JP2008190136A - Device for preventing accumulation of snow - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a safe device for preventing the accumulation of snow, which can prevent the accumulation of the fallen snow. <P>SOLUTION: This device is characterized in that a jet of air sent by a blast mechanism is emitted from an air jet mechanism of an exhaust pipe through a leading pipe. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention can prevent snow accumulation by blowing off snow in an arbitrary direction by continuously injecting air blown from an air blowing mechanism radially from an air blowing mechanism continuously provided in a discharge pipe. The present invention relates to a snow avoidance device characterized by that.

  Conventionally, in order to remove snow that has already accumulated snow, it is possible to remove snow by hand using a scoop, etc., remove snow with a heavy machine such as an excavator with a snow removal bucket at the end of a long arm, or melt snow with a snow melting device. I was removing snow.

Therefore, there were the following problems.
Conventionally, in order to remove snow accumulated on a roof or the like, it has been necessary to manually lift the snow using a snow removal tool such as a scoop after climbing the roof.
At that time, they had to act with the knowledge of the dangers, and at the same time required a lot of effort.

There are also methods for removing snow with a heavy machine such as an excavator with a snow removal bucket at the end of a long arm, melting snow with a snow melting device, and falling snow naturally. In addition to workability such as damage to roofing materials due to snow, there are dangers such as fall accidents of snow removers, fall accidents of heavy machinery, accidents burying in the case of natural fall of snow, etc., and snow must be removed every year Therefore, there were also problems in terms of economic efficiency such as labor costs and mechanical loss.
The present invention has been invented to eliminate these drawbacks.

  The blower mechanism, a guide pipe connected to the blower mechanism, a plurality of discharge pipes branched from the guide pipe, and an air jet mechanism provided in the discharge pipe, the air jet mechanism is a diffusion It is made up of nozzles, slits, holes or the like provided so as to inject air in a shape, and the discharge pipe and air ejection mechanism are arranged and formed in a direction to exclude snow and dust in any specific direction Is done.

During snowfall, by operating the switch mechanism, the high-pressure air blown from the blower mechanism is guided to the discharge pipe through the guide pipe, and it is continuously and radially injected from the air discharge mechanism of the discharge pipe. Thus, it is characterized in that the snowfall before snowfall is continuously blown off in an arbitrary direction to prevent snow accumulation.
The present invention is a snow avoidance device having the above-described configuration.

Therefore, the following effects are exhibited.
When removing snow on the roof of a building or the top of a steel frame, etc., it took a dangerous work at a high place and a great deal of labor. However, according to the present invention, it was not necessary to remove snow because it did not accumulate snow.
It is safe because there are no accidents caused by the natural fall of snow from the roof or the top of the steel frame.
You can rest assured that there will be no catastrophic accidents due to the collapse of buildings, etc. in addition to houses and rain gutters due to the weight of snow.
By installing it at a dangerous location where an avalanche is expected, there is no snow accumulation, so snow damage such as an avalanche can be prevented.

  It is possible to prevent the snow on the railway tracks from being removed, so that not only snow removal is unnecessary, but also a derailment accident and a predictable situation such as a train being disconnected can be prevented.

  Snow cover is a matter of life and death in that area, and snow removal requires a large amount of money every year, both personally and publicly. As shown in FIG. 30, a safe and fulfilling life can be expected by providing a public supply system such as a power or gas supply system.

Examples of the present invention will be described below.
As shown in FIG. 1, the present invention includes a blower mechanism (2), a guide pipe (3) connected to the blower mechanism (2), and a plurality of discharge pipes branched from the guide pipe (3) ( 4) and as shown in FIG. 3, the nozzles (7) and slits (8) provided in the discharge pipe (4) and capable of jetting air diffusely, or air jets such as holes (9) Mechanism (5).

  The blower mechanism (2) includes a blower (10) and a set of equipment attached to the blower (10). The blower (10) is low pollution, hardly breaks down, can be used for a long time with low energy, and when it snows. It has the performance that can secure the air volume and the air pressure that can blow off the snow before it snows, it does not accumulate snow on the roof etc., and the air tank (11) becomes the set pressure If it is less than the set pressure, it automatically has a function to resume operation, and as shown in FIG. 2, it has a switch mechanism (6), which can be used for electric or engine An air compressor that can obtain a large air volume and moderate wind pressure by driving continuously at high speed is suitable.

As shown in FIG. 2, the switch mechanism (6) comprises a computer-controlled automatic type, a timer type / manual type switch, a device including a safety device, and a storage BOX for protecting and storing them. It is provided in the position.
In order to install the blower mechanism (2) and the switch mechanism (6), they are firmly installed in an environment where they can be operated even during snowfall by surrounding them with a roof or a wall.

  In order to keep the air volume and the air pressure at the time of air blowing constant, as shown in FIG. 2, an air tank (11) may be provided between the air blower (10) and the induction pipe (3).

  The air tank (11) is not easily deteriorated and can be used for a long time, and can sufficiently withstand the pressure blown by the blower mechanism (2). It shall have the performance that can be secured.

  The blower (10), the air tank (11), and the guide pipe (3) are connected by a joint mechanism (12).

  The joint mechanism (12) is made of a material that is not easily damaged or deteriorated, has a packing (13), a seal, and the like, and has a firm structure such as a one-touch type or a screw-in type. 10) can be easily connected to the air tank (11), the induction pipe (3), the discharge pipe (4), and the like.

  In order to supply or stop compressed air or the like from the blower (10) to the air tank (11) and from the air tank (11) to the guide pipe (3), an air supply handle (14) is provided. ).

  The air supply handle (14) is made of a material that is not easily damaged or deteriorated, has a packing (13), has a solid structure such as screwed, and can be opened and closed or one-touch. Therefore, an appropriate number is provided at any position where it is easy to operate.

  As shown in FIG. 1, the guide pipe (3) is provided for the purpose of reliably guiding the compressed air from the blower mechanism (2) to the air ejection mechanism (5). It is in the shape of a pipe, it is lightweight, is not easily deteriorated even if it is installed outside for a long time, has sufficient strength to prevent deformation and collapse due to strong winds and the environment, and the air tank (11) and discharge pipe ( 4) and can be easily jointed.

  Further, as shown in FIG. 1, the guide pipe (3) has a drainage gradient, and an appropriate number of water draining devices (15) are provided at arbitrary positions where appropriate operation is easy.

  As shown in FIG. 5, the water draining device (15) has a drain cock (16) with packing, seal, etc., and has a water storage pocket (17) type. Intrusion water from the nozzle (7), slit (8), hole (9), etc. of the provided air ejection mechanism (5) passes through the drainage pipe (4), and the water storage pocket (17 ), The drain cock (16) is released and drained, and then the drain cock (16) is closed so that there is no air leakage during ventilation.

The discharge pipe (4) is made of a metal or a hose and is pipe-shaped, lightweight, not easily deteriorated even when installed outside for a long period of time, and has sufficient strength to resist deformation or collapse due to strong winds or the environment. As shown in FIG. 6, air jet mechanisms (5) continuously arranged at equal intervals are provided, and as shown in FIG. 1, one end of the guide pipe (3) and the joint mechanism ( 12), a necessary number of continuous branch connections are made according to 12), the other end is cut and covered, or a joint mechanism (12) is connected to one end of another discharge pipe (4) by a connecting pipe (18) Connected with.
The connection pipe (18) is made of the same material as the discharge pipe (4), and is provided for the purpose of connecting the discharge pipe (4) and the plurality of other discharge pipes (4) arranged continuously. However, it can also serve as the use of the discharge pipe (4).

  As shown in FIG. 6, the air ejection mechanism (5) is provided in the discharge pipe (4) and has a nozzle (7) slit (8) or a hole ( 9) and the like are continuously arranged at appropriate intervals so that snowfall and dust can be excluded in any specific direction.

As shown in FIG. 3, the slit (8) and the hole (9) are directly cut or perforated in the discharge pipe (4) so as to spray air in a diffused manner.
As shown in FIG. 7, the nozzle (7) is lightweight, easily damaged, or hardly deteriorated even when installed outside for a long period of time, and has sufficient strength to prevent deformation or collapse due to strong wind or environment. The nozzle body (19) is formed in a pipe, and the nozzle body (19) can be straight or square-shaped and has an air injection port (20) at one end that faces upward with an appropriate gradient, and the other end has a skirt ring. In addition, a packing (13) is applied to the nozzle mounting end (21) of the discharge pipe (4) and is fastened with a nut so that the direction of the nozzle (7) can be fixed in a specific direction.

The nozzle mounting end (21) is made of the same material as that of the discharge pipe (4), is pipe-shaped, one end is threaded, and the other end is welded or integrally formed with the discharge pipe (4). A suitable number is provided at appropriate intervals.
Alternatively, the nozzle socket (22) is welded or integrally formed.

  As shown in FIG. 8, the nozzle socket (22) is made of the same material as that of the discharge pipe (4), is pipe-shaped, and both ends of the inner diameter are threaded, and a nozzle mounting end ( 21) is provided in the same manner as described above, and the discharge pipe (4) cut to an appropriate length can be connected to both ends.

  As shown in FIG. 1, the discharge pipe (4) is continuously provided at an appropriate interval at an appropriate interval, and is attached to an exterior material (23) such as a roof or an attachment base material (24). 25) etc. are firmly fixed.

  As shown in FIG. 10, the mounting hardware (25) has an arbitrary shape, is lightweight, is not easily deteriorated even when installed outside for a long period of time, and is not easily deformed or collapsed by strong winds or the environment. It is made of a material having strength, and the presser foot (27) can be fixed to the mounting base metal (26) with bolts or screws. The mounting hardware (25) is loose with the presser foot (27). It can adapt to the thickness of the exterior material (23) by holes and adjusting screws.

  The attachment base metal fitting (26) can be attached by inserting the insertion side of the attachment base metal fitting (26) into the gap between the tiles, the slate, the metal plate, or the overlapping portion of the other exterior material (23). It is sandwiched between hardware (27) and can be firmly and easily fixed to the exterior material (23) with an adjusting screw.

Alternatively, as shown in FIG. 11, it can be directly attached to the exterior member (23) with bolts or screws.
The mounting base metal (26) has an upper half twisted at a right angle and is provided with a loose hole. And the discharge pipe metal fitting (29) can be fastened to the upper part of the mounting base metal fitting (26).

  As shown in FIG. 10, the discharge pipe metal fitting (29) is made of the same material as the mounting base metal fitting (26), and can be fixed by sandwiching an arbitrary position of the discharge pipe (4). It has a loose hole and can be easily fixed to the mounting base metal piece (26) by bolting or screwing.

  And, as shown in FIG. 12, the discharge pipe (4) having the air ejection mechanism (5) is arranged so that flying objects such as snowfall, dust, dead leaves, etc. can be excluded in any specific direction, The attachment fitting (25) securely attached to the exterior member (23) is firmly fixed to the discharge pipe receipt (29).

  As a further application, as shown in FIG. 13, the pier of the roof exterior material (23), the pier fitting (30), and the discharge pipe (4) having the air ejection mechanism (5) are combined and integrated. As shown in FIG. 15, the vertical beam (31) with an air ejection mechanism in which the vertical beam and the discharge pipe (4) are integrated as shown in FIG. It is also a proposal to eliminate snowfall in any direction in combination with 23).

In addition, as shown in FIG. 16, an injection device storage mechanism (32) made of an arbitrary shape is provided in an arbitrary part of the solar system or the exterior material (23), and the blower mechanism (2) has a malfunction or the like. In order to prevent the discharge pipe (4) and the air ejection mechanism (5) from being damaged by snow or the like, the discharge pipe (4) is mounted in the discharge pipe storage mechanism (32) as shown in FIG. It is provided firmly with a band (33) or the like.
Alternatively, it is also a good idea to install it in a solar system frame or pier and install it as an integrated unit.

  Overall, a better effect can be expected by appropriately combining each of the above depending on the shape of the exterior material (23) and other situations.

The present invention has the structure as described above. When this is used, as shown in FIG. 1, the blower mechanism (2) is turned on to start the blower (10), and the air tank (11) is turned on. Pre-fill with a sufficient amount of air.
When the snowfall starts, the air supply handle (14) is opened and air supply from the air tank (11) to the guide pipe (3) is started.
At this time, the air blowing mechanism (2) is in operation, and the air tank (11) is always additionally filled with air.

As described above, the compressed air sent from the air tank (11) to the discharge pipe (4) through the induction pipe (3), as shown in FIG. 12, is an air ejection mechanism (5) provided in the discharge pipe (4). ) And begins to be ejected radially and vigorously continuously.
Then, as shown in FIG. 6, snow that has fallen is blown off so as to be sequentially sent in an arbitrary specific direction before snowfalling to prevent snow accumulation.

  As described above, according to the present invention, as shown in FIG. 6, arbitrary air is continuously ejected from the air ejection mechanism (5) of the discharge pipe (4) to the entire target surface. As the snow blown from the part by the air jetting mechanism (5) is blown further forward by the air jetting mechanism (5) at the next front, the roof surface is sequentially blown in an arbitrary direction before the snowfall arrives. This is a snow avoidance device (1) characterized in that it can prevent snow accumulation on any target surface with a mechanism to prevent snow accumulation on the surface.

Embodiment 2 of the present invention will be described below.
The present invention includes an air blowing mechanism (2) having the same material and function as those of the first embodiment, a guide pipe (3), a discharge pipe (4), and an air provided with a direction adjusting means for adjusting the direction in an arbitrary direction. And a jetting mechanism (5).

  The direction adjusting means for adjusting the direction in the arbitrary direction can be achieved by making the nozzle (7) a rotary nozzle (34) as shown in FIG.

  The rotary nozzle (34) includes a rotary nozzle substrate (35) and a rotary nozzle (36).

  The rotating nozzle substrate (35) is in the shape of a pipe, and the upper part is a rotating shaft so that the rotating nozzle (36) can rotate smoothly, and has an air exhaust port (37) even when rotating. An appropriate number of packing materials (13) such as O-rings are provided at arbitrary positions so as not to cause air leakage.

  Then, the rotating nozzle substrate (35) is screwed to the nozzle mounting end (21) of the discharge pipe (4) or the nozzle socket (22), and the rotating nozzle ( 36) is inserted, and the nut cap (38) is fixed with the packing (13).

  The rotary nozzle (36) includes a rotary bearing (39), a nozzle body (19), an air injection port (20), and a wind receiving blade (40).

  The rotary bearing (39) has a sleeve shape with an emphasis on the size and rotation suitable for the rotary shaft of the rotary nozzle substrate (35), and smoothly feeds air from the air exhaust port (37) to the rotary nozzle (36). A concave portion and an air intake port (41) are provided to lead to the rotary nozzle substrate (35), and the rotary nozzle substrate (35) is positioned at the air exhaust port (37) at a position perpendicular to the rotary nozzle substrate (35). (36) is connected.

  Further, the rotating nozzle (36) is provided with wind direction detecting means, and as shown in FIG. 19, the nozzle body (19) is configured so that the rotating nozzle (36) freely rotates toward the leeward by wind force. The wind receiving blades (40) are provided in the wing, and the spraying direction is arbitrarily changed according to the wind direction, so that the snowfall is always blown away in the leeward direction.

  The wind vane blade (40) is made of the same material as the nozzle main body (19), and has a thin wing shape, and is integrally provided at an arbitrary position of the rotating nozzle main body (19). The nozzle body (19) is freely rotated to the leeward side in accordance with the changing wind direction, the air sprayed radially from the air outlet (20) is directed to the leeward direction at any time, and snowfall is guided to the leeward direction and eliminated. It is provided for the purpose.

  In addition, the rotary nozzle (34) includes an air injection direction that can be arbitrarily changed manually or by computer control, and can freely change the injection angle according to the wind direction. It is also possible to do so.

Embodiment 3 of the present invention will be described below.
The present invention is made of the same material as that of the first embodiment of the present invention, and includes a blower mechanism (2), a guide pipe (3), a discharge pipe (4), and the air ejection mechanisms of the first and second embodiments. (5) and a spatial structure (42).

  The space structure (42) is lightweight, easily damaged, or is not easily deteriorated even if installed outside for a long period of time, and is made of a material having sufficient strength that is difficult to be deformed or collapsed by strong winds or the environment. When the exhaust pipe (4) is difficult to install directly on the roof body of a building or the like because it has a solid structure such as welded joint or bolt joint and is formed in an arbitrary shape, the direct exhaust pipe (4 ), It is more efficient to install an imaginary space structure (42) that covers the entire upper part, and the space structure (42) is constructed and the space structure (42) is There is also a method of installing a discharge pipe (4).

  As shown in FIG. 20, since a flat roof such as a roof of a building has no roof slope, the efficiency of guiding snowfall from the top to the bottom is lower than that of a roof with a normal slope. When it is more effective to provide an imaginary roof structure, it is preferable to provide a space snow avoidance device (43) by providing the space structure (42) as described above.

  In addition, as shown in FIG. 21, when the structure, strength, and the like of the structure are inappropriate for installing the guide pipe (3) and the discharge pipe (4) directly on the structure, the same spatial structure ( 42), which is most effective for a greenhouse.

Furthermore, the space structure (42) can also be used as the discharge pipe (4).
When the space structure (42) is also used as the discharge pipe (4), the base material of the space structure (42) is pipe-shaped and has sufficient strength, and there is no structural problem. When it is determined that the construction method is suitable, the space structure (42) may also be used as a discharge pipe (4) to form a discharge pipe / space snow avoidance device (44).
In particular, it is most suitable for the space structure (42) with many deformations.

  As shown in FIG. 22, the space structure with many deformations is a space for avoiding snow that serves as both a discharge pipe (4) and a space structure (42) on a cliff or steep slope where avalanches are likely to occur. The device (44) may be installed promptly according to the terrain.

  If the above-mentioned discharge pipe combined use space snow avoidance device (44) is provided above the road or railway, it is also effective in preventing snow damage.

  Further, even if the space structure (42) is not used, the discharge pipe (4) is directly connected to the bridge as shown in FIG. 23 or the top of a work such as a traffic light as shown in FIG. ) Is also a good plan.

  As shown in FIG. 26, it is possible to prevent snow accumulation on the route by installing the discharge pipe (4) directly between the rails of the track.

  As a method of installing the discharge pipe (4) directly between the rails of the track, the discharge pipe (4) is arranged so as to eliminate snowfall outside the track, and the T-type discharge pipe as shown in FIG. The mounting hardware (28) is firmly installed, and the discharge pipe (4) is installed at the upper portion thereof by the discharge pipe receiving material (29).

  As shown in FIG. 28, when used for a roof of a garage or the like, collapse due to the weight of snow can be prevented.

  As shown in FIG. 29, it is also a proposal to connect and install the discharge pipe (4) in an arbitrary frame and spread it on the target surface to form a unit-type snow avoiding device (45). .

  The unit-type snow avoiding device (45) has a discharge pipe (4) continuously arranged at a constant and appropriate interval in a frame, and both ends of the discharge pipe (4) are connected to two sides of the frame. As a set of units, the unit is firmly and continuously connected and installed on an exterior material (23) such as a roof with the mounting hardware (25) over an arbitrary target surface.

The frame may also serve as the guide pipe (3) and the discharge pipe (4).
As shown in FIG. 30, a centralized management center (46) is provided by providing a centralized management facility equipped with a blower mechanism (2) capable of supplying high-pressure air to any specific area as in a power or gas supply system. The central management center (46) is equipped with a large-capacity induction pipe (3) with more air supply facilities than the region desires, and the user (47) is free to use the will of the user (47) when necessary. By opening the air supply handle (14) and providing a public supply system that can use the various snow avoidance devices described above, a safe and fulfilling life can be expected in any specific area. It is also possible to realize public works for the future and contribute to society.

1 is a perspective view of Example 1. FIG. 1 is a longitudinal sectional view of Example 1. FIG. 2 is a perspective view of Example 1. FIG. 1 is a cross-sectional view of Example 1. FIG. 1 is an elevational view of Example 1. FIG. 1 is a longitudinal sectional view of Example 1. FIG. 1 is a cross-sectional view of Example 1. FIG. 1 is an exploded perspective view of Example 1. FIG. 1 is a cross-sectional view of Example 1. FIG. 1 is an exploded perspective view of Example 1. FIG. 1 is an exploded perspective view of Example 1. FIG. 1 is a plan view of Example 1. FIG. 1 is a cross-sectional view of Example 1. FIG. 1 is an exploded perspective view of Example 1. FIG. 1 is a cross-sectional view of Example 1. FIG. 1 is a cross-sectional view of Example 1. FIG. 1 is an exploded perspective view of Example 1. FIG. 6 is a cross-sectional view of Example 2. FIG. 6 is a perspective view of Example 2. FIG. 6 is a longitudinal sectional view of Example 2. FIG. 6 is a longitudinal sectional view of Example 3. FIG. 6 is a longitudinal sectional view of Example 3. FIG. 6 is a longitudinal sectional view of Example 3. FIG. 6 is a side view of Example 3. FIG. 6 is a plan view of Example 3. FIG. 6 is a longitudinal sectional view of Example 3. FIG. 6 is a plan view of Example 3. FIG. 6 is a cross-sectional view of Example 3. FIG. 6 is a plan view of Example 3. FIG. 10 is a system diagram of Embodiment 3. FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Snow avoidance apparatus 2 Blower mechanism 3 Induction tube 4 Exhaust tube
5 Air ejection mechanism 6 Switch mechanism
7 Nozzles
8 Slit
9 holes
10 Blower
11 Air tank 12 Joint mechanism
13 Packing 14 Air supply handle
15 Drainage device
16 Drain cock
17 Water storage pocket 18 Connection pipe 19 Nozzle body
20 Air outlet
21 Nozzle mounting end
22 Nozzle socket 23 Exterior material 24 Mounting base material 25 Mounting hardware 26 Mounting base metal
27 Presser foot 28 T-shaped mounting bracket 29 Discharge pipe receiving bracket 30 Crosspiece mounting bracket 31 Vertical beam 32 with air ejection mechanism Injection device storage mechanism
33 Mounting band
34 Rotating nozzle
35 Rotating nozzle base material
36 Rotating nozzle 37 Air exhaust port
38 Nut cap
39 Rotating bearing
40 Wind vane
41 Air inlet
42 Spatial structure
43 Space snow avoidance device
44 Exhaust pipe combined space snow avoidance device
45 Unit type snow avoidance device
46 Central Management Center 47 Users

Claims (8)

A blower mechanism, a guide pipe connected to the blower mechanism, a plurality of discharge pipes branched from the guide pipe, and an air jet mechanism provided in the discharge pipe, the discharge pipe and the air jet mechanism Is a snow avoidance device which is arranged and formed in a direction to exclude snow and dust in an arbitrary specific direction.
2. The snow avoidance device according to claim 1, wherein the air jetting mechanism is provided with direction adjusting means for adjusting the direction in an arbitrary direction.
The snow avoidance device according to claim 1 or 2, wherein the direction adjusting means includes a wind direction detecting means and adjusts the direction in conjunction with the detecting means.
The snow avoidance device according to claim 1, 2 or 3, wherein a roof exterior material having an arbitrary shape and an air ejection mechanism are combined and integrated.
5. The snow avoidance device according to claim 1, further comprising a spatial structure having an arbitrary shape, and an air ejection mechanism provided in the spatial structure.
6. The snow avoidance apparatus according to claim 1, wherein the space structure having an arbitrary shape is also used as an air ejection mechanism.
The snow avoidance device according to claim 1, 2, 3, 4, 5 or 6, wherein the frame structure having an arbitrary shape is also used as an air ejection mechanism.
  It is equipped with a blower mechanism that can supply the required amount of air to any area, and a facility that manages the blower mechanism and a guide pipe connected to the facility are provided to any area to supply public air to users. The snow avoidance device according to claim 1, 2, 3, 4, 5, 6, or 7, wherein the system is a system.

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