Disclosure of Invention
In view of the above, the present invention provides a dynamic landscape fog generating system and a dynamic landscape fog generating method.
In order to achieve the above purpose, the solution of the invention is:
dynamic view fog generating system, including making the fog device, it generates the structure to make the fog device including making the fog to and set up a plurality of atomizer at the output port of making the fog and generating the structure, it is a plurality of atomizer interval arrangement, and each atomizer is connected with respectively and can opens and close the control valve of each atomizer according to the preface, establishes atomizer and is N, and then the interval of opening and close of N control valve is 1/N second.
The dynamic landscape fog generating system also comprises a control part which can control the opening and closing degree and the opening and closing degree of the control valve in sequence.
The plurality of atomizing spray heads are arranged in a linear strip shape or a ring shape.
The plurality of atomizing nozzles arranged in a linear manner are respectively positioned 5-12cm above the water surface; or the plurality of atomizing spray heads are connected into a linear shape through transparent spraying connecting pipes, and the distance between the back of the plurality of atomizing spray heads and the water surface is 5-12cm.
The N atomizing spray heads are 10 atomizing spray heads, the 10 atomizing spray heads are in a group, and the multiple groups of atomizing spray heads are arranged in parallel, oppositely, crossly or in a staggered manner.
The dynamic landscape mist generation method is characterized in that a plurality of atomizing nozzles are arranged at intervals, N atomizing nozzles are arranged, and the atomizing nozzles are sequentially opened and closed according to 1/N second through control valves correspondingly arranged on the atomizing nozzles, so that mist which dynamically changes along the arrangement sequence of the atomizing nozzles is generated.
The plurality of atomizing nozzles are arranged in a linear strip shape or a ring shape.
The plurality of atomizing nozzles arranged in a linear manner are respectively arranged above the water surface by 5-12cm; or the plurality of atomizing spray heads are connected into a linear shape through transparent spraying connecting pipes, and the distance between the back of the plurality of atomizing spray heads and the water surface is 5-12cm.
The N atomizing spray heads are 10 atomizing spray heads, the 10 atomizing spray heads are in a group, and the multiple groups of atomizing spray heads are arranged in parallel, oppositely, crossly or in a staggered manner.
After the scheme is adopted, the invention has the following beneficial effects: can produce running spray, and further improve the cooling and dust settling effects. And aiming at various outdoor landscapes, the fog-making device can meet the diversified fog-making requirements of different environments and interesting landscapes.
Detailed Description
In order to further explain the technical solution of the present invention, the present invention is explained in detail by the following specific examples.
As shown in fig. 1 to 3, the dynamic landscape fog generating system of the present invention includes a fog generating device, the fog generating device includes a fog generating structure, and a plurality of atomizing nozzles 3 disposed at an output port of the fog generating structure.
The existing structure of the mist generating device can be selected, for example, the mist generating device mainly comprises a mist generating structure and a plurality of atomizing nozzles 3. The fog generating structure mainly comprises a pressurizing water pump, a pressure regulating valve, a pipeline 1, an air compressor and an atomizer, wherein the atomizer can use an ultrasonic atomization module. The pressure water pump and the pressure regulating valve are connected to the pipeline 1, the inlet end of the pipeline 1 is connected with a water source, the pipeline is further connected with an air compressor, the outlet end of the pipeline is provided with an atomizer, and the outlet end of the atomizer is provided with an atomizing nozzle. Purifying and pressurizing the water to above 4.6Mpa by a pressurizing water pump, and then impacting high-pressure water by an atomizing nozzle through a high-pressure pipeline to break and atomize large water drops into small water drops, wherein the small water drops are broken and atomized into fine mist with the diameter of 17-20 micrometers under the action of pneumatic force. Thus, the water passing through the atomizer is atomized by the air compressor and the atomizer and is sprayed out by the atomizing nozzle to form artificial fog. The pressure regulating valve is adjusted to adjust pressure, so that the artificial fog making effect is optimized, and the atomization degree, the spraying distance and the like are adjusted.
The plurality of atomizing spray heads are arranged at intervals, each atomizing spray head is connected with a control valve 2 capable of opening and closing each atomizing spray head in sequence, and the opening and closing intervals of the N control valves are 1/N second if N atomizing spray heads 3 are arranged. During spraying, the 1 st control valve that sets up on the pipeline of 1 st atomizer starts, and after 1/N second was spouted to the 1 st atomizer of control, the 1 st control valve was closed, and the 1 st atomizer of control stops the spraying. Then, the 2 nd control valve that sets up on the 2 nd atomizer's the pipeline starts, and after controlling 2 nd atomizer to spout 1/N second, 2 nd control valve closed, controls 2 nd atomizer and stops the spraying. And repeating the steps until the Nth atomizing nozzle stops spraying, and finishing the spraying cycle. The second spraying cycle can be started from the 1 st atomizing nozzle to the Nth atomizing nozzle, and can also be started from the Nth atomizing nozzle to the 1 st atomizing nozzle. And so on, the third, fourth, fifth spraying circulation and so on. Of course, the number of spray cycles may also be set. In this way, a spray effect running in one direction can be produced.
Preferably, the number of the atomizing nozzles is even, the even atomizing nozzles are arranged at intervals and are arranged in a row, and the atomizing nozzles at the two ends are sequentially opened and closed towards the middle, that is, the 1 st atomizing nozzle and the Nth atomizing nozzle are simultaneously started and then closed, then the 2 nd atomizing nozzle and the N-1 st atomizing nozzle are simultaneously started and then closed, then the 3 rd atomizing nozzle and the N-2 th atomizing nozzle are simultaneously started and then closed, and the like. In this way, a spray effect of opposing running can be produced.
Preferably, the plurality of atomizing nozzles can be arranged in a linear shape or a ring shape, such as a straight line, a curve, a wavy line, and the like.
Preferably, when the scheme is applied to lake surfaces, river surfaces and water pool surfaces, the plurality of atomizing nozzles arranged in a linear mode are located 5-12cm above the water surface respectively. When the scheme is applied to waterfalls and water curtains, the plurality of atomizing spray heads are connected into a linear shape through the transparent spray connecting pipe, the plurality of atomizing spray heads are positioned in front of the water surface, and the distance between the back of the plurality of atomizing spray heads and the water surface is 5-12cm. In this way, a waterfall-like spray effect can be created that flows continuously downward.
Preferably, N atomizing nozzles are 10 atomizing nozzles, 10 atomizing nozzles are taken as a group, and the opening and closing interval of 10 atomizing control valves in the group is 1/10 second, so that the spraying effect of continuous running can be visually generated; the multiple groups of atomizing nozzles are arranged in parallel, oppositely, crossly or staggeredly. Preferably, the number of the N atomizing spray heads can be set to be 24, 24 atomizing spray heads are arranged in a group to carry out combination arrangement of various shapes, and the opening and closing interval of each group of 24 atomizing control valves is 1/24 second. Therefore, the device can generate more complex and changeable dynamic spraying effects, and is particularly suitable for places with more dust, such as traffic major roads and places with more scenic spot visitors.
The dynamic landscape fog generation method comprises the following steps: the plurality of atomizing spray heads are arranged at intervals, N atomizing spray heads are arranged, and the atomizing spray heads are opened and closed in sequence according to 1/N second through control valves correspondingly arranged on the atomizing spray heads, so that spray with dynamic change along the arrangement sequence of the atomizing spray heads is generated.
The arrangement shape of the plurality of atomizing nozzles, the upper and lower positions, the front and rear positions of the atomizing nozzles and the water surface, the atomizing nozzle group and the like can be the same as the above, and the description is omitted.
Preferably, still include the control division, through opening and close of above-mentioned each control valve of control division in proper order to realize producing the spraying effect of running. Preferably, the control unit is further capable of controlling the degree of opening and closing of the control valve, thereby controlling the amount of spray. Specifically, the control part can control the opening degrees of the plurality of control valves to be sequentially opened from large to small or from small to large; or from small to large and then from large to small, thereby generating a dynamic spray effect which is like a sine wave or a wave and changes continuously. Therefore, the running spraying effect can be generated, the spraying effect with the sequentially changed size can be generated, and more energy and water are saved.
Preferably, the device further comprises a detector and a spray head steering motor. The detector mainly comprises a wind direction detector, a wind speed detector and a temperature detector. The rotating shaft of the spray head steering motor is connected with the atomizing spray head, and the spraying direction of the atomizing spray head can be adjusted. The output ends of the wind direction detector, the wind speed detector and the temperature detector are connected with the input end of the control part, the control part further controls the spray heads to turn to the motor according to the measured wind direction, wind speed and humidity so as to adjust the spraying directions of the atomizing spray heads, and the control part controls the opening and closing degree of the control valve so as to adjust the spraying amount, so that the spraying directions and the spraying amounts of the atomizing spray heads are adjusted according to the changes of the wind direction, the wind speed and the humidity of the external environment. For example, when wind exists, each atomizing nozzle is adjusted to rotate to spray against the wind direction, so that the phenomenon that the spraying effect is influenced because the spraying runs too fast along with the wind can be avoided. When the humidity is less than the comfort level of the human body, the spraying amount of each atomizing nozzle is increased. Otherwise, the spraying amount of each atomizing nozzle is reduced.
Preferably, the atomizing device further comprises a human body sensor, an output end of the human body sensor is connected with an input end of the control part, and the control part controls the atomizing amount of each atomizing nozzle according to the measured data. For example, the area where each atomizing nozzle is located is used as a spraying area, when the human body sensor detects that a person approaches or passes through the spraying area, the control part controls each control valve to be opened and closed in sequence so as to control each atomizing nozzle to spray in sequence. When the person leaves for 3 minutes, 5 minutes or other set time and no person approaches or passes, the control part controls each control valve to be closed in sequence to finish spraying.
Preferably, each atomizer is further provided with a human body sensor, and the control part can control the opening and closing of each atomizer according to data detected by each human body sensor. When each human body sensor correspondingly detects that a person moves towards one direction along the atomizing nozzle, the control part correspondingly controls each atomizing nozzle to be opened and closed in sequence towards the direction, and therefore when the person moves, a spraying effect synchronously moving with the person is correspondingly generated.
Preferably, the atomizing nozzle further comprises a spray shape generating portion, the spray shape generating portion comprises an inlet and an outlet, the spray shape generating portion is mainly arranged at the spray opening of each atomizing nozzle, and the inlet of the spray shape generating portion is connected with the spray opening of the atomizing nozzle. The shape of the spray shape generating part can be set to be heart shape, animal shape, cloud shape, etc., the foaming agent and helium gas are filled in the spray shape generating part, the fog sprayed by the atomizing nozzle is filled in the spray shape generating part and forms bubbles wrapped with the helium gas, and when the outlet of the spray shape generating part is opened, the spray with the set shape is generated. The foaming agent can be soap solution, detergent, etc.
Preferably, the atomizing nozzle further comprises an arc lamp, and the arc lamp is arranged corresponding to the nozzle of the atomizing nozzle. When the spray is irradiated by the light of the arc lamp, colors similar to seven colors can be generated. In addition, the arc lamp can be replaced by a triple prism or a polygon prism, so that the ornamental value can be improved, and the prompting function can be increased.
Preferably, a lighting device can be further configured, and the lighting device can adopt an existing color-changing lamp, for example, the lighting device mainly comprises a plurality of temperature control switches, each temperature control switch respectively controls the switch of one light emitting diode, and the plurality of light emitting diodes can respectively emit various colors such as red, yellow, blue, green, deep red, deep yellow, deep blue, deep green, light red, light yellow, light blue, light green and the like. In this way, varying color light can be generated in response to temperature changes. The color-changing lamps are respectively arranged corresponding to the atomizing nozzles, so that the color-changing lamps can emit different colored lights according to the temperature change of the external environment, and under the irradiation of the various colored lights, the spraying effects of different colors are generated.
Preferably, the color light of the lighting device can be correspondingly changed from light to dark according to the density degree of the crowd. For example, when the human body sensor detects that the number of people in the spraying area, a certain atomizer or the vicinity of the atomizer exceeds a set value, the control part controls the lighting device to generate darker colored light, such as dark red, dark yellow, dark blue, dark green and the like. On the contrary, when the human body sensor detects that the number of people in the spraying area is less than or equal to the set value, the control part controls the lighting device to generate light with lighter color, such as light red, light yellow, light blue, light green and the like. Therefore, the functions of evacuating and guiding people can be achieved through the change of the shade of the colored light. Of course, the control part can also control the spraying amount of the atomizing nozzle of the fog making device, and the spraying amount is changed from small to large according to the density degree of the crowd.
Preferably, each atomizing nozzle can also adjust the spraying direction of the fog corresponding to the density of people. Specifically, when the human body sensor detects that the number of people in a spraying area, or a certain atomizing nozzle, or near a set atomizing nozzle exceeds a set value, the control part controls the atomizing nozzle to rotate by a steering motor so as to adjust the atomizing nozzle to be slightly close to people, and fine water drops formed by spraying slightly float towards the people, so that the effect of dispersing the people is achieved. Otherwise, the control part controls the atomizing nozzle to rotate by the steering motor so as to adjust the atomizing nozzle to be slightly far away from the crowd.
Preferably, a disinfection device is also included, which may be of existing construction. Specifically, the disinfection device mainly comprises a disinfection control valve, an ultraviolet disinfection structure, a disinfectant or negative oxygen generation structure and the like, wherein the ultraviolet disinfection structure, the disinfectant or negative oxygen generation structure and the like can be communicated with the mist generating device. When the human body sensor detects that the number of people in a spraying area, or a certain atomizing nozzle, or the vicinity of a set atomizing nozzle exceeds a set value, the control part controls the disinfection control valve to be opened, so that water supply firstly passes through the ultraviolet disinfection structure, the disinfectant or the negative oxygen generation structure and then is sprayed out through the atomizing nozzle. Otherwise, the control part controls the disinfection control valve to close.
The above embodiments and drawings are not intended to limit the form and style of the present invention, and any suitable changes or modifications thereof by those skilled in the art should be considered as not departing from the scope of the present invention.