CN108783700B - Human body three-dimensional scanner - Google Patents

Abstract

The invention discloses a human body three-dimensional scanner, which comprises a first motion unit, a second motion unit and a third motion unit, wherein the first motion unit comprises a lifting assembly, a first power assembly and a first bracket assembly; an information acquisition unit is fixed on the first bracket component; and the second motion unit comprises a rotating assembly, a second power assembly and a second support assembly, wherein the second power assembly is fixed on the second support assembly, the power output end of the second power assembly faces upwards, and the rotating assembly is fixed on the power output end of the second power assembly. The human body three-dimensional scanner is of a detachable and assembled structure, and the external wires of all the functional units are divided into two sections and connected through the wiring mechanism, so that the two sections can be detached and assembled along with all the functional units.

Description

Human body three-dimensional scanner

Technical Field

The invention relates to the technical field of digital garment design and production, in particular to a human body three-dimensional scanner.

Background

A human body three-dimensional scanner, also called a human body whole body three-dimensional scanner or a 3D human body scanner, is a non-contact automatic measurement of a three-dimensional human body surface profile by using an optical measurement technology, a computer technology, an image processing technology, a digital signal processing technology and the like. For example, the 3D CaMega DCS series human body whole body (half body) scanning system fully utilizes the advantages of rapidness of optical three-dimensional scanning and harmlessness of white light to a human body, and carries out multi-angle and multi-azimuth instantaneous scanning on the whole body or half body of the human body within 3-5 seconds. The human body whole body (half body) scanning system carries out linkage control rapid scanning on a plurality of optical three-dimensional scanners through a computer, and then realizes automatic splicing through computer software to obtain accurate and complete human body point cloud data. However, the existing human body three-dimensional scanner has many functional units, large volume and difficult movement and transportation, and is generally only arranged in an independent and fixed space, so that the mobility is poor. When the transportation needs to be carried remotely, the field is changed, and the merchant delivers goods in a factory, all the units can be detached and carried in batches, and finally the units are assembled in a unified way. However, each functional unit has many complicated wires, and if all the functional units are disassembled, the process of arranging the lines is complicated, the wires attached to each unit are redundant, and the wires are easy to be damaged in the process of carrying.

Disclosure of Invention

This section is for the purpose of summarizing some aspects of embodiments of the invention and to briefly introduce some preferred embodiments. In this section, as well as in the abstract and the title of the invention of this application, simplifications or omissions may be made to avoid obscuring the purpose of the section, the abstract and the title, and such simplifications or omissions are not intended to limit the scope of the invention.

The present invention has been made in view of the above and/or other problems with the conventional three-dimensional scanner for human body.

Accordingly, it is an object of the present invention, among others, to provide a human body three-dimensional scanner which facilitates the disassembly, assembly and displacement of the whole.

In order to solve the technical problems, the invention provides the following technical scheme: a human body three-dimensional scanner comprises a first motion unit, a second motion unit and a third motion unit, wherein the first motion unit comprises a lifting assembly, a first power assembly and a first support assembly, the lifting assembly penetrates through the first support assembly, and the end part of the first lifting assembly is connected with the first power assembly; an information acquisition unit is fixed on the first bracket component; and the second motion unit comprises a rotating assembly, a second power assembly and a second support assembly, wherein the second power assembly is fixed on the second support assembly, the power output end of the second power assembly faces upwards, and the rotating assembly is fixed on the power output end of the second power assembly.

As a preferable scheme of the human body three-dimensional scanner of the present invention, wherein: the lifting assembly comprises a transmission part and a guide part which are vertically arranged and are parallel to each other; the upper end and the lower end of the guide piece are respectively fixed with an upper limiting piece and a lower limiting piece, the first power assembly is fixed at the lower end of the lower limiting piece, the power output end of the first power assembly penetrates through the lower limiting piece upwards and is in butt joint with the lower end of the transmission piece, and the upper end of the transmission piece is connected with the upper limiting piece.

As a preferable scheme of the human body three-dimensional scanner of the present invention, wherein: the first bracket component comprises a fixing piece and outer edge pieces arranged on two sides of the fixing piece respectively, and the guide piece penetrates through the fixing piece, so that the first bracket component can move vertically and vertically along the guide piece.

As a preferable scheme of the human body three-dimensional scanner of the present invention, wherein: the transmission piece penetrates through the fixing piece, and the outer side surface of the transmission piece is provided with an external thread; the fixing piece is provided with a screw hole matched with the transmission piece, and the inner side wall of the screw hole is provided with an internal thread matched with the external thread.

As a preferable scheme of the human body three-dimensional scanner of the present invention, wherein: go up spacing piece and spacing piece down and all be fixed in on the connecting plate, the lower extreme of connecting plate passes through the bolt fastening in on the second bracket component.

As a preferable scheme of the human body three-dimensional scanner of the present invention, wherein: the first power assembly is connected with a first electric wire, a second electric wire is further paved in the second support assembly, and the first electric wire is connected with the second electric wire through a wiring mechanism and is externally connected with a power supply through the second electric wire.

As a preferable scheme of the human body three-dimensional scanner of the present invention, wherein: the wiring mechanism comprises a covering assembly and a connecting assembly, wherein the covering assembly is divided into a first monomer and a second monomer which have the same structure, are oppositely spliced and are fixed through a butt joint assembly; the first single body comprises a first accommodating piece and a first pressing piece, wherein an insertion hole matched with the first pressing piece is formed in the first accommodating piece, and the first pressing piece is inserted into the insertion hole and extends into the first accommodating piece; and the butt joint assembly is sleeved on the periphery of the covering assembly and locks the combination between the first single body and the second single body, and the inner side wall of the butt joint assembly can inwards extrude the first pressing piece.

As a preferable scheme of the human body three-dimensional scanner of the present invention, wherein: a pair of limiting blocks are arranged inside the first accommodating piece and positioned at two ends of the first pressing piece; the limiting block is provided with a first protrusion on one side face, opposite to the first pressing piece, two end faces of the first pressing piece are provided with first sliding grooves matched with the first protrusion, the first protrusion is embedded into the first sliding grooves, and the direction of the first sliding grooves is consistent with that of the insertion holes.

As a preferable scheme of the human body three-dimensional scanner of the present invention, wherein: two ends of the first single body can be inserted with wires and enter the first accommodating piece, and the end part of the first accommodating piece is provided with a first penetrating opening matched with the wires; the electric wires penetrating from the two ends of the first accommodating piece are overlapped, and the first pressing piece can press the electric wires at the overlapped part under the pressing of the butting assembly.

As a preferable scheme of the human body three-dimensional scanner of the present invention, wherein: the first single body further comprises a sealing element, the sealing element comprises a pushing block which is in compression contact with two ends of the first pressing element, a sealing part arranged on the inner side of the first penetrating opening, and a transmission part which is connected with the pushing block and the sealing part; the two ends of the first pressing piece are provided with butt joints, the bottom surfaces of the butt joints are slopes, the width of an outer opening of each butt joint is larger than that of an inner opening, and the outer ends of the pushing blocks are embedded into the butt joints; the limiting block is provided with a second sliding groove matched with the pushing block, and the pushing block is inserted into the second sliding groove and can linearly slide under the pressing of the slope surface of the butt joint port; accommodating grooves are formed in two ends of the interior of the first accommodating piece, the accommodating grooves are located on the inner side of the first penetrating opening and are opposite to and communicated with the first penetrating opening, and the sealing parts are embedded into the accommodating grooves; the electric wire can sequentially pass through the first through opening and the sealing part and is inserted into the first accommodating piece, and the sealing part is coated on the periphery of the electric wire.

The invention has the beneficial effects that: the human body three-dimensional scanner is of a detachable and assembled structure, and the external wires of the functional units are divided into two sections and connected through the wiring mechanism, so that the two sections can be detached and assembled simultaneously along with the functional units, and therefore the human body three-dimensional scanner can ensure that the device is easy to carry in a long distance, cannot be influenced by complex circuit of the electric wires, and has good maneuverability. In addition, the wiring mechanism can be used for quickly and safely connecting electric wires, can be realized without tools and has the functions of sealing and water proofing.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise. Wherein:

fig. 1 is a schematic view of the overall structure of a human body three-dimensional scanner according to a first embodiment of the present invention.

Fig. 2 is a general structural view of a first motion unit according to a first embodiment of the present invention.

Fig. 3 is a side view, a cross-sectional view and a partial detail view of the human body three-dimensional scanner according to the first embodiment of the present invention.

Fig. 4 is a sectional view of a three-dimensional scanner of a human body according to a second embodiment of the present invention and a partial detailed view thereof.

Fig. 5 is an overall structural view of a connecting member according to a second embodiment of the present invention.

Fig. 6 is a schematic view illustrating an installation position of the platform compensating unit according to the second embodiment of the present invention.

Fig. 7 is a front view, a sectional view and a partial detail thereof of the installation position of the platform compensating unit according to the second embodiment of the present invention.

FIG. 8 is a schematic view and detail view of the installation position of the wiring mechanism according to the third embodiment of the present invention.

Fig. 9 is a structural diagram of the interior of the first accommodating component and a detail diagram of the limiting block according to the third embodiment of the invention.

Fig. 10 is a schematic view illustrating a pressing action of a first pressing member according to a third embodiment of the present invention.

Fig. 11 is an overall structural view of a seal member according to a third embodiment of the present invention.

Fig. 12 is a view showing an internal structure of a first monomer according to a third embodiment of the present invention.

Fig. 13 is a view showing an internal structure of a wiring mechanism according to a third embodiment of the present invention.

Fig. 14 is an assembly view of the overall structure according to the third embodiment of the present invention.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways than those specifically described and will be readily apparent to those of ordinary skill in the art without departing from the spirit of the present invention, and therefore the present invention is not limited to the specific embodiments disclosed below.

Furthermore, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one implementation of the invention. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

Referring to fig. 1 to 3, a first embodiment of the present invention provides a human body three-dimensional scanner. As can be seen from fig. 1, the human body three-dimensional scanner includes a first motion unit 100, a second motion unit 200, and an information acquisition unit 300.

The first moving unit 100 is configured to drive the information obtaining unit 300 to perform vertical lifting movement, and control a vertical height position of the information obtaining unit 300; the second motion unit 200 is used for supporting a person standing thereon and driving the person to horizontally rotate 360 degrees; the information acquisition unit 300 is a camera for collecting human body information.

Further, the first moving unit 100 includes a lifting assembly 101, a first power assembly 102 and a first bracket assembly 103, wherein the lifting assembly 101 passes through the first bracket assembly 103, and the first power assembly 102 is connected to an end of the first lifting assembly 101. Specifically, lifting unit 101 includes driving medium 101a and guide 101b, and both are vertical setting, and are parallel to each other, and screw rod can be chooseed for use to driving medium 101a wherein, and the guide arm can be chooseed for use to guide 101 b. In the present invention, for the sake of overall stability, two guide members 101b may be provided, symmetrically distributed on both sides of the transmission member 101a, and all three are arranged in parallel.

An upper limiting member 101c and a lower limiting member 101d are respectively fixed at the upper end and the lower end of the guide member 101b, and are both horizontal plate-shaped structures arranged in parallel to each other and used for limiting the height of the up-and-down movement of the first bracket component 103. The first power assembly 102 is fixed at the lower end of the lower limiting member 101d, the power output end of the first power assembly penetrates the lower limiting member 101d upwards and is in butt joint with the lower end of the transmission member 101a to form fixation, and the upper end of the transmission member 101a is connected with the upper limiting member 101c to form a thrust mode, so that the transmission member 101a can rotate under the driving of the first power assembly 102. The first power assembly 102 may be a stepper motor capable of forward and reverse rotation, and the rotation process may be performed by an electrical control system.

Further, the first bracket assembly 103 includes a fixing member 103a and outer edge members 103b respectively disposed at both sides of the fixing member 103 a. Wherein, the fixing member 103a is a box-shaped hollow structure, and the guiding member 101b passes through the fixing member 103a (here, "pass" is clearance fit), so that the whole first frame component 103 can move vertically up and down along the guiding member 101b, and the "vertical up and down movement" here is realized by the cooperation of the transmission member 101a and the fixing member 103 a: the transmission member 101a penetrates through the main body of the fixing member 103a, the outer side surface of the transmission member 101a is provided with an external thread, the fixing member 103a is provided with a screw hole matched with the transmission member 101a, and the inner side wall of the screw hole is provided with an internal thread matched with the external thread on the transmission member 101a, so that the transmission member 101a and the fixing member 103a are in transmission. When the first power assembly 102 is started, the transmission member 101a rotates along with the first power assembly, and the fixing member 103a is driven by the screw threads and vertically guided by the guide member 101b, so that the whole first bracket assembly 103 can vertically move up and down.

The fixing member 103a is provided at both sides with outer edge members 103b for mounting and fixing the information acquisition unit 300, i.e., the information acquisition unit 300 is fixed to the outer edges of the outer edge members 103b of the first frame member 103.

Further, the upper limiting member 101c and the lower limiting member 101d are both fixed on the connecting plate 101e, wherein the connecting plate 101e is a strip-shaped structure, is vertically arranged, and is located inside the lifting assembly 101, that is, the lifting assembly 101 is integrally fixed on the connecting plate 101e through the upper limiting member 101c and the lower limiting member 101 d. It should be noted that: the lower end of the connecting plate 101e is fixed on the second bracket assembly 203, so as to realize the mechanical connection between the first moving unit 100 and the second moving unit 200.

In the present invention, the second motion unit 200 includes a rotation component 201, a second power component 202 and a second bracket component 203, the second power component 202 is fixed on the second bracket component 203, the power output end of the second power component faces upward, and the rotation component 201 is fixed on the power output end of the second power component 202. Specifically, the rotating assembly 201 is a standing point of a user, which may be configured in a disc shape and is connected with the second power assembly 202. The second power assembly 202 may be a stepping motor, and a power output end of the upper end of the second power assembly is fixed to the rotating assembly 201 and can drive the rotating assembly 201 to rotate horizontally, and a rotation process of the second power assembly can be realized through an electric control system.

Further, the second bracket assembly 203 serves as a base member for supporting the second moving unit 200 as a whole, and preferably, it may include a first support 203a and a second support 203b which are vertically arranged with each other. The first support member 203a and the second support member 203b are respectively arranged in the longitudinal direction and the transverse direction and are fixedly connected with each other, and in addition, the upper ends of the two support members jointly support the peripheral member 204 for defining the space range in which the human body stands. In the present invention, the second power assembly 202 is fixed on the first supporting member 203a, and the power output end of the upper end thereof passes through the horizontal panel of the peripheral member 204 and is fixedly connected with the rotating assembly 201 disposed on the upper layer of the horizontal panel of the peripheral member 204.

Referring to fig. 4 to 7, a second embodiment of the present invention is different from the previous embodiment in that: the lower terminal surface of rotating assembly 201 still is provided with platform compensation unit 400, and platform compensation unit 400 is used for: when the rotating assembly 201 rotates, the platform compensation unit 400 can adjust the balance state of the rotating assembly 201 in real time without stopping the operation of the rotating assembly, so as to compensate the inclination deviation of the standing human body in real time, and acquire each item of accurate data of the human body information.

Platform compensation unit 400 includes a linkage assembly 401, a third power assembly 402, and a third carriage assembly 403. Wherein, the third bracket assembly 403 is used for fixing and mounting the third power assembly 402; the third power assembly 402 is used to provide power to compensate for motion; the connecting assembly 401 is used for connecting the third power assembly 402 and the rotating assembly 201, and transmitting the output power of the third power assembly 402 to the rotating assembly 201, so as to perform compensatory adjustment on the inclination state of the rotating assembly 201. The lower end of the third power assembly 402 is fixed to the second moving unit 200 through the third bracket assembly 403, and the upper end of the third power assembly 402 is connected to the lower end surface of the rotating assembly 201 through the connecting assembly 401. The third power assembly 402 of the present invention is vertically disposed, and may be implemented by a member capable of performing linear telescopic motion, such as a servo electric cylinder, and the telescopic end of the third power assembly 402 faces upward.

Further, the connecting assembly 401 includes a first mating member 401a and a second mating member 401b, wherein the upper end of the first mating member 401a is embedded in the second mating member 401b, the lower end thereof encloses the upper end of the third power assembly 402, and the first mating member 401a is movable in all directions at the end of the third power assembly 402. Wherein the second fitting member 401b is connected with the rotating assembly 201.

Further, the first fitting member 401a includes a first connecting portion 401a-1 and a clamping portion 401a-2, and a ball 402a is fixed to the upper end of the third power assembly 402. The interior of the clamping part 401a-2 is provided with a hollow space M matched with the sphere 402a, and the hollow space M is used for wrapping the sphere 402a in a clearance fit manner, so that the sphere 402a can freely move in the hollow space M. The first connecting part 401a-1 is located at the upper end of the clamping part 401a-2, and is a ring structure with an outer diameter of the edge larger than that of the clamping part 401a-2, and is used for connecting the first fitting part 401a and the second fitting part 401 b.

The second fitting member 401b includes a sliding portion 401b-1 on the upper end surface and a second connecting portion 401b-2 on the lower end surface, and the second connecting portion 401b-2 is engaged with the structure of the first connecting portion 401a-1 and covers the outer edge of the first connecting portion 401a-1 in a clearance fit manner, so that the first fitting member 401a and the second fitting member 401b can rotate horizontally relative to each other. The lower end face of the rotating component 201 is provided with an annular sliding groove 201a matched with the sliding part 401b-1, wherein the sliding part 401b-1 is a sliding block embedded in the annular sliding groove 201 a. In order to facilitate the relative stability of the second mating member 401b in the present invention, two sets of sliding portions 401b-1 may be provided, and the lower end surface of the rotating assembly 201 is also correspondingly provided with an inner annular sliding groove 201a and an outer annular sliding groove 201 a.

Further, the platform compensation units 400 are provided with at least three groups, and are uniformly distributed on a circumference of the lower layer of the rotating assembly 201. Each third power assembly 402 is secured to the peripheral member 204 by a third bracket assembly 403. When it is desired to adjust the rotating assembly 201 via the platform compensating unit 400, one (or two, three) of the third power assemblies 402 is activated to extend or shorten. When the horizontal rotation of the rotating component 201 is not considered, the second engaging element 401b is fixed to the lower side of the rotating component 201 through the sliding part 401b-1, so that it can be kept stationary relative to the rotating component 201, and the first engaging element 401a cannot be spatially displaced relative to the second engaging element 401b (in addition, the first engaging element 401a is connected to the rotating component 201 in a manner similar to a "ball joint"), so that the third power component 402 can raise or lower the height of the rotating component 201 at this point through the control of the length thereof, and finally control the gradient of the rotating component 201. It should be noted here that: when one or two of the third power assemblies 402 are activated, it is possible to finely adjust the horizontal slope of the rotating assembly 201, and when three third power assemblies 402 are simultaneously activated, it is possible to finely adjust the vertical height of the rotating assembly 201 (coarse adjustment with respect to the first locomotion unit 100).

When considering the horizontal rotation of the rotating assembly 201, since the upper end of the second fitting part 401b has the sliding part 401b-1 fitted to the annular sliding groove 201a, when the third power assembly 402 is started, the connecting assembly 401 can support the rotating assembly 201, and the rotating assembly 201 can horizontally rotate relative to the connecting assembly 401. From the above, the present invention can still adjust the horizontal slope of the rotating assembly 201 and the vertical height thereof without affecting the horizontal rotation of the rotating assembly 201.

Referring to fig. 8 to 14, a third embodiment of the present invention is different from the previous embodiment in that: the human body three-dimensional scanner is of a detachable and assembled structure. Wherein:

the first moving unit 100 is integrated and is connected with the second bracket assembly 203 through the lower end of the connecting plate 101e (the lower end of the connecting plate 101e is connected with one end of the first support 203a through a bolt);

the other end of the first support 203a is connected with the second support 203b through a bolt;

the top of the first support 203a is bolted to the horizontal panel of the peripheral member 204.

The external wires S of the electric devices (including the first power assembly 102, the second power assembly 202, the information acquisition unit 300, and the like) in the present invention are uniformly laid inside the first supporting member 203a, and the first supporting member 203a in the present invention is a hollow box structure.

Because there are many internal circuits of the human body three-dimensional scanner, when an external power supply is needed to power on, all the wires S are uniformly laid and fixed on the bottom surface or the corners inside the first supporting member 203a for the convenience of the orderliness of the circuits and for preventing the external factors from damaging the circuits. But this also presents other problems:

because the human body three-dimensional scanner is large-scale equipment, the size and the mass of the human body three-dimensional scanner are large, and the human body three-dimensional scanner is not easy to move and carry, the human body three-dimensional scanner is designed into a detachable and assembled structure, and when the human body three-dimensional scanner needs to be carried at a long distance and a place is changed, and a merchant delivers goods, all units are detached and carried in batches, and finally are assembled uniformly. However, the disassembly of each functional unit results in a long and redundant wire attached to each unit, which is easily damaged during transportation. Therefore, the invention designs: the external wires S of all the electric equipment are divided into two sections, and the two sections can be detached and assembled simultaneously along with all the functional units. The first section of the electric wire is defined as a first electric wire S-1, the short wire ends of all electric equipment are short in length and are detached together with the electric equipment, and the wire ends are short, so that inconvenience of carrying due to redundant electric wires is not influenced; the second wire is defined as a second wire S-2, which is a main line corresponding to each first wire S-1 and fixed in the box of the first support 203a for a long time. Therefore, based on the above, at the time of disassembly conveyance, the second electric wire S-2 is conveyed along with the first support member 203a case, and the first electric wire S-1 is conveyed along with other functional units. It should be noted that: the butt joint and the reassembly between the first wire S-1 and the second wire S-2 need to be performed by a quick and safe intermediate 'joint'. Therefore, the invention also provides a wiring mechanism J, which can quickly and conveniently connect the first electric wire S-1 and the second electric wire S-2, can be realized without tools and has the functions of sealing and water proofing.

The wiring mechanism J includes a cover assembly 500 and a docking assembly 600. The covering assembly 500 has two halves with the same structure and is used for wrapping and clamping and connecting the ends of two butt-jointed wires S; and the docking assembly 600 serves to connect, lock, and compress and densify the wires S inserted into the interior of the closure assembly 500. The covering assembly 500 of the present invention can be divided into a first unit 501 and a second unit 502, which have the same structure, are opposite to each other and are spliced, and are fixed by the docking assembly 600, and the structure of the first unit 501 is first described in detail herein.

The first single body 501 includes a first receiving part 501a and a first pressing part 501 b. The first container 501a mainly includes: the tubular body is axially cut into one half of the structure and comprises an external shell and an accommodating space in the shell; and the first pressing piece 501b is a block-shaped structure for directly telescopically pressing the electric wire S-terminal. The first accommodating member 501a is provided with an insertion hole 501a-1 matched with the first pressing member 501b, the first pressing member 501b is inserted into the insertion hole 501a-1 and extends into the first accommodating member 501a, and the first pressing member 501b can stretch and slide back and forth in the insertion hole 501a-1 to squeeze and loosen the wire S.

A pair of limiting blocks 501c are disposed inside the first accommodating member 501a (the limiting blocks 501c are fixed on the inner sidewall of the first accommodating member 501 a), and in a spatial position, the limiting blocks 501c are located at two ends (symmetrically distributed) of the first pressing member 501 b. It should be noted that: the side surface of the limiting block 501c opposite to the first pressing piece 501b is provided with a first protrusion 501c-1, two end surfaces of the first pressing piece 501b are provided with first sliding grooves 501b-1 matched with the first protrusion 501c-1, the first protrusion 501c-1 is embedded in the first sliding groove 501b-1, and the direction of the first sliding groove 501b-1 is consistent with the direction of the insertion hole 501a-1, so that the first pressing piece 501b can linearly and telescopically slide along the direction of the first sliding groove 501 b-1.

In the present invention, both ends of the first single body 501 can be inserted with the electric wire S and enter the inside of the first accommodating member 501a, and the end of the first accommodating member 501a has a first through hole 501a-2 fitted to the electric wire S, and it is obvious that the first through hole 501a-2 is a semicircular hole fitted to the outer diameter of the cross section of the electric wire S because the first single body 501 is a half structure of the covering assembly 500. The ends of the electric wires S penetrated from both ends of the first container 501a are overlapped, and the first pressing piece 501b can press the overlapped electric wires S by the pressing of the docking assembly 600. Preferably, the inner edge of the first pressing piece 501b is provided with a densely distributed scissors-like bifurcated structure: each scissor-like bifurcation is in the form of a sheet and the array is in plurality. The middle corner of the branched structure can press the electric wire S. Preferably, the first pressing member 501b may be made of rubber or other flexible and tough insulating materials, which can ensure the compactness of extruding the connector of the electric wire S, prevent the electric wire S and the first pressing member 501b from being damaged, and is non-conductive, safe and reliable.

Further, the first single body 501 further includes a sealing member 501d for ensuring a waterproof and dust-proof sealing function between the surface layer of the electric wire S penetrating into the first accommodating member 501a and the outer port of the first accommodating member 501 a. The sealing member 501d includes a push block 501d-1 which is in press contact with both ends of the first pressing member 501b, a sealing portion 501d-3 which is provided inside the first penetration opening 501a-2, and a transmission portion 501d-2 which connects the push block 501d-1 and the sealing portion 501 d-3. The pushing block 501d-1 is a block that can slide linearly along the longitudinal direction of the first accommodating element 501a, and the two ends of the first pressing element 501b are provided with a docking port 501b-2 corresponding to the pushing block 501d-1, where the docking port 501b-2 is a notch structure at the outer end of the first pressing element 501b, the bottom surface of the docking port 501b-2 is a slope, and the slope makes the width of the outer port of the docking port 501b-2 larger than the width of the inner port. Therefore, when the outer end of the pushing block 501d-1 is inserted into the docking port 501b-2, if the initial state is set as: the outer end of the pushing block 501d-1 abuts against the inner opening of the abutting opening 501b-2, so that when the first pressing piece 501b is pressed upwards, the top surface of the abutting opening 501b-2 can press the end of the pushing block 501d-1, so that the pushing block 501d-1 slides outwards in a straight line.

The above-mentioned "pushing block 501d-1 slides linearly outward" is realized by further including the following structure: the limiting block 501c is provided with a second sliding groove 501c-2 matched with the pushing block 501d-1, and the pushing block 501d-1 is inserted into the second sliding groove 501c-2 and can slide linearly under the pressing of the slope surface of the interface 501 b-2.

In the invention, the two ends of the inside of the first accommodating piece 501a are respectively provided with an accommodating groove 501a-3, the accommodating grooves 501a-3 are accommodating spaces positioned at the inner side of the first penetrating opening 501a-2, and the inner end of the accommodating grooves can be provided with a plug. The receiving groove 501a-3 is opposite to and communicated with the first through opening 501a-2, and the sealing portion 501d-3 is embedded in the receiving groove 501 a-3. The sealing portion 501d-3 in the present invention may be a half structure of a bellows, which is capable of length expansion and contraction. A transmission part 501d-2 for transmitting linear motion is arranged between the sealing part 501d-3 and the pushing block 501d-1 (the transmission part 501d-2 is a middle transitional block-shaped body structure), so when the pushing block 501d-1 slides outwards linearly by the first pressing piece 501b, the pushing block 501d-1 presses the sealing part 501d-3 through the transmission part 501d-2, so that the sealing part 501d-3 is compressed and the cross section is expanded, the contact pressure between the sealing part 501d-3 and the accommodating groove 501a-3 and the contact pressure of the wire S penetrating through the sealing part 501d-3 are increased, and the compactness is also improved.

It should be noted that: the wire S can sequentially pass through the first through hole 501a-2 and the sealing portion 501d-3 and be inserted into the first accommodating member 501a, and the sealing portion 501d-3 covers the periphery of the wire S.

As can be seen from the above, in the present invention, the second unit 502 and the first unit 501 have the same structure and are aligned with each other (the openings of the two housings are aligned with each other and cover each other to form a closed structure). Specifically, the second single body 502 includes a second accommodating member 502a corresponding to the first accommodating member 501a, a second penetrating opening 502a-1 corresponding to the first penetrating opening 501a-2 is formed at an end of the second accommodating member 502a, and when the first single body 501 and the second single body 502 are just spliced, the first penetrating opening 501a-2 and the second penetrating opening 502a-1 can jointly form a threading opening K-1 matched with the electric wire S. In addition, the second unit 502 further includes a second pressing piece 502b corresponding to the first pressing piece 501b, the second pressing piece 502b can be inserted into the second accommodating piece 502a, and the rest corresponding parts are not described in a list.

In the first single body 501 (and the second single body 502) according to the present invention, a functional region formed by the first pressing piece 501b, the stopper 501c and the sealing piece 501d inside the first accommodating piece 501a is a "connecting unit" capable of connecting a set of electric wire S connectors. Preferably, in the present invention, a plurality of "connecting units" may be arranged in parallel in the first accommodating part 501a to be suitable for a plurality of thread ends. The invention is illustrated in the figures as two sets of "connecting units", without limiting the scope of protection of the invention.

In the present invention, the docking assembly 600 is sleeved on the periphery of the covering assembly 500, and locks the combination between the first single body 501 and the second single body 502, and the inner sidewall of the docking assembly 600 can inwardly press the first pressing piece 501 b.

Specifically, the docking assembly 600 includes a first end cap 601 and a second end cap 602 that are coupled to the two end structures of the closing assembly 500, and a tightening member 603 that connects the first end cap 601 and the second end cap 602, that is: when the first monomer 501 and the second monomer 502 are just spliced, the first end cover 601 and the second end cover 602 can be respectively sleeved at two ends of the covering assembly 500, the outer end faces of the first end cover 601 and the second end cover 602 are respectively provided with a second threading opening K-2 corresponding to the threading opening K-1, and the electric wire S can sequentially pass through the second threading opening K-2 and the threading opening K-1 to enter the covering assembly 500 and is finally extruded and compacted.

Further, the first end cap 601 and the second end cap 602 have the same main structure and are symmetrically disposed. The structures of the two are as follows: one end is an open end which is not structurally closed; the other end is a plugging end, and a second threading opening K-2 penetrates through the plugging end. But the difference between the two is that: the outer side wall of the open end of the first end cap 601 has external threads 601a, and the open end of the second end cap 602 has a ring of first limiting rings 602 a. The first confinement ring 602a has an inner ring diameter that is the same as the open end of the second end cap 602 and an outer ring diameter that is larger than the open end of the second end cap 602.

The main body of the tension member 603 is sleeve-shaped, and the front and rear ends thereof are connected to the first end cap 601 and the second end cap 602, respectively. Specifically, one end of the tension member 603 has a second limiting ring 603a fitted to the first limiting ring 602a, the inner diameter of the second limiting ring 603a is smaller than the inner diameter of the tension member 603 and the outer diameter of the first limiting ring 602a, and the inner diameter of the tension member 603 is slightly larger than or equal to the outer diameter of the first limiting ring 602 a. In summary, after the tension member 603 is sleeved on the second end cap 602, the second limiting ring 603a can pull the first limiting ring 602a (i.e. the tension member 603 can be connected to the second end cap 602 through the limitation between the second limiting ring 603a and the first limiting ring 602 a).

The tension member 603 has an inner wall at the other end thereof provided with an internal thread 603b to be engaged with the external thread 601a, and is connected to the first end cap 601 by engagement of the two. Therefore, when one end of the tension member 603 is connected to the second end cap 602, the other end is rotated by the screw thread engagement, so as to tension the first end cap 601 and the second end cap 602 at the same time, thereby shortening the distance between them. It should be noted that: the two ends of the closing assembly 500 are thin, the middle of the closing assembly is thick, and the cross section of the closing assembly 500 gradually increases from the end to the middle, and meanwhile, because the first end cap 601 and the second end cap 602 are respectively matched with the two end structures of the closing assembly 500 and are also in a variable cross section structure, when the first end cap 601 and the second end cap 602 are tightened, the inner side walls of the first end cap 601 and the second end cap 602 can inwardly extrude the first pressing piece 501b and the second pressing piece 502b, and finally extrude and compact the connection of the electric wire S.

The invention takes the first power assembly 102 as an example: the first power assembly 102 is connected with a first electric wire S-1, a second electric wire S-2 is laid in a first supporting piece 203a of the second bracket assembly 203, and a connecting end of the first electric wire S-1 and a connecting end of the second electric wire S-2 are respectively inserted into threading ports at two ends of the wiring mechanism J and are connected and fixed through the wiring mechanism J.

Therefore, other electric equipment can connect the first wire S-1 with the second wire S-2 through the wiring mechanism J and externally connect a power supply through the second wire S-2.

It should be noted that the above-mentioned embodiments are only for illustrating the technical solutions of the present invention and not for limiting, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions may be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, which should be covered by the claims of the present invention.

Claims (3)

1. A human body three-dimensional scanner is characterized in that: comprises the steps of (a) preparing a mixture of a plurality of raw materials,

the first motion unit (100) comprises a first lifting assembly (101), a first power assembly (102) and a first bracket assembly (103), wherein the first lifting assembly (101) penetrates through the first bracket assembly (103), and the end part of the first lifting assembly (101) is connected with the first power assembly (102); an information acquisition unit (300) is fixed on the first bracket component (103); the first lifting assembly (101) comprises a transmission piece (101 a) and a guide piece (101 b), wherein the transmission piece (101 a) and the guide piece (101 b) are vertically arranged and are parallel to each other; an upper limiting piece (101 c) and a lower limiting piece (101 d) are respectively fixed at the upper end and the lower end of the guide piece (101 b), the first power assembly (102) is fixed at the lower end of the lower limiting piece (101 d), the power output end of the first power assembly upwards penetrates through the lower limiting piece (101 d) and is in butt joint with the lower end of the transmission piece (101 a), and the upper end of the transmission piece (101 a) is connected with the upper limiting piece (101 c); the first bracket component (103) comprises a fixing part (103 a) and outer edge parts (103 b) which are respectively arranged at two sides of the fixing part (103 a), and the guide part (101 b) penetrates through the fixing part (103 a) so that the first bracket component (103) can vertically move up and down along the guide part (101 b); and the number of the first and second groups,

the second motion unit (200) comprises a rotating assembly (201), a second power assembly (202) and a second bracket assembly (203), wherein the second power assembly (202) is fixed on the second bracket assembly (203), the power output end of the second power assembly faces upwards, and the rotating assembly (201) is fixed on the power output end of the second power assembly (202);

the first power assembly (102) is connected with a first electric wire (S-1), a second electric wire (S-2) is laid in the second support assembly (203), the first electric wire (S-1) is connected with the second electric wire (S-2) through a wiring mechanism, and an external power supply is connected through the second electric wire (S-2);

the lower end surface of the rotating assembly (201) is also provided with a platform compensation unit (400);

the platform compensation unit (400) comprises a connecting assembly (401), a third power assembly (402) and a third bracket assembly (403), wherein the third bracket assembly (403) is used for fixing and mounting the third power assembly (402); the third power assembly (402) is used for providing power for compensating motion; the connecting assembly (401) is used for connecting the third power assembly (402) and the rotating assembly (201) and transmitting the output power of the third power assembly (402) to the rotating assembly (201) so as to perform compensatory adjustment on the inclination state of the rotating assembly (201), the lower end of the third power assembly (402) is fixed on the second motion unit (200) through the third support assembly (403), and the upper end of the third power assembly (402) is connected with the lower end surface of the rotating assembly (201) through the connecting assembly (401);

the connecting assembly (401) comprises a first matching piece (401 a) and a second matching piece (401 b), the upper end of the first matching piece (401 a) is embedded into the second matching piece (401 b), the lower end of the first matching piece wraps the upper end head of the third power assembly (402), and the first matching piece (401 a) can move in all directions at the end head of the third power assembly (402), wherein the second matching piece (401 b) is connected with the rotating assembly (201);

the first fitting piece (401 a) comprises a first connecting part (401 a-1) and a wrapping part (401 a-2), a ball body (402 a) is fixed at the upper end of the third power assembly (402), a hollow space (M) matched with the ball body (402 a) is formed in the wrapping part (401 a-2), the ball body (402 a) is wrapped by the hollow space (M) in a clearance fit mode, the ball body (402 a) can freely move in the hollow space (M), the first connecting part (401 a-1) is located at the upper end of the wrapping part (401 a-2) and is of an annular structure with the edge outer diameter larger than that of the wrapping part (401 a-2), and the first fitting piece (401 a) is connected with the second fitting piece (401 b);

the second fitting member (401 b) includes a sliding portion (401 b-1) on an upper end surface, and a second connecting portion (401 b-2) on a lower end surface, the second connecting portion (401 b-2) being fitted to the structure of the first connecting portion (401 a-1), and wraps the outer edge of the first connecting part (401 a-1) in a clearance fit manner so that the first fitting piece (401 a) and the second fitting piece (401 b) can rotate horizontally relative to each other, the lower end surface of the rotating component (201) is provided with an annular sliding groove (201 a) matched with the sliding part (401 b-1), wherein the sliding part (401 b-1) is a sliding block embedded in the annular sliding groove (201 a) and is provided with two groups of sliding parts (401 b-1), the lower end surface of the rotating assembly (201) is also correspondingly provided with an inner annular chute (201 a) and an outer annular chute (201 a);

the wiring mechanism comprises a wire-connecting mechanism,

the covering assembly (500) is divided into a first monomer (501) and a second monomer (502), the first monomer and the second monomer have the same structure, are oppositely spliced and are fixed through the butt joint assembly (600); the first single body (501) comprises a first accommodating piece (501 a) and a first pressing piece (501 b), wherein an insertion hole (501 a-1) matched with the first pressing piece (501 b) is formed in the first accommodating piece (501 a), and the first pressing piece (501 b) is inserted into the insertion hole (501 a-1) and extends into the first accommodating piece (501 a); and the number of the first and second groups,

the butt joint component (600) is sleeved on the periphery of the covering component (500) and locks the combination between the first single body (501) and the second single body (502), and the inner side wall of the butt joint component (600) can inwards extrude the first pressing piece (501 b);

a pair of limiting blocks (501 c) are arranged inside the first accommodating piece (501 a), and the limiting blocks (501 c) are positioned at two ends of the first pressing piece (501 b); a first protrusion (501 c-1) is arranged on one side surface of the limiting block (501 c) opposite to the first pressing piece (501 b), first sliding grooves (501 b-1) matched with the first protrusion (501 c-1) are arranged on two end surfaces of the first pressing piece (501 b), the first protrusion (501 c-1) is embedded into the first sliding groove (501 b-1), and the direction of the first sliding groove (501 b-1) is consistent with that of the insertion hole (501 a-1);

two ends of the first single body (501) can be inserted with an electric wire (S) and enter the interior of the first accommodating piece (501 a), and the end of the first accommodating piece (501 a) is provided with a first through opening (501 a-2) matched with the electric wire (S); the electric wires (S) penetrating from two ends of the first accommodating piece (501 a) are overlapped, and the first pressing piece (501 b) can press the overlapped electric wires (S) under the pressing of the butting assembly (600);

the first single body (501) further comprises a sealing piece (501 d), the sealing piece (501 d) comprises a pushing block (501 d-1) which is in pressing contact with two ends of the first pressing piece (501 b), a sealing part (501 d-3) which is arranged on the inner side of the first penetrating opening (501 a-2), and a transmission part (501 d-2) which is connected with the pushing block (501 d-1) and the sealing part (501 d-3);

the two ends of the first pressing piece (501 b) are provided with a butt joint port (501 b-2), the bottom surface of the butt joint port (501 b-2) is a slope surface, the width of an outer port of the butt joint port (501 b-2) is larger than that of an inner port, and the outer end of the pushing block (501 d-1) is embedded into the butt joint port (501 b-2);

the limiting block (501 c) is provided with a second sliding groove (501 c-2) matched with the pushing block (501 d-1), and the pushing block (501 d-1) is inserted into the second sliding groove (501 c-2) and can slide linearly under the pressing of the slope surface of the butt joint port (501 b-2);

accommodating grooves (501 a-3) are formed in two ends of the interior of the first accommodating piece (501 a), the accommodating grooves (501 a-3) are located on the inner side of the first penetrating opening (501 a-2) and are communicated with the first penetrating opening in a facing mode, and the sealing parts (501 d-3) are embedded into the accommodating grooves (501 a-3);

the electric wire (S) can sequentially pass through the first through opening (501 a-2) and the sealing part (501 d-3) and is inserted into the first accommodating piece (501 a), and the sealing part (501 d-3) is coated on the periphery of the electric wire (S);

the butt joint component (600) comprises a first end cover (601) and a second end cover (602) which are matched with structures at two ends of the closing component (500), and a tension piece (603) which connects the first end cover (601) and the second end cover (602), when the first single body (501) and the second single body (502) are oppositely spliced, the first end cover (601) and the second end cover (602) can be respectively sleeved at two ends of the closing component (500);

the outer side wall of the open end of the first end cover (601) is provided with an external thread (601 a), and the open end of the second end cover (602) is provided with a ring of first limiting rings (602 a); the first confinement ring (602 a) has an inner ring diameter equal to the open end of the second end cap (602) and an outer ring diameter greater than the open end of the second end cap (602);

one end of the tension member (603) is provided with a second limiting ring (603 a) matched with the first limiting ring (602 a), the inner diameter of the second limiting ring (603 a) is smaller than the inner diameter of the tension member (603) and the outer diameter of the first limiting ring (602 a), and the inner diameter of the tension member (603) is equal to the outer diameter of the first limiting ring (602 a); the inner side wall of the other end of the tension piece (603) is provided with an internal thread (603 b) matched with the external thread (601 a), and the tension piece is connected with the first end cover (601) through the matching of the internal thread and the external thread; the cross section of the cover assembly (500) is gradually enlarged from the end part to the middle part.

2. The human body three-dimensional scanner of claim 1, wherein: the transmission piece (101 a) penetrates through the fixing piece (103 a), and the outer side surface of the transmission piece (101 a) is provided with an external thread;

the fixing piece (103 a) is provided with a screw hole matched with the transmission piece (101 a), and the inner side wall of the screw hole is provided with an internal thread matched with the external thread.

3. The human body three-dimensional scanner of claim 2, wherein: the upper limiting piece (101 c) and the lower limiting piece (101 d) are fixed on a connecting plate (101 e), and the lower end of the connecting plate (101 e) is fixed on the second support assembly (203) through a bolt.

Images