JP6292973B2 - Fire extinguisher flow regulator - Google Patents

Description

  The present invention relates to a fire extinguisher flow rate regulator in a fire extinguisher mixing apparatus.

Conventionally, in a fire extinguisher mixing apparatus that supplies and mixes a fire extinguisher undiluted solution with flowing water sent to a discharge port that performs fire extinguishing, a fire extinguisher flow rate regulator is used to adjust the supply flow rate of the fire extinguisher .
As a fire extinguisher flow rate adjuster, for example, in a case part into which a fire extinguisher stock solution flows, a piston part that is supported so as to be movable by the inflow of the fire extinguishing agent stock solution, and the moving direction of the piston part by the inflow of the extinguishing agent stock solution The piston portion that is arranged according to the flow rate of the extinguishing agent stock solution adjusts the reduction rate of the reduced diameter portion in the flow path of the extinguishing agent to adjust the supply flow rate of the extinguishing agent. What is made to be done is known (for example, refer patent document 1).
In other words, in this extinguishing agent flow rate adjuster, the operation timing at which the arrangement of the piston part is switched according to the elastic force of the coil spring is set, and the piston part is discharged at the timing when the flow rate of the extinguishing agent stock solution exceeds a predetermined value. The arrangement of is switched.

JP 2006-296918 A

  However, in the case of the extinguishing agent flow rate regulator of Patent Document 1, a coil spring having a predetermined elastic force is required to operate the piston portion at a desired timing to adjust the supply flow rate of the extinguishing agent. It has been found that it is difficult to precisely manufacture a coil spring that operates the piston part with high precision, resulting in an increase in cost.

  An object of the present invention is to provide a fire extinguisher flow rate regulator that can more easily adjust the supply flow rate of a fire extinguisher.

In order to solve the above problems, the invention described in claim 1
A fire extinguisher that adjusts the supply flow rate of the extinguishing agent stock solution in order to adjust the concentration of the extinguishing agent aqueous solution in a fire extinguisher mixing device that supplies and mixes the extinguisher stock solution to the flowing water sent to the discharge port for performing fire extinguishing A flow regulator,
A reduced diameter portion formed narrower than the flow path of the extinguishing agent stock solution located on the upstream side,
According to the supply flow rate of the extinguisher stock solution, a variable that adjusts the diameter reduction rate of the reduced diameter portion by closing a part of the reduced diameter portion when the supply flow rate is high and opening a part when the supply flow rate is low. Means,
With
The variable means is supported so that the extinguisher stock solution flows in from the bottom to the top, and is lowered by its own weight in the case portion and rises by the inflow of the extinguisher stock solution. And a piston portion, and adjusting to reduce the diameter reduction rate of the reduced diameter portion by raising the piston portion.
The “reduced diameter portion” refers to a portion formed such that a cross-sectional area perpendicular to the flow direction is smaller than the upstream flow path.

According to the above configuration, when the supply of the extinguishing agent stock solution is started from the extinguishing agent storage tank, for example, when the supply of the extinguishing agent stock solution is started from the extinguishing agent storage tank, the extinguishing agent stock solution passes through the reduced diameter portion and is mixed with the flowing water. The
And when the water supply flow rate to the discharge port for fire extinguishing is small, the supply flow rate of the extinguishing agent stock solution is also small, so the piston part is lowered to adjust the diameter reduction rate of the reduced diameter part to be relatively large. Then, adjust the flow rate of the extinguishing agent stock solution so that the concentration of the extinguishing agent aqueous solution becomes the target concentration.
In addition, when the flow rate of water supplied to the discharge port for fire extinguishing is large, the supply flow rate of the extinguishing agent stock solution also increases. Adjust the flow rate of the extinguishing agent stock solution so that the concentration of the aqueous solution becomes the target concentration.
That is, with this extinguisher flow rate regulator, the diameter reduction rate of the reduced diameter part is suitably adjusted by the piston part that is supported so as to descend by its own weight in the case part and to rise by the inflow of the extinguishing agent stock solution. The supply flow rate of the fire extinguishing agent can be adjusted more easily.

The invention described in claim 2 is the extinguishing agent flow rate regulator according to claim 1,
The reduced diameter portion is composed of a first opening provided in the case portion, a second opening provided on the upper end surface of the piston portion, and a third opening,
The second opening is formed in an arrangement that communicates with the first opening by rising due to the inflow of the extinguishing agent stock solution of the piston part, and the third opening is the extinguishing agent of the piston part. It is formed in the arrangement | positioning closed by the raise by the inflow of a stock solution.

According to the above configuration, since the third opening of the piston part is arranged to be closed by the rise of the piston part due to the inflow of the extinguishing agent stock solution, the extinguishing agent stock solution that has passed through the third opening of the piston part When the jet flow hits the inner surface of the case portion, a force opposite to the upward movement of the piston portion is applied.
Here, the magnitude of the force opposite to the rise acting on the piston portion by the jet of the extinguishing agent stock solution that has passed through the third opening is adjusted by adjusting the inner diameter size of the third opening. Therefore, when the extinguishing agent stock solution reaches a predetermined flow rate, the timing at which the upper end surface of the piston portion comes into close contact with the case portion and reaches the highest position can be set by adjusting the inner diameter size of the third opening. It becomes possible.
That is, by adjusting the inner diameter size of the third opening of the piston part, it is possible to set the timing when the piston part reaches the highest position when the extinguishing agent stock solution reaches a predetermined flow rate. As described above, the supply flow rate of the extinguishing agent can be adjusted more easily than designing a precise coil spring and operating the piston portion with high accuracy.

The invention according to claim 3 is the extinguishing agent flow rate regulator according to claim 2,
The second opening is formed narrower than the first opening,
The first opening is formed narrower than an opening formed by combining the second opening and the third opening.

According to the said structure, when the flow rate of the water supply to the discharge port which performs fire extinguishing is small, since the flow rate of the extinguishing agent stock solution is also small, the piston part is in a lowered state due to its own weight, and the extinguishing agent stock solution is the second part of the piston part. After passing through the opening and the third opening, and further passing through the first opening of the case part, it is mixed with running water. At this time, the first opening is formed to be narrower than the opening area of the second opening and the third opening, and the fire extinguishing that has passed through the second opening and the third opening. Since the flow rate of the stock solution is adjusted to be a predetermined flow rate by the first opening, even if the flow rate of the fire extinguisher stock solution fluctuates before the piston reaches the highest position, The density is adjusted to the target density.
In addition, when the flow rate of the water supply to the discharge port for fire extinguishing increases, the flow rate of the extinguishing agent stock solution also increases, and when the extinguishing agent stock solution reaches the predetermined flow rate, the piston portion moves to its highest position against its own weight. Thus, the third opening of the piston is closed, and the extinguishing agent stock solution passes only through the second opening, and further passes through the first opening and is mixed with running water. At this time, even if the second opening is formed narrower than the first opening and the flow rate of the extinguisher stock solution exceeds the flow rate that moves the piston portion to the highest position, the piston Since the flow rate of the extinguishing agent stock solution after the part reaches the highest rise position is adjusted to a predetermined flow rate by the second opening, the concentration of the extinguishing agent aqueous solution is adjusted to the target concentration Is done.

The invention according to claim 4 is the extinguishing agent flow rate regulator according to any one of claims 1 to 3,
An upper end side and a lower end side of the piston part are respectively guided so as to move along an inner peripheral surface of the case part, and the piston part is supported so as to be movable up and down.

  According to the above configuration, since the upper end side and the lower end side of the piston part are guided by the inner peripheral surface of the case part and move up and down, the movement of the piston part is stabilized and the diameter reduction rate of the diameter reducing part is adjusted well. be able to.

  ADVANTAGE OF THE INVENTION According to this invention, the fire extinguisher flow volume regulator which can adjust the supply flow rate of a fire extinguisher more easily is obtained.

It is a whole block diagram which shows the fire extinguisher mixing apparatus provided with the fire extinguisher flow volume regulator of this embodiment. It is an enlarged view which shows the mixer of a fire extinguisher mixing apparatus by cross-sectional view. It is sectional drawing along the centerline of a fire extinguisher flow regulator, and shows a state (A) with a small flow rate of a fire extinguishing agent, and a state (B) with a large flow rate of a fire extinguishing agent. It is a diagram which shows the result of the test which calculated | required the relationship between the flow volume of a fire extinguishing piping main pipe, and the mixed concentration of a fire extinguisher using the fire extinguisher flow regulator of this embodiment.

  Hereinafter, with reference to drawings, an embodiment of a fire extinguishing agent flow controller according to the present invention will be described in detail.

(overall structure)
The fire extinguisher flow rate adjuster 10 is installed in a building and is provided in a fire extinguisher mixing device 50 of a fire extinguishing facility that radiates a fire extinguisher aqueous solution from a discharge port.

  As shown in FIG. 1, the fire extinguisher mixing device 50 includes a mixer 101 provided in the middle of a fire extinguishing pipe main pipe 103 connecting a fire extinguishing pump to a discharge port, and a fire extinguisher storage pressurization that is a supply source of the fire extinguishing agent. The tank 102, the pressurized water side pipe 104 and the extinguishing agent side pipe 105 connecting the mixer 101 and the extinguishing agent storage pressure tank 102, and the extinguishing agent side pipe 105 from the extinguishing agent storage pressure tank 102 to the mixer 101. And a fire extinguisher flow rate adjuster 10 for adjusting the supply flow rate of the extinguisher stock solution supplied via

The operation principle of the fire extinguisher mixing apparatus 50 will be described with reference to FIG.
When a cross-sectional area narrow portion (so-called reduced diameter portion) 101a having an inner diameter smaller than that of the inlet portion 101b is provided inside the mixer 101, and a water flow is generated in the mixer 101 by operating the discharge port or opening the test valve, the narrow portion The water speed (flow velocity) of 101a is faster than the flow velocity of the inlet portion 101b of the mixer 101. As a result, the pressure at the narrow portion 101a is lower than the pressure at the inlet portion 101b of the mixer 101 according to Bernoulli's theorem, and a pressure difference (differential pressure) is generated between the inlet portion 101b and the narrow portion 101a.

On the other hand, the inside of the fire extinguishing agent storage pressurization tank 102 is divided into a pressurization water region and a fire extinguishing agent region by a diaphragm, and the inlet portion 101b of the mixer 101 passes through the pressurization water side piping 104 and the fire extinguishing agent storage pressurization tank 102. The narrow portion 101 a of the mixer 101 is connected to the extinguishing agent region of the extinguishing agent storage pressurizing tank 102 via the extinguishing agent side pipe 105. Accordingly, when the pressure on the inlet portion 101b side becomes higher than that of the narrow portion 101a, the pressurized water is pushed into the pressurized water region of the extinguishing agent storage pressurizing tank 102, and the extinguishing agent is pushed out from the extinguishing agent storage pressurizing tank 102 through the diaphragm. It is. The extruded fire extinguishing agent is sent to the mixer 101 through the fire extinguishing agent side pipe 105 and mixed with water flowing through the fire extinguishing pipe main pipe 103.
Thus, the magnitude of the pressure that decreases in the narrow portion 101a of the mixer 101 is relative to the flow velocity passing there, and the differential pressure generated in the mixer 101 is also relative to the flow velocity. The fire extinguishing agent can be sent in accordance with the flow rate per unit time regardless of the pressure.

In the fire extinguisher mixing device 50, the fire extinguisher needs to be mixed at a constant dilution mixed concentration even if the flow rate of water sent from the pump changes. A vessel 10 is provided.
Then, the amount of the extinguishing agent pumped from the extinguishing agent storage pressurization tank 102 is controlled by the extinguishing agent flow rate regulator 10 and fed into the mixer 101, and water and the extinguishing agent are mixed to extinguish the fire with a predetermined mixed concentration. An aqueous solution of the agent is generated.

(Fire extinguishing agent flow controller)
The extinguishing agent flow rate adjuster 10 includes a case part 20 through which the extinguishing agent stock solution passes, a piston part 30 supported in the case part 20 so as to be movable up and down, and the like.

  The case portion 20 includes a lower case 21 and an upper case 22 as shown in FIGS. Bolt holes 21a and 22a are provided in the flange portions of the lower case 21 and the upper case 22, respectively. Bolts 27 are inserted into the bolt holes 21a and 22a aligned with each other, and a nut 28 is fastened. The case portion 20 having a space that can accommodate the piston portion 30 is assembled. An O-ring 26 is interposed between the lower case 21 and the upper case 22 so that watertightness between the lower case 21 and the upper case 22 is maintained.

The lower case 21 is formed with a fire-extinguishing agent inlet 23. The downstream end of the extinguishing agent side pipe 105 in the extinguishing agent supply direction is connected to the inflow port 23.
The upper case 22 is provided with a first opening 24 that is narrower than the inner diameter of the case portion 20 and functions as a reduced diameter portion, and an extinguishing agent outlet 25 that has passed through the first opening 24. ing. The outlet 25 is connected to the narrow portion 101 a of the mixer 101.
That is, the extinguishing agent stock solution flows upward from the inlet 23 on the lower end side of the case portion 20 and flows out from the outlet 25. The first opening 24 is formed to have a smaller diameter than the inner diameter of the case portion 20, and the flow rate of the extinguishing agent stock solution passing through the first opening 24 is adjusted to be a predetermined flow rate.

As shown in FIGS. 3 (A) and 3 (B), the piston part 30 is stored in an internal space of the case part 20 so as to be supported in a vertically movable manner. The piston part 30 has a substantially cylindrical shape, and a second opening part 31 and a third opening part 32 that function as a reduced diameter part and have a smaller diameter than the inner diameter of the piston part 30 on the upper end surface thereof. Is formed. The second opening 31 is formed substantially at the center of the upper end surface of the piston part 30, and the third opening 32 is formed around the second opening 31.
The outer diameter on the upper end side of the piston portion 30 is designed to be approximately the same as the inner diameter of the upper portion of the internal space of the case portion 20, and the outer peripheral surface on the upper end side of the piston portion 30 is a guide for the inner peripheral surface of the upper case 22. Guided so as to move along the surface 22b, the piston portion 30 can move up and down along the direction of the center line.

  A diaphragm 34 sandwiched between annular members 33 is fixed to the lower portion of the piston portion 30 with screws 35.

The annular member 33 is a rubber member having an annular shape, for example, and is disposed to attach the diaphragm 34 to the lower portion of the piston portion 30 in surface contact. An outer edge of the annular member 33 is provided with an edge 33 a protruding to the opposite side of the piston part 30. When the edge portion 33a abuts the lower surface of the internal space of the case portion 20, a predetermined gap can be secured between the annular member 33 and the lower case 21, and the screw 35 is disposed even when the piston portion 30 is lowered. The head does not hit the lower case 21.
Further, the outer diameter of the lower end side of the annular member 33 is designed to be substantially equal to the inner diameter of the lower portion of the internal space of the case portion 20, and the outer peripheral surface of the lower end side of the annular member 33 attached to the piston portion 30 is lower. Guided so as to move along the guide surface 21b on the inner peripheral surface of the case 21, the piston portion 30 can move up and down along the center line direction.

The diaphragm 34 is, for example, a rubber film member having an annular shape, and a thick portion is provided on the outer edge thereof. The thick portion of the diaphragm 34 is inserted between the lower case 21 and the upper case 22, and the water tightness between the lower case 21 and the upper case 22 is also maintained by this diaphragm 34. ing.
The diaphragm 34 prevents the extinguishing agent from leaking from the outer periphery of the piston portion 30 to the first opening 24 side. The diaphragm 34 is attached with a slack play so as not to hinder the vertical movement of the piston portion 30.

The piston portion 30 serves as a flow path for the extinguisher stock solution flowing from the inlet 23 of the case portion 20.
Here, the combined opening area of the second opening 31 and the third opening 32 is formed smaller than the opening area (cross-sectional area) of the flow path in the piston part 30, and the second opening 31 The flow rate of the extinguishing agent stock solution passing through the third opening 32 is adjusted to be a predetermined flow rate.

The piston part 30 is arranged in the case part 20 so that the center lines of the piston part 30 are on the same axis, and the piston part 30 can be moved up and down along the center line direction (axial direction). It is possible.
Specifically, in a state where the extinguishing agent mixing device 50 is not operated, the piston part 30 is lowered by its own weight in the case part 20 and is in a position shown in FIG.
On the other hand, when the fire extinguisher mixing device 50 is operated, the piston part 30 rises due to the flow of the extinguishing agent stock solution into the case part 20, and is the highest as shown in FIG. It is possible to move to a position where the upper end surface of the inner surface of the case 20 is in close contact with the inner top surface of the internal space of the case portion 20.
When the piston part 30 is raised by the inflow of the extinguishing agent stock solution into the case part 20 and the upper end surface of the piston part 30 is in close contact with the inner top surface of the internal space of the case part 20, the second opening part 31. Is formed so as to communicate with the first opening 24 (see FIG. 3A), and the third opening 32 is formed so as to be closed (see FIG. 3B). .

That is, when the piston part 30 has not reached the highest position, the extinguisher stock solution flowing into the piston part 30 from the inlet 23 passes through the second opening 31 and the third opening 32 of the piston part 30. However, it flows so as to pass through the first opening 24 of the case portion 20.
On the other hand, when the piston part 30 reaches the highest position, the extinguishing agent stock solution flowing into the piston part 30 from the inlet 23 passes only through the second opening 31 of the piston part 30, and It flows so as to pass through the first opening 24.
As the piston portion 30 is raised, the diameter reduction rate of the reduced diameter portion formed by the first opening 24, the second opening 31, and the third opening 32 can be adjusted.
The second opening 31 is formed narrower than the first opening 24, and the first opening 24 is an opening formed by combining the second opening 31 and the third opening 32. It is formed narrower than.

(Explanation of fire extinguishing agent flow controller)
Next, the operation of the extinguishing agent flow rate regulator 10 will be described based on the operation of the extinguishing agent mixing apparatus 50.

The fire extinguisher mixing device 50 is operated, and a differential pressure is generated between the inlet portion 101b and the narrow portion 101a as the water flow in the mixer 101 is generated by opening the discharge port.
Due to this differential pressure, the internal pressure of the pressurized water region on the pressurized water side piping 104 side of the extinguishing agent storage pressurization tank 102 increases, and the extinguishing agent stock solution is pushed out from the extinguishing agent region through the diaphragm. The extinguishing agent stock solution pushed out from the extinguishing agent storage pressurization tank 102 flows into the inside from the inlet 23 of the extinguishing agent flow rate regulator 10 through the extinguishing agent side pipe 105.

  When the flow rate of the water flow in the mixer 101 is small, the flow rate of the extinguishing agent stock solution is also small. As shown in FIG. In addition, it is located at the bottom of the internal space of the case portion 20. In this state, the extinguishing agent stock solution passes through the second opening 31 and the third opening 32 of the piston part 30 and further passes through the first opening 24 of the case part 20 before the narrowing of the mixer 101. It is fed into the section 101a and mixed with running water in the fire extinguishing pipe main pipe 103.

Here, the combined opening area of the second opening 31 and the third opening 32 is a target even when the extinguishing agent stock solution has a low flow rate that cannot move the piston part 30 to the highest position. Since the flow rate reaching the mixed concentration is set to a size that can ensure the target concentration, the target concentration of the aqueous fire extinguisher solution supplied to the outlet is maintained.
In particular, the first opening 24 is formed to be narrower than the combined opening area of the second opening 31 and the third opening 32, and the second opening 31 and the third opening 32 are formed. Since the flow rate of the extinguishing agent stock solution that has passed through the first opening 24 is adjusted to be a predetermined flow rate, the flow rate of the extinguishing agent stock solution varies until the piston portion 30 reaches the highest position. In addition, the fire extinguisher mixing apparatus 50 can generate a fire extinguishing agent aqueous solution having a predetermined mixed concentration.

When the flow rate of the water flow in the mixer 101 increases, the flow rate of the extinguishing agent stock solution also increases, and the piston portion 30 starts to move upward in the case portion 20 of the extinguishing agent flow rate regulator 10. At this time, when the jet of the extinguisher stock solution that has passed through the third opening 32 of the piston part 30 hits the inner top surface of the internal space of the case part 20, a force opposite to that when the piston part 30 is raised acts. To do.
When the extinguishing agent stock solution reaches a predetermined flow rate, as shown in FIG. 3 (B), the piston portion 30 reaches the highest position against the reaction force of its own weight and jet flow. In this state, the third opening 32 of the piston part 30 is closed, and the extinguishing agent stock solution passes only through the second opening 31 and further passes through the first opening 24 before the narrowing of the mixer 101. It is fed into the section 101a and mixed with running water in the fire extinguishing pipe main pipe 103.

Here, the opening area of the second opening 31 greatly exceeds the target mixture concentration even when the flow rate of the extinguishing agent stock solution exceeds the flow rate that moves the piston portion 30 to the highest position. Since it is set to a size that can prevent the waste of the chemical stock solution, the extinguishing agent aqueous solution supplied to the water outlet does not greatly exceed the target concentration and can maintain the predetermined mixing concentration almost stably. .
In particular, since the second opening 31 is formed narrower than the first opening 24, the flow rate of the extinguishing agent stock solution after the piston part 30 reaches the highest position is the second opening. Therefore, the extinguishing agent aqueous solution supplied to the water outlet does not greatly exceed the target concentration, and waste of the extinguishing agent stock solution is avoided.
Further, the magnitude of the force opposite to the rise acting on the piston portion 30 by the jet of the extinguishing agent stock solution that has passed through the third opening portion 32 is adjusted by adjusting the inner diameter size of the third opening portion 32. Therefore, when the extinguishing agent stock solution reaches a predetermined flow rate, it is possible to set the timing at which the piston portion 30 reaches the highest position by adjusting the inner diameter size of the third opening portion 32. Yes.

Thus, the inner top surface of the case part 20 in which the first opening 24 is formed and the second opening part 31 by the cooperation of the case part 20 and the piston part 30 according to the flow rate of the extinguishing agent stock solution. And the state which the upper end surface of piston part 30 in which the 3rd opening part 32 is formed closely_contacts | connects and the state which separates is switched.
That is, the case portion 20 and the piston portion 30 have a reduced diameter ratio of the reduced diameter portion including the first opening portion 24, the second opening portion 31, and the third opening portion 32 in accordance with the flow rate of the extinguishing agent stock solution. It functions as a variable means for performing the variable adjustment.
Here, the “reduction ratio” is, for example, the opening area of the first opening 24 of the case portion 20 with respect to the opening area of the piston portion 30 including the second opening 31 and the third opening 32. The ratio or the ratio of the total opening area of the second opening part 31 and the third opening part 32 that can flow in the piston part 30 to the opening area (cross-sectional area) of the flow path in the piston part 30.

(Relationship between the flow rate of the main pipe of the fire extinguishing pipe and the concentration of the extinguishing agent)
Using the fire extinguisher flow rate adjuster 10, a test for determining the relationship between the water supply flow rate (horizontal axis) of the fire extinguishing pipe main pipe 103 and the concentration of the extinguishing agent aqueous solution (vertical axis) is performed, and the result is shown as a diagram in FIG. .

In the above test, the opening area of the first opening 24 of the case portion 20 is 9.62 [mm ² ] (inner diameter 3.5 [mm]), and the opening area of the second opening 31 of the piston portion 30 is 8 .55 [mm ² ] (inner diameter 3.3 [mm]), and the opening area of the third opening 32 of the piston portion 30 is 25.13 [mm ² ] (inner diameter 4.0 [mm] × 2 locations). The fire extinguishing agent flow controller 10 was used, and the test result is shown by a broken line L in FIG. The range where the flow rate of the fire extinguishing pipe main pipe 103 is less than 30 [L / min] and the range where it exceeds 400 [L / min] is out of the operating range of the fire extinguisher mixing device 50 and thus excluded from the test target.
Further, when the value of the opening area of the first opening 24 is A, the value of the opening area of the second opening 31 is B, and the value of the opening area of the third opening 32 is C, as described above. In addition, each opening has an opening size that satisfies a relationship of B <A <B + C.

According to this test result, the extinguishing agent flow rate adjuster 10 has not yet started to rise in the piston portion 30 in the band where the flow rate of the fire extinguishing pipe main pipe 103 (main pipe flow rate) is 30 to 100 [L / min]. In such a range, an aqueous fire extinguisher solution having a relatively high mixed concentration is generated.
When the main pipe flow rate exceeds 100 [L / min], the piston part 30 starts to rise, and the supply amount of the extinguishing agent stock solution is gradually limited, and at 150 [L / min], the piston part 30 reaches the highest ascent position. The diameter reduction rate is switched.
In the zone where the main pipe flow rate is 150 to 400 [L / min], the mixed concentration of the extinguishing agent aqueous solution is maintained at a stable value of about 3.5%.

In addition, when the extinguishing agent flow rate regulator 10 is used, the main pipe flow rate is higher than the target mixing concentration in the band of 30 to 100 [L / min], but the flowing water flow rate flowing through the mixer 101 is small. The absolute amount of the fire extinguishing agent put into the mixer 109 is also small. Therefore, the consumption of the fire extinguishing agent does not cause an influence that cannot be maintained within the set release time.
Moreover, in the extinguishing agent flow rate regulator 10, the main pipe flow rate slightly exceeds the target concentration (3.5%) in the band of 150 to 400 [L / min], but this is reduced by adjusting the inner diameter of each opening. Can be achieved.

As described above, the fire extinguisher flow rate adjuster 10 is a case where the extinguishing agent stock solution passes through the second opening 31 and the third opening 32 of the piston portion 30 when the stock solution of the fire extinguishing agent has a low flow rate. When supplying the mixer 101 so as to pass through the first opening 24 of the unit 20 and the extinguishing agent stock solution has a high flow rate, the third opening 32 of the piston unit 30 is closed, and the fire extinguishing is performed. The agent stock solution is passed through only the second opening 31 and then supplied to the mixer 101 so as to pass through the first opening 24.
Thus, when the water supply flow rate of the fire extinguishing pipe main pipe 103 (mixer 101) is small, the fire extinguisher flow rate adjuster 10 relatively increases the diameter reduction rate of the reduced diameter portion to avoid the supply of fire extinguishing agent shortage. When the water supply flow rate is increased, the reduction rate of the reduced diameter portion is made relatively small so as to avoid excessive supply of the extinguishing agent, the supply amount of the extinguishing agent stock solution is adjusted to an appropriate range, and the extinguishing agent is generated. The concentration of the aqueous solution can be maintained at a stable value.

  The extinguishing agent flow rate adjuster 10 adjusts the supply amount of the extinguishing agent stock solution to an appropriate range, so that the extinguishing agent stock solution is not excessively supplied when the water supply flow rate is increased in the extinguishing agent mixing device 50. It becomes possible to prevent waste of the extinguishing agent stock solution. Further, along with this, it becomes possible to continue the discharge of the extinguishing agent aqueous solution during the set release time without increasing the size of the extinguishing agent storage pressure tank 102 of the extinguishing agent mixing apparatus 50.

Further, the fire extinguisher flow rate adjuster 10 stabilizes the mixed concentration of the fire extinguisher aqueous solution with a simple configuration having the case portion 20 and the piston portion 30 as main parts, so that the production cost of the fire extinguisher flow rate adjuster 10 is reduced. As a result, productivity can be improved.
In particular, the extinguishing agent flow rate regulator 10 acts on the piston portion 30 by the jet of the extinguishing agent stock solution passing through the third opening portion 32 by adjusting the inner diameter size of the third opening portion 32 of the piston portion 30. By adjusting the magnitude of the force in the direction opposite to the rise, when the extinguishing agent stock solution reaches a predetermined flow rate, it is possible to set the timing at which the piston portion 30 reaches the highest rise position. The supply flow rate of the fire extinguishing agent can be adjusted more easily than setting the timing at which the piston portion operates using a coil spring.

  Further, as in the case of the extinguishant flow rate adjuster 10, by moving the piston part 30 up and down in accordance with the flow rate of the extinguishing agent stock solution without using the coil spring, the piston is more than the conventional one using the coil spring. Since the movement of the part 30 becomes smooth, the difference in concentration of the extinguishing agent aqueous solution between when the water supply flow rate of the fire extinguishing pipe main pipe 103 is small and when it increases can be reduced.

In the above embodiment, the second opening 31 of the piston portion 30 is formed at the approximate center of the upper end surface, and the third opening 32 is formed so as to sandwich the second opening 31. However, the present invention is not limited to this, and when the upper end surface of the piston portion 30 is in close contact with the inner top surface of the case portion 20, the second opening 31 is the first of the case portion 20. As long as the third opening 32 is formed so as to communicate with the opening 24 and the third opening 32 is closed, it may be provided on any of the upper end surfaces of the piston 30.
Similarly, the first opening 24 of the case portion 20 may be provided in any of the upper cases 22 as long as the first opening 24 communicates with the second opening 31.

  In addition, with respect to the opening area of the first opening 24 of the case portion 20, the second opening portion 31 of the piston portion 30, and the third opening portion 32, appropriate values may vary depending on use conditions, design conditions, and the like. However, it is not limited to a specific value.

10 Extinguishing agent flow controller 20 Case part (variable means)
21 Lower case 21b Guide surface 22 Upper case 22b Guide surface 23 Inlet 24 First opening (reduced diameter portion)
25 Outlet 30 Piston part (variable means)
31 Second opening (reduced diameter portion)
32 3rd opening part (reduction diameter part)
33 Annular member 34 Diaphragm 50 Fire extinguisher mixing device

Claims (4)

A fire extinguisher that adjusts the supply flow rate of the extinguishing agent stock solution in order to adjust the concentration of the extinguishing agent aqueous solution in a fire extinguisher mixing device that supplies and mixes the extinguisher stock solution to the flowing water sent to the discharge port for performing fire extinguishing A flow regulator,
A reduced diameter portion formed narrower than the flow path of the extinguishing agent stock solution located on the upstream side,
According to the supply flow rate of the extinguisher stock solution, a variable that adjusts the diameter reduction rate of the reduced diameter portion by closing a part of the reduced diameter portion when the supply flow rate is high and opening a part when the supply flow rate is low. Means,
With
The variable means is supported so that the extinguisher stock solution flows in from the bottom to the top, and is lowered by its own weight in the case portion and rises by the inflow of the extinguisher stock solution. A fire extinguisher flow rate regulator, comprising: a piston portion, wherein adjustment is performed to reduce a diameter reduction rate of the reduced diameter portion by raising the piston portion. The reduced diameter portion is composed of a first opening provided in the case portion, a second opening provided on the upper end surface of the piston portion, and a third opening,
The second opening is formed in an arrangement that communicates with the first opening by rising due to the inflow of the extinguishing agent stock solution of the piston part, and the third opening is the extinguishing agent of the piston part. The extinguishing agent flow rate regulator according to claim 1, wherein the extinguishant flow rate regulator is formed so as to be closed by rising due to inflow of the stock solution. The second opening is formed narrower than the first opening,
The fire extinguishing agent flow controller according to claim 2, wherein the first opening is formed narrower than an opening formed by combining the second opening and the third opening.   The upper end side and the lower end side of the piston part are respectively guided so as to move along the inner peripheral surface of the case part, and the piston part is supported so as to be movable up and down. The extinguishing agent flow rate regulator according to any one of the above.

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