RU2170308C2 - Underground fire hydrant - Google Patents

Abstract

FIELD: water supply systems. SUBSTANCE: proposed hydrant has column installed on fire support, nut, rod and valve. Lower part of column is provided additionally with cylindrical branch pipe of diameter corresponding to diameter of fire support passage section and length not exceeding half-of column radius. Upper part of branch pipe is provided with inner ring projection on lower surface of which wedge-shaped ring slot is made to receive ring sealing gasket. Nut is secured on column, and vertical rod is provided with thread turned into nut. Valve is secured on lower shank of rod and is made in form of cylindrical cup with central hole in bottom and with upper edge corresponding in shape and diameter to ring slot of branch pipe. Height of cup corresponds to length of branch pipe. Lower shank of vertical rod is passed with clearance through central hole of cup installed for vertical displacement along shank of rod over distance limited by two thrust nuts located on rod shank over and under cup bottom, respectively. At least three centering projections for cup are made on inner surface of branch pipe. Sealing washer is installed on shank between cup bottom and lower thrust nut. Flexible element made in form of leaf compression spring and resting by its ends on cup bottom is secured by its middle part on rod shank under lower thrust nut. EFFECT: prevention of hydraulic impacts, reduced cost of maintenance in operation, improved reparability. 1 dwg

Description

 The invention relates to the field of construction and mining, in particular, to water supply and sewerage, and can be used in devices designed to draw water from a water supply network for fire fighting.

 Fire hydrants of the so-called Leningrad type are known, including a column mounted on a fire stand with a nut fixed in it, a vertical rod with a thread included in the said nut, and a ball valve that locks the bottom hole of the column from the side of the fire stand [see N.I. Abramov, N.N. Geniuses, V.I. Pavlov. Water supply. Gosstroyizdat, M., 1958, p. 125]. To actuate such a hydrant, a portable part — a stander — is mounted on the column, and rotational movement is transmitted to the vertical rod by rotating the handle of the stander. Rotation of the threaded portion of the shaft in the nut lowers the shaft. At the same time, the lower stem of the rod presses on the ball of the valve, opening the lower hole of the column and passing water from the fire line to the stender pipes. The main advantage of such fire hydrants is the simplicity of their design and the absence of a large number of valve parts, which is especially important for underground fire hydrants because of the difficulty in troubleshooting such hydrants. However, analog solutions have a number of serious drawbacks that limit their use in water supply networks. The locking of such hydrants is due to the positive buoyancy of the ball of the valve when lifting the vertical rod of the hydrant. This does not allow the use of such hydrants with a conditional hydrant diameter of more than 75 mm, i.e. with small estimated water consumption during fire fighting. The low strength of the material of the light ball of the valve is the cause of the destruction of the ball with a large diameter of the ball-locked hole. In addition, analog solutions do not exclude the possibility of hydraulic shocks in the water supply network as a result of a sharp change in the speed of water in the hydrant when the ball breaks or when the hydrant opens / closes quickly [see above source, p. 125]. Such quick actions with a fire hydrant are provoked by the situation in the fire and training fire brigades, when, from the point of view of reducing the time of water supply to the source of ignition, it is preferable to rotate the stender handle with the stender pipes open beforehand. In addition, the situation on the carriageway of the city streets is also not conducive to the leisurely handling of fire hydrants during their mandatory periodic inspections carried out jointly by representatives of the fire departments and the organization operating the water supply network.

 The disadvantages of the analog solutions are partially eliminated in the underground fire hydrant, including the column, nut, stem and valve installed on the fire stand [see Textbook for high schools / Abramov N.N. Water supply, Moscow: Stroyizdat, 1974, pp. 129-130] - prototype.

 The valve in such a hydrant is attached to the nut, and it can be made of a durable material that does not have positive buoyancy. Therefore, such fire hydrants can be used on water mains that create large heads of water to extinguish fires, i.e. The nominal diameter of hydrants can be 125 mm. However, the disadvantage of analog solutions associated with the possibility of hydraulic shocks when using hydrants, the prototype solution does not eliminate. In addition, when using such hydrants, great efforts are required both to overcome the pressure of the water pressing the valve in its closed position and to prevent hydrant leakage due to the large contact surface area of the valve, the irregularities of which can be compensated only by high pressure on the valve gasket, created by the force of its preload by the handle of the stander. The complex shape of the valve surface makes it unrepairable in the simple conditions of water supplying units, especially for remote areas, which significantly increases operating costs.

 The objective of the invention is to eliminate the noted drawbacks, namely, the constructive exclusion of the possibility of hydraulic shocks when using fire hydrants, reducing the effort to open / close the hydrant, which increases the hydrant resource. In addition, the object of the invention is to reduce the cost of operating fire hydrants by increasing the degree of maintainability in simple conditions of the operational sections of water supply networks.

 The technical result is achieved by the fact that in the well-known underground type fire hydrant, including a column, a nut, a rod and a valve installed on a fire stand, the lower part of the column is supplemented by a cylindrical nozzle with a diameter corresponding to the diameter of the passage section of the fire stand and a length not exceeding half the radius of the column , the upper part of the nozzle is made with an inner annular protrusion, on the lower surface of which a wedge-shaped annular groove is made, in which an annular sealing rocladka, the nut is fixed in the column, the rod is made vertical with a thread included in the specified nut, the valve is mounted on the lower shaft of the rod and made in the form of a cylindrical cup with a central hole in the bottom and with an upper edge corresponding to the shape and diameter of the annular groove of the nozzle, when this height of the glass corresponds to the length of the pipe, the lower shank of the vertical rod is passed with a gap through the Central hole of the glass, which is installed with the possibility of vertical movement along the shank the rod to a distance limited by two thrust nuts located on the shank of the rod, respectively above and below the bottom of the cup, while at least three centering cups of protrusions are provided on the inner surface of the nozzle, a sealing washer is installed on the shank between the bottom of the cup and the lower stop nut, and under the bottom a thrust nut on the shank of the rod is fixed with its middle part to an elastic element mainly in the form of a leaf compression spring, resting its ends on the bottom of the glass.

 The idea of the invention lies in the constructive implementation of the hydrant, providing a sequential phased change in the area of the passage section of the hydrant column, regardless of the speed of lowering or raising the valve, which eliminates a sharp change in the flow rate of water in the column, which causes a hydraulic shock. In addition, changing the shape of the contact surface of the valve provides a significant reduction in the contact area while increasing its reliability. Reducing the area of the contact surface allows you to reduce the efforts exerted on the handle of the stander when closing the hydrant. The simple cylindrical shape of the glass and nozzle makes it possible to manufacture them under simple conditions by a mechanical workshop equipped with only a lathe, which increases the degree of maintainability of the hydrant.

 We show the materiality of the distinguishing features. Supplementing the lower part of the hydrant column with a cylindrical nozzle made with an internal annular protrusion in its upper part with a wedge-shaped annular groove on the lower surface of the annular protrusion is a new solution for underground fire hydrants. It provides a reduction in the area of the contact surface of the valve, reducing it to the area of a dent on the surface of the annular sealing gasket located in the annular groove. The reliability of the contact is ensured by the attention of this gasket with the upper edge of the glass entering the specified annular groove when closing the hydrant.

 The implementation of the valve in the form of a cylindrical glass with a central hole in the bottom and with an upper edge corresponding in shape and diameter to the annular groove of the nozzle is a new solution for underground type hydrants. It provides, together with the placement on the inner surface of the pipe of at least three centering the glass protrusions landing of the glass with its upper edge in the annular groove on the lower surface of the annular protrusion of the pipe. This ensures a consistent phased change in the flow area of the hydrant column. For example, when opening the hydrant, the central hole in the bottom of the glass first opens, then the area formed by the gap between the outer surface of the wall of the glass and the inner surface of the nozzle is added to the passage area formed by the gap between the shank of the vertical rod and the walls of the hole in the bottom of the glass. Only when the glass leaves the nozzle, the cross-sectional area of the column becomes the largest; when closing the hydrant, does the change in the cross-sectional area of the column occur in the reverse order.

 Installing the cup on the shank of the vertical rod with a gap with the possibility of its vertical movement along the shank to a distance limited by two thrust nuts, and strengthening the elastic element at the end of the shank, mainly in the form of a leaf compression spring, fixed with its middle part on the shank, and resting on the bottom of the cup with the ends is a new solution for underground hydrants. It provides preliminary opening of the central hole in the bottom of the glass when opening the hydrant and closing the central hole last when closing the hydrant. This, in turn, provides unloading of the valve when it is opened, which leads to a significant reduction in the effort required to overcome the water pressure on the closed valve, since the opening of the valve is facilitated not only by equalizing the pressure on both sides of the bottom of the glass, but also by the elastic force of the elastic compressed when closing the hydrant. This elastic force helps to open the central hole in the bottom of the glass. In the open position of the hydrant, the elastic element presses the bottom of the glass to the upper thrust nut, which eliminates the "rattle" of the glass in a jet of water passing through the column. When closing the hydrant, the force is applied practically only at the overlapping of the central hole in the bottom of the glass, since the glass, when the central hole is closed, presses the water pressure pipe in the fire line to the annular sealing gasket in the annular groove.

 The essence of the technical solution is illustrated by the drawing, which shows a schematic diagram of the proposed device.

The diagram of the device of the fire hydrant of the underground type contains the following components and parts:
1 - column;
2 - a vertical core;
3 - threaded part of the vertical rod;
4 - a nut fixed in a column;
5 - lower shank of the vertical rod;
6 - fire stand.

Nodes 1 ... 6 characterize the prototype. In addition to them, additional units and parts are introduced into the fire hydrant:
7 - cylindrical pipe;
8 - inner annular protrusion in the upper part of the pipe;
9 - centering the glass protrusions on the inner surface of the pipe. The pipe 7 with the inner annular protrusion 8 and the centering the glass protrusions 9 can be a single hollow with the bottom of the column, if the latter is made by casting. In the case of modernization of fire hydrants, such a pipe may be a separate part installed in the column either by a fixed landing or by means of fasteners;
10 - an annular groove on the lower surface of the annular protrusion 8. The groove is made so that in the diametrical section of the nozzle, the groove has the shape of a wedge. To fix in the groove of the gasket at the top of the wedge, a small indentation can be made towards the center of the nozzle. When the diameter of the sealing gasket is slightly smaller than the diameter of the annular groove, the gasket due to its elasticity will be held in the groove without falling out when opening the hydrant, when the lower surface of the gasket can follow the upper edge of the glass that has “stuck” to it. Other methods of fixing the gasket in the groove can be used (see, for example, fixing the gasket in the "ceiling" groove in the AS No. 1560690, E 03 B 9/04);
11 - an annular sealing gasket in the groove 10. The gasket is mainly made of rubber with good sealing properties and low cost;
12 - a cylindrical glass. It can be made on a lathe from a cast iron billet, or from a pipe. In the latter case, the bottom of the glass is attached to the side wall using one of the known methods;
13 - the Central hole in the bottom of the glass 12;
14 and 15, respectively, the upper and lower thrust nuts screwed onto the shank of the vertical rod 2;
16 - nut, fastening the elastic element on the lower shank 5 of the vertical rod 2. It can also serve as a lock nut, locking the lower thrust nut 15;
17 - sealing washer, sealing the central hole in the bottom of the glass 12 with the hydrant closed;
18 - the elastic element mainly in the form of a leaf compression spring, in the middle part of which a hole has been made with a diameter corresponding to the diameter of the lower shank 5 of the vertical rod 2. The middle part of the elastic element is sandwiched between the lower thrust nut 15 and the nut 16. The ends of the elastic element rests on the bottom of the glass 12 .

 Underground fire hydrant according to the proposed solution works as follows. In the initial position, the hydrant is closed and its vertical rod 2 is in the upper position. The glass 12 is pressed by the pressure of water in the fire stand 6 and the lower thrust nut 15 through the sealing washer 17 to the annular sealing gasket 11 in the annular groove 10 on the lower surface of the annular protrusion 8 of the cylindrical pipe 7. Water does not flow from the cavity of the fire stand 6 into column 1. When When opening the hydrate, the vertical rod 2 moves downward and this movement causes the flexible other element 18 to be unclenched. The lower stop nut 15 moves away from the bottom of the glass, allowing water to enter the column through the central hole 13 in the don ke of the glass 12. With a further movement of the rod 2 downward, the upper thrust nut 14 begins to press on the bottom of the glass, causing the upper edge of the glass 12 to exit from the annular groove 10. In this case, water enters column 1 through the gap formed by the walls of the glass 12 and pipe 7. When this sliding surface arising between the rotating upper thrust nut 14 and the non-rotating bottom of the glass 12, is “lubricated” with water entering the glass through its central hole 13. With a further movement down the rod 2, the glass 12 completely leaves the nozzle 7, revealing the full bore of the column. The dimensions of the nozzle and the nozzle are chosen such (the length of the nozzle corresponds to the length of the nozzle, which, in turn, does not exceed half the radius of the column, which corresponds to the height of the ball valve in the prototype solution), so that when the hydrant is fully opened, the nozzle 12 fits in the fire stand 6 Hydrant closure is carried out in the reverse order. First, the glass 12, thanks to the centering protrusions 9, approaches the annular groove 10. The wedge-shaped shape of the groove 10 and the shape of the upper edge of the glass 12 corresponding to the groove ensure that the upper edge of the glass 12 enters the annular groove 10. Under the action of the elastic element 18, the glass 12 sits with its upper edge on the gasket 11 in the annular groove 10, allowing water to enter the column 1 only through the central hole 13 in the bottom of the glass 12. With a further upward movement of the vertical rod 2, this hole is closed by a sealing washer 1 7, pressed against the bottom of the glass 12 by the lower stop nut 15. In this position, the narrow edge of the glass 12 is pressed into the ring gasket 11, reliably sealing the column 1 from water leaks from the fire stand 6.

 Thus, based on the analysis of the structure and functioning of the scheme of the proposed technical solution, we can conclude that the underground fire hydrant in which this solution is implemented has the advantages that meet the objectives of the invention: eliminating the possibility of water hammer when using the hydrant, reducing the effort applied to when using a hydrant, increasing the life of the hydrant and imparting maintainability to the hydrant under the simple conditions of a production site odoprovoda. In addition, the implementation of the proposed technical solution meets the goals of resource-saving technologies, as it does not require the use of rare and expensive materials: brass, bronze, stainless steel, hostalene, which are used in imported fire hydrants, for example, in the hydrant model 93 DN 80 / PN 16 from KOILAHYUTTE KRAUSHWITZ GMBH.

 The proposal was developed at the level of a technical proposal for one of the programs proposed by the city economy of St. Petersburg by the Northwest Guild of Science Leaders.

Claims (1)

 An underground fire hydrant, including a column, a nut, a rod and a valve mounted on a fire stand, characterized in that the lower part of the column is supplemented by a cylindrical nozzle with a diameter corresponding to the diameter of the passage section of the fire stand and a length not exceeding half the radius of the column, the upper part of the nozzle made with an inner annular protrusion, on the lower surface of which a wedge-shaped annular groove is made, in which an annular sealing gasket is fixed, the nut is fixed in the column e, the rod is made vertical with a thread included in the specified nut, the valve is mounted on the lower shaft of the rod and is made in the form of a cylindrical glass with a central hole in the bottom and with an upper edge corresponding in shape and diameter to the annular groove of the pipe, while the height of the glass corresponds to the length pipe, the lower shank of the vertical rod is passed with a gap through the Central hole of the glass, which is installed with the possibility of vertical movement along the shaft of the rod at a distance limited e with two thrust nuts located on the shank of the rod, respectively above and below the bottom of the cup, while at least three centering cups are provided on the inner surface of the nozzle, a sealing washer is installed on the shank between the bottom of the cup and the bottom thrust nut, and under the bottom thrust nut on the shank the rod is fixed with its middle part, the elastic element is predominantly in the form of a leaf compression spring, resting its ends on the bottom of the glass.