Low entropy analog and method of using same
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- SHENZHEN GEZHI MEDICAL TECH RES CO LTD
- Filing Date
- 2023-12-09
- Publication Date
- 2026-07-14
AI Technical Summary
The prior art is difficult to effectively reduce the entropy value of the human body and thus improve the health level.
A low-entropy simulator is designed. By setting up multiple nodes in the simulated spherical space, each node contains a simulated wormhole, allowing only low-entropy energy to pass through, thereby establishing a stable low-entropy energy connection with the human body and reducing the overall entropy value of the human body.
Through the connection with the low entropy simulator, the entropy value of the human body gradually decreases, and the body tends to be more orderly, thereby improving health levels.
Smart Images

Figure CN122396526A_ABST
Abstract
Description
Low entropy simulator and method of use thereof Technical Field
[0001] The present application relates to the field of health care equipment, and in particular to a low-entropy simulator and a method for using the same. Background Art
[0002] Entropy is a measure of the disorder of a system; the higher the entropy, the more disordered the system. The presence of high-entropy energy increases the system's entropy, while the presence of low-entropy energy decreases it. Schrödinger said that entropy reduction is the force of life; the lower the entropy at a particular point in the body, the better the state of life. Therefore, human health is closely related to entropy. When the body's entropy increases, the body tends to become disordered, deteriorating, and more susceptible to illness; conversely, when the body's entropy increases, the body improves.
[0003] If we can create an environment that maintains a stable low-entropy connection with the human body, the entropy of the human body can be reduced, achieving the goal of strengthening the body. According to the theory of general relativity, wormholes exist in the universe. Matter and disordered energy cannot pass through wormholes, but ordered energy can pass through them.
[0004] Based on the above theoretical basis, the inventor proposed a low-entropy simulator that can simulate a low-entropy environment and improve human health.
[0005] Summary of the Invention
[0006] The purpose of this application is to provide a low entropy simulator and a method of using the same to improve human health.
[0007] The present application discloses a low-entropy simulator, which includes at least one simulated spherical space, and the spherical surface of the simulated spherical space includes at least four nodes; wherein, on the spherical surface of the same simulated spherical space, all the nodes are evenly distributed; wherein, each of the nodes includes at least one simulated wormhole, and the axis of the simulated wormhole passes through the center of the sphere corresponding to the simulated spherical space.
[0008] This scheme uses at least four nodes containing simulated wormholes to form a simulated spherical space. Only low-entropy energy can pass through this simulated wormhole, preventing high-entropy energy from escaping. Once a person establishes a connection with the simulated spherical space, the person maintains a stable connection with the simulated spherical space at the low-entropy energy level. This gradually reduces the body's overall entropy, leading to a more orderly body and thus improving human health. This scheme has been verified to achieve the claimed effects.
[0009] Optionally, the simulated wormhole includes a first horn and a second horn that are symmetrically arranged, the first horn includes a large mouth end and a small mouth end, the second horn includes a large mouth end and a small mouth end, the diameter of the large mouth end of the first horn is larger than the diameter of the small mouth end of the first horn, and the diameter of the large mouth end of the second horn is larger than the diameter of the small mouth end of the second horn; the small mouth end of the first horn is connected to the small mouth end of the second horn; the cross-sectional line of the inner wall of the first horn along the central axis of the simulated wormhole is an arc, and the arc is concave toward the central axis.
[0010] Optionally, the number of the nodes located on the same sphere is six, with the center of the sphere as the origin of the three-dimensional rectangular coordinate system, and the six nodes are respectively located at the intersection of the X-axis, Y-axis and Z-axis of the three-dimensional rectangular coordinate system and the sphere.
[0011] In this solution, the arrangement of the nodes is the same no matter which direction you look at it from, whether it is the X-axis, the Y-axis, or the Z-axis. The symmetry is good, and the effect is the same no matter which direction the therapy user faces the low-entropy simulator. The operation is convenient and the consistency is good.
[0012] Optionally, the low entropy simulator has only one simulated spherical space, and all the nodes in the low entropy simulator are on the spherical surface of the simulated spherical space.
[0013] In this solution, the product has a simple structure, small size and is easy to carry.
[0014] Optionally, the node has only one simulated wormhole, and the sizes of the simulated wormholes in all the nodes located on the same sphere are the same.
[0015] Optionally, the node includes at least three simulated wormholes, and the axes of all the simulated wormholes in each node coincide and pass through the center of the simulated spherical space; wherein, the size of the simulated wormhole gradually decreases in the direction away from the center of the simulated spherical space.
[0016] In this scheme, the inner simulated wormhole in each node is large, and the outer simulated wormhole is small. After at least three simulated wormholes are connected in series, low-entropy energy tends to move from the simulated spherical space toward the human body. The human body can receive more low-entropy energy, and can more actively transform the high-entropy environment of the human body, and actively reduce the overall entropy value of the human body.
[0017] Optionally, the low-entropy simulator includes a first simulated spherical space and a second simulated spherical space, the centers of the first simulated spherical space and the second simulated spherical space coincide, and the central axes of all simulated wormholes converge at the same center; wherein the diameter of the first simulated spherical space is larger than the diameter of the second simulated spherical space, and the nodes in the first simulated spherical space correspond one-to-one to the nodes in the first simulated spherical space.
[0018] In this solution, the inner simulated wormhole is small, while the outer simulated wormhole is large. When connected in series, less low-entropy energy flows out of the second simulated spherical space, while more low-entropy energy flows into the first simulated spherical space. This gradually reduces the entropy within the low-entropy simulator, creating a closer connection with the human body at the low-entropy level and more efficiently promoting the overall transition to low-entropy energy, resulting in a better effect. Optionally, each node in the first and second simulated spherical spaces has only one simulated wormhole, and the simulated wormholes in all nodes on the surface of the first simulated spherical space are the same size, and the simulated wormholes in all nodes on the surface of the second simulated spherical space are the same size. The simulated wormholes in nodes on the surface of the first simulated spherical space are larger than those in nodes on the surface of the second simulated spherical space.
[0019] Optionally, the nodes in the first simulated spherical space and the second simulated spherical space each include at least three simulated wormholes, and the axes of all the simulated wormholes in each node coincide and pass through the center of the corresponding simulated spherical space; wherein, along the direction away from the center of the simulated spherical space, the sizes of the at least three simulated wormholes in the node are arranged in order from large to small; and, the size of the largest simulated wormhole in the first simulated spherical space is smaller than the size of the largest simulated wormhole in the second simulated spherical space.
[0020] In this scheme, the wormholes in the nodes close to the center of the sphere are large in size, and the wormholes far from the center of the sphere are small in size. After at least three simulated wormholes are connected in series, low-entropy energy tends to move from the low-entropy simulator toward the human body. The human body can receive more low-entropy energy, and can more actively transform the high-entropy environment of the human body, and actively reduce the overall entropy value of the human body.
[0021] Optionally, the low-entropy simulator includes a third simulated spherical space, a fourth simulated spherical space and a fifth simulated spherical space, the centers of the third simulated spherical space, the fourth simulated spherical space and the fifth simulated spherical space coincide, and the central axes of all simulated wormholes converge at the same center; wherein, the diameter of the third simulated spherical space is greater than the diameter of the fourth simulated spherical space, the diameter of the fourth simulated spherical space is greater than the diameter of the fifth simulated spherical space, and the nodes in the third simulated spherical space, the nodes in the fourth simulated spherical space and the nodes in the fifth simulated spherical space correspond one to one.
[0022] This scheme uses a three-layer simulated spherical space, which reduces the amount of low-entropy energy flowing out of the low-entropy simulator and increases the amount of low-entropy energy flowing in. This further reduces the entropy within the low-entropy simulator, creating a closer connection with the human body at the low-entropy level and more efficient transition to low-entropy energy, resulting in a more effective effect.
[0023] Optionally, each node in the third simulated spherical space, the fourth simulated spherical space and the fifth simulated spherical space has only one simulated wormhole, the sizes of the simulated wormholes in all nodes located on the spherical surface of the third simulated spherical space are the same, the sizes of the simulated wormholes in all nodes located on the spherical surface of the fourth simulated spherical space are the same, and the sizes of the simulated wormholes in all nodes located on the spherical surface of the fifth simulated spherical space are the same; wherein, the size of the simulated wormhole in the node located on the spherical surface of the third simulated spherical space is larger than the size of the simulated wormhole in the node located on the spherical surface of the fourth simulated spherical space; the size of the simulated wormhole in the node located on the spherical surface of the fourth simulated spherical space is larger than the size of the simulated wormhole in the node located on the spherical surface of the fifth simulated spherical space.
[0024] Optionally, the nodes in the third simulated spherical space, the fourth simulated spherical space and the fifth simulated spherical space all include at least three simulated wormholes, and the axes of all the simulated wormholes in each node coincide and pass through the center of the corresponding simulated spherical space; wherein, along the direction away from the center of the simulated spherical space, the sizes of at least three simulated wormholes in the nodes are arranged in order from large to small; and, the size of the largest simulated wormhole in the third simulated spherical space is smaller than the size of the largest simulated wormhole in the fourth simulated spherical space; the size of the largest simulated wormhole in the fourth simulated spherical space is smaller than the size of the largest simulated wormhole in the fifth simulated spherical space.
[0025] Optionally, the low entropy simulator further includes an energy source, which is disposed at the center of the simulated spherical space.
[0026] Optionally, the low entropy simulator includes a shell, the node is fixed inside the shell, and a hollow portion is provided in an area of the shell corresponding to the node.
[0027] In this solution, the shell protects each node to improve the stability of each node, and the hollow part is designed to avoid the existence of the shell affecting the effect of wormhole simulation.
[0028] Optionally, the shell is spherical, the hollow portion is circular, and the hollow portion and the node correspond one-to-one; the shell includes an upper shell and a lower shell, and the edge of the upper shell is fixed to the edge of the lower shell; the low-entropy simulator also includes a plurality of insertion strips, each of which is provided with at least one mounting slot, and the simulated wormholes in the nodes are fixed one-to-one on the mounting slot; each of the hollow portions is provided with a socket, and one end of the insertion strip is inserted into the socket for fixation, and the axis of the simulated wormhole fixed on the insertion strip passes through the center of the corresponding hollow portion.
[0029] In this solution, the simulated wormholes are first fixed one by one on the corresponding installation slots, and then the inserts are inserted into the sockets in the hollow area. Finally, the upper shell and the lower shell are matched to complete the assembly of the entire product. The assembly process is simple, and the assembled product does not leak the internal structure, which makes the overall visual effect of the low-entropy simulator good.
[0030] Optionally, an ear is provided in the upper shell, the ear protrudes from the surface of the upper shell, the two ends of the ear are open and the interior is hollow, and it passes through the interior and exterior of the upper shell; the low-entropy simulator also includes a feeding component, the feeding component includes an ear cover, a connecting rod and a loading bead, the side wall of the ear cover matches the inner wall of the ear, one end of the connecting rod is connected to the ear cover, and the other end of the connecting rod is connected to the loading bead, and the loading bead is used to adsorb the energy source; wherein, when the ear cover is matched with the ear, the loading bead is located at the center of the simulated spherical space.
[0031] In this embodiment, the cylindrical ear cover and the tubular insert ear are designed to fit together to limit the insertion direction of the feeding assembly. This prevents the feeding bead or connecting rod from contacting the internal components of the housing during the insertion of the ear cover and affecting the stability of the structure. Optionally, the insert ear is located between three adjacent hollow portions.
[0032] In this solution, as the ear cover is inserted into the inserting ear, the connecting rod and the loading bead have a large space for movement and are not likely to collide with the inserting strip in the shell.
[0033] The present application also discloses a method for using the low entropy simulator, comprising the steps of:
[0034] Point the low entropy simulator directly at the therapy user;
[0035] The low entropy simulator is removed after a preset time.
[0036] Optionally, the step of removing the low entropy simulator after a preset time includes:
[0037] The low entropy simulator is removed after being kept for a first preset time.
[0038] Optionally, the step of removing the low entropy simulator after a preset time includes:
[0039] Keeping the low entropy simulator for a second preset time;
[0040] Moving the low entropy simulator in a direction away from the user being treated at a first preset speed for a third preset time; and
[0041] The low entropy simulator is removed.
[0042] Optionally, before the step of pointing the low-entropy simulator directly at the user undergoing physical therapy, an energy source is first added to the low-entropy simulator. The beneficial effect of this solution is that at least four nodes containing simulated wormholes are used to enclose a simulated spherical space, through which only low-entropy energy can pass, while high-entropy energy cannot escape. Once a connection is established with a person, a stable connection is established between the person and the simulated spherical space only at the low-entropy energy level. The overall entropy value of the human body will gradually decrease, and the body will tend to be more orderly, thereby achieving the purpose of improving human health. BRIEF DESCRIPTION OF THE DRAWINGS
[0043] The included drawings are used to provide a further understanding of the embodiments of the present application, which constitute a part of the specification, are used to illustrate the implementation methods of the present application, and together with the text description, explain the principles of the present application. Obviously, the drawings described below are only some embodiments of the present application. For those of ordinary skill in the art, other drawings can be obtained based on these drawings without inventive work. In the drawings:
[0044] FIG1 is a schematic diagram of a low entropy simulator provided in a first embodiment of the present application;
[0045] FIG2 is a schematic diagram of a simulated wormhole provided in the first embodiment of the present application;
[0046] FIG3 is a schematic diagram of the external structure of a low entropy simulator provided in the first embodiment of the present application;
[0047] FIG4 is a schematic diagram of an explosion of a low entropy simulator provided in the first embodiment of the present application;
[0048] FIG5 is a schematic diagram of a housing provided in the first embodiment of the present application;
[0049] FIG6 is a schematic cross-sectional view of FIG5 taken along line AA';
[0050] FIG7 is a flow chart of a method for using a low entropy simulator provided in the first embodiment of the present application;
[0051] FIG8 is a further schematic diagram based on FIG7 ;
[0052] FIG9 is a further schematic diagram based on FIG7 ;
[0053] FIG10 is a schematic diagram of a low entropy simulator provided in a second embodiment of the present application;
[0054] FIG11 is a schematic diagram of a cutting provided in the second embodiment of the present application;
[0055] FIG12 is a cross-sectional schematic diagram of a low entropy simulator provided in a second embodiment of the present application;
[0056] FIG13 is a schematic diagram of a low entropy simulator provided in a third embodiment of the present application;
[0057] FIG14 is a schematic diagram of a cutting provided in the third embodiment of the present application;
[0058] FIG15 is a schematic diagram of a low entropy simulator provided in a fourth embodiment of the present application;
[0059] FIG16 is a schematic diagram of a cutting strip provided in the fourth embodiment of the present application;
[0060] FIG17 is a schematic diagram of a low entropy simulator provided in a fifth embodiment of the present application;
[0061] FIG. 18 is a schematic diagram of an insert provided in accordance with a fifth embodiment of the present application.
[0062] Among them, 10, low entropy simulator; 100, simulated spherical space; 100A, first simulated spherical space; 100B, second simulated spherical space; 100C, third simulated spherical space; 100D, fourth simulated spherical space; 100E, fifth simulated spherical space; M, node; N simulated wormhole; N1, first speaker; N2, second speaker; 300, shell; 310 hollow part; 311, socket; 320, upper shell; 321, ear plug; 330, lower shell; 340, support foot; 400, insertion strip; 410, installation slot; 500, feeding assembly; 510, ear cover; 520, connecting rod; 530, feeding bead. DETAILED DESCRIPTION
[0063] It should be understood that the terms used herein, the specific structures and functional details disclosed are only for describing specific embodiments and are representative. However, the present application can be implemented in many alternative forms and should not be construed as being limited to the embodiments described herein.
[0064] The present application is described in detail below with reference to the accompanying drawings and optional embodiments.
[0065] Example 1:
[0066] Figure 1 is a low-entropy simulator 10 provided in an embodiment of the present application. As shown in Figure 1, the low-entropy simulator 10 adopts a single-layer spherical design, that is, the low-entropy simulator 10 only includes a simulated spherical space 100, and at least four nodes M are provided on the spherical surface of the simulated spherical space 100, and at least four nodes M are evenly distributed on the spherical surface of the simulated spherical space 100; wherein each of the nodes M is a simulated wormhole N, the simulated wormhole N is an axially symmetric structure, and the central axis of all simulated wormholes N passes through the center of the simulated spherical space 100.
[0067] This embodiment of the present application utilizes at least four nodes M containing simulated wormholes N to enclose a simulated spherical space 100. Only low-entropy energy can pass through this space, preventing high-entropy energy from escaping. Once a person establishes a connection with this space, the person and the simulated spherical space 100 establish a stable connection only at the low-entropy energy level. This gradually reduces the overall entropy of the human body, leading to a more orderly body, thereby improving human health. This solution has been verified to achieve the claimed effects.
[0068] In an embodiment of the present application, six nodes M are specifically provided on the spherical surface of the simulated spherical space 100, that is, there are six simulated wormholes N in the low-entropy simulator 10. When the low-entropy simulator 10 is upright, the six simulated wormholes N are respectively located at the top, bottom, left, right, front and back of the simulated spherical space 100.
[0069] Alternatively, it can be expressed as follows: with the center of the simulated spherical space 100 as the origin of a three-dimensional rectangular coordinate system, the six simulated wormholes N are located at the intersections of the X-axis, Y-axis, and Z-axis of the three-dimensional rectangular coordinate system with the spherical surface. With the radius of the simulated spherical space 100 being R, the coordinates of the six simulated wormholes N are (R, 0, 0), (-R, 0, 0), (0, R, 0), (0, -R, 0), (0, 0, R), and (0, 0, -R).
[0070] After adopting the above design, all nodes M are evenly distributed on the spherical surface of the simulated spherical space 100. No matter which direction you look from, whether it is the X-axis, the Y-axis or the Z-axis, the arrangement of the nodes M is the same, with good symmetry. No matter which direction the therapy user faces the low-entropy simulator 10, the effect is the same, the operation is convenient and the consistency is good.
[0071] Of course, in the embodiment of the present application, the number of nodes M on the spherical surface of the simulated spherical space 100 may not be six, but may be four, five, seven, eight, etc., depending on the actual situation. However, regardless of the number of nodes M on the spherical surface of the simulated spherical space 100, these nodes M are evenly distributed on the spherical surface of the simulated spherical space 100, and a sphere of a certain size can be formed by these nodes M.
[0072] It is understood that all nodes M in the embodiments of the present application are not located on the same plane. The "simulated spherical space 100" mentioned in the embodiments of the present application is a virtual spherical structure, a spherical surface determined by the positions of all nodes M. "All nodes M are evenly distributed" means that the distance between two adjacent nodes M on the spherical surface of the simulated spherical space 100 is the same. In the embodiments of the present application, the spacing between two opposing nodes M is 20-60 mm, preferably 30-50 mm.
[0073] Figure 2 is a schematic diagram of a simulated wormhole. As shown in Figure 2, the simulated wormhole N includes a first horn N1 and a second horn N2 that are symmetrically arranged. The first horn N1 includes a large mouth end and a small mouth end, and the second horn N2 includes a large mouth end and a small mouth end. The diameter of the large mouth end of the first horn N1 is larger than the diameter of the small mouth end of the first horn N1, and the diameter of the large mouth end of the second horn N2 is larger than the diameter of the small mouth end of the second horn N2; the small mouth end of the first horn N1 is connected to the small mouth end of the second horn N2; the cross-sectional line of the inner wall of the first horn N1 along the central axis of the simulated wormhole N is an arc, and the arc is concave toward the central axis.
[0074] It should be noted that the inner wall of the simulated wormhole N may be a smooth surface, or a surface with strip-shaped protruding guide lines or strip-shaped grooved guide lines.
[0075] As is well known, a wormhole can have any shape, but is often described as a pipe or tunnel in which space is curved into a surface, shortening the distance between two points. In this embodiment, the small openings of the first and second speakers N1 and N2 simulate the pipe or tunnel structure of the wormhole N; the large openings of the first and second speakers N1 and N2 simulate the distorted spacetime at both ends of the pipe.
[0076] As an implementation method of simulating a wormhole, the small mouth end of the first speaker N1 is directly connected to the small mouth end of the second speaker N2, and the connection between the small mouth end of the first speaker N1 and the small mouth end of the second speaker N2 is smoothly transitioned.
[0077] As another embodiment of the simulated wormhole, the simulated wormhole N further includes a throat; the throat is hollow inside and open at both ends; the two ends of the throat are smoothly connected to the small mouth end of the first horn N1 and the small mouth end of the second horn N2 respectively.
[0078] Furthermore, the cross-sectional lines of the inner walls of the first horn N1 and the second horn N2 along the central axis of the simulated wormhole N are arcs, and the curvatures of the arcs of the first horn N1 and the second horn N2 increase from the large mouth end to the small mouth end.
[0079] Moreover, a tangent line of the arc of the first speaker N1 corresponding to the endpoint of the large mouth end of the first speaker N1 tends to be perpendicular to the central axis; the arc approaches the central axis toward the small mouth end of the first speaker N1; a tangent line of the arc of the second speaker N2 corresponding to the endpoint of the large mouth end of the second speaker N2 tends to be perpendicular to the central axis; the arc approaches the central axis toward the small mouth end of the second speaker N2.
[0080] In the embodiment of the present application, the six simulated wormholes N are of the same size, and the diameter of the large mouth of the simulated wormhole N is 8-12 mm, the length of the simulated wormhole N is 5-9 mm, and the diameter of the throat of the simulated wormhole N is 0.8-1.2 mm.
[0081] In an embodiment of the present application, all simulated wormholes N are fixed on a shell 300. Specifically, as shown in Figures 3 and 4, the low-entropy simulator 10 includes a shell 300, which is spherical. The simulated wormhole N is fixed inside the shell 300, and the shell 300 is provided with a hollow portion 310 in the area corresponding to the node M. The hollow portion 310 is a hole-like structure arranged in a circular array, and the position and number of the hollow portion 310 and the node M correspond one to one.
[0082] Moreover, the area of the hollow portion 310 is larger than the area of the large end of the simulated wormhole N. The hollow portion 310 completely covers the simulated wormhole N, preventing the existence of the shell 300 from affecting the function of the simulated wormhole N.
[0083] Among them, the shell 300 includes an upper shell 320 and a lower shell 330. The upper shell 320 and the lower shell 330 divide the shell 300 into two parts from the middle area. The edge of the upper shell 320 is fixed to the edge of the lower shell 330. Specifically, it can be connected by snapping, bonding, screws, etc. Here, it is preferably connected by ultrasonic welding to prevent the upper shell 320 and the lower shell 330 from falling off, and to reduce the gap between the upper shell 320 and the lower shell 330, making the product more beautiful.
[0084] Furthermore, when the low-entropy simulator 10 is aligned, the hollow portions 310 located in front, behind, to the left and to the right of the shell 300 are an integrated structure with the upper shell 320. This can reduce the assembly process, facilitate the alignment of the upper shell 320 and the lower shell 330, and improve assembly efficiency.
[0085] As shown in Figures 5 and 6 , the low-entropy simulator 10 also includes six inserts 400, each of which is provided with a mounting slot 410. Six simulated wormholes N are fixed to the mounting slots 410 of the six inserts 400, one for each. Each hollow portion 310 has a socket 311 positioned within it, facing the center of the simulated spherical space 100. One end of the insert 400 is inserted into the socket 311 for securement. After assembly, the axis of the simulated wormhole N fixed to the insert 400 passes through the center of the corresponding hollow portion 310.
[0086] During assembly, first fix the simulated wormholes N one by one on the corresponding mounting slots 410, then insert the insert strip 400 into the socket 311 in the hollow portion 310 area, and finally align the upper shell 320 and the lower shell 330 to complete the assembly of the entire product. The assembly process is simple, and the assembled product does not leak the internal structure, so that the overall visual effect of the low-entropy simulator 10 is good.
[0087] Furthermore, as shown in FIG4 , the upper shell 320 is provided with an ear 321 , which protrudes outward from the surface of the upper shell 320 . The ear 321 is in the shape of a circular tube with both ends open and a hollow interior, and passes through the interior and exterior of the upper shell 320 .
[0088] Correspondingly, as shown in Figures 3 and 4 , the low-entropy simulator 10 further includes a feeding assembly 500, which includes an ear cover 510, a connecting rod 520, and a loading bead 530. The ear cover 510 is cylindrical. When the ear cover 510 is fixed to the plug ear 321, the outer wall of the ear cover 510 is in contact with the inner wall of the plug ear 321, and the bottom of the ear cover 510 protrudes from the outside of the plug ear 321 to facilitate removal of the ear cover 510. One end of the connecting rod 520 is connected to the ear cover 510, and the other end of the connecting rod 520 is connected to the loading bead 530. When the ear cover 510 is engaged with the plug ear 321, the loading bead 530 is located at the center of the simulated spherical space 100.
[0089] The loading beads 530 are used to absorb energy sources, wherein the loading beads 530 are wooden beads, and the energy source (not shown in the figure) is essential oil.
[0090] When using the low entropy simulator 10, first pull the ear cover 510 off the ear plug 321 to expose the loading bead 530, drop essential oil on the loading bead 530, and then insert the ear cover 510 along the length direction of the ear plug 321. Once the ear cover 510 is fixed, the low entropy simulator 10 can be put into use.
[0091] In the embodiment of the present application, the cylindrical ear cover 510 and the tubular plug ear 321 are designed to be plugged together to limit the insertion direction of the feeding component 500, thereby preventing the feeding bead 530 or the connecting rod 520 from touching the internal structural parts of the shell 300 during the insertion of the ear cover 510 into the plug ear 321, thereby affecting the stability of the structure.
[0092] Furthermore, the insertion ear 321 is located between three adjacent hollow portions 310 and at the center of the area enclosed by the three adjacent hollow portions 310. It should be noted that the three adjacent hollow portions 310 here do not refer to three adjacent hollow portions 310 whose centers are on the same plane, but rather three hollow portions 310 whose centers are on different planes.
[0093] At this time, as the ear cover 510 is inserted into the inserting ear 321 , the connecting rod 520 and the loading bead 530 have a large space for movement and are less likely to collide with the inserting strip 400 in the housing 300 .
[0094] In the embodiment of the present application, four supporting feet 340 are further provided on the bottom of the lower shell 330. The supporting feet 340 are arranged in a square shape on the bottom of the lower shell 330 and are used to support and fix the housing 300 and the structure inside the housing 300. Of course, the bottom of the lower shell 330 can also have only three or five or more supporting feet 340, as long as the product can be placed stably.
[0095] In the embodiment of the present application, the inserting ear 321 may not protrude outward from the surface of the upper shell 320, but may protrude inward from the surface of the upper shell 320, or may protrude both outward and inward from the surface of the upper shell 320. Furthermore, the cross-section of the inserting ear 321 and the ear cover 510 may not be circular, but may be triangular, square, polygonal, or other shapes.
[0096] Of course, in the embodiment of the present application, the low-entropy simulator 10 may also not have the shell 300, and each simulated wormhole N may be fixed by a bracket, a frame and other structures.
[0097] In the embodiment of the present application, the energy source may also adopt other structures besides essential oil, such as moxa sticks, light sources, etc.
[0098] As shown in FIG7 , the embodiment of the present application further discloses a method for using the low entropy simulator, comprising the steps of:
[0099] S1: Direct the low entropy simulator towards the user;
[0100] S2: removing the low entropy simulator after a preset time.
[0101] Before step S1 , an energy source is first added into the low entropy simulator 10 .
[0102] As a specific implementation, as shown in FIG8 , in step S2, the low entropy simulator is left for a first preset time and then removed. At this time, the method for using the low entropy simulator is specifically as follows:
[0103] S01: Remove the ear cover of the low entropy simulator and add essential oil to the feeding beads;
[0104] S02: Align the ear cover with the ear plug and insert the upper bead into the housing;
[0105] S1: Direct the low entropy simulator towards the user;
[0106] S21: After the low entropy simulator is left for a first preset time, the low entropy simulator is removed.
[0107] Wherein, the first preset time is 10-30 minutes.
[0108] It should be noted that in step S1, a hollow portion 310 on the shell 300 is directed toward the user for physical therapy. Specifically, the hollow portion 310 located right in front of the shell 300 is directed toward the user for physical therapy.
[0109] As another specific embodiment, as shown in FIG9 , in step S2, the low entropy simulator is first stopped for a second preset time, then the low entropy simulator is moved away from the user at a first preset speed for a third preset time, and finally the low entropy simulator is removed. In this case, the method of using the low entropy simulator is specifically as follows:
[0110] S01: Remove the ear cover of the low entropy simulator and add essential oil to the feeding beads;
[0111] S02: Align the ear cover with the ear plug and insert the upper bead into the housing;
[0112] S1: Direct the low entropy simulator towards the user;
[0113] S22: keeping the low entropy simulator for a second preset time;
[0114] S23: moving the low entropy simulator in a direction away from the user for treatment at a first preset speed for a third preset time;
[0115] S24: Remove the low entropy simulator.
[0116] The second preset time is 5-30s, the first preset speed is 4-10mm / s, and the third preset time is 150-250s.
[0117] Example 2:
[0118] Figure 10 is a schematic diagram of a low-entropy simulator 10 provided in the second embodiment of the present application. As shown in Figure 10 , the difference from the first embodiment is that the low-entropy simulator 10 in the embodiment of the present application adopts a double-layer spherical design.
[0119] Specifically, the low-entropy simulator 10 includes a first simulated spherical space 100A and a second simulated spherical space 100B. The centers of the first simulated spherical space 100A and the second simulated spherical space 100B coincide. The central axes of all simulated wormholes N converge at the same center. That is, the central axes of all simulated wormholes N in the first simulated spherical space 100A and the central axes of all simulated wormholes N in the second simulated spherical space 100B intersect at a single point, namely, the center of the first simulated spherical space 100A or the second simulated spherical space 100B.
[0120] The diameter of the first simulated spherical space 100A is greater than the diameter of the second simulated spherical space 100B, and the nodes M in the first simulated spherical space 100A correspond one-to-one with the nodes M in the first simulated spherical space 100A. Furthermore, each node M in the first simulated spherical space 100A and the second simulated spherical space 100B has only one simulated wormhole N. The size of the simulated wormhole N in all nodes M located on the spherical surface of the first simulated spherical space 100A is the same, and the size of the simulated wormhole N in all nodes M located on the spherical surface of the second simulated spherical space 100B is the same.
[0121] The size of the simulated wormhole N in the node M located on the spherical surface of the first simulated spherical space 100A is greater than the size of the simulated wormhole N in the node M located on the spherical surface of the second simulated spherical space 100B.
[0122] The present embodiment utilizes a double-layered simulated spherical space 100, with the inner simulated wormhole N being smaller and the outer simulated wormhole N being larger. After the two are connected in series, less low-entropy energy flows outward from the second simulated spherical space 100B, while more low-entropy energy flows into the first simulated spherical space 100A from the outside. This gradually reduces the entropy value within the low-entropy simulator 10, creating a closer connection with the human body at the low-entropy level, more efficiently promoting the overall transformation of the human body toward low-entropy energy, and achieving a better effect.
[0123] In the embodiment of the present application, both the first simulated spherical space 100A and the second simulated spherical space 100B have six simulated wormholes N. Of course, more than four simulated wormholes N can be provided depending on the actual situation. The simulated wormholes N in the first simulated spherical space 100A correspond one-to-one with the simulated wormholes N in the second simulated spherical space 100B in both number and position. The axes of the simulated wormholes N in the first simulated spherical space 100A and the simulated wormholes N in the second simulated spherical space 100B are collinear and pass through the center of the first simulated spherical space 100A or the second simulated spherical space 100B, respectively. As shown in Figures 10 and 11, in the embodiment of the present application, the simulated wormholes in the first simulated spherical space 100A are designated by N1, and the simulated wormholes in the second simulated spherical space 100B are designated by N2. The size of the simulated wormholes N2 in the second simulated spherical space 100B is 65%-90% of the size of the simulated wormholes N1 in the first simulated spherical space 100A, and specifically can be 80%. In the embodiment of the present application, the distance L01 between the simulated wormhole N1 in the first simulated spherical space 100A and the simulated wormhole N2 in the second simulated spherical space 100B is 1-5 times the length L1 of the simulated wormhole in the first simulated spherical space 100A, and specifically can be 3 times.
[0124] In the embodiment of the present application, the diameter of the second simulated spherical space 100B is 20-60 mm, preferably 30-50 mm, and specifically can be 40 mm.
[0125] Similarly, the simulated wormholes in this embodiment are also disposed within the housing 300, as shown in Figures 11 and 12. Unlike the first embodiment, each insert 400 in this embodiment is provided with two spaced-apart mounting slots 410. The simulated wormholes in the second simulated spherical space 100B are secured within the mounting slot 410 on the insert 400 near the center, while the simulated wormholes in the first simulated spherical space 100A are secured within the mounting slot 410 on the insert 400 away from the center. Furthermore, the dimensions, spacing, and positions of the mounting slots 410 on the insert 400 are adaptively designed to suit the corresponding simulated wormholes.
[0126] Example 3:
[0127] FIG13 is a schematic diagram of a low-entropy simulator provided in the third embodiment of the present application. As shown in FIG13 , the difference from the first embodiment is that the low-entropy simulator 10 in the embodiment of the present application adopts a three-layer spherical design.
[0128] Specifically, the low-entropy simulator 10 includes a third simulated spherical space 100C, a fourth simulated spherical space 100D and a fifth simulated spherical space 100E. The centers of the third simulated spherical space 100C, the fourth simulated spherical space 100D and the fifth simulated spherical space 100E coincide, and the central axes of all simulated wormholes converge at the same center.
[0129] Among them, the diameter of the third simulated spherical space 100C is greater than the diameter of the fourth simulated spherical space 100D, the diameter of the fourth simulated spherical space 100D is greater than the diameter of the fifth simulated spherical space 100E, and the node M in the third simulated spherical space 100C, the node M in the fourth simulated spherical space 100D and the node M in the fifth simulated spherical space 100E correspond one to one.
[0130] Moreover, the sizes of the simulated wormholes N in each simulated spherical space 100 are the same. Specifically, the nodes M in the third simulated spherical space 100C, the fourth simulated spherical space 100D and the fifth simulated spherical space 100E each have only one simulated wormhole N. The sizes of the simulated wormholes N in all nodes M located on the spherical surface of the third simulated spherical space 100C are the same, the sizes of the simulated wormholes N in all nodes M located on the spherical surface of the fourth simulated spherical space 100D are the same, and the sizes of the simulated wormholes N in all nodes M located on the spherical surface of the fifth simulated spherical space 100E are the same.
[0131] As shown in Figures 13 and 14, in an embodiment of the present application, the simulated wormhole located in the third simulated spherical space 100C is represented by N3, the simulated wormhole located in the fourth simulated spherical space 100D is represented by N4, and the simulated wormhole located in the fifth simulated spherical space 100E is represented by N5.
[0132] The size of the simulated wormhole N gradually decreases as it moves outward from the center of the sphere. Specifically, the size of the simulated wormhole N3 located at the node M on the spherical surface of the third simulated spherical space 100C is larger than the size of the simulated wormhole N4 located at the node M on the spherical surface of the fourth simulated spherical space 100D. The size of the simulated wormhole N4 located at the node M on the spherical surface of the fourth simulated spherical space 100D is larger than the size of the simulated wormhole N5 located at the node M on the spherical surface of the fifth simulated spherical space 100E.
[0133] In the embodiment of the present application, no matter the third simulated spherical space 100C, the fourth simulated spherical space 100D or the fifth simulated spherical space 100E, they all have four or more simulated wormholes, specifically six simulated wormholes. The simulated wormholes in the third simulated spherical space 100C, the fourth simulated spherical space 100D and the fifth simulated spherical space 100E correspond one to one in number and position, and the axis of the simulated wormhole N3 in the third simulated spherical space 100C is on the same straight line as the axis of the simulated wormhole N4 in the fourth simulated spherical space 100D and the axis of the simulated wormhole N5 in the fifth simulated spherical space 100E, and pass through the center of the sphere.
[0134] In this embodiment of the present application, the size of the simulated wormhole N5 in the fifth simulated spherical space 100E is a preset ratio of the size of the simulated wormhole N4 in the fourth simulated spherical space 100D. The size of the simulated wormhole N4 in the fourth simulated spherical space 100D is a preset ratio of the size of the simulated wormhole N3 in the third simulated spherical space 100C. The preset ratio is between 65% and 90%, and specifically can be 80%.
[0135] In this embodiment of the present application, the distance L03 between the simulated wormhole N3 in the third simulated spherical space 100C and the simulated wormhole N4 in the fourth simulated spherical space 100D is a preset multiple of the length L3 of the simulated wormhole in the third simulated spherical space 100C. The distance L04 between the simulated wormhole N4 in the fourth simulated spherical space 100D and the simulated wormhole N5 in the fifth simulated spherical space 100E is a preset multiple of the length L4 of the simulated wormhole in the fourth simulated spherical space 100D. The preset multiple is between 1 and 5, and can specifically be 3.
[0136] In the embodiment of the present application, the diameter of the fifth simulated spherical space 100E is 20-60 mm, preferably 30-50 mm, and specifically can be 40 mm.
[0137] Similarly, the simulated wormholes in this embodiment are also disposed within the housing, as shown in FIG14 . Unlike the first embodiment, each insert 400 in this embodiment is provided with three spaced-apart mounting slots 410. The simulated wormhole in the fifth simulated spherical space 100E is secured in the mounting slot 410 closest to the center of the insert 400. The simulated wormhole in the third simulated spherical space 100C is secured in the mounting slot 410 farthest from the center of the insert 400. The simulated wormhole in the fourth simulated spherical space 100D is secured in the mounting slot 410 located between these two mounting slots 410. Furthermore, the dimensions, spacing, and positions of the mounting slots 410 on the insert 400 are adaptively designed to suit the corresponding simulated wormholes.
[0138] Example 4:
[0139] FIG15 is a schematic diagram of a low-entropy simulator provided in the fourth embodiment of the present application. As shown in FIG15 , the difference from the first embodiment is that, although a single-layer spherical design is adopted in the embodiment of the present application, each node M is composed of three simulated wormholes, namely simulated wormhole N1-1, simulated wormhole N1-2, and simulated wormhole N1-3; simulated wormhole N1-1, simulated wormhole N1-2, and simulated wormhole N1-3 are arranged in sequence, and the large end of simulated wormhole N1-1 is opposite to the large end of simulated wormhole N1-2, and the large end of simulated wormhole N1-2 is opposite to the large end of simulated wormhole N1-3. Of course, in the embodiment of the present application, each node M can also be composed of more than four simulated wormholes.
[0140] Moreover, the axes of the simulated wormhole N1-1, the simulated wormhole N1-2 and the simulated wormhole N1-3 coincide and pass through the center of the simulated spherical space 100; wherein, the size of the simulated wormhole gradually decreases in the direction away from the center of the simulated spherical space 100, that is, the size of the simulated wormhole N1-1 is smaller than the size of the simulated wormhole N1-2, and the size of the simulated wormhole N1-2 is smaller than the size of the simulated wormhole N1-3.
[0141] In the low-entropy simulator 10 provided in the embodiment of the present application, the wormhole near the center of the sphere in each node M is large in size, and the wormhole away from the center of the sphere is small in size. After the three simulated wormholes are connected in series, the low-entropy energy tends to move from the low-entropy simulator 10 toward the human body. The human body can receive more low-entropy energy, can more actively transform the high-entropy environment of the human body, and actively reduce the overall entropy value of the human body.
[0142] In the embodiment of the present application, the low-entropy simulator 10 has only one simulated spherical space 100, which has six nodes M. Each node M has three simulated wormholes connected in series. As the distance from the center of the sphere increases, the size of the simulated wormholes in each node M gradually decreases. That is, the size of the simulated wormholes in the nodes M close to the center of the sphere is the largest, and the size of the simulated wormholes far from the center of the sphere is the smallest.
[0143] In the embodiment of the present application, at each node M, the spacing between two adjacent simulated wormholes is equal to 0.5-1.5 times the length of the smaller simulated wormhole, and specifically, may be 1 times the length of the smaller simulated wormhole. Specifically, the spacing L011 between simulated wormholes N1-1 and N1-2 is equal to 1 times the length L11 of simulated wormhole N1-1; and the spacing L012 between simulated wormholes N1-2 and N1-3 is equal to 1 times the length L12 of simulated wormhole N1-2.
[0144] In this embodiment of the present application, the diameter of the simulated spherical space 100 is 20-60 mm, preferably 30-50 mm, and specifically 40 mm. The simulated wormholes in this embodiment are also disposed within the housing, as shown in Figure 16 . Unlike the first embodiment, each insert 400 in this embodiment is provided with three spaced-apart mounting slots 410. The three simulated wormholes at each node M correspond to the three mounting slots 410 of one insert 400. The dimensions, spacing, and position of the mounting slots 410 on each insert 400 are adaptively designed to suit the simulated wormholes.
[0145] Embodiment 5:
[0146] Figure 17 is a schematic diagram of a low-entropy simulator provided by the fifth embodiment of the present application. As shown in Figure 17, the difference from the fourth embodiment is that a double-layer spherical design is adopted in the embodiment of the present application. Similarly, the nodes M on each layer of the sphere have three simulated wormholes connected in series. Of course, according to specific needs, the nodes M on each layer of the sphere can also be designed to be composed of more than four simulated wormholes.
[0147] Specifically, the low-entropy simulator 10 includes a first simulated spherical space 100A and a second simulated spherical space 100B. Each node M in the first simulated spherical space 100A includes three simulated wormholes, N1-1, N1-2, and N1-3. Each node M in the second simulated spherical space 100B includes three simulated wormholes, N2-1, N2-2, and N2-3. Moreover, in the two corresponding nodes M in the first simulated spherical space 100A and the second simulated spherical space 100B, the axes of the six simulated wormholes, N1-1, N1-2, N1-3, N2-1, N2-2, and N2-3, coincide and pass through the center of the corresponding simulated spherical space 100.
[0148] In the direction away from the center of the simulated spherical space 100, the three simulated wormholes at node M are arranged in descending order. Specifically, the three simulated wormholes N1-3, N1-2, and N1-1 are arranged in descending order. Similarly, the three simulated wormholes N2-3, N2-2, and N2-1 are arranged in descending order. Furthermore, the largest simulated wormhole in the first simulated spherical space 100A is smaller than the largest simulated wormhole in the second simulated spherical space 100B. Specifically, the size of simulated wormhole N1-3 is smaller than the size of simulated wormhole N2-3.
[0149] Among them, the nodes M in the first simulated spherical space 100A and the second simulated spherical space 100B correspond one to one, and the axes of all simulated wormholes on a node M in the first simulated spherical space 100A coincide with the axes of all simulated wormholes on the corresponding node M in the second simulated spherical space 100B.
[0150] Regarding the design of the simulated wormhole in each node M, reference may be made to the description in the fourth embodiment, which will not be elaborated here.
[0151] Similarly, the simulated wormholes in this embodiment of the present application are also disposed within the housing, as shown in FIG18 . Unlike the fourth embodiment, each insert 400 in this embodiment is provided with six spaced-apart mounting slots 410. The simulated wormholes corresponding to nodes M in the first simulated spherical space 100A and the second simulated spherical space 100B are all located within the six mounting slots 410 of a single insert 400. Furthermore, the dimensions, spacing, and positions of the mounting slots 410 on each insert 400 are adaptively designed to suit the corresponding simulated wormholes.
[0152] Of course, in the present application, the low-entropy simulator 10 further includes four or more simulated spherical spaces 100, and the number of simulated wormholes in each node M is one; or, the low-entropy simulator 10 further includes three or more simulated spherical spaces 100, and the number of simulated wormholes in each node M is three or more; or, in the low-entropy simulator 10, there are both simulated spherical spaces 100 in which the node M is a simulated wormhole and simulated spherical spaces 100 in which the node M is three or more wormholes. The specific selection is made according to the actual situation.
[0153] In addition, the present application also provides the following specific test cases to demonstrate the use effect of the low entropy simulator 10 in the present application:
[0154] First, 20 healthy subjects were randomly divided into two groups of 10 each. Each subject was assigned a computer-generated random number between 1 and 99. The random numbers were arranged from largest to smallest. The ten subjects with the smallest numbers formed the experimental group, while the ten subjects with the largest numbers formed the control group. Using this grouping method, the inventors obtained the following results: the experimental group consisted of 4 males and 6 females, and the control group consisted of 5 males and 5 females.
[0155] It should be added that the criteria for subjects are: 1. Age 18-35 years old; 2. Signed informed consent; 3. Able to provide detailed contact information, no intention to migrate in the short term, and willing to cooperate with follow-up; 4. No history of chronic diseases such as heart disease, hypertension, diabetes, as well as acute diseases, infectious diseases, and malignant tumors; 5. No other reasons for the current pain; 6. No serious mental or psychological diseases; 7. No plantar ulcers or wounds; 8. Not pregnant or breastfeeding women; 9. No history of alcohol or drug abuse; 10. Not participating in other clinical studies.
[0156] Testing process:
[0157] For the subjects in the experimental group, the subjects were asked to relax and lie flat. After the Yongquan acupoints on both feet were stimulated accordingly, two low-entropy simulators in Example 1 were placed 5-10 cm away from the Yongquan acupoints, and the hollow part in front of the low-entropy simulator was facing the Yongquan acupoints. The two low-entropy simulators corresponded to the Yongquan acupoints on both feet respectively, and then the subjects were asked to lie quietly for 20 minutes.
[0158] For the people in the control group, the subjects were also asked to relax and lie flat. After the Yongquan acupoints on both feet were stimulated accordingly, two sham instruments (the difference from the low-entropy simulator in Example 1 is that the sham instruments have no nodes and simulated wormholes, only a shell) were placed 5-10 cm away from the Yongquan acupoints, with the hollow part in front of the sham instruments facing the Yongquan acupoints. The two sham instruments corresponded to the Yongquan acupoints on both feet respectively, and then the subjects were asked to lie quietly for 20 minutes.
[0159] Then, the people in the experimental group and the control group were asked to perform the above experiment once a day for three days (that is, each subject was subjected to the corresponding test operation three times), and the subjects' feelings were observed (observe whether the subjects had sour, numb, swollen, hot, cold and other reactions in the Yongquan acupoint in each test, and how long this feeling lasted in the last test).
[0160] Test results:
[0161] The first time: 5 people in the experimental group felt warm in the soles of their feet, 3 people felt numb in the soles of their feet, and 2 people felt no feeling; 1 person in the control group felt slightly warm in the soles of their feet, and 9 people had no obvious feeling; the effective rate of the experimental group was 80%, and that of the control group was 10%.
[0162] Second treatment: 5 people in the experimental group felt warmth in their soles, 2 felt numbness, 2 felt cooling, and 1 felt no noticeable sensation. In the control group, 2 felt slight warmth in their soles, and 8 felt no noticeable sensation. The efficacy rate was 90% in the experimental group and 20% in the control group. Third treatment: 6 people in the experimental group felt warmth in their soles, 3 felt numbness, and 1 felt cooling. In the control group, 2 felt slight warmth in their soles, and 8 felt no noticeable sensation.
[0163] After three attempts, 100% of the experimental group experienced sensation in the soles of their feet, while only 20% of the control group did. Furthermore, in the third attempt, all participants in the experimental group experienced sensation, which lasted for more than 15 minutes, with an average of around 18 minutes. The sensation was continuous and largely uninterrupted. Only two participants in the control group experienced sensation, lasting for 8 and 7 minutes, respectively. These sensations were intermittent and not continuous.
[0164] The Yellow Emperor's Classic of Internal Medicine states, "When righteous qi is present within, evil cannot enter." Only when the body's qi is well-regulated can we achieve the goal of curing illness and preventing it before it occurs. To nourish qi, one must first obtain it. Feelings of soreness, numbness, swelling, heat, and coldness are similar to the sensation of obtaining qi in Traditional Chinese Medicine. The Lingshu: Nine Needles and Twelve Origins states, "When qi arrives, it is effective. The effect is so reliable, like wind blowing away clouds, making it clear as if the sky is visible."
[0165] The results of the above-mentioned test cases indicate that the low-entropy simulator 10 provided by this application can help users experience a sensation of Qi at acupoints in a short period of time, thereby unblocking the meridians, promoting the circulation of Qi and blood, resisting pathogenic factors, and protecting the body. Furthermore, the low-entropy simulator 10 can enhance the sensitivity of acupoints, that is, awakening the acupoints and allowing them to maintain the sensation of Qi for a longer period of time. This can provide a more lasting and stable effect of strengthening the body, relieving fatigue, and invigorating vitality, thereby improving human health.
[0166] In addition, the inventive concept of this application can form a large number of embodiments, but the length of the application document is limited and it is impossible to list them one by one. Therefore, under the premise of no conflict, the various embodiments or technical features described above can be arbitrarily combined to form new embodiments. After the various embodiments or technical features are combined, the original technical effects will be enhanced.
[0167] The above content is a further detailed description of the present application in conjunction with specific optional implementation methods, and the specific implementation of the present application cannot be considered to be limited to these descriptions. For ordinary technicians in the technical field to which the present application belongs, they can make several simple deductions or substitutions without departing from the concept of the present application, which should be considered to fall within the scope of protection of the present application.
Claims
1. A low-entropy simulator, characterized in that, the low-entropy simulator includes at least one simulated spherical space, and at least four nodes are included on the spherical surface of the simulated spherical space; wherein, on the spherical surface of the same simulated spherical space, all the nodes are evenly distributed; wherein, each node includes at least one simulated wormhole, and the axis of the simulated wormhole passes through the center of the corresponding simulated spherical space.
2. The low-entropy simulator according to claim 1, characterized in that, the simulated wormhole includes a first horn and a second horn arranged symmetrically, the first horn includes a large-mouth end and a small-mouth end, the second horn includes a large-mouth end and a small-mouth end, the diameter of the large-mouth end of the first horn is greater than the diameter of the small-mouth end of the first horn, and the diameter of the large-mouth end of the second horn is greater than the diameter of the small-mouth end of the second horn; the small-mouth end of the first horn is communicated with the small-mouth end of the second horn; the profile line of the inner wall of the first horn along the central axis of the simulated wormhole is an arc, and the arc is recessed towards the central axis direction.
3. The low-entropy simulator according to claim 1, characterized in that, the number of the nodes on the same spherical surface is six, taking the center of the spherical surface as the origin of the three-dimensional rectangular coordinate system, and the six nodes are respectively located at the intersections of the X-axis, Y-axis and Z-axis of the three-dimensional rectangular coordinate system and the spherical surface.
4. The low-entropy simulator according to claim 1, characterized in that, the low-entropy simulator has only one simulated spherical space, and all the nodes in the low-entropy simulator are on the spherical surface of the simulated spherical space.
5. The low-entropy simulator according to claim 4, characterized in that, each node has only one simulated wormhole, and the sizes of the simulated wormholes in all the nodes on the same spherical surface are the same.
6. The low-entropy simulator according to claim 4, characterized in that, each node includes at least three simulated wormholes, and the axes of all the simulated wormholes in each node coincide and pass through the center of the simulated spherical space; wherein, along the direction away from the center of the simulated spherical space, the size of the simulated wormhole gradually decreases.
7. The low-entropy simulator according to claim 1, characterized in that, the low-entropy simulator includes a first simulated spherical space and a second simulated spherical space, the centers of the first simulated spherical space and the second simulated spherical space coincide, and the central axes of all the simulated wormholes intersect at the same center of the sphere; wherein, the diameter of the first simulated spherical space is greater than the diameter of the second simulated spherical space, and the nodes in the first simulated spherical space correspond one by one to the nodes in the first simulated spherical space.
8. The low-entropy simulator according to claim 7, characterized in that, each node in the first simulated spherical space and the second simulated spherical space has only one simulated wormhole, the sizes of the simulated wormholes in all the nodes on the spherical surface of the first simulated spherical space are the same, and the sizes of the simulated wormholes in all the nodes on the spherical surface of the second simulated spherical space are the same; Among them, the size of the simulated wormhole in the nodes located on the spherical surface of the first simulated spherical space is larger than the size of the simulated wormhole in the nodes located on the spherical surface of the second simulated spherical space.
9. The low-entropy simulator according to claim 7, wherein, the nodes in the first simulated spherical space and the second simulated spherical space each include at least three simulated wormholes, and the axes of all the simulated wormholes in each node coincide and pass through the center of the corresponding simulated spherical space; among them, along the direction away from the center of the simulated spherical space, the sizes of at least three simulated wormholes in the node are arranged in descending order; moreover, the size of the largest simulated wormhole in the first simulated spherical space is smaller than the size of the largest simulated wormhole in the second simulated spherical space.
10. The low-entropy simulator according to claim 1, wherein, the low-entropy simulator includes a third simulated spherical space, a fourth simulated spherical space, and a fifth simulated spherical space, the centers of the third simulated spherical space, the fourth simulated spherical space, and the fifth simulated spherical space coincide, and the central axes of all the simulated wormholes intersect at the same center of the sphere; among them, the diameter of the third simulated spherical space is larger than the diameter of the fourth simulated spherical space, the diameter of the fourth simulated spherical space is larger than the diameter of the fifth simulated spherical space, and the nodes in the third simulated spherical space, the nodes in the fourth simulated spherical space, and the nodes in the fifth simulated spherical space correspond one by one.
11. The low-entropy simulator according to claim 10, wherein, each of the nodes in the third simulated spherical space, the fourth simulated spherical space, and the fifth simulated spherical space has only one simulated wormhole, the sizes of the simulated wormholes in all the nodes located on the spherical surface of the third simulated spherical space are the same, the sizes of the simulated wormholes in all the nodes located on the spherical surface of the fourth simulated spherical space are the same, and the sizes of the simulated wormholes in all the nodes located on the spherical surface of the fifth simulated spherical space are the same; among them, the size of the simulated wormhole in the nodes located on the spherical surface of the third simulated spherical space, is larger than the size of the simulated wormhole in the nodes located on the spherical surface of the fourth simulated spherical space; the size of the simulated wormhole in the nodes located on the spherical surface of the fourth simulated spherical space is larger than the size of the simulated wormhole in the nodes located on the spherical surface of the fifth simulated spherical space.
12. The low-entropy simulator according to claim 10, wherein, each of the nodes in the third simulated spherical space, the fourth simulated spherical space, and the fifth simulated spherical space includes at least three simulated wormholes, and the axes of all the simulated wormholes in each node coincide and pass through the center of the corresponding simulated spherical space; among them, along the direction away from the center of the simulated spherical space, the sizes of at least three simulated wormholes in the node are arranged in descending order; Moreover, the size of the largest simulated wormhole in the third simulated spherical space is smaller than the size of the largest simulated wormhole in the fourth simulated spherical space; the size of the largest simulated wormhole in the fourth simulated spherical space is smaller than the size of the largest simulated wormhole in the fifth simulated spherical space.
13. The low-entropy simulator according to claim 1, characterized in that, the low-entropy simulator further includes an energy source, and the energy source is arranged at the center of the simulated spherical space.
14. The low-entropy simulator according to claim 1, characterized in that, the low-entropy simulator includes a housing, the nodes are fixed inside the housing, and the housing is provided with a hollowed-out portion corresponding to the area of the nodes.
15. The low-entropy simulator according to claim 14, characterized in that, the housing is spherical, the hollowed-out portion is circular, and the hollowed-out portion and the nodes correspond one by one; the housing includes an upper shell and a lower shell, and the edge of the upper shell is fixed to the edge of the lower shell; the low-entropy simulator further includes a plurality of insertion strips, and at least one installation groove is provided on the insertion strips, the simulated wormholes in the nodes are fixedly arranged on the installation grooves one by one; each hollowed-out portion is provided with a socket, one end of the insertion strip is inserted into the socket for fixation, and the axis of the simulated wormhole fixed on the insertion strip passes through the center of the corresponding hollowed-out portion.
16. The low-entropy simulator according to claim 15, characterized in that, an insertion ear is provided in the upper shell, the insertion ear protrudes from the surface of the upper shell, both ends of the insertion ear are open and the interior is hollow, and it penetrates the interior and exterior of the upper shell; the low-entropy simulator further includes a feeding assembly, the feeding assembly includes an ear cover, a connecting rod and a feeding bead, the side wall of the ear cover matches the inner wall of the insertion ear, one end of the connecting rod is connected to the ear cover, the other end of the connecting rod is connected to the feeding bead, and the feeding bead is used for adsorbing the energy source; wherein, when the ear cover is matched with the insertion ear, the feeding bead is located at the center of the simulated spherical space.
17. The low-entropy simulator according to claim 16, characterized in that, the insertion ear is located between three adjacent hollowed-out portions.
18. A method for using a low-entropy simulator, for the low-entropy simulator according to any one of claims 1-17, characterized in that, including the steps of: facing the low-entropy simulator towards the physiotherapy user; removing the low-entropy simulator after a preset time.
19. The method for using a low-entropy simulator according to claim 18, characterized in that, in the step of removing the low-entropy simulator after a preset time, it includes: removing the low-entropy simulator after the low-entropy simulator stays for a first preset time.
20. The method for using a low-entropy simulator according to claim 18, characterized in that, in the step of removing the low-entropy simulator after a preset time, it includes: letting the low-entropy simulator stay for a second preset time; moving the low-entropy simulator away from the physiotherapy user at a first preset speed for a third preset time; and removing the low-entropy simulator.
21. The method for using a low-entropy simulator according to claim 18, characterized in that, Before the step of aligning the low-entropy simulator with the physical therapy user, an energy source is added to the low-entropy simulator first.