JPH07198237A - Nozzle purge mechanism of artificial-snow spray machine - Google Patents

Abstract

PURPOSE:To obtain a nozzle purge mechanism of an artificial-snow spray machine, which requires no manual operation, has such a construction that pressurized water is hard to flow back to an air line, is easy to maintain, and is also easy to connect an air line as an air inlet of a nozzle header is used in common. CONSTITUTION:A nozzle purge mechanism includes a pressurized air inlet chamber 15-2 that communicates with an air chamber 18, a valve disc chamber 15-3 that communicated with a water chamber 17, a through-hole which connects the pressurized air inlet chamber 15-2 and the valve disc chamber 15-3 and a spring 15-6 that powers a valve disc 15-5 to block the though hole. When pressurized water is stopped at the time of finish of snow spray, pressurized air in the pressurized air chamber 15-2 overcomes the repulsion force of the spring 15-6 and opens the through hole, so that pressurized air flows into the water chamber 17 through the through-hole and purges the residual water.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention relates to a large number of water nozzles and water
TECHNICAL FIELD The present invention relates to a nozzle purging mechanism of an artificial snowfall machine for purging water remaining in a nozzle header of an artificial snowfall machine (which is usually called a fan type artificial snowfall machine) having an air nozzle.

[0002]

2. Description of the Related Art In this type of snowfall machine, if water remains in the nozzle header after the snowfall work is completed, the residual water freezes before the next snowfall work, and the next snowfall work can be performed normally. There was a problem of not having. Conventionally, as a method for removing residual water in the nozzle header, there are a valve switching type in which a valve is switched and a check valve type in which a ball type check valve is embedded in the nozzle header.

FIG. 4 is a view showing the structure of a nozzle header provided with the above-described conventional valve switching type purging mechanism. Inside the ring-shaped air line 101, the ring-shaped water line 1 is also provided.
02 is provided, the water line 102 is connected to a water nozzle 104 for injecting a large number of water, and a large number of water / air nozzles 103 are connected between the air line 101 and the water line 102. Pressurized water (7 to 20 Kg /
A pressurized water pipe 105 for supplying cm ² ) is connected, and a pressurized air pipe 106 for supplying pressurized air (7 Kg / cm ² ) is connected to the air line 101. A switching valve 107 for purging is connected between the pressurized water pipe 105 and the pressurized air pipe 106.

In the above structure, after the completion of the snowfall operation, the supply of the pressurized water from the pressurized water pipe 105 is stopped, the switching valve 107 is switched, and the pressurized air from the pressurized air pipe 106 is supplied to the water line 102 and remains. Water is purged with pressurized air.

FIG. 5 is a view showing the structure of a nozzle header provided with the above-mentioned conventional embedded ball check type purge mechanism. In FIG. 5, the parts designated by the same reference numerals as in FIG. 4 indicate the same or corresponding parts. As shown, pressurized water pipe 1
The embedded ball check type purge mechanism 108 is disposed between the pressure check pipe 05 and the pressurized air pipe 106.

The ball check type purge mechanism 108 is shown in FIG.
As shown in, a water chamber 109 and an air chamber 110 are provided,
Pressurized water is supplied to the water chamber 109 from the water line 102,
Pressurized air is supplied to the air chamber 110 from the air line 101. A ball type check valve 111 is provided between the water chamber 109 and the air chamber 110.
When the snowfall work is completed and the supply of the pressurized water from the pressurized water pipe 105 is stopped, the pressurized air flows into the water chamber 109 through the air chamber 110 and the check valve 111, and the water remaining in the water chamber 109 and the water line 102 is automatically removed. It is designed to be purged.

[0007]

The above-described valve switching type purge mechanism is a work for supplying pressurized air to the water line 102 by stopping the supply of pressurized water at the end of the snowfall work and switching the switching valve 107. It takes time and effort, and the switching valve 10
If the switching of 7 is forgotten, the problem that the next snowfall work cannot be performed due to freezing of residual water may occur.

Further, the ball check type purge mechanism has a pressurized air pressure of 7 Kg / c required for an artificial snowfall machine.
When the pressure of the pressurized water is close to this pressure with respect to m ² (usually about 7 to 20 kg / cm ² ), the check valve 11
There is a problem that pressurized water flows into the air line 101 due to the opening of No. 1 and the check valve 111 is an embedded type, which makes maintenance difficult.

The present invention has been made in view of the above-mentioned problems, and eliminates the above-mentioned problems, does not require manual operation, and has a structure in which pressurized water does not easily flow back into the air line, is easy to maintain, and has a nozzle header. It is an object of the present invention to provide a nozzle purging mechanism for an artificial snowmaking machine that also serves as an air inlet and in which an air line can be easily attached.

[0010]

In order to solve the above problems, the present invention provides a large number of water nozzles and water / air nozzles, a water chamber connected to the water nozzles and the water / air nozzles, and a water / air nozzle. A nozzle header having an air chamber connected to the water chamber, and by supplying pressurized water to the water chamber and supplying pressurized air to the air chamber, purging water remaining in the nozzle header of an artificial snowmaking machine that produces snow. As shown in FIGS. 1 and 3, the nozzle purging mechanism is
The pressurized air inflow chamber (15- that communicates with the air chamber (18)
2), a valve body chamber (15-3) communicating with the water chamber (17), a through hole (15-13) for communicating the pressurized air inflow chamber (15-2) and the valve body chamber (15-3). And the valve body chamber (15-3)
Valve body (15-5) housed in the
5) and a spring (15-6) which acts to close the through hole (15-13) so as to close the through hole (15-13), the compressed air passes through the compressed air inflow chamber (15-2) during snowfall. Is supplied to the air chamber (18) of the nozzle header, and the pressurized water enters the valve body chamber (15-3) from the water chamber (17) of the nozzle header, and the water pressure of the pressurized water is added to the repulsive force of the spring (15-6). Then, the valve body (15-5) is pushed, and when the supply of the pressurized water is stopped at the end of the snowfall, the pressurized air in the pressurized air inflow chamber (15-2) causes the valve body (15-5) to spring (15-6). The push through hole (15-13) is opened by overcoming the repulsive force of.

The nozzle purging mechanism (15) is characterized in that it is attached to the outside of the nozzle header (fixed with attachment bolts 15-11).

The nozzle purging mechanism (15) is characterized in that it also serves as an inlet for introducing pressurized air into the air chamber of the nozzle header.

The pressurized air receiving area of the valve body (15-5) is smaller than the pressurized water receiving area.

[0014]

According to the present invention, by adopting the above configuration, the pressurized air flows into the air chamber (18) of the nozzle header through the pressurized air inflow chamber (15-2) at the time of snowfall, and the water / air nozzle. 13 and the pressurized water is supplied to the water chamber (17) of the nozzle header.
Goes into the valve body chamber (15-3) from the spring (15-6)
The repulsive force of the valve body (15-
Since 5) is pushed, the valve body (15-5) closes the through hole (15-13) which connects the pressurized air inflow chamber (15-2) and the valve body chamber (15-3). This prevents pressurized air from flowing into the water chamber (17). When the supply of pressurized water is stopped at the end of snowfall, the pressurized air inflow chamber (15-2)
The pressurized air of the valve element (15-5) causes the spring (15-
Since the push through hole (15-13) is opened by overcoming the repulsive force of 6), the pressurized air flows into the pressurized air inflow chamber (15-2).
Is supplied to the water chamber (17) through the valve body chamber (15-3), the water remaining in the nozzle header is automatically purged.

Further, the nozzle purging mechanism (15) has a structure attached to the outside of the nozzle header.
The inside can be easily cleaned.

Further, since the nozzle purging mechanism (15) also serves as an inlet for introducing pressurized air into the air chamber (18) of the nozzle header, it suffices to connect only the end of the pressurized air pipe (16). Therefore, it becomes easy to install an air line through which pressurized air flows.

Since the pressurized air receiving area of the valve body (15-5) is smaller than the pressurized water receiving area, when pressurized water is supplied for snowfall, the pressurized water receives the pressurized water from the valve body chamber (15- 3) and the valve body (15-5) is pushed toward the pressurized air inflow chamber (15-2) side. At this time, even if the pressure of the pressurized water is close to the pressure of the pressurized air,
As described above, since the pressurized air receiving area of the valve body (15-5) is smaller than the pressurized water receiving area, and the repulsive force of the spring (15-6) is added to the area, the valve body (1
5-5) securely closes the through hole (15-13) and does not open it.

[0018]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 2 is a diagram showing a configuration of a nozzle header of an artificial snowfall machine equipped with the nozzle purging mechanism of the present invention. As shown in the figure, the nozzle header 10 is provided with a ring-shaped water line 12 inside a ring-shaped air line 11, and the water line 12 injects a large number of water.
Are connected, and a large number of water / air nozzles 13 are connected between the air line 11 and the water line 12.

A nozzle purging mechanism 15 for purging water remaining in the nozzle header 10 is connected between the air line 11 and the water line 12. The nozzle purging mechanism 15 also serves as the air inlet of the nozzle header 10, and the pressurized air pipe 1 for supplying pressurized air (7 Kg / cm ² ).
6 is connected. A pressurized water pipe 20 for supplying pressurized water (7 to 20 Kg / cm ² ) to the water line 12.
Are connected.

FIG. 1 is a diagram (a sectional view taken along the line AA in FIG. 2) showing a nozzle purging mechanism attached to a nozzle header. The nozzle purging mechanism 15 is fixed to the outer peripheral side of the nozzle header 10. A water chamber 17 and an air chamber 18 are provided inside the nozzle header 10, the water chamber 17 is connected to the water nozzle 14 and the water / air nozzle 13, and the air chamber 18 is the water / air nozzle 1.
Connected to 3. The water chamber 17 communicates with the water line 12, and the air chamber 18 communicates with the air line 11 (the water chamber 17 is a part of the water line 12, and the air chamber 18 is the air line 1).
Part of 1.).

3A and 3B are views showing the structure of the nozzle purging mechanism 15. FIG. 3A is a vertical sectional view, and FIG. 3B is X in FIG.
-X sectional drawing, FIG.3 (c) is YY sectional drawing of (a). The nozzle purging mechanism 15 includes a purging mechanism body 15-1, and the purging mechanism body 15-1 is provided with a pressurized air inflow chamber 15-2 and a valve body chamber 15-3. The pressurized air inlet chamber 15-2 is provided with a pressurized air supply port 15-2a into which the end 16a of the pressurized air pipe 16 shown in FIG. 1 is screwed. A through hole 15-13 for allowing the valve guide 15-4 to reciprocate is provided between the pressurized air inflow chamber 15-2 and the valve body chamber 15-3.

The valve guide 15-4 is provided in the valve body chamber 15-3.
The valve body 15-5, to which the
Is always the pressurized air inflow chamber 1 due to the repulsive force of the spring 15-6.
It is biased to the 5-2 side. Incidentally, 15-7 is a valve body packing, and 15-8 is a plain washer. Pressurized air inflow chamber 15
-2, a pressurized air inlet 15-2b communicating with the air chamber 18 of the nozzle header 10 is provided, and the valve body chamber 15-3
Is provided with a pressurized water inlet 15-3b communicating with the water chamber 17. Further, the valve body chamber 15-3 is sealed with a lid 15-10 via an O-ring 15-9.

The nozzle purging mechanism 15 is fixed on the nozzle header 10 by placing the purging mechanism body 15-1 on the nozzle header 10 and tightening the mounting bolts 15-11. At this time, the pressurized air inlet 15-2b and the pressurized water inlet 15-3b have O-rings 15-12 and 15-12 in the air introduction hole 18a of the air chamber 18 and the pressurized water introduction hole 17a of the water chamber 17, respectively, shown in FIG. Let me be connected in a confidential state.

The nozzle purging mechanism 15 having the above structure operates as follows. When starting snowfall with an artificial snowfall machine, generally only the compressor (not shown) is first operated. The pressurized air flowing into the nozzle purging mechanism 15 through the pressurized air pipe 16 enters the air chamber 18 of the nozzle header 10 through the pressurized air inflow chamber 15-2. At this time, since the pressurized water is not yet supplied to the water chamber 17, the nozzle purging mechanism 15
No water pressure is applied to the valve body chamber 15-3 side, and the air pressure (about 7 Kg / cm ² ) of the pressurized air overcomes the repulsive force of the spring 15-6, and the valve body 15-5 moves to the valve guide 15-4. It is guided and moves to the valve body chamber 15-3 side (right side in FIG. 3) and opens.

When the valve body 15-5 is opened, part of the pressurized air flowing into the pressurized air inflow chamber 15-2 is part of the valve body chamber 15-.
3 and flows into the water chamber 17. That is, the pressurized air is jetted from all the water / air nozzles 13 and the water nozzles 14. The clogging state of these nozzles can be determined by whether or not pressurized air is being jetted from the water / air nozzle 13 and the water nozzle 14 instead of water.

Next, when the pressurized water is supplied to the water line 12 through the pressurized water pipe 20 for snowfall, the pressurized water flows into the water chamber 17 of the nozzle header 10 and further through the pressurized water introducing hole 17a to the valve body of the nozzle purging mechanism 15. Room 15-
Inflow to 3. As a result, the valve body 15-5 is pressed against the pressurized air inflow chamber 15-2 side (left side in FIG. 3). At this time, even if the water pressure of the pressurized water is close to the air pressure of the pressurized air, the pressure receiving area of the valve body 15-5 is larger than that of the pressurized air, and the spring is Since the spring force of 15-6 is added,
The valve body 15-5 is guided by the valve guide 15-4 and is pressed and held toward the pressurized air inflow chamber 15-2 side and never opens. Thus, during the snowfall, all the supplied pressurized air enters the air chamber 18 of the nozzle header 10 through the nozzle purging mechanism 15 and is supplied to the water / air nozzle 13.

When the snowfall operation is completed and the supply of the pressurized water is stopped, the valve body 15-5 of the nozzle purging mechanism 15 is no longer pressurized with the pressurized water. The valve body chamber 1 is pushed by the pressurized air in the inflow chamber 15-2 and overcomes the repulsive force of the spring 15-6.
Move to the 5-3 side (right side in FIG. 3) and open. As a result, the pressurized air flows into the water chamber 17 of the nozzle header 10 through the valve body chamber 15-3, and the water remaining in the nozzle header 10, that is, the water line 12, the water / air nozzle 13 and the water nozzle 14 is discharged.
Automatically purge the water remaining inside. Therefore, since no water remains in the nozzle header 10, normal operation, that is, normal snowfall work can be performed in the next snowfall.

When the nozzle purging mechanism 15 is used for a long time, foreign matter such as scale adheres to the contact surface of the valve body 15-5 (contact surface of the valve body packing 15-7) and the spring 15-6. However, since the nozzle purging mechanism 15 has a structure that is fixed to the upper part of the nozzle header 10, that is, an external structure, the inside can be easily cleaned by removing the lid 15-10.

[0029]

As described above, according to the present invention, the following excellent effects can be obtained. (1) It is possible to automatically perform the residual water purging work that has been troublesome until the end of the snowfall work. (2) Even when the water pressure of the pressurized water becomes close to the air pressure of the pressurized air at the start of snowfall or during snowfall, the water does not flow back into the air line. (3) Since the nozzle purging mechanism is externally attached to the nozzle header, maintenance such as cleaning becomes easy. (4) Since the nozzle purging mechanism also serves as the pressurized air introduction port to the nozzle header, the number of parts as the entire nozzle header part can be reduced.

[Brief description of drawings]

FIG. 1 is a view (sectional view taken along the line AA of FIG. 2) showing a nozzle purging mechanism of the present invention attached to a nozzle header.

FIG. 2 is a diagram showing a configuration of a nozzle header of an artificial snowfall machine equipped with the nozzle purging mechanism of the present invention.

3 is a diagram showing a structure of a nozzle purging mechanism 15, and FIG.
3A is a vertical sectional view, FIG. 3B is a YY sectional view of FIG. 3A, and FIG. 3C is an XX sectional view of FIG.

FIG. 4 is a diagram showing a configuration of a nozzle header including a conventional valve switching type purge mechanism.

FIG. 5 is a view showing a configuration of a nozzle header provided with a conventional embedded ball check type purging mechanism.

6 is a cross-sectional view taken along the line AA of FIG.

[Explanation of symbols]

 10 Nozzle Header 11 Air Line 12 Water Line 13 Water / Air Nozzle 14 Water Nozzle 15 Nozzle Purge Mechanism 15-1 Purge Mechanism Main Body 15-2 Pressurized Air Inflow Chamber 15-3 Valve Body Chamber 15-4 Valve Guide 15-5 Valve Body 15-6 Spring 15-7 Valve body packing 15-8 Flat washer 15-9 O-ring 15-10 Lid 15-11 Mounting bolt 15-12 O-ring 15-13 Through hole 16 Pressurized air pipe 17 Water chamber 18 Air chamber 20 Pressurized water pipe

Claims (4)

[Claims] 1. A large number of water nozzles and water / air nozzles,
A nozzle header having a water chamber connected to the water nozzle and the water / air nozzle and an air chamber connected to the water / air nozzle is provided, and pressurized water is supplied to the water chamber and pressurized air is supplied to the air chamber. A nozzle purging mechanism for purging water remaining in the nozzle header of an artificial snowmaking machine that supplies snow, the nozzle purging mechanism including a pressurized air inflow chamber communicating with the air chamber and a valve communicating with the water chamber. A body chamber, a through hole that connects the pressurized air inflow chamber and the valve body chamber, a valve body housed in the valve body chamber, and a valve body that constantly urges the valve body to close the through hole. When the snow falls, the pressurized air is supplied to the air chamber of the nozzle header through the pressurized air inflow chamber, and the pressurized water enters the valve body chamber from the water chamber of the nozzle header and repels the spring. Valve by adding the water pressure of the pressurized water to the force When the supply of pressurized water is stopped at the end of snowfall, the pressurized air in the pressurized air inflow chamber overcomes the repulsive force of the spring and pushes the valve body to open the through hole. Nozzle purge mechanism. 2. The nozzle purging mechanism for an artificial snowfall according to claim 1, wherein the nozzle purging mechanism has a structure attached to the outside of the nozzle header. 3. The nozzle purging mechanism for an artificial snowfall according to claim 1, wherein the nozzle purging mechanism also serves as an inlet for introducing pressurized air into the air chamber of the nozzle header. 4. The nozzle purging mechanism for an artificial snowfall according to claim 1, wherein the pressurized air receiving area of the valve body is smaller than the pressurized water receiving area.