KR102615800B1 - the monitor for the fire-extinguishing capable of flow control - Google Patents

Abstract

The present invention relates to a fire extinguishing monitor, and more specifically, to a fire extinguishing monitor capable of controlling the waterproof type and amount of fluid discharged to the inlet through automatic or manual operation.
The present invention includes a supply unit 120 that receives fluid from the outside and supplies the fluid to the fire extinguishing monitor; A body portion (110) coupled to the supply portion (120) and having a conduit (112) communicating therewith; One side is coupled to the body portion 110, and the other side has a nozzle portion 130 formed with a discharge portion 132 that discharges fluid to the outside; And a cone member 140 formed inside the nozzle unit 130 in a curved shape with an outer surface curved to be tapered, and installed to be able to adjust a distance from the discharge unit 132, A fire extinguishing monitor can be provided, characterized in that the emitted flow rate is adjusted by adjusting the gap between the inner diameter of (132) and the outer diameter of the conical member (140).

Description

{the monitor for the fire-extinguishing capable of flow control}

The present invention relates to a fire extinguishing monitor, and more specifically, to a fire extinguishing monitor capable of controlling the waterproof type and amount of fluid discharged to the inlet through automatic or manual operation.

Generally, when a fire occurs on land or at sea, such as in a building, tunnel, or ship, the fire is extinguished using fire suppression equipment such as fire hoses, fire extinguishers, pipes, and fire robots.

In particular, in order to extinguish the fire, the fire is extinguished by spraying high-pressure fire extinguishing liquid or fire prevention water at the point of fire. The fire suppression equipment used at this time includes general pipes, special pipes, foam pipes, waterproof guns, and fire extinguishing monitors. there is.

Fire suppression devices used for fire extinguishing receive water from fire trucks, fire hydrants, the sea, etc., and adjust the flow rate of the fluid to be waterproofed or change the form of the fluid to be discharged depending on the type of fire and the environment being extinguished, thereby preventing the fire scene. Make sure it is suitable for .

At this time, in order to adjust the flow rate, the water pressure must be increased or lowered by operating the pump or communicating with the supplier. In this case, the problem is that it is difficult for the user operating the fire suppression device to adjust the desired waterproof type and water volume. occurs.

In addition, in the case of a fire suppression device that regulates the flow rate, the flow rate is controlled by adjusting the diameter of the nozzle being waterproofed using a member that controls the flow rate. At this time, the member that controls the flow rate and the inner surface of the fire suppression device are formed in an inclined shape with a smaller radius. In this case, a cavitation phenomenon occurs inside the fire suppression device and the fluid becomes vortexed, making it difficult for the fluid to flow smoothly. and the flow speed slows down.

In addition, internal wear occurs due to cavitation, and resistance to fluid flow occurs, which reduces the efficiency of fluid waterproofing.

In order to solve this problem, Korean Patent No. 10-2223782 has announced technology regarding a conical valve capable of controlling pressure and flow rate, and the 'conical valve capable of controlling pressure and flow rate' is based on the movement of the tubular body and the movable body. The flow rate is controlled as the movable body moves due to the movement of the moving conical member and the ring gear that rotates according to the rotation of the barbell gear.

However, the 'conical valve capable of controlling pressure and flow rate' has difficulties in use as the user must directly rotate the barbell gear to control the flow rate, and has problems in the manufacturing process that require a barbell gear and ring gear to control the flow rate. There is a problem that the structure is complicated.

Republic of Korea Patent No. 10-2223782 (2021.02.26.)

The purpose of the present invention was to solve the above problems, and the purpose of the present invention is to provide a fire extinguishing monitor that easily adjusts the flow rate discharged through a fluid control member forming a curved surface to be supplied.

The objects of the present invention are not limited to the objects mentioned above, and other objects not mentioned will be clearly understood by those skilled in the art from the description below.

In order to achieve the above object, in the fire extinguishing monitor capable of controlling the waterproof form and waterproof flow rate of the fluid according to the present invention, a supply unit 120 that receives fluid from the outside and supplies the fluid to the fire extinguishing monitor; The supply unit A body portion 110 coupled to (120) and formed with a conduit 112 communicating with the inside; One side is coupled to the body portion 110, and the other side is formed with a discharge portion 132 for discharging fluid to the outside. nozzle unit 130; And a cone member 140 formed inside the nozzle unit 130 in a curved shape with an outer surface curved to be tapered, and installed to be able to adjust a distance from the discharge unit 132, It is characterized by controlling the water discharged flow rate by adjusting the gap between the inner diameter of (132) and the outer diameter of the conical member (140).

In addition, the fire extinguishing monitor 100 includes a piston part 150 formed on one side of the body part 110, and the piston part 150 has a housing shape that forms an internal space. A piston chamber 152, a plate-shaped moving plate 154 formed inside the piston chamber 152 to be movable in the forward and backward directions, and a plate-shaped moving plate 154 that is vertically coupled to the moving plate 154 and has an end It includes a piston rod 156 engaged with the conical member 140, and the conical member 140 moves forward and backward according to the forward and backward motion of the moving plate 154, and the inner diameter of the discharge portion 132 and the cone The radiated flow rate of the fluid is controlled by adjusting the spacing of the outer diameter of the member 140.

At this time, the supply part 120 is formed of a main supply part 122 that supplies fluid to the body part 110 and an auxiliary supply part 124 that supplies fluid to the piston chamber 152, and the auxiliary supply part (124) includes a valve member 125 that controls the flow rate flowing into the piston chamber 152, and the piston rod 156 includes an elastic member 158 formed on one side of the piston rod 156. ) further includes, and when the flow rate flowing into the piston chamber 152 increases by manipulating the valve member 125, the moving plate 154 moves forward, and the flow flowing into the auxiliary supply unit 124 When the flow rate decreases, it is moved backward by the elastic restoring force of the elastic member 158.

In addition, the body portion 110 includes a spiral groove 113 formed along the outer peripheral surface, and the nozzle portion 130 is threadedly coupled to the spiral groove 113 to form the nozzle portion. It is characterized in that the water discharged flow rate is adjusted by moving forward and backward according to the rotation of (130) to adjust the gap between the inner diameter of the discharge portion (132) and the outer diameter of the conical member (140).

In addition, the nozzle unit 130 has a back-end front portion having a curved surface that becomes narrower toward the discharge portion 132 at one end where the inner side surface 131 is coupled with the body portion 110. It is characterized by being formed in the shape of.

The present invention improves waterproofing efficiency compared to a straight flow control member by using a flow control member forming a curved surface, and adjusts the gap between the inlet through which the fluid is discharged and the flow control member to control the flow rate and waterproof form of the fluid. There is a possible effect.

In addition, by operating the flow rate control member using the incoming fluid, there is an effect of controlling the flow rate without the user directly manipulating it.

1 is a schematic cross-sectional view of a fire extinguishing monitor capable of controlling flow rate according to the present invention.
Figure 2 is a cross-sectional view illustrating the operation of a fire extinguishing monitor capable of controlling flow rate according to the present invention.

The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and will be implemented in various different forms. The present embodiments only serve to ensure that the disclosure of the present invention is complete and that common knowledge in the technical field to which the present invention pertains is not limited. It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims.

Specific details for implementing the present invention will be described in detail with reference to the drawings attached below. Regardless of the drawings, the same reference numerals refer to the same elements, and “and/or” includes each and all combinations of one or more of the mentioned items.

The terminology used herein is for describing embodiments and is not intended to limit the invention. As used herein, singular forms also include plural forms, unless specifically stated otherwise in the context. As used in the specification, “comprises” and/or “comprising” does not exclude the presence or addition of one or more other elements in addition to the mentioned elements.

Unless otherwise defined, all terms (including technical and scientific terms) used in this specification may be used with meanings that can be commonly understood by those skilled in the art to which the present invention pertains. Additionally, terms defined in commonly used dictionaries are not interpreted ideally or excessively unless clearly specifically defined.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings.

Figure 1 is a schematic cross-sectional view of a fire extinguishing monitor capable of controlling flow rate according to the present invention, and Figure 2 is a cross-sectional view for explaining the operation of the fire extinguishing monitor capable of adjusting flow rate according to the present invention.

First, in describing a preferred embodiment of the present invention, 'front' and 'front' refer to the direction in which the nozzle portion 130, through which fluid is discharged from the fire extinguishing monitor 100, is formed, and 'rear'. And 'rear' refers to the part where the supply part 120, which supplies fluid, is formed opposite the nozzle part 130, but this is only mentioned for explanation and does not limit the position or shape of the configuration according to the present invention. It's not like that.

As shown in Figure 1, the fire extinguishing monitor 100 capable of controlling the flow rate includes a body portion 110 that forms the body of the fire extinguishing monitor 100, and a fluid supplied from the outside to the body portion 110. A supply unit 120 that supplies fluid, a nozzle unit 130 that is coupled to the body unit 110 to discharge the introduced fluid to the outside, and a cone member that adjusts the flow rate by adjusting the gap between the nozzle unit 130 and the nozzle unit 130. (140), and includes a piston unit 150 that controls the operation of the conical member 140.

First, the body portion 110 includes a conduit 112, a guide 113, and a guiding ring 115.

The body portion 110 is preferably formed in the shape of a housing with a hollow interior so that the water supplied through the supply portion 120 communicates.

More preferably, it may be formed in a cylindrical shape with a hollow interior so that fluid flows along the inner peripheral surface of the body portion 110, which is formed in a curved shape.

At this time, the body part 110 is formed with a conduit 112 formed inside to allow fluid to flow, and the conduit 112 allows the fluid supplied from the supply part 120 to communicate with the nozzle part 130. It is formed in a tubular shape, and the inner surface from the rear end to the front end is preferably formed in a straight shape to facilitate the flow of fluid.

The supply unit 120 can supply various fluids such as seawater, firefighting water, and water with fire extinguishing chemicals added, and the body unit 110 is supplied from the outside through a pump (not shown) using hydraulic pressure, pneumatic pressure, motor, etc. Supply fluid to

At this time, the supply part 120 may be formed of a main supply part 122 for supplying fluid to the body part 110 and discharging it to the outside, and an auxiliary supply part 124 for supplying fluid to the piston part.

More detailed information about the auxiliary supply unit 124 will be described together with the piston unit 150, which will be described later.

Next, the nozzle unit 130 includes a discharge unit 132 through which fluid is discharged, and a nozzle unit inner surface 131 that forms the inner surface of the nozzle unit 130.

The nozzle unit 130 may be formed in a cylindrical shape with a hollow interior and open front and rear ends.

The rear end of the nozzle part 130 is coupled to the body part 110, and the discharge part 132 is formed at the front end.

The discharge portion 132 discharges the fluid introduced from the body portion 110. It is preferable that the inner diameter of the discharge portion 132 is smaller than the inner diameter of the body portion 110 to facilitate flow control. do.

Additionally, the inner surface of the nozzle unit 131 may be formed in the shape of a back-front narrowing with a curved surface that becomes narrower from the rear end to the front end.

The inner surface of the nozzle unit 131 is formed in a curved shape, so that even though the conical member 130 is formed in a shape that impedes the flow of fluid, the passage width is kept constant when the fluid is discharged to the discharge unit 132. This has the effect of suppressing the occurrence of cavitation.

In addition, the inner surface 131 of the nozzle part is formed as a curved surface, so when the internal pressure changes by adjusting the gap with the discharge part 132 to control the flow rate, the pressure changes compared to the body and nozzle formed at an angle. It has a relatively small effect on the flow rate, allowing the flow rate to be adjusted smoothly.

It is preferable that the outer diameter of the nozzle portion 130 is formed to be larger than that of the body portion 110 and be combined in a shape that covers the outer surface of the body portion 110.

More preferably, a spiral groove 113 is formed on the outer surface of the body portion 110, and a groove 134 corresponding to the spiral groove 113 is formed in the nozzle portion 130, so that the body portion ( 113) and is combined neatly.

At this time, as the body portion 110 and the nozzle portion 130 are combined, the nozzle portion 130 moves forward and backward while moving along the spiral groove 113 through rotation of the nozzle portion 130. That is, by moving the nozzle unit 130 forward and backward, the distance between it and the conical member 140 fixed to one side of the fire-fighting monitor 100 can be adjusted.

In addition, the spiral grooves 113 and 134 may further include separate ball bearings (not shown) to facilitate movement when adjusting the distance between the discharge portion 132 and the cone member 140.

In addition, the spiral grooves 113 and 134 may be provided with separate locking protrusions (not shown) that prevent them from coming off or being damaged when the spiral grooves 113 and 134 are adjusted forward and backward to a certain length or more.

In addition, the nozzle unit 130 has a handle 133 formed in a vertical direction on the outer peripheral surface, so that the nozzle unit 130 can be operated more easily when rotating.

The conical member 140 includes a conical member front end 140a formed at the front end, a conical member rear end 140b coupled to the conical member front end 140a, and formed at the rear end of the conical member 140, and It includes a joining surface (140c) where the front end of the conical member (140a) and the rear end of the conical member (140b) are joined.

At this time, the conical member 140 is preferably formed at the center of the inner surface of the nozzle unit 130, and is formed in a ‘water drop’-shaped cone with a convex curved surface.

At this time, it is preferable that the diameter of the conical member 140 is smaller than the inner diameter of the discharge part 132 so that the conical member 140 protrudes out of the discharge part 132 to control the fluid. do.

The conical member 140 is coupled to one inner side of the body portion 110, and the spiral grooves 113 and 134 move forward and backward due to the rotation of the nozzle portion 130, and the conical member 140 and It can be formed to adjust the water discharge rate by adjusting the spacing of the discharge portion 132.

That is, the nozzle unit 130 moves forward and backward to adjust the gap between the conical members 140 fixed to the body unit 110 so that the outer diameter of the nozzle unit 130 and the inner diameter 132 of the discharge unit 132 are adjusted. ) is adjusted by changing the width of the discharge portion 132 by adjusting the spacing.

The rear end of the conical member (140b) may be formed in the form of a pre-gwang narrow narrowing that widens from the rear to the front, and the fluid supplied from the body portion 110 may flow to the rear end of the conical member (140b). It is formed in a curved shape so that it can be supplied smoothly along the outer surface.

If the member that controls the flow rate is formed in an angled shape, the flow of fluid is interrupted, and vortices and cavitation are formed inside the fire extinguishing monitor, which reduces the lifespan of the fire extinguishing monitor and lowers the fluid's water discharge speed and waterproof efficiency. occurs.

The rear end 140b of the conical member has the effect of smoothing the flow of fluid compared to a flow control member formed at a right angle by forming a curved surface so as not to impede the flow of fluid. That is, the rear end of the conical member 140b has the effect of improving durability and waterproofing efficiency by suppressing cavitation and eddy currents inside the fire extinguishing monitor 100 by facilitating the flow of fluid.

The conical member front end 140a is detachably coupled to the conical rear end 140b to form the conical member 140, and is formed in the shape of a halo that narrows from the rear end to the front end. It can be.

The conical member front end 140a is preferably formed to be spaced apart from the inner surface 131 of the nozzle unit 130 to form a space through which fluid can flow.

The conical member front end 140a maintains a constant distance between the inner surface 131 of the nozzle unit 130 and the width through which the fluid flows, thereby reducing the pressure change in the fluid caused by the difference in the width of the fluid through which the fluid flows. It has the effect of reducing the occurrence of cavitation by minimizing .

In addition, when the flow rate is adjusted by adjusting the cone member 140 back and forth, the pressure generated due to changes in the flow rate can be smoothly adjusted, thereby providing convenience of operation to the user and improving stability of use.

The outer diameter of the joint surface 140c is preferably smaller than the inner diameter of the discharge portion 132 by a predetermined size.

More preferably, when the joint surface 140c is formed at the same position as the discharge portion 132, the fluid can be discharged in a radial form at the widest angle.

In addition, the conical member front end 140a and the conical member rear end 140b are formed to be detachable and can be easily replaced when worn or damaged, thereby reducing maintenance costs.

The piston unit 150 includes a piston chamber 152, a moving plate 154, a piston rod 156, and an elastic member 158.

The piston chamber 152 is preferably formed in the shape of a housing that forms a space therein.

The piston chamber 152 is formed on one side of the body portion 110, and is preferably formed at the rear end of the fire extinguishing monitor 100 so as not to impede the flow of fluid supplied to the supply portion 120. do.

A plate-shaped moving plate 154 is formed inside the piston chamber 152 to be movable forward and backward of the piston chamber 152.

One side of the piston rod 156 is vertically coupled to the moving plate 154, and the other side is coupled to the conical member 140.

At this time, the piston chamber 152 is formed with a guide groove 157 through which the piston rod 156 can penetrate, and is provided with an O-ring 159 so that the piston rod 156 moves forward and backward. Ensure stable operation.

In addition, a guide 113 that guides the operation of the piston rod 156 and an O-ring 115 coupled to the guide 113 are formed inside the body portion 110 to It stably guides the movement of (157).

The piston unit 150 is provided with a solenoid (not shown) inside the piston chamber 152 that moves the moving plate 154 forward and backward, using a method of moving the moving plate 154 forward and backward. The distance between the outer diameter of the conical member 140 and the inner diameter of the discharge portion 132 can be adjusted.

The piston unit 150 can be used to pressurize the moving plate 154 by receiving fluid through the auxiliary supply pipe 124.

At this time, a valve member 125 that controls the flow rate flowing into the piston chamber 152 may be formed in the auxiliary supply pipe 124.

At this time, the valve member 125 may be provided with various types of valves such as needle valves, pinch valves, ball valves, plug valves, globe valves, gate valves, and butterfly valves. More preferably, it is a valve that can control the flow rate. It is desirable to form

The valve member 125 has the effect of controlling the flow rate supplied into the piston chamber 152 and pressurizing the moving plate 154 to move it forward or return it to the rear.

Specifically, when a certain amount of fluid flows into the piston chamber 152 due to the flow rate control of the valve member 125, the moving plate 154 is pressed from the rear to the front by the introduced fluid, and the piston rod As (156) moves forward, the gap between the outer diameter of the conical member 140 and the inner diameter of the discharge part 132 decreases, thereby reducing the width of the discharge part 132, thereby reducing the discharged flow rate.

At this time, the reduced width of the discharge portion 132 impedes the flow of fluid, causing the discharged fluid to be formed in a radial shape.

In a general fire scene, the fire is extinguished in various ways depending on the type of fire and the surrounding environment. The fire extinguishing monitor adjusts the gap between the discharge part and the cone member to reduce the width of the discharge part, making it suitable for the fire scene. The type and amount of waterproofing can be easily adjusted.

Meanwhile, a discharge hole 153 is formed at the front end of the piston chamber 152 through which a portion of the fluid flowing into the piston chamber 152 can flow to the body portion 110 and flows into the auxiliary supply unit 124. The moving plate 154 is pressed forward due to the fluid flowing into the piston chamber 152, but the fluid flowing into the piston chamber 152 is discharged forward to prevent the inside of the piston chamber 152 from expanding due to pressure.

In addition, the moving plate outlet 155 is formed to penetrate through the moving plate 154, so that the fluid supplied from the auxiliary supply unit 124 presses the moving plate, and is discharged through the moving plate outlet 155. By allowing fluid to communicate with the piston chamber 152, the moving plate 154 is prevented from being pressurized more than a certain amount.

That is, a certain amount of fluid flowing in through the auxiliary supply unit 124 pressurizes the moving plate 154, and other fluids pass through the moving plate discharge part 155 and move to the discharge hole 153 and are This is to prevent an increase in the internal pressure of the piston chamber 152 due to the fluid flowing in through the auxiliary supply part 124 while being discharged to the discharge part 132 through the pipe 112.

Next, when fluid does not flow into the piston chamber 152 due to flow rate control of the valve member 125, the moving plate 154 is connected to the elastic member 158 and the fire extinguishing monitor ( 100) It moves rearward due to an increase in internal pressure, and the piston rod 156 and the conical member 140 coupled to the moving plate 154 move rearward, thereby reducing the width of the discharge portion 152. The (H) volume is restored and the fluid can be sprayed in a direct manner.

Therefore, the valve member 125 supplies a certain amount of fluid to move the moving plate 154 to the front end, or when the supply of fluid decreases due to the operation of the valve member 125, it moves downward by elastic restoring force. As it moves, the conical member 140 moves downward, and the distance between the discharge portion 132 and the conical member 140 is adjusted to control the flow rate or to adjust the waterproofing form in a rectangular or radial manner.

At this time, the valve member 125 may be formed to be automatically adjustable through a separate control unit (not shown), and may be adjusted through a separate movable member (not shown) that can be directly operated by the user.

In addition, a separate sensor unit (not shown) is provided to measure the pressure of the fluid supplied from the supply unit 120, the internal pressure of the piston chamber 152, the elastic force of the elastic member 158, and the discharged flow rate. Thus, the flow of fluid can be controlled by installing the valve member 125 through the control unit (not shown).

Although embodiments of the present invention have been described with reference to the above and the attached drawings, those skilled in the art will understand that the present invention can be implemented in other specific forms without changing the technical idea or essential features. You will understand that it exists. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive.

110: body part
120: Supply department
130: nozzle part
140: Conical member
150: Piston part

Claims (5)

In a fire extinguishing monitor capable of controlling the radiation form and radiated flow rate of the fluid,
A supply unit 120 that receives fluid from the outside and supplies the fluid to the monitor;
A body portion (110) coupled to the supply portion (120) and having a conduit (112) communicating therewith;
One side is coupled to the body portion 110, and the other side has a nozzle portion 130 formed with a discharge portion 132 that discharges fluid to the outside; and
Inside the nozzle unit 130, the outer surface is formed in a tapered curved shape and has a diameter smaller than the inner diameter of the discharge unit 132 so as to be spaced apart from the discharge unit 132 by a predetermined distance. It includes a conical member 140 movably installed within the nozzle unit 130,
The radiated flow rate is controlled by adjusting the gap between the inner diameter of the discharge portion 132 and the outer diameter of the conical member 140,
The nozzle unit 130,
The inner surface 131 is formed in the shape of a back-end cone having a curved surface that narrows from one end of the body portion 110 to the discharge portion 132, and the conical member ( It includes a conical member front end (140a) that forms the front end of the conical member (140), and a conical member rear end (140b) that is combined with the conical member front end (140a) to form the rear end of the conical member (140),
The conical member front end 140a is formed in a shape that maintains a constant predetermined distance from the inner surface of the nozzle portion 130 to prevent cavitation caused by the difference in width through which fluid flows,
The rear end 140b of the conical member is formed in a front-to-back narrow shape that widens from the rear to the front. This occurs due to a change in the flow rate when the conical member 140 is adjusted forward and backward to adjust the flow rate. A fire extinguishing monitor that ensures smooth flow control despite pressure differences. According to clause 1,
The fire extinguishing monitor 100,
It includes a piston part 150 formed on one side of the body part 110,
The piston unit 150,
A piston chamber 152 in the shape of a housing forming an internal space, a plate-shaped moving plate 154 formed inside the piston chamber 152 to be movable in the forward and backward directions, and the movement It is vertically coupled to the plate 154 and includes a piston rod 156 whose end is engaged with the conical member 140,
The conical member 140 moves forward and backward according to the forward and backward motion of the moving plate 154, and adjusts the radiated flow rate by adjusting the gap between the inner diameter of the discharge portion 132 and the outer diameter of the conical member 140. A fire extinguishing monitor characterized in that. In paragraph 2
The supply unit 120,
It is formed of a main supply part 122 that supplies fluid to the body part 110 and an auxiliary supply part 124 that supplies fluid to the piston chamber 152,
The auxiliary supply unit 124,
It further includes a valve member 125 that regulates the flow rate flowing into the piston chamber 152,
The piston rod 156 is,
It further includes an elastic member 158 formed on one side of the piston rod 156,
The moving plate 154 is,
When the flow rate flowing from the auxiliary supply part 124 to the piston chamber 152 increases, it moves forward, and when the flow rate flowing from the auxiliary supply part 124 to the piston chamber 152 decreases, the elastic member ( 158) A fire extinguishing monitor, characterized in that it is moved rearward by the elastic restoring force. According to clause 1,
The body portion 110 is,
It includes a spiral groove 113 formed along the outer peripheral surface,
The nozzle unit 130,
It is threadedly coupled to the spiral groove 113 and moves forward and backward according to the rotation of the nozzle unit 130 to adjust the gap between the inner diameter of the discharge part 132 and the outer diameter of the conical member 140. A fire extinguishing monitor, characterized in that the emitted flow rate is controlled by doing so. delete