and the descending door is provided between the housing and the descending door. A fire hydrant device provided with a damper that extends by lowering and gives resistance to lowering of the lowering door.

  In the fire hydrant apparatus, the damper may provide resistance to the lowering of the lowering door from the beginning of the lowering of the lowering door.

  In the fire hydrant apparatus, the damper may provide resistance to the lowering of the lowering door after the lowering door is lowered to a predetermined position.

  In the fire hydrant apparatus, the damper may be contracted by the rising of the descending door and may not give resistance to the rising of the descending door.

  In the fire hydrant apparatus, the damper includes a cylinder, a piston that divides the inside of the cylinder into a compression side cylinder chamber and an extension side cylinder chamber, a piston rod that is connected to the piston and extends outward from the cylinder, The piston has a communication passage that communicates the compression-side cylinder chamber and the expansion-side cylinder chamber, and an attachment portion on the other end side of the cylinder is attached to the rear surface of the front panel of the housing, and the piston rod is extended. A mounting portion on the exit end side can be attached to the rear surface of the descending door, wherein the damper can be filled with oil inside the cylinder, and the damper can be The cylinder may be filled with oil and gas, and an oil layer and a gas layer may be formed inside the cylinder. The mounting portion on the end side can be slidably mounted on the descending door along the expansion / contraction direction of the piston rod, and the damper is formed on the piston and extends from the compression-side cylinder chamber. It is possible to have a check flow passage that allows flow to the side cylinder chamber and prevents flow from the expansion side cylinder chamber to the contraction side cylinder chamber, for example, a flow passage having a check valve.

  In the fire hydrant apparatus, the casing includes the front opening that is opened by the descending door, and includes a front panel that is detachably attached to the casing, and the damper includes the front panel and the lowering. A door unit that is provided between the door and includes the front panel, the lower door, the front opening opened by the lower door, and the damper, and is detachably attached to the housing. Can be configured.

  In the fire hydrant apparatus, the casing may be housed with a fire hose wound around an inner winding.

  According to the present invention, by providing the damper between the housing and the descending door so as to extend by the descending of the descending door and to provide resistance against the descending of the descending door, the fall of the descending door While having a speed control mechanism, it is possible to obtain a fire hydrant device that is easy to assemble, and to obtain a fire hydrant device that is easy to perform maintenance work, as compared to the conventional example. Thus, it is possible to obtain a fire hydrant apparatus that can reduce the depth dimension of the fire hydrant.

  Further, according to the present invention, since the damper is given resistance against the lowering of the lowering door from the initial stage of the lowering of the lowering door, the dropping speed is controlled from the initial lowering of the lowering door. And damage to the housing can be prevented. Specifically, for example, by setting the damper so that the inside of the cylinder is filled with oil, the falling speed of the lower door can be controlled by the damper from the initial descent of the lower door.

  Further, according to the present invention, the damper is lowered quickly to the predetermined position by providing resistance to the lowering of the lowering door after the lowering door is lowered to the predetermined position. Thus, it can be lowered from the predetermined position while controlling the speed, and the fire can be extinguished quickly by opening the front opening while preventing the casing from being damaged. Specifically, for example, the damper is assumed to be filled with oil and gas inside the cylinder, an oil layer and a gas layer are formed inside the cylinder, and the piston passes through the gas layer. When the piston passes through the oil layer, it resists the descending of the descending door while giving little resistance to the descending of the descending door. It can be quickly lowered by free fall without applying a damping force to a predetermined position, and can be lowered while controlling the speed by applying a damping force from a predetermined position.

  Further, according to the present invention, the damper is contracted by the raising of the lowering door and does not give resistance to the raising of the lowering door, so that the lowering of the lowering door is prevented. While resistance is given, resistance to raising of the descending door, that is, return, can be not given, and a return operation for closing the front opening can be easily performed. Specifically, for example, in addition to the communication path in which the piston communicates between the compression side cylinder chamber and the expansion side cylinder chamber, for example, an orifice, the damper is allowed to flow from the compression side cylinder chamber to the expansion side cylinder chamber. It shall have a check flow passage that allows and prevents the flow from the expansion side cylinder chamber to the compression side cylinder chamber, for example, a check flow passage having a check valve. Is used as a flow passage that allows the movement of the piston, and when the lowering door is raised, a check flow passage having a check valve in addition to the orifice is also used as a flow passage that allows the movement of the piston. It is possible to give resistance to the movement toward the expansion side and hardly give resistance to the movement toward the contraction side of the piston. For the rise of the descending door, that is, return It can be made not give Tondo resistance.

  Further, according to the present invention, the casing has the front opening that is opened by the descending door, the front panel is detachably attached to the casing, and the damper is connected to the front surface. The front panel includes the lower door, the front opening opened by the lower door, and the damper, and is detachable from the housing. By constituting the door unit to be attached, the door unit includes the lowering door, the front opening opened by the lowering door, and a mechanism for controlling the falling speed of the lowering door. On the other hand, the fire hydrant device can be obtained so that it can be integrally attached to and detached from the housing, and the assembly work and the maintenance work are easier.

  An embodiment of the present invention will be described with reference to FIGS. 1 is a front view of the entire fire hydrant device of the present invention, FIG. 2 is a rear view of the door unit in the fire hydrant device of the present invention, FIG. 3 is a plan view of the door unit, and FIG. 4 is a side view of the door unit. FIG. 5, FIG. 5 is a partially enlarged view of FIG. 3, FIG. 6 is a front view of a door unit showing an open / closed state of a descending door in the fire hydrant device of the present invention, and FIG. 7 is a damper used in the fire hydrant device of the present invention. FIG. 8 is a sectional view showing the other two types, and FIG. 9 is a front view of the door unit showing the open / closed state of the other types in the fire hydrant device of the present invention. FIG.

  FIG. 1 shows the entire fire hydrant device 1 of the present invention. As shown in the figure, various devices for fire extinguishing are stored in the housing 2 of the fire hydrant apparatus 1. The fire hydrant device 1 is installed, for example, in an inspection path of a tunnel. In the event of a fire, the fire hose 3 housed in an internally wound manner is pulled out from the inside of the housing 2, and the fire extinguishing nozzle 3a Fire extinguishing foam can be released to perform fire fighting activities.

  In the housing 2, a fire hose 3 having a fire extinguishing nozzle 3a, a bucket type hose housing part 4 in which the fire hose 3 is housed in an inner winding, and a discharge inspection port 5 are provided in the central storage part 2a. The maintenance valve 6, the pressure regulating valve 7, the fire hydrant valve 8, the foam stock solution tank 9, the foam stock solution introduction valve 10, the foam stock solution introduction check valve 11 having the foam stock solution introduction inspection port 11a and the like are stored.

  A front panel 13 as an example of a front panel that is detachably attached to the front surface of the housing is attached to the front surface of the housing 2 so as to cover the central storage portion 2a.

  In addition, on the side of the central storage portion 2a, there is a fire extinguisher storage portion 14 and an electrical equipment storage portion 15 such as a fire alarm on one side, and a storage portion for a fire hydrant 17 on the other side. 18 is provided.

  The front panel 13 detachably attached to the housing 2 is formed with a front opening 20 as an example of a front opening that opens when the lowering door 19 is lowered. When the lowering door 19 is lowered and the front opening 20 is opened, the hose outlet 4a of the hose accommodating portion 4, the fire-extinguishing nozzle 3a supported by a support portion (not shown), and the fire hydrant valve 8 are exposed. That is, when the lowering door 19 is lowered and the front opening 20 is opened, the fire-extinguishing hose 3 is pulled out from the hose outlet 4a of the hose housing 4 by holding the fire-extinguishing nozzle 3a, and the fire hydrant valve 8 is opened. It can be operated to plug.

  1 is an example of the present invention. That is, the present invention is not limited to the fire hydrant apparatus as shown in FIG. 1, and the lowering is performed by lowering the front opening of the housing. Application is possible if it is a fire hydrant device provided with a door.

  The front panel 13 in which the front opening 20 is formed is provided with a lowering door 19, a mechanism for guiding the vertical movement of the lowering door 19, a mechanism for giving resistance to the lowering of the lowering door 19, and the like. A detachable door unit 27 is configured. 2 to 5 show details of the door unit 27. As shown in the figure, two roller units 23, 23, 23, 23 in total are provided on each side edge of the lower door 19, that is, a total of four roller units 23, 23, 23. , 23, 23 are accommodated in travel guide portions 21, 21 provided on the back surface of the front panel back surface 13 on both sides of the lower door 19. Accordingly, the lower door 19 can be moved up and down by the roller units 23, 23, 23, 23 and the travel guide portions 21, 21 on the back side of the front panel 13. Furthermore, two dampers 25 and 25 are provided between the front panel 13 and the descending door 19 on the back side of the descending door 19, and the piston rods 25 c and 25 c are lowered by the dampers 25 and 25. The end side mounting portions 25g and 25g of the cylinders 25a and 25a are attached to the back surface of the front panel 13 so that the door 19 moves to the expansion side as the door 19 descends and moves to the contraction side as the door 19 rises. The extension end side attachment portions 25h, 25h of the piston rods 25c, 25c are attached to the lower rear side of the descending door 19. Accordingly, in the dampers 25 and 25, the piston rods 25c and 25c are extended by the lowering of the lowering door 19, and the piston rods 25c and 25c are contracted by the raising of the lowering door 19. Reference numeral 24 denotes a lower door accommodating portion that forms a door when the lower door 19 is lowered, 26 is a latch mechanism for holding and releasing the closed state of the lower door 19, and 28 is a rear surface of the front panel 13. It is a stopper of the descent door 19 provided in the. Reference numeral 30 denotes fixing members provided at four corners on the back surface of the front panel 13, and the fixing members 30 are detachably fixed to fixed members (not shown) of the central storage portion 2a.

  The roller unit 23 includes two orthogonal rollers 23 a and 23 b around the horizontal axis, and the roller 23 a that rotates about the horizontal axis along the width direction of the descending door 19 faces the back surface of the front panel 13. A roller 23b that travels between the inner surface of the back plate portion 21a of the traveling guide portion 21 and that has a smaller diameter than the roller 23a and rotates about a horizontal axis along the thickness direction of the descending door 19 is a side edge of the descending door 19 And the side plate portion 21b of the traveling guide portion 21 opposed thereto. Accordingly, the lower door 19 can be moved up and down while restricting the movement in the front and rear and right and left directions. For example, there is a slight inclination in the front and rear and right and left directions in the installed state of the fire hydrant apparatus 1. Even so, the lowering door 19 can be moved up and down smoothly. The travel guide portion 21 is covered by travel guide cover portions 24a and 24a formed integrally with the descending door accommodating portion 24 over the entire length thereof, and the travel guide cover portions 24a and 24a The back plate portion also serves as the back plate portions 21a and 21a in the travel guide portions 21 and 21.

  6 is a front view of the door unit 27 showing the opened / closed state of the lowering door 19, FIG. 6 (a) shows the fully closed state of the lowering door 19, and FIG. 6 (b) shows the fully opened state of the lowering door 19. ing. As shown in FIG. 6A, the fully-closed descending door 19 is positioned upward so as to close the front opening 20, and is held by the latch mechanism 26. At this time, the dampers 25, 25 The piston rods 25c, 25c are located at the most contracted length position. When the handle 26a of the latch mechanism 26 is operated to release the closed state of the lowering door 19, the lowering door 19 falls due to its own weight, and the front opening 20 is opened by the lowering. As shown in FIG. 6B, the fully opened lowering door 19 is positioned below to open the front opening 20, and is stopped by stoppers 28, 28. At this time, the dampers 25, 25 are The piston rod 25c is located at the most extended position.

  The dampers 25 and 25 are configured so that resistance is given to the movement toward the extension side when the piston rods 25b and 25b extend. Therefore, when the lower door 19 is lowered, The dampers 25, 25 give resistance to the lowering, whereby the lowering speed of the lowering door 19 can be controlled.

  7 and 8 show four types of dampers used in the fire hydrant measures of the present invention. The four types are a cylinder 25a, a piston 25b that divides the inside of the cylinder 25a into a compression side cylinder chamber 25d and an expansion side cylinder chamber 25e, and a piston rod that is connected to the piston 25b and extends outward from the cylinder 25a. 25c, an orifice 25f as an example of a communication path formed in the piston 25b and communicating the compression side cylinder chamber 25d and the expansion side cylinder chamber 25e, a cylinder other end side mounting portion 25g, and a piston rod extending end side mounting It is common in the point which has the part 25h.

  The damper 25-1 in FIG. 7A shows a type in which the cylinder 25a is filled with oil 25k. In this type of damper 25-1, the flow resistance by the oil 25k flowing through the orifice 25f is given to the piston 25b over the entire stroke of the movement toward the expansion side and the contraction side. Therefore, when this type of damper 25-1 is used for the fire hydrant measure 1, the damper 25-1 provides resistance over the entire stroke against the lowering and rising of the lowering door 19, that is, the lowering door. The resistance is given to the descending from the beginning of the descending of 19. The damper 25-1 provides resistance against the rising of the descending door 19.

  The damper 25-2 in FIG. 7B shows a type in which the cylinder 25a is filled with oil 25k and gas (which may be simply air or nitrogen) 25m. In this type of damper 25-2, an oil 25k layer and a gas 25m layer are formed in the cylinder 25b, and flow resistance to the piston 25b does not occur when passing through the gas 25m layer. This occurs only when the piston 25b passes through the oil 25k layer, and the gas 25m layer is formed above and the oil 25k layer is formed below the boundary 25mk. Therefore, when the piston 25b moves from the contracted length position to the extended side, it passes through the layer of gas 25m having no flow resistance and then passes through the layer of oil 25k having flow resistance by the oil 25k. Therefore, when this type of damper 25-2 is used in the fire hydrant device 1, the damper 25-2 does not give resistance from the beginning of the lowering of the lowering door 19, that is, first, the lowering door 19 is almost dropped freely. After the piston 25b is lowered quickly and then reaches the layer of the oil 25k, resistance is given to the descending of the descending door 19. In this damper 25-2, the timing for giving resistance to the lowering of the lowering door 19 can be made desired by changing the position of the boundary 25mk, that is, by adjusting the amount of the oil 25k, that is, According to the damper 25-2, resistance can be applied after the lowering door 19 is lowered to a predetermined position. The damper 25-2 also provides resistance against the ascent of the descending door 19.

  The damper 25-3 in FIG. 8 (a) is similar to the damper 25-1 in that the cylinder 25a is filled with the oil 25k. Further, the piston 25b is connected to the expansion side cylinder from the compression side cylinder chamber 25d. It has a check flow passage 25p having a check valve 25n as an example of a check flow passage that allows the flow to the chamber 25e and prevents the flow from the expansion side cylinder chamber e to the compression side cylinder chamber d. Indicates the type. In this type of damper 25-3, when the piston 25b moves to the expansion side, the check valve 25n is in a closed state, and the flow passage for communicating the compression side cylinder chamber 25d and the expansion side cylinder chamber 25e is an orifice. Since only 25f, the same effect as that of the damper 25-1 is exhibited. However, when the piston 25b moves to the contraction side, the check valve 25n is in an open state, and the check flow passage 25p is added to the orifice 25f. In addition to the orifice 25f, the oil 25k passes through the check flow passage 25p and communicates from the compression side cylinder chamber 25d to the expansion side cylinder chamber 25e. The non-return flow passage 25p has a size that does not give flow resistance to the movement of the piston 25b. It can be made which does not give resistance to movement. Therefore, when this type of damper 25-3 is used in the fire hydrant device 1, the lowering door 19 is given resistance against the lowering of the lowering door 19 from the initial stage of the lowering, similarly to the damper 25-1. It can be assumed that no resistance is given to the rise of.

  In the damper 25-4 in FIG. 8B, the cylinder 25a is filled with the oil 25k and the gas 25m like the damper 25-2, and the piston 25b includes the check valve 25n like the damper 25-3. The type which has the non-return flow path 25p which has is shown. Therefore, when this type of damper 25-4 is used in the fire hydrant device 1, resistance to the lowering of the lowering door 19 is given after the lowering door 19 is lowered to a predetermined position in the same manner as the damper 25-2. However, no resistance can be given to the rising of the descending door 19.

  FIG. 9 shows a case where the dampers 25 and 25 are given resistance after the lower door 19 is lowered to a predetermined position, that is, when the damper 25-2 or 25-4 is used as the damper 25. FIG. 9A is a front view of the door unit 27 showing the open / closed state of the door 19, FIG. 9A shows the fully closed state of the descending door 19, and FIG. 9B shows that the descending door 19 is lowered to a predetermined position. , 25 indicate a state in which resistance to the lowering of the lowering door 19 starts to be applied. While the lowering door 19 is lowered from the position shown in FIG. 9A to the position shown in FIG. 9B, that is, while lowering the section A, the lowering door 19 is not subjected to the resistance by the dampers 25 and 25, and is therefore almost free. It will descend in the fall state. While the lowering door 19 is lowered to the position of FIG. 9B and further descending, that is, while lowering the section B, the lowering door 19 receives resistance by the dampers 25 and 25, so that the lowering speed is It will be controlled and descend. Therefore, by providing the dampers 25 and 25 with resistance after the lowering door 19 is lowered to a predetermined position, the lowering door 19 is first lowered in a substantially free fall state, and then the lowering speed is controlled. The lowering can be stopped while the lowering door 19 is opened, and the lowering door 19 can be gently stopped while the lowering door 19 is quickly lowered.

  In addition, as shown in FIG. 9, when the dampers 25 and 25 are to be given resistance after the lowering door 19 is lowered to a predetermined position, a damper such as the damper 25-1 or 25-3 is used as the damper 25. Is also possible. That is, although illustration is omitted, when the piston rod extending end side mounting portion 25h is slidably attached to the descending door 19 within a certain range along the extending and contracting direction of the piston rod 25c, and the descending door 19 is in a closed state. When the piston rod extension end side mounting portion 25h is positioned at the lower end of the sliding range and the lowering door 19 is lowered from the closed state to the open state, first, as the lowering door 19 is lowered, the piston The rod extension end side mounting portion 25h is moved from the lower end to the upper end of the sliding range. During this sliding, the piston rod 25c is not extended, that is, the damper is lowered against the lowering of the lowering door 19. 25, the lowering door 19 is lowered without acting, and the piston rod extending end side mounting portion 25h reaches the upper end of the sliding range. By out, it is also possible to as the action of the damping force due to the damper 25 with respect to the descent of the descent door 19. In this case, the timing for giving resistance to the lowering of the lowering door 19 can be made desired by changing the position of the upper end of the sliding range up and down.

It is a front view of the whole fire hydrant apparatus of this invention. It is a rear view of the door unit in the fire hydrant apparatus of this invention. It is a top view of a door unit same as the above. It is a side view of a door unit same as the above. FIG. 4 is a partially enlarged view of FIG. 3. It is a front view of the door unit which shows the state of opening and closing of the descending door in the fire hydrant device of this invention. It is sectional drawing which shows the damper used for the fire hydrant apparatus of this invention, and shows the two types. It is sectional drawing which shows the same as the above and shows two other types. It is a front view of the door unit which shows the open / close state of the other type in the fire hydrant apparatus of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Fire hydrant apparatus 2 Case 2a Central storage part 3 Fire hose 3a Fire extinguishing nozzle 4 Hose accommodating part 4a Hose outlet 5 Release check port 6 Maintenance valve 7 Pressure adjustment valve 8 Fire hydrant valve 9 Foam stock solution tank 10 Foam stock solution introduction valve 11 Foam stock solution introduction check valve 11a Foam stock solution introduction check port 13 Front panel 14 Fire extinguisher storage portion 15 Electrical equipment storage portion 17 Fire hydrant faucet 18 Fire brigade hydrant storage portion 19 Lower door 20 Front opening 21 Travel guide portion 21a Back Plate portion 21b Side plate portion 23 Roller unit 23a Roller 23b Roller 24 Lower door accommodating portion 24a Traveling guide cover portion 25 Damper 25a Cylinder 25b Piston 25c Piston rod 25d Reduction side cylinder chamber 25e Extension side cylinder chamber 25f Orifice 25g Cylinder end side attachment portion 25h Piston rod extension end Attaching portion 25k Oil 25m gas 25n check valve 25p check passage

Claims (6)

In the fire hydrant device provided with a descending door that opens by lowering the front opening of the housing,
A fire hydrant apparatus, wherein a damper is provided between the housing and the lower door to extend by lowering the lower door and to provide resistance to lowering the lower door. The damper is formed in a cylinder, a piston that divides the inside of the cylinder into a compression-side cylinder chamber and an expansion-side cylinder chamber, a piston rod that is connected to the piston and extends outward from the cylinder, and the piston And a communication passage for communicating the compression side cylinder chamber and the extension side cylinder chamber.
2. The fire hydrant apparatus according to claim 1, wherein the damper is filled with oil.   2. The fire hydrant device according to claim 1, wherein the damper gives resistance to the lowering of the lowering door after the lowering door is lowered to a predetermined position. The damper is formed in a cylinder, a piston that divides the inside of the cylinder into a compression-side cylinder chamber and an expansion-side cylinder chamber, a piston rod that is connected to the piston and extends outward from the cylinder, and the piston And a communication passage for communicating the compression side cylinder chamber and the extension side cylinder chamber.
4. The fire hydrant device according to claim 3, wherein the damper is filled with oil and gas inside the cylinder, and an oil layer and a gas layer are formed inside the cylinder.   The damper is formed in the piston, and has a check flow passage that allows flow from the compression side cylinder chamber to the expansion side cylinder chamber and prevents flow from the expansion side cylinder chamber to the compression side cylinder chamber. The fire hydrant device according to claim 2 or 4, wherein the device has a fire hydrant device. The casing has the front opening that is opened by the descending door, and has a front panel that is detachably attached to the casing.
The damper is provided between the front panel and the descending door,
The front panel includes the descending door, the front opening opened by the descending door, and the damper, and constitutes a door unit that is detachably attached to the housing. The fire hydrant device according to any one of claims 1 to 5.

Images