CN113280546A - Snow making module system - Google Patents

Abstract

The invention relates to the technical field of artificial snow making, in particular to a snow making module system; the snow making module system includes: the water treatment module is used for filtering and/or cooling water for making snow; the conveying module is connected with the water treatment module and is used for conveying the water for making snow which is treated by the water treatment module; the snow making module is connected with the conveying module and used for cooling and crystallizing the snow making water conveyed by the conveying module. The snow-making module system of the present invention has good adaptability and is favorable to raising building efficiency.

Description

Snow making module system

Technical Field

The invention relates to the technical field of artificial snow making, in particular to a snow making module system.

Background

Snow making modular systems are important devices for various types of ski fields.

The snow-making module system provided by the related art is poor in adaptability when being built in different project places, and the building efficiency is not convenient to improve.

Disclosure of Invention

The invention aims to provide a snow-making module system which has good adaptability and is beneficial to improving the building efficiency.

The embodiment of the invention is realized by the following steps:

the present invention provides a snow making module system comprising:

the water treatment module is used for filtering and/or cooling the snow making water;

the conveying module is connected with the water treatment module and is used for conveying the water for making snow, which is treated by the water treatment module;

and the snow making module is connected with the conveying module and used for cooling and crystallizing the snow making water conveyed by the conveying module.

In an alternative embodiment, the water treatment module includes at least one of a water filtration mechanism, a water cooling mechanism, and a water color and odor removal mechanism.

In an optional embodiment, the water treatment module comprises a water filtering mechanism, a water color and odor removing mechanism and a water cooling mechanism which are sequentially connected, and the water cooling mechanism is connected with the conveying module.

In an optional embodiment, the conveying module comprises a water pump mechanism and a water conveying pipeline, the water conveying pipeline is connected between the water pump mechanism and the snow making module, and the water pump mechanism is connected with the water treatment module and is used for conveying the snow making water treated by the water treatment module to the snow making module through the water conveying pipeline.

In an optional embodiment, the water pump mechanism comprises a water pump and a water collecting and distributing device connected with the water pump, and the water collecting and distributing device is further connected with a water conveying pipeline.

In an alternative embodiment, the water line comprises a main water pipe and an outlet pipe, the main water pipe is connected between the water pump mechanism and the outlet pipe, and the outlet pipe is connected with the snow making module.

In an alternative embodiment, the water pipeline further comprises a branch pipe, and the main water pipe and the outlet water pipe are connected through the branch pipe.

In an optional embodiment, the water pipeline further comprises a corner component, the main water pipe and the branch pipes are connected through the corner component, and the corner component is used for enabling the water conveying direction of the main water pipe and the water conveying direction of the branch pipes to form an included angle.

In an optional embodiment, the water pipeline further comprises a reducing pipeline, the main water pipe and the branch pipes are connected through the reducing pipeline, and the reducing pipeline is used for adjusting the flow of the snow making water.

In an optional embodiment, the snow making module system further comprises a control module, the water treatment module, the conveying module and the snow making module are all in communication connection with the control module, and the control module can receive feedback signals of the water treatment module, the conveying module and the snow making module.

The snow making module system of the embodiment of the invention has the beneficial effects that: the snow making module system provided by the embodiment of the invention comprises a water treatment module, a conveying module and a snow making module, wherein the water treatment module is used for filtering and/or cooling water for making snow; the conveying module is connected with the water treatment module and is used for conveying the water for making snow which is treated by the water treatment module; the snow making module is connected with the conveying module and used for cooling and crystallizing the snow making water conveyed by the conveying module. In this way, the water treatment module, the conveying module and the snow making module are respectively arranged in a modularized manner, so that the adaptability of snow making module systems established in different project places can be improved, and the establishing efficiency can be improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

FIG. 1 is a first block diagram of a snow making module system according to an embodiment of the present invention;

FIG. 2 is a block diagram of a second embodiment of the snow making module system of the present invention;

FIG. 3 is a schematic structural view of a snow making module system in an embodiment of the present invention;

FIG. 4 is a first schematic structural diagram of a corner assembly according to an embodiment of the present invention;

FIG. 5 is a second schematic structural diagram of a corner assembly according to an embodiment of the present invention;

FIG. 6 is a schematic structural diagram of a T-pipe according to an embodiment of the present invention;

FIG. 7 is a schematic structural diagram of a reducer pipe according to an embodiment of the present invention;

FIG. 8 is a schematic structural diagram of a water outlet pipe according to an embodiment of the present invention;

FIG. 9 is a schematic structural view of a mounting block in an embodiment of the invention;

fig. 10 is a schematic structural view of another snow making module system in accordance with an embodiment of the present invention.

Icon: 010-snow making module system; 100-a water treatment module; 110-a water filtration mechanism; 120-a water cooling mechanism; 130-a water color and odor removing mechanism; 200-a delivery module; 210-a water pump mechanism; 220-water conveying pipeline; 221-a corner assembly; 222-a variable diameter pipe; 223-a first tube; 224-a second tube; 225-a third tube; 226-water outlet pipe; 227-a fourth tube; 228-a fifth tube; 229-a sixth tube; 230-a valve; 231-T-shaped pipe; 232-seventh tube; 233-eighth tube; 240-fixed pier; 241-concrete pier; 242-a tube gripping assembly; 243-pipe support; 300-a snow making module; 400-a control module; 410-a mobile control module; 500-water getting module.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

In the description of the present invention, it should be noted that the terms "vertical", "horizontal", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings or orientations or positional relationships that the products of the present invention are conventionally placed in use, which are merely for convenience of describing the present invention and simplifying the description, but do not indicate or imply that the devices or elements to be referred must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like are used merely to distinguish one description from another, and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed" and "connected" are to be interpreted broadly, e.g., as being either fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Referring to fig. 1, the present embodiment provides a snow making module system 010, which can be used in a ski field for making artificial snow.

The snow making module system 010 comprises a water treatment module 100, a conveying module 200 and a snow making module 300, wherein the water treatment module 100 is used for filtering and/or cooling water for making snow; the conveying module 200 is connected with the water treatment module 100 and is used for conveying the water for making snow, which is treated by the water treatment module 100; the snow making module 300 is connected with the conveying module 200 and used for cooling and crystallizing the snow making water conveyed by the conveying module 200. In this way, the modular arrangement of the water treatment module 100, the transport module 200 and the snow making module 300 is beneficial to improving the adaptability of the snow making module system 010 built in different projects, so as to improve the building efficiency.

In the related art, when the snow making module system is established, temporary design and planning of a water pump, a conveying pipeline and the like are needed according to different project places, the snow making module system is poor in adaptability in different project places, and the establishment efficiency is low. The water treatment, the water conveying and the snow making are respectively built in different modularization modes, so that the adaptability and the building efficiency are improved.

It should be noted that the water treatment module 100 of the present embodiment is disposed at a low altitude position, the snow making module 300 is disposed at a high altitude position, and the conveying module 200 is configured to convey the water for making snow at the low altitude position to the snow making module 300 at the high altitude position for making snow, so that the artificial snow prepared by the snow making module 300 can be sprayed from top to bottom, which is beneficial to ensuring the reliability of artificial snow making.

The water treatment module 100 comprises at least one of a water filtering mechanism 110, a water cooling mechanism 120 and a water color and odor removing mechanism 130, and the combination manner can be optimized according to different requirements.

Optionally, the water filtering mechanism 110 may be a filtering net, a filtering cotton, a filtering membrane, and the like, and is not specifically limited herein, the water filtering mechanism 110 is configured to filter impurities such as particles, floating objects, and the like in water to reduce the impurities in the water for making snow, so as to facilitate forming protection for the conveying module 200 and the snow making module 300, and avoiding the conveying module 200 and the snow making module 300 from being blocked and jammed by the impurities; the water filtering unit 110 may also be an RO membrane filtration device for removing harmful bacteria, viruses, etc. from water. The water cooling mechanism 120 may be a water heat exchanger, a refrigerator, or the like, and is not specifically limited herein, and the water cooling mechanism 120 is used to reduce the temperature of water, so as to subsequently more efficiently cool and crystallize the cooled snow making water. The water deodorization and deodorization mechanism 130 may be an activated carbon filter mechanism, etc., and is not limited thereto, and the water deodorization and deodorization mechanism may be used to remove odor, color, etc. in water.

Referring to fig. 1, the water treatment module 100 of the present embodiment includes a water filtering mechanism 110, a water color removing and odor removing mechanism 130, and a water cooling mechanism 120, which are connected in sequence, and the water cooling mechanism 120 is connected to the conveying module 200. So set up, can filter, remove the look, remove flavor and cooling back to the raw water in proper order, carry to the snow making module 300 through transport module 200 again.

It should be noted that, filtering the raw water first can protect the subsequent water color removing and odor removing mechanism 130 and the water cooling mechanism 120, and the problem of blockage and embedding of the water color removing and odor removing mechanism 130 and the water cooling mechanism 120 is solved.

It should be understood that, depending on the quality of the raw water, the water treatment module 100 may only include any one or two of the water filtering mechanism 110, the water cooling mechanism 120 and the water color and odor removing mechanism 130, and is not limited in particular.

In the present embodiment, the raw water for making snow is tap water; referring to fig. 2, in other embodiments, the raw water for making snow may also be river water, and in order to facilitate the water treatment module 100 to treat the river water, the snow making module system 010 further includes a water taking module 500, and the water taking module 500 is configured to deliver the river water to the water treatment module 100; alternatively, the water intake module 500 includes a water pump or the like for delivering water, which is not particularly limited herein.

It should be further noted that the water filtering mechanism 110, the water color removing and odor removing mechanism 130 and the water cooling mechanism 120 of the water treatment module 100 can be arranged in the same container, and the water filtering mechanism 110, the water color removing and odor removing mechanism 130 and the water cooling mechanism 120 which are arranged in the container are sequentially connected, so that the modular arrangement of the water treatment module 100 is ensured, the improvement of the adaptability of the snow making module system 010 in different project places is facilitated, and the establishment efficiency is improved.

Referring to fig. 3, the transportation module 200 of the present embodiment includes a water pump mechanism 210 and a water transportation pipeline 220, the water transportation pipeline 220 is connected between the water pump mechanism 210 and the snow making module 300, and the water pump mechanism 210 is connected to the water treatment module 100 and is configured to transport the snow making water treated by the water treatment module 100 to the snow making module 300 through the water transportation pipeline 220. So set up, can utilize water pump mechanism 210 and hydraulic pipeline 220 to carry the water of making snow that water treatment module 100 handled to make snow module 300 reliably, especially, the water pump can be used to the feedwater pressure boost to make water follow supreme transport from down reliably, and then ensure that the water delivery module can carry the water of making snow that water treatment mechanism handled to the snow module 300 that is located high altitude department, so that the artificial snow that makes snow module 300 and make can be from last spraying to down.

The water pump mechanism 210 can be arranged as required, the water pump mechanism 210 of this embodiment includes a water pump and a water collecting and distributing device connected with the water pump, and the water collecting and distributing device is further connected with the water conveying pipeline 220, that is, the water pump is connected with the water conveying pipeline 220 through the water collecting and distributing device. Further, the water collecting and distributing device is connected to at least two water conveying lines 220, and each water conveying line 220 is connected to one snow making module 300, so that the water collecting and distributing device is used for conveying the water for making snow to at least two different water conveying lines 220, and the water for making snow is respectively provided to at least two snow making modules 300, so that the snow making efficiency is improved, namely, the water collecting and distributing device can be used as a module distribution point of at least two snow making modules 300.

Of course, in other embodiments, the at least two water lines 220 connected to the water collecting and distributing device may be connected to the same snow making module 300, that is, the at least two water lines 220 may be converged downstream and supply the snow making water to the same snow making module 300 together, which is not limited in particular.

In other embodiments, the water collecting and distributing device is connected to at least two water pumps, and the water collecting and distributing device is connected to one water conveying pipeline 220, so that the snow making water conveyed by the at least two water pumps is collected by the water collecting and distributing device and then conveyed to the snow making module 300 through the same water conveying pipeline 220.

It should be understood that in other embodiments, the water pump mechanism 210 does not include a water collecting and distributing device, and the water pump can be directly connected to the water pipeline 220, or the water pump can be connected to the water pipeline 220 through a valve 230, and the like, and is not limited in detail herein.

It should be noted that the water pump of the present embodiment is connected to the water cooling mechanism 120 of the water treatment module 100, so that the filtered, decolored, deodorized and cooled snow making water can be delivered to the snow making module 300 through the water pump and water delivery line 220.

It should be further noted that the arrangement direction of the water pump in the water pump mechanism 210 can be selected according to the needs, for example: the water pump mechanism 210 is provided with only one water pump for connecting the water treatment module 100 and the water delivery pipeline 220; alternatively, the water pump mechanism 210 includes a plurality of water pumps connected in series or in parallel to meet different head requirements.

Alternatively, the water pump mechanism 210 may be assembled within the container to facilitate modular assembly when assembling the snow making module system 010; furthermore, the water pump mechanism 210 may be configured with a variable frequency device to save energy consumption by the variable frequency device.

The water pump may be selected according to needs, and for example, the water pump may be at least one of a horizontal pump, a vertical pump, and a water lift pump, and is not particularly limited herein. Wherein the water lift pump is used for conveying the snow making water and also has a pressurizing effect so as to more reliably convey the snow making water to the snow making module 300.

The water line 220 of this embodiment includes a main pipe and an outlet pipe 226 (shown in fig. 8), the main pipe is connected between the water pump mechanism 210 and the outlet pipe 226, and the outlet pipe 226 is connected to the snow making module 300. Specifically, the end of the main water pipe remote from the outlet pipe 226 is connected to the water collection and diversion device. Of course, in other embodiments where the pump mechanism 210 does not include a water collection and diversion device, the end of the main water line remote from the outlet pipe 226 is connected to a water pump.

Further, the water pipeline 220 further includes branch pipes, and the main water pipe and the water outlet pipe 226 are connected through the branch pipes; so set up, can be through main water pipe, bleeder and outlet pipe 226 more nimble setting hydraulic line 220, when avoiding single water pipe of setting up to carry the water of making snow, need set up very long water pipe, and also avoid a water pipe to carry the water of making snow and be not convenient for adjust the problem of carrying the angle.

Still further, the water pipeline 220 further includes a corner component 221 (as shown in fig. 4), the main water pipe and the branch pipes are connected through the corner component 221, and the corner component 221 is used for enabling the water conveying direction of the main water pipe and the water conveying direction of the branch pipes to form an included angle. So set up, be convenient for make the water change flow direction of making snow through corner subassembly 221, and then be favorable to making the water adaptation different relief corners of making snow, carry to the module 300 of making snow reliably, for example: when the snow making module 300 is arranged 300 meters higher than the water treatment module 100, and the snow making module 300 and the water treatment module 100 are distributed at intervals in the horizontal direction, the conveying module 200 is required to convey the snow making water provided by the water treatment module 100 to the snow making module 300 in an inclined manner, the main water pipe extends in the horizontal direction, the branch pipe extends between one end of the main water pipe, which is far away from the water pump mechanism 210, and the snow making module 300, and the main water pipe and the branch pipe are connected through the corner assembly 221, so that the snow making water conveyed horizontally through the main water pipe changes the flow direction through the corner assembly 221 and flows in the inclined direction through the branch pipe.

Alternatively, referring to fig. 4 and 5, the corner assembly 221 includes at least one bent pipe, and when the main water pipe and the branch pipe are connected by one bent pipe, the flow direction angle of the water flow from the main water pipe to the branch pipe is determined by the angle of the bent pipe, for example: the angle of the elbow is 90 degrees, and the flow direction of the water flow flowing from the main water pipe to the branch pipe is changed by 90 degrees.

It should be noted that, referring to fig. 5, the corner assembly 221 includes at least two curved tubes, which are connected in sequence, wherein the two curved tubes at two ends are respectively connected to the main water tube and the branch tube, so that the flow direction angle of the water flowing from the main water tube to the branch tube is determined by the angles of all curved tubes, for example: two 30 degree elbows are connected to each other, one of which is connected to the main pipe and the other of which is connected to the branch pipe, and the flow direction of the water flowing from the main pipe to the branch pipe is changed by 60 degree.

Optionally, referring to fig. 6, the corner assembly 221 includes a t-shaped pipe 231, the t-shaped pipe includes a seventh pipe 232 and an eighth pipe 233, the eighth pipe 233 is connected to the middle of the seventh pipe 232 and is communicated with the seventh pipe 232, an included angle between the seventh pipe 232 and the eighth pipe 233 is about 90 °, the main water pipe is connected to one end of the seventh pipe 232, and the branch pipe is connected to one end of the eighth pipe 233 far from the seventh pipe 232; in this way, the tee pipe 231 can be used to change the direction of the water flow from the main water pipe to the branch pipe. It should be noted that one end of the seventh pipe 232 is connected to the main water pipe, and the other end thereof may be connected to a return pipe, another main water pipe, another branch pipe, or the like, so that the tee pipe 231 is used to transport the snow making water to other water requiring connection points or the like except for the branch pipe connected to the eighth pipe 233, thereby improving flexibility in connection and assembly of the snow making module system.

The connection mode of the main water pipe and the elbow pipe and the connection mode of the branch pipe and the elbow pipe can be selected according to the requirement, for example, by flange connection, and the like, and are not particularly limited herein.

In other embodiments, the water pipeline 220 may not be provided with the corner assembly 221, and at least one of the main water pipe and the branch pipe may be provided with an elbow pipe, so that the flow direction of the snow making water conveyed by the main water pipe is changed when the snow making water enters the branch pipe.

Referring to fig. 7, the water pipeline 220 of the present embodiment further includes a variable diameter pipeline 222, the main water pipe and the branch pipes are connected by the variable diameter pipeline 222, and the variable diameter pipeline 222 is used for adjusting the flow rate of the snow making water. It should be noted that the reducing pipe 222 may be disposed upstream or downstream of the corner assembly 221, that is, the water pipeline 220 may include a main water pipe, the reducing pipe 222, the corner assembly 221, and a branch pipe, which are connected in sequence, or the water pipeline 220 may include a main water pipe, a corner assembly 221, a reducing pipe 222, and a branch pipe, which are connected in sequence, and is not limited in particular.

Of course, in other embodiments where no corner assembly 221 is provided, the main water line is connected directly to the branch line via a reducer pipe 222.

It should be understood that in other embodiments, the reducing conduit 222 may not be provided, and a flow valve may be provided between the main conduit and the branch conduit for regulating the flow of snow making water from the main conduit to the branch conduit.

Referring to fig. 7, the reducing pipe 222 includes a first pipe 223, a second pipe 224 and a third pipe 225 connected in sequence, wherein the pipe diameter of the first pipe 223 is greater than that of the third pipe 225, and the pipe diameter of the second pipe 224 gradually decreases from one end close to the first pipe 223 to one end close to the third pipe 225. Alternatively, the main water pipe is connected to the first pipe 223 and the branch pipe is connected to the third pipe 225, so that the flow rate of the snow making water flowing from the main water pipe to the branch pipe is reduced through the reducing pipe 222.

Referring to fig. 8, the outlet pipe 226 of the present embodiment includes a fourth pipe 227, a fifth pipe 228, a sixth pipe 229 and a valve 230, the fourth pipe 227 is connected to the branch pipe, a first end of the fifth pipe 228 is connected to the fourth pipe 227, a second end of the fifth pipe 228 is connected to the snow making module 300, the valve 230 is disposed adjacent to the second end of the fifth pipe 228 on the fifth pipe 228, a first end of the sixth pipe 229 is connected to the fifth pipe 228, a first end of the sixth pipe 229 is disposed between the first end of the fifth pipe 228 and the valve 230, a second end of the sixth pipe 229 is connected to the fourth pipe 227, and a second end of the sixth pipe 229 is disposed downstream of the first end of the fourth pipe 227; wherein the fourth pipe 227 is connected to the main water pipe through the branch pipe, and when the valve 230 is opened, only the fourth pipe 227 and the fifth pipe 228 of the snow making water delivered from the main water pipe and the branch pipe flow to the snow making module 300; when the valve 230 is closed, the snow making water entering the fourth pipe 227 enters the fifth pipe 228 and then flows back to the fourth pipe 227 through the sixth pipe 229, so that the snow making water is prevented from staying in the fifth pipe 228, the water in the fifth pipe 228 which stops flowing is prevented from being frozen, and the fifth pipe 228 is prevented from being blocked.

It should be noted that, referring to fig. 9, both the main water pipe and the branch pipes can be fixed in position by the fixing piers 240; optionally, the fixed pier 240 comprises a concrete pier 241 and a pipe clamping assembly 242 arranged on the concrete pier 241, wherein the concrete pier 241 can be arranged on the ground, and the pipe clamping assembly 242 is used for clamping a main water pipe or a branch pipe; so set up, can set up concrete pier 241 and pipeline centre gripping subassembly 242 in advance in the position that needs set up main water pipe and bleeder, and then the setting of the main water pipe of being convenient for and bleeder. Further, the pipe clamping assembly 242 includes two pipe holders 243 detachably connected to each other, and a main water pipe and a branch pipe are disposed between the two pipe holders 243; the two pipe brackets 243 may be detachably connected by a fastener such as a bolt or a screw, and is not particularly limited herein. It should be understood that in other embodiments, the fixed pier 240 can also be provided with the tube gripping assembly 242 using stainless steel brackets or the like, and is not particularly limited herein.

It should also be noted that outlet pipe 226 may also be secured in place with a retaining pier 240 to facilitate assembly of outlet pipe 226.

The snow making module 300 of the present embodiment includes a snow making machine, and the type and model of the snow making machine are not particularly limited herein.

It should be noted that the snow making module system 010 of this embodiment can selectively set different numbers of conveying modules 200 according to the altitude at which the snow making modules 300 are set, and not only can the conveying modules 200 be modularly combined according to the terrain of the project site, but also because the conveying modules 200 are modularly set, when the number of the conveying modules 200 of the snow making module system 010 is greater than or equal to 2, the conveying modules 200 can be efficiently set; for example: referring to fig. 3, when the elevation of the snow making module 300 is 300 m, only one conveying module 200 may be provided, that is, one conveying module 200 processed by the water treatment module 100 conveys water for making snow to the snow making module 300; referring to fig. 10, when the elevation of the snow making module 300 is 600 m, two conveying modules 200 may be provided, wherein one conveying module 200 is used for conveying the water for making snow, which is treated by the water treatment module 100, to the other conveying module 200, and conveying the water for making snow to the snow making module 300 through the latter conveying module 200.

Referring to fig. 10, taking the snow making module system 010 includes two conveying modules 200, and the elevation of the snow making module 300 is 600 m for an example, the two conveying modules 200 are sequentially arranged along the extending direction from the water treatment module 100 to the snow making module 300, the water pump mechanism 210 of the conveying module 200 adjacent to the water treatment module 100 can be arranged at the same horizontal position as the water treatment module 100, the water pump mechanism 210 of the conveying module 200 adjacent to the snow making module 300 is arranged between the water treatment module 100 and the snow making module 300, and the elevation is 300 m, so that the water pump mechanism 210 of the conveying module 200 adjacent to the snow making module 300 can be used to provide conveying force for the snow making water again, so as to ensure that the snow making water can be reliably conveyed to the snow making module 300 with the elevation of 600 m.

Of course, in other embodiments, the number of snow-making modules 300 of the snow-making module system 010 may also be three, four, etc., and is not particularly limited herein.

Referring to fig. 1, the snow making module system 010 of the present embodiment further includes a control module 400, the water treatment module 100, the transportation module 200, and the snow making module 300 are all in communication connection with the control module 400, and the control module 400 can receive feedback signals of the water treatment module 100, the transportation module 200, and the snow making module 300. With the above arrangement, when the control module 400 receives the feedback signals sent by the water treatment module 100, the conveying module 200 and the snow making module 300, the working states of the water treatment module 100, the conveying module 200 and the snow making module 300 can be adjusted according to the feedback signals, so as to obtain a better snow making effect.

The control module 400 of this embodiment is in communication connection with the water filtering mechanism 110, the water color removing and odor removing mechanism 130 and the water cooling mechanism 120 of the water treatment module 100, so that the water filtering mechanism 110, the water color removing and odor removing mechanism 130 and the water cooling mechanism 120 can all feed back signals to the control module 400. Optionally, the control module 400 may determine whether the service life of the water filtering mechanism 110 reaches a limit according to a signal fed back by the water filtering mechanism 110, so as to prompt a user to replace the water filtering mechanism 110 or wash the water filtering mechanism 110; the control module 400 can determine whether the service life of the water color-removing and odor-removing mechanism 130 reaches a limit according to the signal fed back by the water color-removing and odor-removing mechanism 130, and then prompt the user to replace the water color-removing and odor-removing mechanism 130; the control module 400 determines the temperature of the snow making water cooled by the water cooling mechanism 120 according to the signal fed back by the water cooling mechanism 120, so that when the temperature of the snow making water is not reduced to the target temperature, the water cooling mechanism 120 is controlled to further reduce the temperature of the subsequent snow making water, or when the temperature of the snow making water is lower than the target temperature, the water cooling mechanism 120 is controlled to increase the cooling temperature of the subsequent snow making water.

The control module 400 of the embodiment is in communication connection with the water pump mechanism 210 of the conveying module 200, and specifically, the control module 400 is in communication connection with the water pump, so as to judge whether the conveying power provided by the water pump for the water for making snow meets the target requirement in real time according to a signal fed back by the water pump; alternatively, when the control module 400 determines that the conveying power provided by the water pump to the snow making water does not meet the target requirement, the control module 400 controls the water pump to increase the conveying power; when the control module 400 determines that the delivery power provided by the water pump to the snow making water is greater than the target demand, the control module 400 controls the water pump to reduce the delivery power.

Optionally, the water pipeline 220 of the present embodiment is provided with a flow sensor and a temperature sensor, both of which are in communication connection with the control module 400 to feed back the conveying flow information and the temperature information of the snow making water to the control device. Thus, when the control module 400 receives the flow rate information, it may be determined whether the amount of water for snow making delivered by the water delivery line 220 reaches a target value, if the amount of water is lower than the target value, the control module 400 may control the water pump to increase the delivery amount, and if the amount of water is higher than the target value, the control module 400 may control the water pump to decrease the delivery amount. Similarly, when the control module 400 receives the temperature information, the control module 400 is configured to determine whether the temperature of the snow making water in the water transmission pipeline 220 reaches a target value, if the temperature of the snow making water in the water transmission pipeline 220 is lower than the target value, the control module 400 controls the water cooling mechanism 120 to increase the cooling temperature, and if the temperature of the snow making water in the water transmission pipeline 220 is higher than the target value, the control module 400 controls the water cooling mechanism 120 to decrease the cooling temperature; or, when the control module 400 receives the temperature information fed back by the temperature sensor disposed in the water transmission line 220, the control module 400 determines whether the temperature of the snow making water in the water transmission line 220 reaches a target value, if the temperature of the snow making water in the water transmission line 220 is lower than the target value, the control module 400 controls the snow making module 300 to cool and crystallize the snow making water flowing to the snow making module 300 at a temperature higher than the target temperature, and if the temperature of the snow making water in the water transmission line 220 is higher than the target value, the control module 400 controls the snow making module 300 to cool and crystallize the snow making water flowing to the snow making module 300 at a temperature lower than the target temperature.

It should be noted that the temperature sensor and the flow sensor may be selectively provided in at least one of the main water pipe, the branch pipe, and the water outlet pipe 226 as needed, and are not particularly limited herein.

The control module 400 of the present embodiment is also communicatively coupled to the snow making module 300, so that the control module 400 controls at least one of the amount and temperature of snow made by the snow making module 300 according to the signal fed back from the snow making module 300, for example: a flow sensor is arranged at the water inlet of the snow making module 300, the flow sensor is in communication connection with the control module 400 and is used for detecting the flow rate of the snow making water entering the snow making module 300 and feeding back a detection signal to the control module 400, the control module 400 judges whether the flow rate of the snow making water entering the snow making module 300 reaches a target value according to the flow sensor arranged on the snow making module 300, when the control module 400 judges that the flow rate of the snow making water entering the snow making module 300 is lower than the target value, the conveying module 200 (such as a water pump of the conveying module 200) is controlled to increase the conveying power or conveying amount, and when the control module 400 judges that the flow rate of the snow making water entering the snow making module 300 is higher than the target value, the conveying module 200 (such as the water pump of the conveying module 200) is controlled to decrease the conveying power or conveying amount; or, the snow making module 300 is provided with a temperature sensor, the temperature sensor provided in the snow making module 300 is in communication connection with the control module 400, and is configured to detect the snow making temperature of the snow making module 300 and feed back a detection signal to the control module 400, the control module 400 determines whether the snow making temperature of the snow making module 300 reaches a target value according to the temperature sensor provided in the snow making module 300, when the control module 400 determines that the snow making temperature of the snow making module 300 is higher than the target value, the control module 400 controls the snow making module 300 to lower the snow making temperature, and when the control module 400 determines that the snow making temperature of the snow making module 300 is lower than the target value, the control module 400 controls the snow making module 300 to raise the snow making temperature.

The communication connection between the control module 400 and the water treatment module 100, the delivery module 200, and the snow making module 300 may be a wired network, a wireless network, etc., and is not limited in particular.

Alternatively, the control module 400 may select various types of programmable logic controllers according to needs, and is not limited in particular.

Further, referring to fig. 2, the control module 400 may also be in communication connection with the water treatment module 100, the delivery module 200 and the snow making module 300 through a mobile control module 410, and the mobile control module 410 may refer to various types of mobile terminals, such as a mobile phone, a tablet computer, and the like. Of course, in other embodiments, the motion control module 410 may also be directly selected as the control module 400. The movement of the control module 410 also facilitates a user to flexibly master the operation of each module of the snow-making module system 010 at any time and any place.

Alternatively, referring to fig. 2, the water intake module 500 may be in communication with the control module 400, so that the control module 400 determines whether the water intake amount of the water intake module 500 reaches the target value according to the information fed back by the water intake module 500, and if the control module 400 determines that the water intake amount of the water intake module 500 does not reach the target value according to the information fed back by the water intake module 500, the control module 400 controls the water intake module 500 to increase the water intake amount; if the control module 400 determines that the water intake amount of the water intake module 500 is greater than the target value according to the information fed back by the water intake module 500, the control module 400 controls the water intake module 500 to reduce the water intake amount.

Further, the water intake module 500 may be communicatively coupled to the control module 400 via the mobile control module 410.

Still further, the information fed back to the control module 400 by the water intaking module 500 may be the flow information of the water intaking module 500, that is, the water intaking module 500 is provided with a flow meter, and the flow meter arranged on the water intaking module 500 is in communication connection with the control module 400, and is used for feeding back the flow signal of the water intaking module 500 to the control module 400.

The snow making module 300 of the present embodiment may be installed in a place such as a ski resort, and when the snow making module 300 is installed, the water treatment module 100, the transport module 200, and the snow making module 300 may be respectively assembled in a modularized manner.

In summary, the snow making module system 010 of the present invention facilitates improving the adaptability of the snow making module system 010 built in different project places by the respective modularized arrangement of the water treatment module 100, the conveying module 200 and the snow making module 300, so as to improve the building efficiency.

The above is only a preferred embodiment of the present invention, and is not intended to limit the present invention, and various modifications and changes will occur to those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A snow module system, comprising:

the water treatment module is used for filtering and/or cooling the snow making water;

the conveying module is connected with the water treatment module and is used for conveying the water for making snow, which is treated by the water treatment module;

and the snow making module is connected with the conveying module and used for cooling and crystallizing the snow making water conveyed by the conveying module.

2. The snow-making module system of claim 1, wherein the water treatment module comprises at least one of a water filtration mechanism, a water cooling mechanism, and a water color and odor removal mechanism.

3. The snow making module system according to claim 2, wherein the water treatment module comprises the water filtering mechanism, the water color and odor removing mechanism and the water cooling mechanism which are connected in sequence, and the water cooling mechanism is connected with the conveying module.

4. The snow-making module system according to claim 1, wherein the transport module comprises a water pump mechanism and a water transport line, the water transport line is connected between the water pump mechanism and the snow-making module, and the water pump mechanism is connected with the water treatment module for transporting the snow-making water treated by the water treatment module to the snow-making module via the water transport line.

5. The snow-making module system according to claim 4 wherein the water pump mechanism comprises a water pump and a water collection and diversion device connected to the water pump, the water collection and diversion device further connected to the water delivery line.

6. The snow generating module system of claim 4 wherein the water line comprises a main water pipe and an outlet pipe, the main water pipe is connected between the water pump mechanism and the outlet pipe, and the outlet pipe is connected to the snow generating module.

7. The snow generating module system of claim 6, wherein the water conduit line further comprises a lateral pipe, the main water pipe and the outlet pipe being connected by the lateral pipe.

8. The snow making module system according to claim 7, wherein the water conveying line further comprises a corner assembly, the main water pipe and the lateral pipe are connected by the corner assembly, and the corner assembly is used for enabling the water conveying direction of the main water pipe and the water conveying direction of the lateral pipe to form an included angle.

9. The snow making module system according to claim 7, wherein the water pipeline further comprises a variable diameter pipeline, the main water pipe and the branch pipe are connected through the variable diameter pipeline, and the variable diameter pipeline is used for adjusting the flow rate of the snow making water.

10. The snow generating module system of claim 1 further comprising a control module, said water treatment module, said transport module and said snow generating module being communicatively coupled to said control module, said control module capable of receiving feedback signals from said water treatment module, said transport module and said snow generating module.

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