A small-sized artistic stage fog forest mood landscaping device

Abstract

The present application belongs to the technical field of stage equipment, and particularly relates to a small-sized performance stage mist forest artistic conception landscaping device. The device comprises a gas jet part, a gap gasket, an ultrasonic atomization part, a water conveying sponge and an air water taking part. The gap gasket is arranged between the gas jet part and the ultrasonic atomization part, and the water conveying sponge is arranged between the ultrasonic atomization part and the air water taking part. The device has the characteristics that the condensate fin and the semiconductor refrigerating fin in the air water taking part can realize automatic water taking function, and the combination design of the ultrasonic atomization part and the gas jet part can realize mist forest wind resistance resisting directional injection function. The device has the advantages of small size, light weight and portability.

Description

Technical Field

[0001] This invention belongs to the field of stage equipment technology, specifically relating to a small-scale fog-and-smooth-scenery device for performing arts stages. Background Technology

[0002] Stage performance is an art form that uses actors' movements, language, music, lighting, and other means to present a fictional or real story to the audience. To enhance the atmosphere and effect of a stage performance, stage setting is an essential element. Stage setting refers to the use of various materials and techniques to create scenes and environments on the stage that are suitable for the performance's theme and plot.

[0003] Fog effects are a common stage design technique that uses artificial or natural methods to create a white mist on stage, similar to natural fog, to evoke different moods such as dreamlike, mysterious, romantic, or eerie. Fog effects can be combined with other elements such as lighting and music to create a variety of rich and colorful stage effects.

[0004] Currently, there are two main types of stage fogging systems: fixed and mobile. Fixed fogging systems involve installing fogging equipment in fixed locations above or around the stage, connected to a controller via pipes or wires, and spraying fog in specific areas as needed. Mobile fogging systems involve installing fogging equipment on a movable platform or vehicle, powered by batteries or a plug-in power source, to achieve localized fogging effects.

[0005] Fixed and mobile fogging systems each have their advantages and disadvantages. While fixed fogging systems are stable and reliable, their spray range and angle are limited, preventing them from adapting to actors' movements and plot changes, thus lacking flexibility and creativity. Mobile fogging systems, while flexible and versatile, are larger and heavier, requiring additional water and power sources, making them inconvenient for actors to carry or move, affecting performance effects and safety. Furthermore, both fixed and mobile fogging systems face common problems: water supply and the directionality of fog spray. To address these issues, this invention proposes a fogging-themed scenic device for performing arts stages. Summary of the Invention

[0006] 1. Technical problems to be solved

[0007] To address the current issues of water supply and spray directionality in fogging systems, this invention proposes a small-scale fogging landscape device for performance stages. The device includes a gas jet section, a gap ring, an ultrasonic atomizing section, a water-carrying sponge, and an air-to-water intake section. The gap ring is positioned between the gas jet section and the ultrasonic atomizing section, and the water-carrying sponge is positioned between the ultrasonic atomizing section and the air-to-water intake section. Its key features include: automatic water intake via condensation fins and a semiconductor cooling chip in the air-to-water intake section; and directional fogging via a combination of the ultrasonic atomizing section and the gas jet section. The device is small, lightweight, and portable.

[0008] 2. Technical Solution

[0009] To achieve the above objectives, the present invention adopts the following technical solution:

[0010] This invention discloses a stage fogging effect device, comprising a gas jet section, a gap ring, an ultrasonic atomizing section, a water-carrying sponge, and an air-water intake section. The key feature is that the gap ring is disposed between the gas jet section and the ultrasonic atomizing section, and the water-carrying sponge is disposed between the ultrasonic atomizing section and the air-water intake section.

[0011] Preferably, the gas jet section includes a pressure cap and a jet plate. The pressure cap is provided with a central through hole, a central boss, an end face of the central boss, a corner boss, and a fastening threaded hole. The jet plate is provided with a central through hole, a jet hole, an upper end face, and a lower end face. The gap washer is provided with a central through hole, an upper end face, and a lower end face. The end face of the central boss of the pressure cap abuts against the upper end face of the jet plate, and the lower end face of the jet plate abuts against the upper end face of the gap washer. The central through hole of the pressure cap, the central through hole of the jet plate, and the central through hole of the gap washer are interconnected.

[0012] Preferably, the ultrasonic atomizing unit includes a transducer and a transducer mounting base. The transducer includes an elastic porous plate, a front electrode insulating film, a front electrode sheet, an inter-electrode insulating film, a back electrode sheet, a back electrode insulating film, and an annular piezoelectric crystal. The elastic porous plate, the front electrode insulating film, the front electrode sheet, the inter-electrode insulating film, the back electrode sheet, the back electrode insulating film, and the annular piezoelectric crystal are connected in sequence. The elastic porous plate is provided with atomizing nozzles, a lower end face of the elastic porous plate, and an upper end face of the elastic porous plate. The transducer mounting base is provided with a transducer mounting surface, a base corner groove, a base corner through hole, a base side window, a lower end center hole of the base, a lower end face of the base, and an upper end center hole of the base. The lower end center hole of the base communicates with the upper end center hole of the base. The base corner groove communicates with the base corner through hole. The pressure cap corner boss is embedded in the base corner groove. The water conveying sponge is provided with a water conveying sponge upper end face and a water conveying sponge upper circle. The system comprises a column, a water-carrying sponge intermediate connection, a water-carrying sponge intermediate hollow, a water-carrying sponge lower ring, a water-carrying sponge lower end face, and a water-carrying sponge lower ring inner cavity. The upper cylinder of the water-carrying sponge is connected to the water-carrying sponge intermediate connection, and the water-carrying sponge intermediate connection is connected to the water-carrying sponge lower ring. One end of the atomizing nozzle abuts against the upper end face of the water-carrying sponge. The transducer is installed in the upper center hole of the base. The reverse electrode insulating film abuts against the transducer mounting surface. The lower end face of the elastic porous plate abuts against the upper end face of the water-carrying sponge. The upper end face of the elastic porous plate abuts against the lower end face of the gap washer. The water-carrying sponge is installed in the lower center hole of the base. The base side window and the water-carrying sponge intermediate hollow are connected to the lower center hole of the base. The atomizing nozzle is connected to the center through hole of the gap washer. The jet hole is connected to the center through hole of the gap washer. The jet hole is connected to the center through hole of the pressure cap.

[0013] Preferably, the air-to-water intake section includes condenser fins, a semiconductor cooling chip, heat dissipation fins, and a water collector mounting base. The condenser fins are provided with condenser ribs, a lower end face of the condenser fins, and threaded holes. The water collector mounting base is provided with an upper end face of the water intake base, an upper groove of the water intake base, an end face of the upper groove of the water intake base, a lower groove of the water intake base, an end face of the lower groove of the water intake base, corner grooves of the water intake base, a middle cavity of the water intake base, and a through hole of the water intake base. The semiconductor cooling chip is provided with a semiconductor cooling surface and a semiconductor heating surface. The heat dissipation fins are provided with heat dissipation ribs, an upper end face of the heat dissipation fins, and... The condenser fins are installed in the inner cavity of the lower annular cavity of the water supply sponge and the upper groove of the water intake base plate. The lower end face of the condenser fins abuts against the semiconductor cooling surface, the lower end face of the water supply sponge abuts against the upper surface of the water intake base plate, the semiconductor cooling chip is installed in the middle cavity of the water intake base plate, the condenser fins are installed in the lower groove of the water intake base plate, and the upper end face of the condenser fins abuts against the semiconductor heating surface. The condenser fin through holes, the water intake base plate through holes, and the condenser fin threaded holes are connected. The water intake base plate corner grooves and the base corner through holes are connected to the fastening threaded holes.

[0014] 3. Beneficial effects

[0015] This invention discloses a small-scale stage fog effect device. During use, it automatically collects water from the air via condensation fins and a semiconductor cooling chip in the air-water intake section, and delivers the water to the ultrasonic atomizing section, achieving a self-sufficient water supply without the need for an external water source. Furthermore, the combined design of the ultrasonic atomizing section and the gas jet section allows for adjustment of the fog density, range, and shape, enabling directional fog spraying and controlling the fog spray path to create different moods and visual effects. In addition, this device is characterized by its small size, light weight, easy installation, flexible mobility, simple control, and resource and cost savings. It is suitable for various stage performance occasions, can move with the actors, creating different stage moods and providing more diverse, flexible, and innovative fog effects for stage performances. Attached Figure Description

[0016] Figure 1 This is a schematic diagram of the performance stage fog forest landscape device of the present invention;

[0017] Figure 2 This is an exploded view of the gas jet section and gap gasket ring of the present invention;

[0018] Figure 3 This is an exploded view of the transducer of the present invention;

[0019] Figure 4 This is an isometric view of the water-carrying sponge of the present invention;

[0020] Figure 5This is an exploded view of the ultrasonic atomizing section of the present invention;

[0021] Figure 6 This is a cross-sectional view of the air-water intake section of the present invention;

[0022] Figure 7 This is an axonometric view of the water dispenser mounting base of the present invention;

[0023] Figure 8 This is an exploded view of the air-water intake section of the present invention.

[0024] In the diagram, 1-Gas jet section, 11-Gland cap, 12-Jet plate, 111-Gland cap center through hole, 112-Gland cap center boss, 113-Gland cap center boss end face, 114-Gland cap corner boss, 115-Fasting threaded hole, 121-Jet plate center through hole, 122-Jet hole, 123-Jet hole upper end face, 124-Jet hole lower end face, 2-Gap washer, 21-Gap washer center through hole, 22-Gap washer upper... 23-Lower end face of gap washer ring, 31-Transducer, 311-Elastic porous plate, 312-Front electrode insulating film, 313-Front electrode sheet, 314-Inter-electrode insulating film, 315-Reverse electrode sheet, 316-Reverse electrode insulating film, 317-Annular piezoelectric crystal, 3111-Atomizing nozzle, 3112-Lower end face of elastic porous plate, 3113-Upper end face of elastic porous plate, 41-Upper end face of water conveying sponge 42-Upper cylinder of water-conveying sponge; 43-Middle connection of water-conveying sponge; 44-Hollow center of water-conveying sponge; 45-Lower ring of water-conveying sponge; 46-Lower end face of water-conveying sponge; 47-Inner cavity of lower ring of water-conveying sponge; 51-Condensation fin; 52-Semiconductor cooling chip; 53-Heat dissipation fin; 54-Water dispenser mounting base; 511-Condensation rib; 512-Lower end face of condensation fin; 513-Threaded hole of condensation fin; 521-Semiconductor cooling chip. Cold side, 522-Semiconductor heating side, 531-Heat dissipation fin, 532-Upper end face of heat dissipation fin, 533-Through hole of heat dissipation fin, 541-Upper end face of water intake base plate, 542-Upper groove of water intake base plate, 543-End face of groove of upper end of water intake base plate, 544-Lower groove of water intake base plate, 545-End face of groove of lower end of water intake base plate, 546-Corner groove of water intake base plate, 547-Middle cavity of water intake base plate, 548-Through hole of water intake base plate. Detailed Implementation

[0025] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

[0026] In this invention, unless otherwise explicitly specified and limited, the terms "installation," "connection," "linking," "fixing," and "abutment," etc., should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral part; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; they can refer to the internal communication of two components or the interaction between two components. Those skilled in the art can understand the specific meaning of the above terms in this invention according to the specific circumstances.

[0027] Example 1

[0028] like Figures 1-8 As shown, the small-scale performance stage fog forest landscape device of this embodiment includes a gas jet section 1, a gap gasket 2, an ultrasonic atomizing section 3, a water conveying sponge 4, and an air water intake section 5; the gap gasket 2 is disposed between the gas jet section 1 and the ultrasonic atomizing section 3, and the water conveying sponge 4 is disposed between the ultrasonic atomizing section 3 and the air water intake section 5.

[0029] The gas jet section 1 includes a pressure cap 11 and a jet plate 12. The pressure cap 11 is provided with a pressure cap central through hole 111, a pressure cap central boss 112, a pressure cap central boss end face 113, a pressure cap corner boss 114, and a fastening threaded hole 115. The jet plate 12 is provided with a jet plate central through hole 121, a jet hole 122, a jet plate upper end face 123, and a jet plate lower end face 124. The gap washer 2 is provided with a gap washer central through hole 21, a gap washer upper end face 22, and a gap washer lower end face 23. The pressure cap central boss end face 113 abuts against the jet plate upper end face 123, and the jet plate lower end face 124 abuts against the gap washer upper end face 22. The pressure cap central through hole 111, the jet plate central through hole 121, and the gap washer central through hole 21 are interconnected.

[0030] The ultrasonic atomizing unit 3 includes a transducer 31 and a transducer mounting base 32. The transducer 31 includes an elastic porous plate 311, a front electrode insulating film 312, a front electrode 313, an inter-electrode insulating film 314, a back electrode 315, a back electrode insulating film 316, and an annular piezoelectric crystal 317. The elastic porous plate 311, the front electrode insulating film 312, the front electrode 313, the inter-electrode insulating film 314, the back electrode 315, the back electrode insulating film 316, and the annular piezoelectric crystal 317 are connected in sequence. The transducer 311 is provided with an atomizing nozzle 3111, a lower end face 3112 of an elastic porous plate, and an upper end face 3113 of an elastic porous plate. The transducer mounting base 32 is provided with a transducer mounting surface 321, a base corner groove 322, a base corner through hole 323, a base side window 324, a base lower end center hole 325, a base lower end face 326, and a base upper end center hole 327. The base lower end center hole 325 is connected to the base upper end center hole 327, and the base corner groove 322 is connected to the base corner through hole 323. The pressure cap corner boss 114 is embedded in the base corner groove. In the groove 322, the water-carrying sponge 4 is provided with an upper end face 41, an upper cylinder 42, a middle connection 43, a middle hollow 44, a lower ring 45, a lower end face 46, and an inner cavity 47. The upper cylinder 42 is connected to the middle connection 43, and the middle connection 43 is connected to the lower ring 45. One end of the atomizing nozzle 3111 abuts against the upper end face 41. The transducer 31 is installed in the center hole 327 at the upper end of the base. The reverse electrode is insulated. The diaphragm 316 abuts against the transducer mounting surface 321, the lower end face 3112 of the elastic porous plate abuts against the upper end face 41 of the water conveying sponge, the upper end face 3113 of the elastic porous plate abuts against the lower end face 23 of the gap gasket, the water conveying sponge 4 is installed in the lower center hole 325 of the base, the side window 324 of the base and the hollow 44 in the middle of the water conveying sponge are connected to the lower center hole 325 of the base, the atomizing nozzle 3111 is connected to the center through hole 21 of the gap gasket, the jet hole 122 is connected to the center through hole 21 of the gap gasket, and the jet hole 122 is connected to the center through hole 111 of the pressure cap.

[0031] The air intake water section 5 includes a condensation fin 51, a semiconductor cooling chip 52, a heat dissipation fin 53, and a water collector mounting base 54. The condensation fin 51 is provided with condensation ribs 511, a lower end face 512, and threaded holes 513. The water collector mounting base 54 is provided with an upper end face 541, an upper groove 542, an upper groove end face 543, a lower groove 544, a lower groove end face 545, a corner groove 546, a middle cavity 547, and a through hole 548. The semiconductor cooling chip 52 is provided with a semiconductor cooling surface 521 and a semiconductor heating surface 522. The heat dissipation fin 53 is provided with heat dissipation ribs 531. The upper end face 532 and the through hole 533 of the heat dissipation fins are provided. The condensation fins 51 are installed in the inner cavity 47 of the lower ring of the water supply sponge and the upper groove 542 of the water intake base plate. The lower end face 512 of the condensation fins abuts against the semiconductor cooling surface 521. The lower end face 46 of the water supply sponge abuts against the upper surface 541 of the water intake base plate. The semiconductor cooling chip 52 is installed in the middle cavity 547 of the water intake base plate. The heat dissipation fins 53 are installed in the lower groove 544 of the water intake base plate. The upper end face 532 of the heat dissipation fins abuts against the semiconductor heating surface 522. The through hole 533 of the heat dissipation fins and the through hole 548 of the water intake base plate are connected to the threaded hole 513 of the condensation fins. The corner groove 546 of the water intake base plate and the corner through hole 323 of the base are connected to the fastening threaded hole 115.

[0032] Example 2

[0033] The small-scale performance stage fogging landscape device in this embodiment is basically the same as that in Embodiment 1, except that the jet plate 12 of the fogging device has a central through hole 121, jet holes 122, and an upper surface 123 on the jet plate. Adjusting the angle between the center line of the jet hole 122 and the upper surface 123 on the jet plate can change the direction of the gas jet. If the center lines of all the jet holes on the jet plate are inclined sequentially along the central through hole 121, a rotating jet cyclone can be generated. This cyclone affects the direction of the atomized water droplets, producing a fogging landscape with spiral water mist spray.

[0034] Although this application has been described above with reference to specific embodiments, those skilled in the art will understand that many modifications can be made to the configurations and details disclosed in this application within the principles and scope of the disclosure. The scope of protection of this application is determined by the appended claims, and the claims are intended to cover all modifications included in the literal meaning or scope of equivalents of the technical features in the claims.

Claims

1. A small-scale performance stage fog-and-forest themed landscaping device, characterized in that, It includes a gas jet section (1), a gap gasket (2), an ultrasonic atomizing section (3), a water conveying sponge (4), and an air water intake section (5); the gap gasket (2) is disposed between the gas jet section (1) and the ultrasonic atomizing section (3), and the water conveying sponge (4) is disposed between the ultrasonic atomizing section (3) and the air water intake section (5); The gas jet section (1) includes a pressure cap (11) and a jet plate (12). The pressure cap (11) is provided with a pressure cap central through hole (111), a pressure cap central boss (112), a pressure cap central boss end face (113), a pressure cap corner boss (114), and a fastening threaded hole (115). The jet plate (12) is provided with a jet plate central through hole (121), a jet hole (122), a jet plate upper end face (123), and a jet plate lower end face (124). The gap washer (2) is provided with a gap washer center through hole (21), a gap washer upper end face (22) and a gap washer lower end face (23). The end face (113) of the pressure cap center boss abuts against the upper end face (123) of the jet plate, and the lower end face (124) of the jet plate abuts against the upper end face (22) of the gap washer. The pressure cap center through hole (111), the jet plate center through hole (121) and the gap washer center through hole (21) are interconnected. The ultrasonic atomizing unit (3) includes a transducer (31) and a transducer mounting base (32). The transducer (31) includes an elastic porous plate (311), a front electrode insulating film (312), a front electrode (313), an inter-electrode insulating film (314), a back electrode (315), a back electrode insulating film (316), and an annular piezoelectric crystal (317). The elastic porous plate (311), the front electrode insulating film (312), the front electrode (313), the inter-electrode insulating film (314), the back electrode (315), the back electrode insulating film (316), and the annular piezoelectric crystal (317) are connected in sequence. The elastic porous plate (311) is provided with The transducer mounting base (32) has an atomizing nozzle (3111), a lower end face (3112) of an elastic porous plate, and an upper end face (3113) of an elastic porous plate. The transducer mounting base (32) is provided with a transducer mounting surface (321), a base corner groove (322), a base corner through hole (323), a base side window (324), a base lower end center hole (325), a base lower end face (326), and a base upper end center hole (327). The base lower end center hole (325) is connected to the base upper end center hole (327), and the base corner groove (322) is connected to the base corner through hole (323). The pressure cap corner boss (114) is embedded in the base corner groove (322). The water-carrying sponge (4) is provided with... The base has an upper end face (41), an upper cylinder (42), a middle connector (43), a middle hollow (44), a lower ring (45), a lower end face (46), and an inner cavity (47) of the lower ring. The upper cylinder (42) is connected to the middle connector (43), and the middle connector (43) is connected to the lower ring (45). One end of the atomizing nozzle (3111) abuts against the upper end face (41) of the water-conducting sponge. The transducer (31) is installed in the center hole (327) at the upper end of the base. The insulating film (316) of the reverse electrode is connected to the transducer. The mounting surface (321) abuts against each other, the lower end face (3112) of the elastic porous plate abuts against the upper end face (41) of the water conveying sponge, the upper end face (3113) of the elastic porous plate abuts against the lower end face (23) of the gap gasket, the water conveying sponge (4) is installed in the lower end center hole (325) of the base, the side window (324) of the base and the hollow (44) in the middle of the water conveying sponge are connected to the lower end center hole (325) of the base, the atomizing spray hole (3111) is connected to the center through hole (21) of the gap gasket, the jet hole (122) is connected to the center through hole (21) of the gap gasket, and the jet hole (122) is connected to the center through hole (111) of the pressure cap.

2. The small-scale performance stage fog-and-forest landscape device according to claim 1, characterized in that, The air-to-water intake unit (5) includes a condenser fin (51), a semiconductor cooling chip (52), a heat dissipation fin (53), and a water collector mounting base (54). The condenser fin (51) is provided with a condenser rib (511), a lower end face (512) of the condenser fin, and a threaded hole (513) of the condenser fin. The water collector mounting base (54) is provided with an upper end face (541) of the water collector base plate, an upper end groove (542) of the water collector base plate, and a water collector base plate. The upper end groove end face (543), the lower end groove of the water intake base plate (544), the lower end groove end face of the water intake base plate (545), the corner groove of the water intake base plate (546), the middle cavity of the water intake base plate (547), and the through hole of the water intake base plate (548) are provided. The semiconductor cooling chip (52) is provided with a semiconductor cooling surface (521) and a semiconductor heating surface (522). The heat dissipation fins (53) are provided with heat dissipation ribs (531) and the upper end face of the heat dissipation fins. (532) and heat dissipation fin through hole (533), the condensation fin (51) is installed in the inner cavity (47) of the lower ring of the water conveying sponge and the upper groove (542) of the water intake base plate, the lower end face (512) of the condensation fin abuts against the semiconductor cooling surface (521), the lower end face (46) of the water conveying sponge abuts against the upper surface (541) of the water intake base plate, and the semiconductor cooling chip (52) is installed in the middle layer cavity of the water intake base plate. In (547), the heat dissipation fins (53) are installed in the groove (544) at the lower end of the water intake base plate, the upper end face (532) of the heat dissipation fins abuts against the semiconductor heating surface (522), the through hole (533) of the heat dissipation fins and the through hole (548) of the water intake base plate are connected to the threaded hole (513) of the condensate fins, and the corner groove (546) of the water intake base plate and the corner through hole (323) of the base are connected to the fastening threaded hole (115).

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