JP2014201937A - Snow-melting system, and snow melting method employing the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a new snow-melting system of which snow melting efficiency is devised and which can uniformly melt snow while suppressing running cost, and a new snow melting method employing the same.SOLUTION: A snow melting system comprises: a main snow melting part 10 in which electric heating elements are arranged; and a sub-snow melting part 20. The main snow melting part 10 is divided into a plurality of main snow melting blocks 11, 12, 13 to form them, and the sub-snow melting part 20 has one or plural knit-in areas 21 arranged between the main snow melting blocks 11, 12, 13, or in the main snow melting blocks 11, 12, 13, or between and in the main snow melting blocks 11, 12, 13. The main snow melting blocks 11, 12, 13 and the sub-snow melting part 20 are individually operated and controlled to melt snow.

Description

        The present invention relates to a system for melting and extinguishing snow accumulated on asphalt pavement surfaces and concrete pavement surfaces such as roads and parking lots, and a snow melting method using the same, and particularly under the pavement surface. A system that can achieve effective snow melting by increasing the thermal efficiency of the heating elements to be installed, and of course the fields related to construction and use to realize an efficient snow melting method thereby, as well as those systems and their use Materials necessary for construction, management and use of snow-melting methods, equipment, etc., and materials required for those materials, machinery and parts, such as wood, stone, various fibers, plastic , To move the equipment and instruments to the field of providing various metal materials, the electronic components incorporated in them, the field of control related equipment integrating them, and the field of various measuring instruments. Fields generally referred to as industrial machinery, such as the field of machinery, the electric power that is the energy and the energy and energy sources that are energy sources, and the field of oil, as well as testing and researching those facilities and instruments, Fields related to display, sales, import / export, generals, fields related to the collection, transportation, etc. of garbage waste generated as a result of their use and the equipment and equipment used to build them. There is no technical field that is not related to the new field that cannot be envisaged at present, such as the recycling field that efficiently recycles garbage.

(Points of interest)
One of the systems for removing snow on pavement surfaces such as roads and parking lots, etc. Snow melting using the road heating method, in which a heating element is buried near the pavement surface, and it is melted by supplying power and heating it. There is a system. Such an electric snow melting system is simple and has a feature that its long-term cost is low compared to other systems. However, even in an electric snow melting system, considering the long-term running cost, it is desired to further reduce the cost without reducing the snow melting capacity.

(Conventional technology)
For example, the most standard method used in the past is to embed a heating element in the entire snow melting portion and energize the entire snow melting. According to this method, although there is a merit that the snow melting time is short, there is a demerit that the running cost is high.
In addition, there is a priority / non-priority method in which the snow melting part is divided into a priority part and a non-priority part, mainly the snow melting of the priority part, and the non-priority part melts snow only when the priority part is stopped, Although this method has the advantage that running costs can be reduced, it is not efficient and not only lengthens the snow melting time, but also because the priority part is the center, there is a problem that it is easy to leave snow in the non-priority part. Remain.

Further, there is an alternate operation method in which the snow melting part is divided into two and alternate operation is performed at regular intervals. According to this method, there is a merit that the basic charge of electric power is halved, but there is a demerit that the snow melting time is doubled.
In addition, there is a sequential stop method in which the snow melting part is divided into four parts, one block is stopped at regular intervals, and only three blocks are operated. In this method, the running cost is low, and priority / non-priority. Although there is an advantage that the snow melting time can be shortened compared to the method and the alternating operation method, since it is divided into a wide range of blocks, it makes it easier to cause large unevenness in snow melting and compared to the standard method The snow melting time becomes long.

In this way, any method that has been adopted so far will cause the problem of reducing the essential snow melting effect if the running cost is to be suppressed. The realization of a new snow melting system that can be widely spread while keeping running costs as low as possible without impeding the snow melting effect has spread over the entire snowfall area including here in Aomori. It was an urgent issue.
Japanese Patent No. 3273147

(Awareness of problems)
Patent Document 1 has first, second, and third heating elements, and selects any one of the first to third heating elements and the remaining two combinations to make the remaining Are connected in series, and a snow melting system is described in which one heating element selected at a predetermined time interval is sequentially changed. The first, second, and third heating elements are substantially mutually connected. Although it has the same installation area and realizes uniform snow melting throughout the installation area, the running cost can be kept low, but the heat generation is low, so the main range is more effective It is difficult to melt snow in a short time, and for many years, we have been involved in the installation of snow melting systems and have continued to develop and provide snow melting equipment that responds to various market needs. Shorter time based on knowledge and information from users On the efficient snow melting possible heating, the running cost can be greatly reduced, its also excelled in effectiveness and economy, it has been led to realize the importance of new snow melting technology development.

(Object of invention)
Therefore, the present invention can quickly melt snow in a short period of time, can greatly reduce running costs, and can quickly develop new snow melting technology that is more economical. As a result of starting development and research and repeating trial and error over many years and many trial productions and experiments, this time, we finally succeeded in realizing a snow melting system and a snow melting method with a new structure. In the following, the configuration will be described in detail together with an embodiment representative of the present invention shown in the drawings.

(Structure of the invention)
As clearly understood from the embodiments representing the present invention shown in the drawings, the snow melting system of the present invention basically has the following configuration.
That is, the snow melting system of the present invention comprises a main snow melting part and a semi-snow melting part each provided with a heating element, and a control unit for controlling the operation of the main snow melting part and the semi-snow melting part. The quasi-snow melting portion is divided between the main snow melting blocks, in the main snow melting blocks, or in addition to the main snow melting blocks. It is assumed that it has one or a plurality of braided regions arranged either in or between, and the area of each braided region is regulated to be smaller than the area of each main snow melting block. In the snow melting system, the main snow melting block and the semi-snow melting unit are individually and automatically operated and controlled by the control unit.

(Related invention 1)
In relation to the above-described snow melting system that forms the basis of the present invention, the present invention also includes a snow melting method that employs it.
That is, a main snow melting part and a semi-snow melting part each formed with a heating element are formed, and the main snow melting part is divided and formed into a plurality of blocks having substantially the same capacity. Constructed to have one or more braided regions disposed either between or within each of the main snow melting blocks, or both between and within each of the main snow melting blocks In addition, the area of the quasi-snow melting portion knitting area is formed to be smaller than the area of each main snow melting block, and each main snow melting block and the quasi-snow melting portion are individually controlled and operated individually to operate the snow melting. The present invention is a snow melting method employing the snow melting system of the present invention having the configuration as described above.

    According to the snow melting system of the present invention and the snow melting method employing the snow melting system, the main snow melting part is either between the main snow melting blocks, or among them, or both, and both. The quasi-snow melting area is smaller than each main snow-melting block, and the quasi-snow-melting area is knitted into the main snow-melting area because each main snow-melting block and quasi-snow melting area are controlled. As a result, the snow melting area can be secured over a wide area and the semi-snow melting part can be arranged over a wide range, and the main snow melting block and the semi-snow melting part, only the main snow melting block, only the semi-snow melting part according to the degree of snowfall. In addition to being able to achieve snow melting while automatically controlling the three stages of operation, the temperature of the roadbed in the warmed and warmed-up stage has cooled down even after the desired snow melting has been achieved. Open air To avoid assimilation every time, it is possible to keep economic operation in which the semi-snow melting part is automatically controlled in order to keep it in a reasonable temperature range and keep the minimum snow melting function. Then, when it comes down to the main snowfall, when it is reheated to the required snow melting function, the temperature rises from the maintenance temperature, and it is efficient without taking time to warm up to the temperature required for the main snowfall. Therefore, it is possible to demonstrate an economical snow melting function, and to achieve an even and economical snow melting even in a wide range. When introduced as a snow melting system in places such as parking lots, sidewalks, and roadways in public facilities, a great effect that cannot be expected from conventional snow melting systems can be obtained.

    As for the operation procedure, one of the main snow melting blocks and the quasi-snow melting part is stopped in order, and the other operation is performed, and after the snow melting of any block is completed, the remaining A higher effect can be obtained by driving the blocks.

In implementing the present invention having the configuration as described above, the best or desirable mode will be described.
The control unit controls the main snow melting part and the semi-snow melting part individually and in an integrated manner, and has a function to enable efficient snow melting while suppressing energy consumption. Any one of them can be stopped in order, and a sequential stop control means for controlling to operate the other can be provided.

    The main snow melting part shares the function of heating the main area other than the area where the semi-snow melting part is arranged so that the snow can be melted, and should be arranged in a larger area than the semi-snow melting part. At the same time, it should be divided into a plurality of main snow melting blocks. The main snow melting blocks have a function of forming a main snow melting portion by combining the plurality of main snow melting blocks, and are arranged in parallel at equal intervals. A heating element is used.

    The quasi-snow melting part shares the function of heating the range other than the main range where the main snow melting part is arranged to enable snow melting, and must be arranged in a smaller area than the main snow melting part, It is arranged between each main snow melting block, in each main snow melting block, or between and inside each main snow melting block to form one or a plurality of braided regions, and is arranged in parallel at equal intervals. A plurality of heating elements.

  Between each main snowmelt block of the main snowmelt section, or between them, and / or both between them, a quasi-snow melt knitting area having a smaller area than each main snowmelt block is provided. One block of the main snow melting portion and the semi-snow melting portion are each composed of one to a plurality of snow melting circuits, each circuit uses one heating element, and the semi-snow melting portion is one block of the main snow melting portion. The heating capacity of the quasi-snow melting part and the heating element of the main snow melting part are knitted in parallel at equal intervals so as to form an interdigital shape.

In the snow melting method of the present invention, each main snow melting block and the quasi-snow melting unit are individually operated to reduce energy consumption and enable more efficient snow melting. Any one of the snow melting portions is stopped in order, and the others are operated to control the snow melting.
In the following, the structure of the present invention will be described in detail together with an embodiment representative of the present invention shown in the drawings.

The drawings show some typical embodiments embodying the technical idea of the snow melting system and the snow melting method of the present invention.
It is a block diagram showing the structure of the snow melting system which concerns on one embodiment of this invention. It is a figure showing the example of arrangement | positioning of the main snow melting part shown in FIG. 1, and a semi-snow melting part. It is a flowchart showing operation | movement of the snow melting system shown in FIG. It is a flowchart showing operation | movement of the snow melting system shown in Table 1.

FIG. 1 is a block diagram showing the configuration of the snow melting system 1 according to this embodiment, and FIG. 2 shows an arrangement example of the main snow melting portion 10 and the semi-snow melting portion 20 shown in FIG.
In FIG. 2, in order to easily distinguish the main snow melting part 10 and the semi-snow melting part 20, the arrangement of the heating elements of the main snow melting part 10 is represented by a thick line, and the arrangement of the heating elements of the semi-snow melting part 20 is represented by a thin line. Represents.

    The snow melting system 1 includes, for example, a main snow melting part 10 and a semi-snow melting part 20 formed by arranging heating elements, and a control unit 30 that controls the operation of the main snow melting part 10 and the semi-snow melting part 20. The main snow melting part 10 and the quasi-snow melting part 20 embed and form a heating element at a predetermined position near the surface of a pavement structure such as a road or a parking lot where snow melting is necessary, The main snow melting portion 10 is divided and formed into a plurality of blocks. In this embodiment, the main snow melting portion 10 is divided into three main snow melting blocks 11, 12 and 13. The semi-snow melting portion 20 is located between the main snow melting blocks 11, 12, 13 or between the main snow melting blocks 11, 12, 13 or between and inside the main snow melting blocks 11, 12, 13 as well. The main snow melting part 10 and the semi-snow melting part 20 are respectively connected to the control part 30 for controlling the control part 30. Based on driving.

Each of the main snow melting blocks 11, 12, 13 has a heating element arranged in parallel at equal intervals and arranged in a comb shape with a predetermined width.
The semi-snow melting portion 20 is composed of heating elements arranged in parallel at equal intervals, and is arranged between and inside each main snow melting block 11, 12, 13 to form a knitted region 21. Yes. In the main snow melting portion 10, the area of each braided region 21 is configured to be smaller than the area of the main snow melting blocks 11, 12, 13.

    FIG. 2 shows an example in which the braided region 21 is formed between the main snow melting blocks 11, 12 and 13, and both of them, but only between the main snow melting blocks 11, 12 and 13, Or you may make it form only in each main snowmelt block 11,12,13. Further, in FIG. 2, the number of the interdigital heater elements in each of the main snow melting blocks 11, 12, and 13 and the number in the quasi-snow melting portion knitting region 21 are specifically shown, but these numbers are limited. is not.

    Each main snow melting block 11, 12, 13 and the semi-snow melting part 20 are wired with respect to a power supply so that it can each drive | operate separately. In addition, it is desirable that each main snow melting block 11, 12, 13 and the semi-snow melting unit 20 incorporate, for example, sensors such as a snow melting sensor that can detect moisture, ground temperature, outside temperature, and the like. Convenience can be enhanced by enabling automatic control of the operation of each of the main snow melting blocks 11, 12, 13 and the semi-snow melting unit 20 according to the snowfall situation.

The control part 30 is comprised so that each main snow melting block 11, 12, 13 and the semi-snow melting part 20 can be drive-controlled separately.
For example, when snow is detected by the snow melting sensor, each block can be driven, and they can be driven automatically. Since the braided region 21 of the semi-snow melting portion 20 is disposed between and within each of the main snow melting blocks 11, 12, 13, the heat retaining effect extends to the periphery even if some of them automatically stop. Therefore, a high snow melting effect can be obtained, and as a whole, the running cost is reduced.

For example, as a means for automatically controlling the operation, the control unit 30 stops any one of the main snow melting blocks 11, 12, 13 and the semi-snow melting unit 20 in order, and operates the others. In this way, sequential stop control means 31 is controlled.
Table 1 below shows an operation table by the sequential stop control means 31.

    As shown in Table 1, the sequential stop control means 31 is, for example, a procedure as illustrated in FIGS. 3 and 4, that is, a first stop procedure for stopping the semi-snow melting part 20 and operating the other, The second stop procedure for stopping the main snow melting block 11 and operating the other, the third stop procedure for stopping the semi-snow melting unit 20 and operating the other, and the fourth stop for stopping the main snow melting block 12 and operating the other The procedure, the fifth stop procedure for stopping the semi-snow melting unit 20 and operating the other, and the sixth stop procedure for stopping the main snow melting block 13 and operating the other are repeated in this order. Yes.

The lengths of the first stop procedure, the second stop procedure, the third stop procedure, the fourth stop procedure, the fifth stop procedure, and the sixth stop procedure can be arbitrarily set according to the snow melting condition, whether they are the same or different. can do.
With this configuration, while any of the main snow melting blocks 11, 12, 13 is stopped, the quasi-snow melting part 20 inserted and formed in the meantime is operated, and the quasi-snow melting part 20 is operated. Since the main snow melting blocks 11, 12, and 13 are operated while the engine is stopped, a high snow melting effect can be obtained while lowering the running cost.

    As described above, in the above-described embodiment, the main snow melting blocks 11, 12, 13 are arranged between the main snow melting blocks 11, 12, 13 of the main snow melting section 10, or in the middle thereof, or both in between. Since the braided region 21 of the semi-snow melting part 20 having a smaller area is formed and the main snow melting blocks 11, 12, 13 and the semi-snow melting part 20 are individually controlled for operation, the main snow melting part 10 The snow melting area can be ensured in a wide range, and the semi-snow melting portion 20 can be arranged uniformly in a wide range, and any of the main snow melting blocks 11, 12, 13 and the semi-snow melting portion 20 can be provided. Even if it is temporarily stopped, the heat insulation state of each part of the pavement will continue to be maintained, and it will be possible to obtain a snow melting effect that can melt snow uniformly and indefinitely. So that the lead to be reduced.

(Conclusion)
As described above, the snow melting system of the present invention and the snow melting method using the snow melting system make it possible to achieve the intended purpose uniformly by the new configuration. In the conventional method, the running cost and the snow melting effect are linked. However, trying to reduce the running cost could not eliminate the problem of lowering the essential snow melting effect, but the snow melting function efficiently with shorter heating while greatly reducing the running cost It is possible to realize a snow melting function that could not be achieved with conventional technology in terms of its effectiveness and economy, and to achieve economical snow melting evenly over a wide range Therefore, it can be used not only as a snow melting system for the general public, but particularly as a snow melting system in places such as parking lots, sidewalks, and roadways in public facilities. Recognized as a snow melting system and a snow melting method that adopts it, the construction industry that has been tackling as a long-standing issue is more secure, and the general residents and companies in cold regions that have suffered from winter snow damage countermeasures First, it will be highly valued by local governments that have been forced to spend a lot of money on residents' services during the winter season, and is expected to be widely used and spread.

1 Snow melting system
10 Main snow melting part
11 Main snow melting block
12 Main snow melting block
13 Main snow melting block
14 Interdigital main snow melting heating element
20 Semi-snow melting part
21 Weaving area
22 Interdigital snowmelt heating element
30 Control unit
31 Sequential stop control means

Claims (5)

    A main snow melting part and a semi-snow melting part each provided with a heating element, and a control part for controlling the operation of the main snow melting part and the semi-snow melting part, and the main snow melting part is divided and arranged into a plurality of main snow melting blocks. And the semi-snow melting section is arranged either between each main snow-melting block, inside each main snow-melting block, or both between and inside each main snow-melting block. The quasi-snow melting part knitting area is formed so that the area of the quasi-snow melting part knitting area is smaller than the area of each main snow-melting block. The snow melting system is characterized in that it is operated and controlled individually and automatically by the control unit.     The control unit includes a sequential stop control unit configured to stop any one of the main snow melting blocks and the semi-snow melting unit in order and control the other ones to operate. The snow melting system described.     Between each main snowmelt block of the main snowmelt section, or between them, and / or both between them, a quasi-snow melt knitting area having a smaller area than each main snowmelt block is provided. One block of the main snow melting portion and the semi-snow melting portion are each composed of one to a plurality of snow melting circuits, each circuit uses one heating element, and the semi-snow melting portion is almost the same as one block of the main snow melting portion. 3. The snow melting system according to claim 1, wherein the heat melting elements of the semi-snow melting part and the heating elements of the main snow melting part are knitted in parallel at equal intervals so as to be formed in a comb shape.     A main snow melting portion and a semi-snow melting portion each having a heating element are formed, and the main snow melting portion is divided and formed into a plurality of main snow melting blocks. Or have one or more braided regions disposed either in or between each of the main snowmelt blocks, or both between and in each of the main snowmelt blocks, The area of the knitting area of the snow melting portion is regulated to be smaller than the area of each main snow melting block, and each main snow melting block and the semi-snow melting portion are individually controlled automatically and operated to melt snow. A snow melting method employing the snow melting system according to any one of claims 1 to 3. The snow melting method according to claim 4, wherein one of the main snow melting blocks and the semi-snow melting portion is stopped in order and the other snow is operated to melt the snow.

Images