Flow directing module and low entropy analog

Abstract

The application discloses a flow guide module and a low-entropy simulation instrument, the flow guide module comprises a multi-surface flow guide group and a double-opening flow guide, the multi-surface flow guide group comprises at least one multi-surface flow guide, the multi-surface flow guide comprises six horn bodies, the double-opening flow guide is internally hollow to form a channel with a first opening end and a second opening end at two ends; the double-opening flow guide takes the extension direction of the channel as an axis, and the double-opening flow guide is in an axial symmetry structure; wherein the first opening end faces a large end of one horn body in the multi-surface flow guide; the horn body faced by the first opening end is a main horn body, the second opening end is arranged away from the main horn body, and the cross-sectional area of the second opening end is greater than that of the large end of the main horn body. Compared with the prior art, the above design of the application increases the contact strength between the multi-surface flow guide and the human body, and improves the physiotherapy effect.

Description

Technical Field

[0001] This application relates to the field of healthcare devices, and more particularly to a flow guiding module and a low-entropy simulator. Background Technology

[0002] Entropy is a measure of the degree of disorder in a system; the higher the entropy, the more disordered the system. The presence of high-entropy energy increases the entropy of a system, while the presence of low-entropy energy decreases it. Schrödinger said that entropy reduction is the force of life; when the entropy at a certain point in the body is relatively lower, the state of life is better. Therefore, human health is closely related to entropy. When the entropy value of the human body increases, the body tends towards disorder, health deteriorates, and one becomes more susceptible to illness; conversely, health improves.

[0003] If an environment can be created that allows the human body to maintain a stable low-entropy connection, the body's entropy value can be reduced, thus achieving the goal of strengthening the body.

[0004] The previous case, PCT / CN2024 / 094085, described a flow-guiding module that can simulate a low-entropy environment to achieve therapeutic effects. However, in actual use, it was found that the low-entropy environment constructed by the flow-guiding module in the previous case had a weak connection with the human body and needs further improvement. Utility Model Content

[0005] The purpose of this application is to provide a flow guiding module and a low-entropy simulator that, compared with the previous flow guiding module, can improve the connection between the human body and the low-entropy environment and improve the physiotherapy effect.

[0006] This application discloses a flow guiding module, which includes a multi-faceted flow guiding group and a double-opening flow guide. The multi-faceted flow guiding group includes at least one multi-faceted flow guide, and the multi-faceted flow guide includes six horn bodies. Each horn body forms a channel that gradually decreases in size from a large opening end to a small opening end. The large opening ends of the six horn bodies all face outwards, respectively facing six directions: up, down, left, right, front, and back. The six horn bodies converge at their small opening ends and are seamlessly connected. The channels of the six horn bodies are interconnected. The double-opening flow guide is hollow inside, forming a channel with a first opening end and a second opening end at both ends. The first opening end faces the large opening end of one of the horn bodies in the multi-faceted flow guide. The horn body facing the first opening end is the main horn body. The second opening end is disposed opposite to the main horn body, and the cross-sectional area of ​​the second opening end is larger than the cross-sectional area of ​​the large opening end of the main horn body.

[0007] Compared to the previous application PCT / CN2024 / 094085, which describes a flow-guiding module that directly connects with the human body via a multi-faceted flow guide, this application adds a double-opening flow guide to one side of the multi-faceted flow guide. Utilizing the channel design with openings at both ends of the double-opening flow guide, when using the flow-guiding module, the first opening of the double-opening flow guide faces the large opening of the main horn body in the multi-faceted flow guide, while the second opening faces the physiotherapy user. This allows the double-opening flow guide to establish a channel between the multi-faceted flow guide and the physiotherapy user, reducing interference from the external environment and making the connection more stable. Furthermore, since the cross-sectional area of ​​the second opening of the double-opening flow guide is larger than the cross-sectional area of ​​the large opening of the main horn body—that is, the opening area of ​​the end of the double-opening flow guide facing the physiotherapy user is larger than the opening area of ​​the horn body in the multi-faceted flow guide—the second opening can cover the main horn body in the multi-faceted flow guide, thus providing sufficient space for the human body and the multi-faceted flow guide to establish a sufficient connection.

[0008] Optionally, the dual-opening guide is a single-horn guide, the dual-opening guide has its central axis length direction as the extension direction of the channel, and the dual-opening guide has an axisymmetric structure; the cross-sectional area of ​​the first opening end is smaller than the cross-sectional area of ​​the second opening end.

[0009] The single-horn flow guide features a design with a large opening at one end and a small opening at the other, which can gradually guide the human body to establish a connection with the negative entropy environment. Compared with a straight cylindrical channel, it establishes a connection faster.

[0010] Optionally, the dual-opening guide is a conical single-horn guide, and the cross-sectional line of the inner wall of the dual-opening guide along the central axis is an oblique line. From the first opening end to the second opening end, the cross-sectional area of ​​the dual-opening guide gradually increases.

[0011] The design employs a cone-shaped single-horn flow guide to establish a frustum-shaped channel between the physiotherapy user and the multi-faceted flow guide assembly. As the channel gradually expands from the first opening to the second opening and the slope of the channel side is fixed, the guidance between the low-entropy environment inside the multi-faceted flow guide assembly and the physiotherapy user is stronger. Therefore, the cone-shaped single-horn flow guide design enables the human body to establish a connection with the low-entropy environment inside the multi-faceted flow guide assembly more quickly.

[0012] Optionally, the dual-opening guide is a curved single-horn guide, and the cross-sectional line of the inner wall of the dual-opening guide along the central axis is an arc, and the arc is concave towards the central axis.

[0013] By setting up a curved single-horn flow guide, the connection between the negative entropy environment and the human body is enhanced. Furthermore, since the channel of the double-opening flow guide is horn-shaped and the side of the channel is a concave curved surface, the convergence of the double-opening flow guide is enhanced, making the connection between the negative entropy environment and the human body more stable.

[0014] Optionally, the cross-sectional area of ​​the first opening end is larger than the cross-sectional area of ​​the large opening end of the main horn body.

[0015] Because the cross-sectional area of ​​the second opening is larger than that of the first opening, and the cross-sectional area of ​​the first opening is larger than that of the large opening of the main horn body, the guiding effect between the physiotherapy user and the multi-faceted flow guide group gradually decreases without abrupt changes, thereby improving the stability of the connection between the human body and the low-entropy environment.

[0016] Optionally, both the first opening end and the second opening end are circular, the diameter of the second opening end is 4-10 times the diameter of the first opening end, and the distance between the first opening end and the second opening end is less than the diameter of the second opening and greater than half the diameter of the second opening.

[0017] By designing the dimensions of the dual-opening flow guide as described above, and by controlling the length of the dual-opening flow guide (i.e., the distance between the first and second opening ends) and the degree of lateral tilt, it is possible to enable the human body to quickly establish a connection with the low-entropy environment while ensuring the stability of the connection.

[0018] Optionally, the distance between the first opening end and the main horn body is greater than or equal to 0.5 times the diameter of the large opening end of the main horn body, and less than or equal to 2 times the diameter of the large opening end of the main horn body.

[0019] By designing the distance between the dual-opening flow guide and the multi-faceted flow guide as described above, we can avoid both the weakening of the connection between the human body and the low-entropy environment due to the distance between the dual-opening flow guide and the multi-faceted flow guide being too far apart, and the blockage of the connection between the human body and the low-entropy environment due to the distance between the dual-opening flow guide and the multi-faceted flow guide being too close, thereby ensuring a good guiding effect between the human body and the low-entropy environment.

[0020] Optionally, the dual-opening flow guide is a dual-horn flow guide, which includes a first horn and a second horn arranged symmetrically. The small opening ends of the first horn and the second horn are connected. The large opening end of the first horn is the first opening end, and the large opening end of the second horn is the second opening end. The diameter of the large opening end of the first horn is larger than the diameter of the small opening end of the first horn, and the diameter of the large opening end of the second horn is larger than the diameter of the small opening end of the second horn.

[0021] By employing a dual-horn flow guide design, the interference of high-entropy information is filtered out, making it easier for the human body to establish a connection with the multi-faceted flow guide group in a low-entropy environment, further reducing the entropy value of the human body and improving the therapeutic effect.

[0022] Optionally, the double-opening guide is a conical double-horn guide, wherein the cross-sectional line of the inner wall of each horn body in the double-opening guide along the central axis is an oblique line.

[0023] Because the cone-shaped horn design enhances the guidance between the low-entropy environment inside the multi-faceted flow guide group and the physiotherapy user, this embodiment employs a cone-shaped double-horn flow guide. The cross-sectional line along the central axis of the inner wall of the channel inside each horn in the cone-shaped double-horn flow guide is oblique, thereby enabling each horn in the cone-shaped double-horn flow guide to have a good guiding effect, allowing the human body to establish a connection with the low-entropy environment inside the multi-faceted flow guide group more quickly.

[0024] Optionally, the dual-opening guide is a curved dual-horn guide, with the extension direction of the channel as the length direction of the central axis, and the dual-opening guide has an axisymmetric structure; the cross-sectional line of the inner wall of the first horn and the second horn along the central axis is an arc, and the arc is concave towards the central axis.

[0025] Because the inner wall of the curved double-horn diffuser is a concave curved surface, the convergence of the double-opening diffuser is enhanced, making the connection between the negative entropy environment and the human body more stable.

[0026] Optionally, the diameter of the small end of the first horn is smaller than the diameter of the large end of the main horn body.

[0027] The above design allows the center of the dual-opening flow guide to have a smaller size, thereby creating a converging and focusing effect, making the connection between the human body and the low-entropy environment inside the multi-faceted flow guide group more stable.

[0028] Optionally, the distance between the first opening end and the main horn body is greater than or equal to twice the diameter of the large opening end of the main horn body, and less than or equal to ten times the diameter of the large opening end of the main horn body.

[0029] The above design can better shield against high-entropy information interference and stabilize the connection between the human body and the low-entropy environment.

[0030] Optionally, the central axis of the dual-opening guide coincides with one of the central axes of the multi-faceted guide.

[0031] With the above design, the first opening end of the dual-opening guide is aligned with the opening end of the main horn body, which can improve the guiding effect of the dual-opening guide.

[0032] Optionally, the multi-faceted flow guide group includes at least two multi-faceted flow guides. In the multi-faceted flow guide group, the multi-faceted flow guides are of different sizes, and the smaller multi-faceted flow guide is at least partially disposed in the throat region of the larger multi-faceted flow guide. The throat region is the intersection of the channels of the six horn bodies. The larger end of the horn body in the smaller multi-faceted flow guide is connected to the channel of the corresponding horn body in the larger multi-faceted flow guide.

[0033] By adding a small-sized multifaceted flow guide in the middle cavity of a large-sized multifaceted flow guide, the small-sized multifaceted flow guide makes secondary adjustments to the low-entropy environment of the middle cavity of the large-sized multifaceted flow guide, resulting in a lower entropy value in the spherical space at the center of the small-sized multifaceted flow guide. This can more efficiently promote the overall transformation of the human body towards low-entropy energy, resulting in better effects.

[0034] Optionally, the spacing between the multi-faceted flow guide assembly and the dual-opening flow guide can be adjusted.

[0035] Because everyone's health level and internal entropy environment are different, by adjusting the distance, a low-entropy connection pathway suitable for each person can be found, allowing the user to find the feeling, so as to quickly establish a connection between the human body and the low-entropy environment inside the multi-faceted flow guide group, thereby improving the therapeutic effect in a targeted manner.

[0036] Optionally, the dual-opening flow guide is made of a transparent material.

[0037] This application also discloses a low-entropy simulator, which includes the flow guiding module described above.

[0038] Optionally, the low-entropy simulator includes a housing, and the multi-faceted flow guide assembly is disposed within the housing. The housing has five small perforated sections and one large perforated section. The small perforated sections include multiple arrayed first through holes, and the large perforated section includes a second through hole. The large perforated section is positioned directly opposite the large opening of the main horn body, and the five small perforated sections are respectively positioned directly opposite the large openings of the other five horn bodies in the multi-faceted flow guide assembly. The diameter of the second through hole is also larger than the diameter of the large opening of the main horn body.

[0039] By designing a second through-hole with a larger diameter on one side of the housing, which is the same as the dual-opening air guide, instead of using multiple arrayed small holes on other sides, the conductivity between the human body and the low-entropy environment inside the multi-faceted air guide assembly is improved, ensuring unobstructed communication between the two. Meanwhile, the other perforated sections with multiple small holes not only prevent the housing from affecting the effectiveness of the multi-faceted air guide assembly but also prevent dust from falling onto it and affecting its performance. Attached Figure Description

[0040] The accompanying drawings, which form part of the specification, are used to provide a further understanding of the embodiments of this application and illustrate the implementation methods of this application, together with the textual description, to explain the principles of this application. Obviously, the drawings described below are merely some embodiments of this application, and those skilled in the art can obtain other drawings based on these drawings without any creative effort. In the drawings:

[0041] Figure 1 This is a front view of a flow guiding module provided in the first embodiment of this application;

[0042] Figure 2 This is a cross-sectional schematic diagram of the first type of multi-faceted flow guide assembly provided in the first embodiment of this application;

[0043] Figure 3 This is a cross-sectional schematic diagram of the second type of multi-faceted flow guide assembly provided in the first embodiment of this application;

[0044] Figure 4 This is a cross-sectional schematic diagram of a double-opening guide provided in the first embodiment of this application;

[0045] Figure 5 This is a dimensional schematic diagram of a flow guiding module provided in the first embodiment of this application;

[0046] Figure 6 This is a three-dimensional schematic diagram of a low-entropy simulator provided in the first embodiment of this application;

[0047] Figure 7 This is an explosion diagram of a low-entropy simulator provided in the first embodiment of this application;

[0048] Figure 8 This is a schematic diagram of another low-entropy simulator provided in the first embodiment of this application;

[0049] Figure 9 This is a schematic diagram of the structure of another low-entropy simulator provided in the first embodiment of this application;

[0050] Figure 10 This is a front view of a low-entropy simulator provided in the second embodiment of this application;

[0051] Figure 11 This is a cross-sectional schematic diagram of a double-opening guide provided in the second embodiment of this application;

[0052] Figure 12 This is a front view of a low-entropy simulator provided in the third embodiment of this application;

[0053] Figure 13 This is a schematic diagram of a dual-opening flow guide provided in the third embodiment of this application;

[0054] Figure 14 This is a schematic diagram showing the dimensions of a low-entropy simulator provided in the third embodiment of this application;

[0055] Figure 15 This is a front view of a low-entropy simulator provided in the fourth embodiment of this application;

[0056] Figure 16 This is a three-dimensional schematic diagram of a low-entropy simulator provided in the fourth embodiment of this application;

[0057] Figure 17 This is a three-dimensional schematic diagram of a double-opening guide provided in the fourth embodiment of this application.

[0058] Among them, 1. Low-entropy simulator; 10. Flow guiding module; 100. Multi-faceted flow guiding group; 110. Multi-faceted flow guide; 111. Horn body; 111a. Main horn body; 200. Double-opening flow guide; 210. First opening end; 220. Second opening end; 230. First horn; 240. Second horn; 300. Housing; 310. Hollowed-out small hole part; 311. First through hole; 320. Hollowed-out large hole part; 321. Second through hole; 330. Upper shell; 340. Lower shell; 350. Support foot; 400. Base; 410. Slide rail; 500. First fixing part; 600. Second fixing part; 610. Slider. Detailed Implementation

[0059] It should be understood that the terminology, specific structural and functional details used herein are merely for describing particular embodiments and are representative. However, this application may be implemented in many alternative forms and should not be construed as being limited to the embodiments set forth herein.

[0060] The present application will now be described in detail with reference to the accompanying drawings and optional embodiments.

[0061] Example 1: Conical Single-Horn Flow Guide

[0062] Figure 1 This is a schematic diagram of a flow guiding module provided in the first embodiment of this application, as shown below. Figure 1As shown, the flow guiding module 10 includes a multi-faceted flow guiding group 100 and a double-opening flow guide 200. The multi-faceted flow guiding group 100 includes at least one multi-faceted flow guide 110, which includes six horn bodies 111. Each horn body 111 forms a channel that gradually decreases in size from a large opening to a small opening. The large openings of the six horn bodies 111 all face outwards, oriented in six directions: up, down, left, right, front, and back. The six horn bodies 111 converge at their small openings and are seamlessly connected. The channels of the six horn bodies 111 are interconnected. The interior of the double-opening guide 200 is hollow, forming a channel with a first opening end 210 and a second opening end 220 at both ends; wherein, the first opening end 210 faces the large opening end of one of the horn bodies 111 in the multi-faceted guide 110; the horn body 111 facing the first opening end 210 is the main horn body 111a, the second opening end 220 is disposed opposite to the main horn body 111a, and the cross-sectional area of ​​the second opening end 220 is larger than the cross-sectional area of ​​the large opening end of the main horn body 111a.

[0063] Compared to the previous application PCT / CN2024 / 094085, which describes a flow-guiding module that directly connects with the human body via a multi-faceted flow guide, this application adds a double-opening flow guide 200 to one side of the multi-faceted flow guide 110. Utilizing the double-opening flow guide 200's channel design with openings at both ends, when using the flow-guiding module 10, the first opening end 210 of the double-opening flow guide 200 faces the large opening end of the main horn body 111a in the multi-faceted flow guide 110, while the second opening end 220 of the double-opening flow guide 200 faces the physiotherapy user, allowing the double-opening flow guide 200 to connect with the human body directly via a multi-faceted flow guide. The face diffuser 110 establishes a channel between itself and the physiotherapy user, reducing interference from the external environment and making the connection more stable. Moreover, since the cross-sectional area of ​​the second opening end 220 in the double-opening diffuser 200 is larger than the cross-sectional area of ​​the large opening end of the main horn body 111a, that is, the opening area of ​​the end of the double-opening diffuser 200 facing the physiotherapy user is larger than the opening area of ​​the horn body 111 in the multifaceted diffuser 110, the second opening end 220 can cover the main horn body 111a in the multifaceted diffuser 110, thus providing sufficient space for the human body and the multifaceted diffuser 110 to establish a sufficient connection.

[0064] Figure 2 This is a schematic diagram of a cross-section of a multi-faceted flow guide assembly, such as... Figure 2 As shown, the multi-faceted flow guide group 100 is composed of a multi-faceted flow guide 110, in which the horn body 111, which is directly opposite the first opening end 210, is the main horn body 111a.

[0065] Figure 3 This is a cross-sectional schematic diagram of another type of multi-faceted flow guide assembly, such as... Figure 3As shown, the multi-faceted flow guide group 100 is composed of two nested multi-faceted flow guides 110. At this time, the multi-faceted flow guide group 100 is a nested multi-faceted flow guide component, and the main horn body 111a is one of the horn bodies 111 of the largest multi-faceted flow guide 110 in the multi-faceted flow guide group 100.

[0066] Of course, the multi-faceted flow guide group 100 can also be composed of three or more nested multi-faceted flow guides 110. In this case, the main horn body 111a is still one of the horn bodies 111 of the largest multi-faceted flow guide 110 in the multi-faceted flow guide group 100. When the multi-faceted flow guide group 100 is composed of three or more nested multi-faceted flow guides 110, it is required that the sizes of the multi-faceted flow guides 110 in the multi-faceted flow guide group 100 are different, and the smaller multi-faceted flow guide 110 is at least partially disposed in the throat region of the larger multi-faceted flow guide 110. The throat region is the intersection of the channels of the six horn bodies 111. The larger end of the horn body 111 in the smaller multi-faceted flow guide 110 is connected to the channel of the corresponding horn body 111 in the larger multi-faceted flow guide 110.

[0067] When using a multi-faceted flow guide nested component, by adding a small-sized multi-faceted flow guide 110 to the middle cavity of the large-sized multi-faceted flow guide 110, the small-sized multi-faceted flow guide 110 makes secondary adjustments to the low-entropy environment of the middle cavity of the large-sized multi-faceted flow guide 110, so that the entropy value in the spherical space at the center of the small-sized multi-faceted flow guide 110 is lower, which can more efficiently promote the overall transformation of the human body to low-entropy energy, resulting in better effects.

[0068] The specific design of the multi-faceted flow guide 110 and the multi-faceted flow guide nested component has been described in detail in the previous document PCT / CN2024 / 094085, and will not be repeated here.

[0069] In this embodiment of the application, the dual-opening guide 200 has an axisymmetric structure with the extension direction of the channel as the length direction of the central axis.

[0070] Figure 4 This is a cross-sectional schematic diagram of a dual-opening guide provided in an embodiment of this application, as shown below. Figure 4 As shown in the embodiment of this application, the double-opening guide 200 is a conical single-horn guide. The cross-sectional line of the inner wall of the double-opening guide 200 along the central axis is an oblique line. From the first opening end 210 to the second opening end 220, the cross-sectional area of ​​the double-opening guide 200 gradually increases.

[0071] This application embodiment adopts a cone-shaped single-horn flow guide design to establish a frustum-shaped channel between the physiotherapy user and the multi-faceted flow guide group 100. Since the channel gradually expands from the first opening end 210 to the second opening end 220, and the slope of the channel side is fixed, the guidance between the low-entropy environment inside the multi-faceted flow guide group 100 and the physiotherapy user is stronger. Therefore, the cone-shaped single-horn flow guide design enables the human body to establish a connection with the low-entropy environment inside the multi-faceted flow guide group 100 more quickly.

[0072] In some embodiments, the cross-sectional area of ​​the first opening end 210 is larger than the cross-sectional area of ​​the large opening end of the main horn body 111a. Since the cross-sectional area of ​​the second opening end 220 is larger than the cross-sectional area of ​​the first opening end 210, and the cross-sectional area of ​​the first opening end 210 is larger than the cross-sectional area of ​​the large opening end of the main horn body 111a, the guiding effect between the physiotherapy user and the multi-faceted flow guide group 100 gradually decreases without abrupt changes, thereby improving the stability of the connection between the human body and the low-entropy environment.

[0073] In this embodiment of the application, both ends of the multi-faceted guide 110 are circular, and the first open end 210 and the second large opening end are also circular, so as to maintain the uniformity of guidance while ensuring a large guiding area.

[0074] like Figure 5 As shown, in some embodiments, the diameter φ2 of the second opening end 220 is 4-10 times the diameter φ1 of the first opening end 210, and the distance L1 between the first opening end 210 and the second opening end 220 is less than the diameter φ2 of the second opening, but greater than half of the diameter φ2 of the second opening. Through the above-described dimensional design of the dual-opening flow guide 200, and by controlling the length of the dual-opening flow guide 200 (i.e., the distance L1 between the first opening end 210 and the second opening end 220) and the degree of lateral tilt, this embodiment of the application enables the human body to quickly establish a connection with the low-entropy environment while ensuring the stability of the connection.

[0075] Furthermore, the distance L1 between the first opening end 210 and the second opening end 220 is two-thirds of the diameter φ2 of the second opening.

[0076] In some embodiments, the distance L2 between the first opening end 210 and the main horn body 111a is greater than or equal to 0.5 times the diameter φ3 of the large opening end of the main horn body 111a, and less than or equal to 2 times the diameter φ3 of the large opening end of the main horn body 111a. Through the above-described distance design between the dual-opening guide 200 and the multi-faceted guide group 100, this embodiment of the application avoids both situations where the distance between the dual-opening guide 200 and the multi-faceted guide group 100 is too far, leading to a weakened connection between the human body and the low-entropy environment, and situations where the distance between the dual-opening guide 200 and the multi-faceted guide group 100 is too close, leading to a blockage of the connection between the human body and the low-entropy environment, thereby ensuring a good guiding effect between the human body and the low-entropy environment.

[0077] Furthermore, the distance L2 between the first opening end 210 and the main horn body 111a is greater than or equal to 1 times the diameter φ3 of the large opening end of the main horn body 111a, and less than or equal to 1.5 times the diameter φ3 of the large opening end of the main horn body 111a.

[0078] In some embodiments, the central axis of the dual-opening guide 200 coincides with one of the central axes of the multi-faceted guide 110 (the central axis of the main horn body 111a) to improve the guiding effect. Furthermore, the extension line of the central axis of the dual-opening guide 200 also passes through the center of the multi-faceted guide assembly 100.

[0079] At this point, the first opening end 210 of the double-opening guide 200 is directly opposite the large opening end of the main horn body 111a in the multi-faceted guide 110, resulting in a large relative area between the double-opening guide 200 and the main horn body 111a. Of course, during the actual assembly of the guide module 10, minor deviations may occur between the double-opening guide 200 and the multi-faceted guide 110, causing the central axis of the double-opening guide 200 and the central axis of the main horn body 111a to be not on the same straight line. This does not affect the normal use of the guide module 10.

[0080] In some embodiments, the dual-opening flow guide 200 is made of a transparent material. Of course, in other embodiments, the dual-opening flow guide 200 may also be made of an opaque material.

[0081] like Figure 1 and Figure 6As shown, this application also provides a low-entropy simulator. The low-entropy simulator 1 includes a base 400, a first fixing part 500, a second fixing part 600, and a housing 300. The first fixing part 500 and the second fixing part 600 are respectively arranged side by side on the base 400. The base 400, the first fixing part 500, and the second fixing part 600 can be integrally molded to ensure the stability and strength of the structure. Moreover, the multi-faceted flow guide group 100 is disposed inside the housing 300, the housing 300 is disposed on the second fixing part 600, and the double-opening flow guide 200 is disposed on the first fixing part 500.

[0082] In this embodiment, the interior of the housing 300 is hollow, and the bottom of the housing 300 is provided with multiple support legs 350. The support legs 350 can be fixedly connected to the second fixing part 600 to improve the stability of the housing 300, or the support legs 350 can be not fixedly connected to the second fixing part 600. When using the flow guiding module 10, the housing 300 can be placed directly on the second fixing part 600, and the large opening end of the main horn body 111a of the multi-faceted flow guiding assembly 100 inside the housing 300 can be directly aligned with the first opening end 210 of the double-opening flow guide 200.

[0083] In this embodiment, the housing 300 is provided with five small perforated holes 310 and one large perforated hole 320. The small perforated holes 310 include a plurality of arrayed first through holes 311, and the large perforated hole 320 includes a second through hole 321. The diameter of the second through hole 321 is larger than the diameter of the first through hole 311. The large perforated hole 320 is directly opposite to the large opening end of the main horn body 111a, and the five small perforated holes 310 are respectively directly opposite to the large opening ends of the other five horn bodies 111 in the multi-faceted flow guide 110.

[0084] This embodiment of the application improves the conductivity between the human body and the low-entropy environment inside the multi-faceted flow guide assembly 100 by setting a second through hole 321 with a larger diameter on one side of the housing 300 and the dual-opening flow guide 200, instead of using multiple arrayed small holes on other sides. This ensures unobstructed communication between the two. Meanwhile, the other perforated small hole portions 310 with multiple small holes not only prevent the presence of the housing 300 from affecting the effect of the multi-faceted flow guide assembly 100, but also prevent dust from falling onto the multi-faceted flow guide assembly 100 and affecting its performance.

[0085] Furthermore, the diameter of the second through hole 321 is also larger than the diameter of the large opening end of the main horn body 111a.

[0086] In some embodiments, the first fixing part 500 may adopt a design of multiple support columns, which are spaced apart at the bottom of the double-opening guide 200. One end of the support column is connected to the base 400, and the other end of the support column is connected to the outer wall of the double-opening guide 200. The support columns may be fixed to the double-opening guide 200 by welding, bonding, snap-fitting, or other methods, which are not limited here.

[0087] In some embodiments, the first fixing part 500 may be a block design, located below the second opening end 220 of the double-opening guide 200, and connected to the lowest point of the second opening end 220, thus fixing the double-opening guide 200 to the base 400. Of course, in other embodiments, the first fixing part 500 may also adopt other designs, depending on the actual situation.

[0088] In some embodiments, the second fixing part 600 can be cylindrical, or it can be a design of a round rod plus a disc, or other designs. What they all have in common is that the second fixing part 600 needs to maintain the height of the multi-faceted flow guide assembly 100 while also improving the stability of the housing 300.

[0089] In some embodiments, such as Figure 7 As shown, the housing 300 includes a connected upper housing 330 and a lower housing 340. The bottom of the lower housing 340 has three legs 350, which are arranged in an equilateral triangle to stably support the housing 300. Furthermore, the legs are not obstructed by the perforated openings 310 at the bottom of the housing 300, and the design of the perforated openings 310 and the legs 350 does not interfere with each other.

[0090] The edges of the upper shell 330 and the lower shell 340 are fixed together, specifically by means of snap-fit, adhesive, screws, or ultrasonic welding, to prevent the upper shell 330 and the lower shell 340 from falling off and to reduce the gap between them, making the product more aesthetically pleasing. Figure 7 As shown, the top of the lower shell 340 is provided with multiple hooks, and the bottom inner side of the upper shell 330 is provided with multiple corresponding grooves. During installation, the upper shell 330 and the lower shell 340 are fixed by engaging the hooks and grooves.

[0091] In some embodiments, the largest multi-faceted flow guide 110 in the multi-faceted flow guide assembly 100 is fixed inside the housing 300 by adhesive bonding. Specifically, during product assembly, adhesive is first applied to the bottom of the largest multi-faceted flow guide 110 or the inside of the lower housing 340, then the multi-faceted flow guide assembly 100 is fixed inside the lower housing 340, and finally the upper housing 330 and the lower housing 340 are fixed together. Of course, in other embodiments, the multi-faceted flow guide assembly 100 can also be fixed inside the housing 300 by other methods, such as support and fixation by fixing posts, or insertion, welding, etc., depending on the actual situation.

[0092] like Figure 8 As shown, in some embodiments, the low-entropy simulator 1 may only have a lower shell 340, which is mounted on the second fixing part 600 via a support foot 350, and the bottom of the lower shell 340 also has a perforated small hole 310. In this case, the outermost multi-faceted flow guide 110 of the multi-faceted flow guide assembly 100 is fixed to the lower shell 340 by adhesive bonding. The specific connection method can be referred to the previous description and will not be repeated here.

[0093] Moreover, the height of the lower shell 340 is lower than the height of the lowest point of the large mouth of the four horn bodies 111 of the outermost multi-faceted flow guide 110 in the horizontal direction, so that the lower shell 340 will not affect the connection between the human body and the low-entropy environment inside the multi-faceted flow guide 100, and can also improve the low-entropy effect inside the multi-faceted flow guide 100.

[0094] In some embodiments, the distance between the multi-faceted flow guide group 100 and the dual-opening flow guide 200 is adjustable. Since everyone's health level and internal entropy environment are different, adjusting the distance allows for the discovery of a suitable low-entropy connection pathway for each individual, enabling the user to feel and quickly establish a connection between the body and the low-entropy environment within the multi-faceted flow guide group 100, thereby specifically improving the therapeutic effect.

[0095] like Figure 9 As shown, the base 400 is provided with a slide rail 410, the length direction of which is the same as the central axis direction of the double-opening guide 200; the bottom of the second fixing part 600 is provided with a slider 610, which slides with the slide rail 410, allowing the second fixing part 600 and the multi-faceted guide assembly 100 to slide, thereby adjusting the distance between the multi-faceted guide assembly 100 and the double-opening guide 200. Of course, in other embodiments, the distance between the multi-faceted guide assembly 100 and the double-opening guide 200 can also be adjusted in other ways, depending on the actual situation, and is not limited here.

[0096] Example 2: Curved Single-Horn Flow Guide

[0097] like Figure 10 and Figure 11 As shown, the low-entropy simulator 1 provided as the second embodiment of this application differs from the first embodiment in that the double-opening guide 200 in the low-entropy simulator 1 in this embodiment is a curved single-horn guide, and the inner wall of the double-opening guide 200 is an arc along the cross-sectional line s on the central axis M, and the arc is concave towards the central axis.

[0098] This embodiment of the application enhances the connection between the negative entropy environment and the human body by setting a curved single-horn flow guide. Since the channel of the double-opening flow guide 200 is horn-shaped and the side of the channel of the double-opening flow guide 200 is a concave curved surface, the convergence of the double-opening flow guide 200 can be enhanced, making the connection between the negative entropy environment and the human body more stable.

[0099] In one specific implementation, the curvature of the arc increases first and then decreases in the direction from the first opening end 210 to the second opening end 220. This design, where the curvature increases first and then decreases, enhances the converging effect of the dual-opening flow guide 200, making the connection between the negative entropy environment and the human body more stable.

[0100] As another specific implementation, the curvature of the arc gradually increases from the first opening end 210 to the second opening end 220.

[0101] Of course, in other embodiments, the dual-opening guide 200 can also adopt other types of single-horn designs. For example, when using a curved single-horn guide, the curvature is the same at all points on the curve; or when using a conical single-horn guide, the cross-sectional line of the inner wall of the dual-opening guide 200 along the central axis has multiple segments with different slopes. As long as the cross-sectional area of ​​the first opening end 210 is smaller than the cross-sectional area of ​​the second opening end 220, the specific design can be adjusted according to the actual situation. Moreover, by adopting the design of a single-horn guide, utilizing the characteristic that one end of the single-horn guide has a large opening and the other end has a small opening, the human body can be gradually guided to establish a connection with the negative entropy environment, and the connection is established faster compared to a straight cylindrical channel.

[0102] Example 3: Conical Double-Horn Flow Guide

[0103] like Figure 12 and Figure 13As shown, the low-entropy simulator 1 provided in the third embodiment of this application differs from the first embodiment in that the dual-opening flow guide 200 in the low-entropy simulator 1 in this embodiment is a dual-horn flow guide. The dual-horn flow guide includes a first horn 230 and a second horn 240 symmetrically arranged. The small opening end of the first horn 230 and the small opening end of the second horn 240 are connected. The large opening end of the first horn 230 is the first opening end 210, and the large opening end of the second horn 240 is the second opening end 220. The diameter of the large opening end of the first horn 230 is larger than the diameter of the small opening end of the first horn 230, and the diameter of the large opening end of the second horn 240 is larger than the diameter of the small opening end of the second horn 240.

[0104] This application embodiment employs a dual-speaker flow guide design, which filters out interference from high-entropy information, making it easier for the human body to establish a connection with the multi-faceted flow guide group 100 in a low-entropy environment, further reducing the entropy value of the human body and improving the therapeutic effect.

[0105] like Figure 13 As shown in the embodiment of this application, the double-opening guide 200 is a conical double-horn guide, and the cross-sectional line S of the inner wall of each horn body 111 in the double-opening guide 200 along the central axis M is an oblique line.

[0106] Because the cone-shaped horn body 111 design enhances the guidance between the low-entropy environment inside the multi-faceted flow guide group 100 and the physiotherapy user, this embodiment of the application employs a cone-shaped double horn flow guide. The cross-sectional line along the central axis of the channel inner wall of each horn body 111 in the cone-shaped double horn flow guide is oblique, thereby enabling each horn body 111 in the cone-shaped double horn flow guide to have a good guiding effect, allowing the human body to establish a connection with the low-entropy environment inside the multi-faceted flow guide group 100 more quickly.

[0107] In some embodiments, the diameter of the small end of the horn body 111 of the dual-opening flow guide 200 is smaller than the diameter of the large end of the main horn body 111a. This design results in a smaller center size for the channel of the dual-opening flow guide 200, thereby creating a converging and focusing effect, and making the connection between the human body and the low-entropy environment inside the multi-faceted flow guide assembly 100 more stable.

[0108] In some embodiments, the central axis of the dual-horn diffuser coincides with one of the central axes of the multi-faceted diffuser 110.

[0109] like Figure 14As shown, in some embodiments, the distance L2 between the first opening end 210 and the main horn body 111a is greater than or equal to twice the diameter φ3 of the large opening end of the main horn body 111a, and less than or equal to ten times the diameter φ3 of the large opening end of the main horn body 111a.

[0110] By designing the distance between the dual-opening flow guide 200 and the multi-faceted flow guide group 100 as described above, we can avoid the weakening of the connection between the human body and the low-entropy environment due to the distance between the dual-opening flow guide 200 and the multi-faceted flow guide group 100 being too far apart, and also avoid the blockage of the connection between the human body and the low-entropy environment due to the distance between the dual-opening flow guide 200 and the multi-faceted flow guide group 100 being too close, thereby ensuring a good guiding effect between the human body and the low-entropy environment.

[0111] Example 4: Curved Double Horn Flow Guide

[0112] like Figure 15 , Figure 16 and Figure 17 As shown, the low-entropy simulator 1 provided in the fourth embodiment of this application differs from the third embodiment in that the dual-opening guide 200 in the low-entropy simulator 1 in this embodiment is a curved dual-horn guide, also called a simulated wormhole guide. The curved dual-horn guide also includes a first horn 230 and a second horn 240. Both the first horn 230 and the second horn 240 have a large opening end and a small opening end. The small opening end of the first horn 230 and the small opening end of the second horn 240 are connected. The large opening end of the first horn 230 is the first opening end 210, and the large opening end of the second horn 240 is the second opening end 220. The diameter of the large opening end of the first horn 230 is larger than the diameter of the small opening end of the first horn 230, and the diameter of the large opening end of the second horn 240 is larger than the diameter of the small opening end of the second horn 240.

[0113] In this embodiment, the curved double-horn guide has the extension direction of the channel as the length direction of the central axis. The double-opening guide 200 has an axisymmetric structure and a central axis. The inner walls of the first horn 230 and the second horn 240 are curved along the cross-sectional line on the central axis, and the curved line is concave towards the central axis.

[0114] This embodiment employs a curved double-horn diffuser to enhance the connection between the negative entropy environment and the human body. Because the channels of the curved double-horn diffuser are symmetrically shaped like two horns, its converging ability is stronger, further improving the filtering effect on high entropy information. Moreover, since the inner wall of the curved double-horn diffuser is a concave curved surface, the converging ability of the dual-opening diffuser 200 is enhanced, making the connection between the negative entropy environment and the human body more stable.

[0115] In this embodiment, the first horn 230 and the second horn 240 are symmetrically arranged, such that the first horn 230 and the second horn 240 have the same shape and size, and the sidewalls of the small opening ends of the first horn 230 and the second horn 240 intersect without gaps. The dual-opening guide device 200 adopts a symmetrical dual-horn structure, and the guiding capabilities of the second horn 240 and the first horn 230 are matched. During physiotherapy, the connection between the human body and the multi-faceted guide group 100 is more stable and less prone to interruption.

[0116] In one specific implementation, the cross-sectional lines of the inner walls of the first horn 230 and the second horn 240 along the central axis are both arcs, and the curvature of the arcs increases first and then decreases from the large end to the small end of the first horn 230 and from the large end to the small end of the second horn 240.

[0117] As another specific implementation, the cross-sectional lines of the inner walls of the first horn 230 and the second horn 240 along the central axis are both arcs, and the curvature of the arcs gradually increases from the large end to the small end of the first horn 230 and from the large end to the small end of the second horn 240.

[0118] In some embodiments, the diameter of the smaller opening of the first horn 230 and the second horn 240 is smaller than the diameter of the larger opening of the main horn body 111a. This design results in a smaller channel center for the dual-opening flow guide 200, creating a converging and focusing effect, thus stabilizing the connection between the human body and the low-entropy environment inside the multi-faceted flow guide assembly 100.

[0119] In some embodiments, the curved double-horn guide has an axisymmetric structure, and the central axis of the double-horn guide coincides with one of the central axes of the multi-faceted guide 110.

[0120] like Figure 15 As shown, in some embodiments, the distance L2 between the large end of the first horn 230 and the main horn body 111a is greater than or equal to twice the diameter φ3 of the large end of the main horn body 111a, and less than or equal to ten times the diameter φ3 of the large end of the main horn body 111a.

[0121] like Figure 16 As shown in the embodiment of this application, the first fixing part 500 is connected to the center position of the double-opening guide 200, so that the two ends of the double-opening guide 200 can maintain balance and improve the stability of the double-opening guide 200.

[0122] In other embodiments, when the dual-opening guide is a dual-horn guide, the dual-horn guide may also adopt other designs.

[0123] Furthermore, the inventive concept of this application can form many embodiments, but due to the limited space of the application documents, they cannot all be listed. Therefore, without conflict, the embodiments described above or the technical features can be arbitrarily combined to form new embodiments. After the embodiments or technical features are combined, the original technical effect will be enhanced.

[0124] The above description, in conjunction with specific optional embodiments, provides a further detailed explanation of this application and should not be construed as limiting the specific implementation of this application to these descriptions. For those skilled in the art, various simple deductions or substitutions can be made without departing from the concept of this application, and all such modifications or substitutions should be considered within the scope of protection of this application.

Claims

1. A flow guiding module, characterized in that, include: A multi-faceted flow guide group, the multi-faceted flow guide group including at least one multi-faceted flow guide, the multi-faceted flow guide including six horn bodies, each horn body forming a channel that gradually decreases in size from a large opening end to a small opening end, the large opening ends of the six horn bodies all face outward, respectively facing up, down, left, right, front, and back; the six horn bodies converge at the small opening end and are seamlessly connected, the channels of the six horn bodies are interconnected. A double-opening guide, wherein the interior of the double-opening guide is hollow, forming a channel with a first opening end and a second opening end at both ends; The first opening faces the large opening of one of the horn bodies in the multi-faceted flow guide; the horn body facing the first opening is the main horn body, the second opening is opposite to the main horn body, and the cross-sectional area of ​​the second opening is larger than the cross-sectional area of ​​the large opening of the main horn body.

2. The flow guiding module as described in claim 1, characterized in that, The dual-opening guide is a single-horn guide, and the dual-opening guide has an axisymmetric structure with the extension direction of the channel as the length direction of the central axis. Wherein, the cross-sectional area of ​​the first opening end is smaller than the cross-sectional area of ​​the second opening end.

3. The flow guiding module as described in claim 2, characterized in that, The dual-opening guide is a conical single-horn guide. The cross-sectional line of the inner wall of the dual-opening guide along the central axis is an oblique line. From the first opening end to the second opening end, the cross-sectional area of ​​the dual-opening guide gradually increases.

4. The flow guiding module as described in claim 2, characterized in that, The dual-opening guide is a curved single-horn guide, and the cross-sectional line of the inner wall of the dual-opening guide along the central axis is an arc, which is concave towards the central axis.

5. The flow guiding module as described in any one of claims 2-4, characterized in that, The cross-sectional area of ​​the first opening end is greater than the cross-sectional area of ​​the large opening end of the main horn body.

6. The flow guiding module as described in any one of claims 2-4, characterized in that, Both the first opening end and the second opening end are circular. The diameter of the second opening end is 4-10 times the diameter of the first opening end. The distance between the first opening end and the second opening end is less than the diameter of the second opening and greater than half the diameter of the second opening.

7. The flow guiding module as described in any one of claims 2-4, characterized in that, The distance between the first opening end and the main horn body is greater than or equal to 0.5 times the diameter of the large opening end of the main horn body, and less than or equal to 2 times the diameter of the large opening end of the main horn body.

8. The flow guiding module as described in claim 1, characterized in that, The dual-opening flow guide is a dual-horn flow guide, which includes a first horn and a second horn arranged symmetrically. The small opening end of the first horn and the small opening end of the second horn are connected. The large opening end of the first horn is the first opening end, and the large opening end of the second horn is the second opening end. Wherein, the diameter of the larger end of the first horn is greater than the diameter of the smaller end of the first horn, and the diameter of the larger end of the second horn is greater than the diameter of the smaller end of the second horn.

9. The flow guiding module as described in claim 8, characterized in that, The dual-opening guide is a curved double-horn guide, with the extension direction of the channel as the length direction of the central axis, and the dual-opening guide has an axisymmetric structure; The inner walls of the first and second horns have an arc-shaped cross-section along the central axis, and the arc is concave towards the central axis.

10. The flow guiding module as described in claim 8 or 9, characterized in that, The diameter of the smaller end of the first and second horns is smaller than the diameter of the larger end of the main horn body.

11. The flow guiding module as described in claim 8 or 9, characterized in that, The distance between the first opening end and the main horn body is greater than or equal to twice the diameter of the large opening end of the main horn body, and less than or equal to ten times the diameter of the large opening end of the main horn body.

12. The flow guiding module as described in claim 1, characterized in that, The multi-faceted flow guide group includes at least two multi-faceted flow guides. In the multi-faceted flow guide group, the multi-faceted flow guides are of different sizes, and the smaller multi-faceted flow guide is at least partially disposed in the throat area of ​​the larger multi-faceted flow guide. The throat area is the intersection of the channels of the six horn bodies. The large opening end of the horn body in the small-sized multifaceted flow guide is connected to the channel of the corresponding horn body in the large-sized multifaceted flow guide.

13. The flow guiding module as described in claim 1, characterized in that, The distance between the multi-faceted flow guide assembly and the double-opening flow guide is adjustable.

14. A low-entropy simulator, characterized in that, Includes the flow guiding module as described in any one of claims 1-13.

15. The low-entropy simulator as described in claim 14, characterized in that, The low-entropy simulator includes a housing, the multi-faceted flow guide group is disposed inside the housing, the housing is provided with five hollowed-out small holes and one hollowed-out large hole, the hollowed-out small holes include a plurality of arrayed first through holes, and the hollowed-out large hole includes a second through hole; The large hollowed-out portion is positioned directly opposite the large opening end of the main speaker body, and the five small hollowed-out portions are respectively positioned directly opposite the large opening ends of the other five speaker bodies in the multi-faceted guide. The diameter of the second through hole is larger than the diameter of the large end of the main horn body.

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