CN213121529U

CN213121529U - Intelligent human head model for testing child mask

Info

Publication number: CN213121529U
Application number: CN202021545980.0U
Authority: CN
Inventors: 张智军; 伍小东; 林俊杰; 林锦坤; 郭锦嘉
Original assignee: Foshan Shunde Zhike Intelligent Technology Co ltd
Current assignee: Foshan Shunde Zhike Intelligent Technology Co ltd
Priority date: 2020-07-30
Filing date: 2020-07-30
Publication date: 2021-05-04
Anticipated expiration: 2030-07-30

Abstract

The utility model discloses an intelligent human head model for children mask test, which comprises a head model outer sleeve, a head model inner shell, a control box, a head shaking mechanism, a nodding mechanism, an opening and closing mechanism, a nasal cavity hose and an oral cavity hose, wherein the head shaking mechanism, the nodding mechanism, the opening and closing mechanism, the nasal cavity hose and the oral cavity hose are arranged inside the head model inner shell; the control box controls the human-like head model to complete the head shaking motion, the head nodding motion and the mouth opening and closing motion in the mask tester, so as to complete the detection of the children mask; the utility model overcomes the defects of large accumulated error, excessive space occupation and easy vibration in the motion process caused by incomplete design of each action mechanism in the prior art; the control system is difficult to maintain in the later period and cannot feed back angle information in real time; the motion precision of the motion mechanism is improved, the occupied space is reduced, the oral cavity and nasal cavity catheters are reasonably arranged, and the angle sensor realizes the real-time feedback of the angle information in the motion process.

Description

Intelligent human head model for testing child mask

Technical Field

The utility model relates to an intelligence type human head model technical field especially relates to an intelligence type human head model and children's gauze mask test method for testing children's gauze mask resistance of breathing in, expiration resistance and protecting effect.

Background

The testing of the inhalation resistance and the exhalation resistance of the children mask is very necessary. The existing mechanical structure of the head die for testing the child mask for simulating the motion action is usually realized by adopting a plane link mechanism, namely the motion of the nodding mechanism and the opening and closing mechanism is realized by adopting the plane link mechanism. The number of components and kinematic pairs of the plane link mechanism is large, the accumulated error is large, and the motion precision of the mechanism is reduced; meanwhile, the connecting rod mechanism occupies too much space resources in the inner cavity of the head die, so that the arrangement of the oral and nasal cavity catheters is difficult; inertia force generated by a component which does plane reciprocating motion in the mechanism is difficult to balance, and vibration is easy to occur during motion. Meanwhile, the gear of the oscillating mechanism adopts a one-level speed reduction scheme, the radial size of the driven wheel is overlarge, and the head die occupies too much space resources at the neck part. In addition, the control system of the existing head die for the child mask test is embedded in the base, so that the firmware upgrading and maintenance of the control system in the later period are not convenient, and the control system also occupies too much space resources of the base. And because the angle sensor is not arranged in the head die, the control system cannot feed back the angle information of the current action of the head die in real time.

SUMMERY OF THE UTILITY MODEL

In order to overcome among the prior art accumulated error that the imperfection that the mechanical structure of simulation motion action and control system design lead to is big, space resources occupy too much, the motion process appears the vibration easily, control system later maintenance difficulty, unable real-time feedback angle information defect, the utility model discloses a direct current gear motor realizes the action of nodding the head mechanism with the steering wheel scheme, mechanism and the chin mechanism that opens and shuts, reduces the space resources occupation condition to rationally arrange oronasal cavity pipe, realize the real-time feedback of motion process angle information through angle sensor.

The utility model provides a technical scheme that its technical problem adopted is:

an intelligent human head model for testing a child mask comprises a head model body and a control box (5); the head die body comprises a head die outer sleeve (11), a head die inner shell, a head shaking mechanism, a head nodding mechanism, an opening and closing mechanism, a bottom plate (16), a bottom box (17), a nasal cavity hose (34) and an oral cavity hose (33); the head shaking mechanism, the head nodding mechanism and the opening and closing mechanism are all arranged in an inner cavity of the head die inner shell, and the head die inner shell is arranged on the bottom box (17); the shapes of the head model outer sleeve (11) and the head model inner shell are similar to the shapes of the head, the neck and the chest of a human body; the head die outer sleeve (11) is sleeved on the outer surface of the head die inner shell and is elastically attached; the head die inner shell comprises a head inner shell (12), a chin inner shell (13) and a chest inner shell (14), and the head inner shell (12), the chin inner shell (13) and the chest inner shell (14) are all hollow structures;

ear-shaped ear holes (18) are formed in the positions of two ears of the head inner shell (12), a well-shaped plate (221) is arranged on the plane where the lower edges of the two ear holes (18) penetrate through the inside of the head inner shell (12), and the well-shaped plate (221) is fixedly connected with the inner side of the head inner shell (12); a first strip-shaped plate (2221) and a second strip-shaped plate (2222) which vertically extend downwards are symmetrically arranged on the lower surface of the well-shaped plate (221) and close to the two sides of the hindbrain, a transverse plate (223) is fixed between the first strip-shaped plate (2221) and the second strip-shaped plate (2222), and a plurality of threaded holes (2231) are formed in the first strip-shaped plate (2221), the second strip-shaped plate (2222) and the transverse plate (223); a nasal cavity guide tube (32) and an oral cavity guide tube (31) are fixedly arranged at the edge of the # -shaped plate (221) positioned at the hindbrain position of the head inner shell (12); one end of the nasal cavity guide tube (32) and one end of the oral cavity guide tube (31) are both positioned behind the transverse plate (223) and extend downwards to a position between the first strip-shaped plate (2221) and the second strip-shaped plate (2222); the other end of the nasal cavity guide tube (32) penetrates through the hollow part of the # -shaped plate (221) and bends upwards to extend to the nasal cavity direction of the inner shell of the head mould at the edge of the # -shaped plate (221); the other end of the oral cavity guide pipe (31) penetrates through the hollow part of the 'well' -shaped plate (221) to be bent and extended upwards, and then penetrates through the hollow part of the 'well' -shaped plate (221) to be bent and extended downwards to the oral cavity direction of the inner shell of the head die;

the oscillating mechanism comprises an oscillating motor (29), an oscillating rotating plate (26), a middle position sensor (27), a right limit switch (281) and a left limit switch (282); the oscillating motor (29) is fixed below the bottom plate (16), an output shaft of the oscillating motor (29) extends into a shaft of the first flange (291) and is connected with the shaft of the first flange (291), and a disc of the first flange (291) penetrates through a through hole in the bottom plate (16) and is fixedly connected with the oscillating rotating plate (26); the neutral position sensor (27) is arranged on the bottom plate (16) along the axis of the oscillating rotating plate (26) and at a position right behind the back head of the head die body; the left limit switch (282) is arranged on the bottom plate (16) and positioned at the left side of the axis of the oscillating rotating plate (26), the right limit switch (281) is arranged on the bottom plate (16) and positioned at the right side of the axis of the oscillating rotating plate (26), and the left limit switch (282) and the right limit switch (281) are symmetrically arranged relative to the axis of the oscillating rotating plate (26); the axis is the central axis of the oscillating rotating plate (26) when the face of the head die body faces to the right front;

the nodding mechanism comprises a nodding motor fixing seat (25), a nodding motor (24), a second flange (241) and an angle sensor (21), wherein the nodding motor fixing seat (25) is composed of a base and two trapezoidal vertical plates vertically arranged on two sides of the upper surface of the base; the height of the nodding motor fixing seat (25) is matched with that of the head die body; the base of the nodding motor fixing seat (25) is fixed on the oscillating rotating plate (26), the nodding motor (24) is arranged between the two trapezoidal vertical plates of the nodding motor fixing seat (25) and is fixedly connected with the two trapezoidal vertical plates, the nodding motor (24) is a double-shaft output motor, and two output shafts of the nodding motor (24) are respectively connected with the first strip-shaped plate (2221) and the second strip-shaped plate (2222) of the head inner shell (12) through second flanges (241); the angle sensor (21) is arranged on a well-shaped plate (221) of the head inner shell (12) and close to an ear hole on one side, and two output shafts of the nodding motor (24) are parallel to the well-shaped plate (221);

the opening and closing mechanism comprises a steering engine component (22), and the steering engine component (22) comprises a large U-shaped frame (232), a steering engine (23) and a small U-shaped frame (231); the middle cross frame of the large U-shaped frame (232) is connected with a transverse plate (223) of the head inner shell (12) through a bolt, two side frames of the large U-shaped frame (232) are respectively connected with two shafts of the steering engine (23) through a third flange (233), two side frames of the small U-shaped frame (231) are connected with two sides of the steering engine (23) through bolts, and the middle cross frame of the small U-shaped frame is connected with the chin inner shell (13) through a bolt;

the chest inner shell (14) is fixed on the bottom plate (16);

a power supply unit and a control unit are arranged in the control box (5); the power supply unit is connected with the control unit and the head die body; the control unit is connected with the oscillating motor (29), the middle position sensor (27), the left limit switch (282), the right limit switch (281), the nodding motor (24), the steering engine (23) and the angle sensor (21).

Preferably, the control unit includes: the singlechip main control board and the motor drive board are connected with each other; the single chip microcomputer main control board outputs a motor control signal to the motor drive board, and the motor drive board outputs a motor drive signal to the oscillating motor (29) and the nodding motor (24) to drive the oscillating motor and the nodding motor to rotate; the single chip microcomputer main control board inputs a control signal to the steering engine (23) to control the steering engine (23) to swing; the angle sensor (21), the left limit switch (282) and the right limit switch (281) input signals to the singlechip main control board, so that the singlechip main control board can acquire the signals; the signal output end of the middle position sensor (27) is connected with the signal input end of the level conversion plate, and the signal output end of the level conversion plate is connected with the single chip microcomputer main control board through a signal line, so that the single chip microcomputer main control board can collect data of the middle position sensor;

the power supply unit includes: the power supply comprises a switching power supply, a first power supply voltage reduction module, a second power supply voltage reduction module, a power supply adapter plate and a level conversion plate;

a first output end of the switching power supply is respectively connected to the first power supply voltage reduction module and the second power supply voltage reduction module; the output ends of the first power supply voltage reduction module and the second power supply voltage reduction module are connected to the power supply adapter plate; the second output end of the switching power supply is directly connected to the power supply adapter plate; the first output end of the power supply adapter plate is respectively connected to the level conversion plate, the single chip microcomputer main control plate and the motor drive plate; a second output end of the power supply adapter plate is fixed on the rear surface of the box body of the control box (5) through an adapter to form a power line interface (55) of the head die body; the signal output end of the level conversion board is connected with the signal input end of the singlechip main control board; the signal input end of the level conversion plate, the signal output end of the motor driving plate and the signal input and output end of the single chip microcomputer main control plate are fixed on the rear surface of the box body through an adapter to form a signal line interface (56) of the head die body;

the control box (5) further comprises a box body, a touch screen (51) embedded in the front surface of the box body, an emergency stop switch (52) and a power switch (53), wherein the emergency stop switch and the power switch are sequentially arranged on the touch screen (51) in an up-and-down mode; the head die body power line interface (55) and the head die body signal line interface (56) are embedded in the rear surface of the box body; the back surface of the box body is fixed with a clamping bracket (58) for supporting the box body, and two side surfaces of the box body are provided with handles (57).

Preferably, power lines of the middle position sensor (27), the left limit switch (282), the right limit switch (281), the steering engine (23) and the angle sensor (21) are integrated into a multi-core power line (531), and the multi-core power line (531) penetrates through a lead guide hole (43) in the bottom plate (16) and is led out from a power line connecting port (171) arranged on the outer side surface of the bottom box (17); the signal lines of the head shaking motor (29), the middle position sensor (27), the left limit switch (282), the right limit switch (281), the nodding motor (24), the steering engine (23) and the angle sensor (21) are integrated into a multi-core signal line (532), and the multi-core signal line (532) passes through a guide wire guide hole (43) on the bottom plate (16) and is led out from a signal line connecting port (172) arranged on the outer side surface of the bottom box (17); the connector of a multi-core power line (531) of the head die body is connected with a head die body power line interface (55) on the control box (5) to supply power to a steering engine (23), an angle sensor (21), a left limit switch (282), a right limit switch (281) and a middle position sensor (27) in the head die body; the connector of the multi-core signal wire (532) of the head die body is connected with a head die body signal wire interface (56) on the control box (5), so that signal transmission between the head die body and the control box (5) is realized.

Preferably, the chest inner shell (14) is formed by combining a left chest inner shell and a right chest inner shell which are symmetrical, hollow upright posts are fixedly arranged in the left chest inner shell and the right chest inner shell, and stepped holes matched with bolts are formed in the lower ends of the hollow upright posts; the thoracic cavity inner shell (14) is fixed on a bottom plate (16) through bolts, and the head shaking mechanism and the head nodding mechanism are both arranged in an inner cavity of the thoracic cavity inner shell (14); the cross section of the bottom box (17) is the same as that of the bottom plate (16) in shape and size, and the bottom plate (16) is fixed on the upper surface of the bottom box (17) through bolts; a power line connecting port (171), a signal line connecting port (172) and two partition straight-through mounting holes (173, 174) are formed in the outer side surface of the bottom box (17), and two cylinders (1751, 1752) for mounting a right-angle elbow are fixedly arranged on the inner side surface of the bottom box (17); the bottom plate (16) is provided with an oral cavity hose guide hole (41), a nasal cavity hose guide hole (42) and a guide wire guide hole (43).

Preferably, the nasal cavity hose (34) passes through a first clapboard straight-through hole (174) arranged on the outer side surface of the bottom box (17), is inserted into a first straight-angle bent-through hole arranged on the inner side surface of the bottom box (17) and is led out from the first straight-angle bent-through hole, upwards passes through a nasal cavity hose guide hole (42) on the bottom plate (16), and then extends into a nasal cavity guide tube (32) of the head inner shell (12) until the nasal cavity guide tube (32) extends out to be inserted into a through hole arranged in the nose bridge of the head die outer sleeve (11), and is communicated with two nostrils arranged on the head die outer sleeve (11); the oral cavity hose (33) penetrates through a second clapboard straight-through hole (173) arranged on the outer side surface of the bottom box (17), is inserted into a second right-angle bend arranged on the inner side surface of the bottom box (17) and is led out of the second right-angle bend, upwards penetrates through an oral cavity hose guide hole (41) on the bottom plate (16) and then extends into an oral cavity guide pipe (31) of the head inner shell (12) until the oral cavity guide pipe (31) extends out to be inserted into a round hole arranged at the mouth part of the head die outer sleeve (11).

Preferably, the head mould cover (11) has eyes, nose, mouth, ears, neck and chest; the nose is provided with two nostrils, a through hole is formed along the inner part of the nose bridge, and the two nostrils are communicated with the through hole; an elastic film is arranged between the upper lip and the lower lip of the mouth part, and a round hole is formed in the middle of the elastic film; a circle of bolt holes are formed in the lower edge of the head die outer sleeve at intervals; the lower edge of the head die outer sleeve (11) is bent outwards to be attached to the bottom plate (16), a metal pressing strip (15) is arranged on the surface of the part, bent outwards, of the lower edge of the head die outer sleeve (11), the metal pressing strip (15), the lower edge of the head die outer sleeve (11) and the bottom plate (16) are connected through bolts, and the head die outer sleeve (11) is fixed on the bottom plate (16); the contour of the metal pressing strip (15) is the same as that of the bottom plate (16).

Preferably, the head die outer sleeve (11) is made of elastic silica gel materials and is integrally formed through a die.

Preferably, the inner diameter of the nasal cavity guide tube (32) is larger than the inner diameter of the oral cavity guide tube (31); reinforcing columns (2241, 2242) are further arranged between the inner side of the top of the head part inner shell (12) and the # -shaped plate (221).

Preferably, bolts (2511, 2512) are respectively arranged at appropriate positions on two sides of the nodding motor fixing seat (25); when the head die body performs oscillating motion in the horizontal plane, the bolts (2511, 2512) on two sides of the nodding motor fixing seat (25) touch the left limit switch (282) or the right limit switch (281), the head die body stops oscillating motion firstly, and then begins to perform oscillating motion in the opposite direction.

Preferably, the neutral position sensor (27) comprises a sensor body and a metal induction sheet fixed on the nodding motor fixing seat (25); the sensor body is arranged on the bottom plate (16), is positioned along the axis of the oscillating rotating plate (26) and is positioned right behind the back brain of the head model body; the sensor body contacts with the metal induction sheet to send a trigger signal to the singlechip main control board, and the singlechip main control board controls the head die body to reset to return to an initial position.

Preferably, the oscillating motor (29) and the nodding motor (24) are direct current speed reduction motors, and the steering gear (23) is an electric rotating steering gear.

Preferably, the oscillating mechanism enables the head mould body to rotate in a horizontal plane relative to the axis of the oscillating rotating plate (26) within an angle range of-75 degrees to +75 degrees; the head nodding mechanism enables the rotation angle range of the head mould body relative to the transverse section of the neck part to be-45 degrees to +45 degrees; the opening and closing mechanism makes the jaw swing at an angle ranging from 0 DEG to +30 DEG relative to the upper and lower lip interfaces.

Preferably, the touch screen (51) is provided with an instruction option, the instruction option is clicked to send a signal to the single chip microcomputer main control board, and the single chip microcomputer main control board controls the head die body to move correspondingly and collects the signal.

Preferably, the head inner shell (12), the chin inner shell (13), the chest inner shell (14) and the nodding motor fixing seat (25) are integrally formed through 3D printing, and the used material is photosensitive resin.

Compared with the prior art, the beneficial effects of the utility model reside in that:

the utility model adopts the scheme of the direct current speed reducing motor and the steering engine to replace the scheme of the traditional plane connecting rod mechanism so as to realize the action of the nodding mechanism and the chin opening and closing mechanism, thereby greatly reducing the condition that the space resource of the head mould cavity occupies large space, facilitating the optimal design and arrangement of the mouth and nose cavity guide tube and reducing the condition of the flow resistance loss of the gas in the pipeline; because the number of the components and the kinematic pairs of the motion mechanism is reduced, the overall motion precision of the motion mechanism is improved, and the vibration caused by the difficulty in balancing the inertia force during the motion of the planar connecting rod mechanism is avoided. The direct-current speed reduction motor scheme is adopted to replace a primary speed reduction scheme of a traditional head shaking mechanism, and the problem that excessive space resources are occupied at the neck part of the head mould is optimized. Based on the idea of modular design, the control system is separated from the head die, hardware and firmware in later period are convenient to upgrade and maintain, and the occupation condition of space resources of the bottom box is reduced, so that the size of the bottom box model is reduced. The angle sensor and the middle position sensor are arranged in the head die, so that the angle information of the current action of the head die is fed back in real time.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the head mold jacket of the present invention;

fig. 3A is a left side perspective view of the head inner shell of the present invention;

fig. 3B is a right perspective view of the inner shell of the head of the present invention;

fig. 3C is a rear perspective view of the head inner shell of the present invention;

fig. 3D is a rear view of the inner head shell of the present invention;

FIG. 3E is a partial enlarged view of the "well" shaped plate of the present invention;

FIG. 4 is a schematic structural view of the inner shell moving mechanism of the head mold of the present invention;

fig. 5 is a top view of the bottom plate of the present invention;

fig. 6A is a front view of the control box of the present invention;

fig. 6B is a rear view of the control box of the present invention;

fig. 7 is a structural diagram of the control unit and the power supply unit of the present invention;

fig. 8 is a connection diagram of the elements of the control unit of the present invention;

in the figure, 11-head-form jacket; 12-a head inner shell; 13-inner chin shell; 14-intrathoracic shell; 15-metal pressing strips; 16-a base plate; 17-a bottom box; 18-ear hole; 34-nasal hoses; 33-oral flexible tube; 5-a control box; 221- "well" shaped plate; 2221-a first strip; 2222-a second strip; 223-a transverse plate; 2231-a threaded hole; 32-a nasal cavity guide tube; 31-a buccal guide tube; 29-oscillating motor; 26-oscillating rotating plate; 27-a neutral position sensor; 281-right limit switch; 282-left limit switch; 291-first flange; 25-nodding motor fixing seat; 24-a nodding motor; 241-a second flange; 21-an angle sensor; 22-a steering engine component; 232-big U-shaped frame; 23-a steering engine; 231-small U-shaped frame; 233-a third flange; 171-power line connector; 172-signal line connection port; 173, 174-straight through mounting holes for the partition; 1751,1752-column; 41-oral hose guide holes; 42-nasal hosepipe guide holes; 43-a wire guide hole; 531-multicore power lines; 532-multicore signal lines; 51-a touch screen; 52-emergency stop switch; 53-power switch; 54-power plug interface; 55-head die body power line interface; 56-head die body signal line interface; 58-a clamping bracket; 57-handle; 2241,2242-reinforcing columns; 2511,2512-bolt.

Detailed Description

The present invention will be further explained with reference to the drawings and examples.

As shown in fig. 1-2, 3A-3E, and 4-5, the intelligent human head model for testing the children mask comprises a head model body and a control box 5; the head die body comprises a head die outer sleeve 11, a head die inner shell, a head shaking mechanism and a head nodding mechanism which are arranged in the head die inner shell, an opening and closing mechanism, a bottom plate 16, a bottom box 17, a nasal cavity hose 34 and an oral cavity hose 33; the head model coat 11 is similar to the head, neck and chest of a human body in appearance and is provided with eyes, a nose, a mouth, two ears, a neck and a chest, wherein the nose is provided with two nostrils, a through hole is formed along the inner part of the nose bridge, and the two nostrils are communicated with the through hole; an elastic film is arranged between the upper lip and the lower lip of the mouth part, and a round hole is formed in the middle of the elastic film; the aperture of the through hole is larger than that of the round hole; and a circle of bolt holes are formed in the lower edge of the head die outer sleeve. The head die outer sleeve 11 is made of elastic silica gel materials and is integrally formed through a die.

The appearance of head mould inner shell is the appearance of imitative human head, neck and chest, including head inner shell 12, chin inner shell 13 and thorax inner shell 14, head inner shell 12, chin inner shell 13 and thorax inner shell 14 are hollow structure.

The chest inner shell 14 is formed by combining a left chest inner shell and a right chest inner shell which are symmetrical, a plurality of hollow upright posts are fixedly arranged in the chest inner shell on each side, and stepped holes matched with bolts are formed in the lower ends of the hollow upright posts; the hollow upright post can play a role in fixing the intrathoracic shell and a role in strengthening and supporting the intrathoracic shell. Preferably, the intrathoracic shell is integrally formed by 3D printing, and the material is photosensitive resin.

Ear-shaped ear holes 18 are formed in the positions of two ears of the head inner shell 12, a well-shaped plate 221 is arranged on the plane where the lower edges of the two ear holes penetrate through the inside of the head inner shell 12, and the well-shaped plate 221 is fixedly connected with the inner side of the head inner shell 12. A first strip-shaped plate 2221 and a second strip-shaped plate 2222 which vertically extend downwards are symmetrically arranged on the lower surface of the well-shaped plate 221 close to the two sides of the hindbrain, a transverse plate 223 is fixed between the first strip-shaped plate 2221 and the second strip-shaped plate 2222, and a plurality of threaded holes 2231 are arranged on the first strip-shaped plate 2221, the second strip-shaped plate 2222 and the transverse plate 223; the edge of the well-shaped plate 221, which is positioned at the hindbrain position of the head inner shell 12, is fixedly provided with a nasal cavity guide tube 32 and an oral cavity guide tube 31; one end of each of the nasal cavity guide tube 32 and the oral cavity guide tube 31 is located behind the transverse plate 223 and extends downwards to a position between the first strip-shaped plate 2221 and the second strip-shaped plate 2222;

the other end of the nasal cavity guide tube 32 penetrates through the hollow part of the shaft-shaped plate 221 and bends upwards to extend to the nasal cavity direction of the inner shell of the headform at the edge of the shaft-shaped plate 221; the other end of the oral cavity guide tube 31 passes through the hollow part of the shaft-shaped plate 221 to be bent and extended upwards, and then passes through the hollow part of the shaft-shaped plate 221 to be bent and extended to the oral cavity direction of the inner shell of the head mould downwards;

the inner diameter of the nasal cavity guide tube 32 is larger than that of the oral cavity guide tube 31; reinforcing

columns

2241,2242 are also provided between the inside of the head inner shell 12 and the floor 221 in the shape of a Chinese character 'jing'. Preferably, the head inner shell 12 is integrally formed by 3D printing, and the material used is photosensitive resin.

The oscillating mechanism comprises an oscillating motor 29, an oscillating rotating plate 26, a middle position sensor 27, a right limit switch 281 and a left limit switch 282. The oscillating motor 29 is fixed below the bottom plate 16, an output shaft of the oscillating motor 29 extends into a shaft of the first flange 291 and is welded with the shaft of the first flange, and a disc of the first flange 291 penetrates through a through hole in the bottom plate 16 to be fixedly connected with the oscillating rotating plate 26 through a bolt. When the face of the head die body faces the right front, the head die body is at an initial position; when the head model body is in the initial position, the neutral position sensor 27 is mounted on the bottom plate 16 along the axis of the oscillating and rotating plate 26 and at a position right behind the back head of the head model body; the left limit switch 282 is mounted on the bottom plate 16 at a position on the left side of the axis of the oscillating and rotating plate 26, the right limit switch 281 is mounted on the bottom plate 16 at a position on the right side of the axis of the oscillating and rotating plate 26, and the left limit switch 282 and the right limit switch 281 are arranged symmetrically with respect to the axis of the oscillating and rotating plate 26; the specific position can be correspondingly set according to the angle range of the left-right shaking head; when the head mould body shakes, the head mould body touches the left limit switch 282 or the right limit switch 281, the shaking motion is stopped firstly, and then the shaking motion is started to the opposite direction until the head mould body returns to the initial position.

The nodding mechanism comprises a nodding motor fixing seat 25, a nodding motor 24, a second flange 241 and an angle sensor 21, wherein the nodding motor fixing seat 25 consists of a base and two trapezoidal vertical plates vertically arranged on two sides of the upper surface of the base; the height of the nodding motor fixing seat 25 is matched with that of the head die body. Preferably, the nodding motor fixing base 25 is integrally formed through 3D printing. The base of the nodding motor fixing seat 25 is fixed on the oscillating rotating plate 26 through bolts, the nodding motor 24 is arranged between the two trapezoidal vertical plates of the nodding motor fixing seat 25 and fixedly connected with the two trapezoidal vertical plates through bolts, the nodding motor 24 is a double-shaft output motor, and two output shafts of the nodding motor 24 are connected with the first strip-shaped plate 2221 and the second strip-shaped plate 2222 of the head inner shell 12 through the second flange 241. The angle sensor 21 is arranged on a transverse plate of a shape like a Chinese character 'jing' of the head inner shell 12 close to an ear hole on one side, and the shape like the Chinese character 'jing' 221 and the angle sensor 21 are parallel to a straight line where two output shafts of the nodding motor 24 are located.

Further,

bolts

2511 and 2512 are respectively arranged at appropriate positions on two sides of the nodding motor fixing seat 25; when the head mould body is in oscillating motion in the horizontal plane, the

bolts

2511 and 2512 on the two sides of the nodding motor fixing seat 25 touch the left limit switch 282 or the right limit switch 281, so that the head mould body stops oscillating motion firstly, and then starts oscillating motion in the opposite direction until the head mould body returns to the initial position.

The middle position sensor 27 comprises a sensor body which is arranged on the bottom plate 16 and is positioned right behind the back head of the head die body along the axis of the oscillating and rotating plate 26 and a metal induction sheet which is fixed on the nodding motor fixing seat 25; the sensor body with the contact of metal response piece to STM32 singlechip main control board sends trigger signal, STM32 singlechip main control board control the type people's head mould resets, returns initial position.

The mouth opening and closing mechanism comprises a steering engine component 22, the steering engine component 22 comprises a large U-shaped frame 232, a steering engine 23 and a small U-shaped frame 231, a middle cross frame of the large U-shaped frame 232 is connected with a transverse plate 223 of the head inner shell 12 through bolts, two side frames of the large U-shaped frame 232 are respectively connected with two shafts of the steering engine 23 through third flanges 233, two side frames of the small U-shaped frame 231 are fixedly connected with two sides of the steering engine through bolts, and the middle cross frame of the small U-shaped frame 231 is fixedly connected with the chin inner shell 13 through bolts.

The oscillating mechanism enables the head mould body to rotate in a horizontal plane at an angle ranging from-75 degrees to +75 degrees relative to the axis of the oscillating rotating plate 26, and the oscillating angle range of the head mould can be correspondingly set according to actual detection requirements. The head nodding mechanism enables the rotation angle range of the head die body relative to the transverse section of the neck to be-45 degrees to +45 degrees, and the head nodding angle of the head die can also be correspondingly set according to actual detection requirements. The opening/closing mechanism makes the jaw swing at an angle ranging from 0 DEG to +30 DEG with respect to the interface between the upper and lower lips. The opening and closing angle of the mouth part of the head die can be correspondingly set according to actual detection requirements.

The oscillating motor 29 and the nodding motor 24 are both direct-current speed reduction motors, and the steering gear 23 is an electric rotating steering gear.

Set up in inside the head mould inner shell the mechanism of shaking the head and the installation of some mechanism and oral area mechanism of opening and shutting are accomplished the back, head inner shell 12, chin inner shell 13 also corresponding equipment the head. Place left side thorax inner shell and right side thorax inner shell on bottom plate 16, put into the shoulder hole of the cavity stand bottom of left and right sides thorax inner shell with the bolt, with left and right sides thorax inner shell fixed mounting on bottom plate 16, the thorax inner shell of the left and right sides will shake the head mechanism with the mechanism of nodding surrounds. The bottom plate 16 is provided with a plurality of through holes with different hole diameters, and the specific holes are arranged according to the installation requirement; the shape of the bottom plate 16 is the same as the shape of the cross section of the thoracic cavity and is enlarged in a proper ratio according to the shape of the cross section of the thoracic cavity.

The head die outer sleeve 11 is sleeved on the head die inner shell, the head die outer sleeve 11 is tightly attached to the head die inner shell, the elasticity is good, and the head die outer sleeve can keep synchronous motion along with the motion of the head die inner shell. The lower edge of the head die outer sleeve 11 is bent outwards to be attached to the bottom plate 16, a metal pressing strip 15 is arranged on the surface, attached to the bottom plate 16, of the lower edge of the head die outer sleeve 11, the metal pressing strip 15, the lower edge of the head die outer sleeve 11 and the bottom plate 16 are connected through bolts, and the head die outer sleeve 11 is fixed on the bottom plate 16; the contour of the metal bead 15 is identical to the contour of the base plate 16.

The cross section shape and size of the bottom box 17 are the same as those of the bottom plate 16, and the bottom plate 16 is fixed on the upper surface of the bottom box 17 through bolts; the outer side surface of the bottom box 17 is provided with a power line connecting port 171, a signal line connecting port 172 and two straight-through mounting

holes

173 and 174 of the partition plate, and the inner side surface of the bottom box 17 is fixedly provided with two

columns

1751 and 1752 for mounting right-angle elbow. The bottom plate 16 is provided with an oral cavity hose guide hole 41, a nasal cavity hose guide hole 42 and a guide wire guide hole 43.

The nasal cavity hose 34 passes through a partition board arranged on the outer side surface of the bottom box 17 to be straight, then is inserted into a right-angle bend arranged on the inner side surface of the bottom box 17 and is led out, upwards passes through the nasal cavity hose guide hole 42 on the bottom plate 16 and then extends into the nasal cavity guide tube 32 of the head inner shell 12 until extending out of the nasal cavity guide tube 32 to be inserted into a through hole arranged in the nose bridge of the head die outer sleeve 11 and is communicated with two nostrils arranged on the head outer sleeve 11. The oral cavity hose 33 passes through another partition board arranged on the outer side surface of the bottom box 17 and is inserted into another right-angle bend arranged on the inner side surface of the bottom box 17 and is led out, upwards passes through an oral cavity hose guide hole 41 on the bottom plate 16 and then extends into an oral cavity guide pipe 31 of the head inner shell 12 until the oral cavity guide pipe 31 is inserted into a round hole arranged at the mouth part of the head die outer sleeve 11.

The power lines of the middle position sensor 27, the left limit switch 282, the right limit switch 281, the steering engine 23 and the angle sensor 21 are integrated into a multi-core power line 531, which passes through the guide wire guide hole 43 on the bottom plate 16 and is led out from the power line connecting port 171 arranged on the outer side surface of the bottom box 17. The signal lines of the oscillating motor 29, the middle position sensor 27, the left limit switch 282, the right limit switch 281, the nodding motor 24, the steering engine 23 and the angle sensor 21 are integrated into a multi-core signal line 532 which passes through the guide wire guide hole 43 on the bottom plate 16 and is led out from a signal line connecting port 172 arranged on the outer side surface of the bottom box 17.

As shown in fig. 6A-6B and fig. 7-8, the control box 5 includes a box body, a touch screen 51 embedded in the outer surface of the box body, an emergency stop switch 52 and a power switch 53 which are arranged next to the touch screen 51 in sequence from top to bottom, a power plug interface 54 and a head module body power line interface 55 embedded in the rear surface of the box body, and a head module body signal line interface 56, a clamping bracket 58 mounted on the rear surface of the box body, and handles 57 fixed on two sides of the box body; the power supply is characterized by also comprising a switching power supply, a first power supply voltage reduction module, a second power supply voltage reduction module, a power adapter plate, a level conversion plate, an STM32 singlechip main control plate and a motor drive plate which are arranged in the box body;

the switching power supply can convert 220V commercial power into 12V direct current power and is provided with a plurality of output ends; the first power supply voltage reduction module is a power supply voltage reduction module for converting 12V into 5V, and the second power supply voltage reduction module is a power supply voltage reduction module for converting 12V into 6V.

The power plug interface 54 is inserted into a power plug, connected with 220V commercial power, and pressed down the power switch 53, the switch power supply is electrified, and the switch power supply converts the 220V commercial power into a 12V direct-current power supply; the first output end of the switching power supply is respectively connected with the first power supply voltage reduction module and the second power supply voltage reduction module, and the output ends of the first power supply voltage reduction module and the second power supply voltage reduction module are connected with the power supply adapter plate; the second output end of the switching power supply is directly connected with the power supply adapter plate; the first output end of the power supply adapter plate is respectively connected with the touch screen 51, the level conversion plate, the STM32 singlechip main control board and the motor drive board to provide 5V and/or 12V voltage for the touch screen, the level conversion plate, the STM32 singlechip main control board and the motor drive board; the second output of the power adapter plate is fixed to the rear surface of the case by an adapter to form the head die body power line interface 55.

The joint of a multi-core power line 531 of the head die body is connected with a head die body power line interface 55 on the control box 5, and 5V, 6V or 12V direct-current voltage is provided for a steering engine, an angle sensor, a left limit switch, a right limit switch and a middle position sensor in the head die body; the output end of the power supply adapter plate supplies power to the steering engine at 6V, supplies power to the angle sensor 21, the left limit switch 282 and the right limit switch at 5V, and supplies 12V direct-current voltage to the middle position sensor 27;

the STM32 single chip microcomputer main control board is provided with a plurality of signal input and output ends, and the STM32 single chip microcomputer main control board is connected with the touch screen 51 through signal lines to carry out data transmission interaction; and clicking the corresponding instruction option on the touch screen 51 to send a signal to an STM32 singlechip main control board, and controlling the similar human head model to perform corresponding movement by the STM32 singlechip main control board and acquiring the signal.

The STM32 singlechip main control board is connected with the motor drive board through a signal line and outputs a motor control signal to the motor drive board, and the motor drive board is provided with a plurality of signal output ends; the signal output end of the level conversion board is connected with the STM32 singlechip main control board through a signal line, and the level conversion board outputs signals to the STM32 singlechip main control board; the signal input end of the level conversion board, a plurality of signal output ends of the motor drive board and a plurality of signal input and output ends of the STM32 singlechip main control board are fixed on the rear surface of the box body through an adapter, and the head die body signal line interface 56 is formed.

The joints of the multi-core signal wires 532 of the head die body are connected with the head die body signal wire interface 56 on the control box 5, so that signal transmission between the head shaking motor, the head nodding motor, the steering engine, the angle sensor, the left limit switch, the right limit switch and the middle position sensor in the control box 5 and the head die body is realized.

The STM32 single chip microcomputer main control board outputs motor control signals to the motor drive board, and the motor drive board outputs motor drive signals to the oscillating motor 29 and the spot head motor 24 to drive the oscillating motor 29 and the spot head motor 24 to rotate; the STM32 singlechip main control board inputs control signals to the steering engine 23 to control the steering engine to swing; the angle sensor, the left limit switch and the right limit switch input signals to an STM32 single chip microcomputer main control board for the STM single chip microcomputer main control board to carry out signal acquisition; the signal output end of the middle position sensor is connected with the signal input end of the level conversion plate, the signal output end of the level conversion plate is connected with the STM32 single chip microcomputer main control board through a signal line, and the STM32 single chip microcomputer main control board collects data of the middle position sensor.

The intelligent human head model of the utility model can do shaking head movement, nodding head movement and opening and closing movement of the mouth part at a single time; also can do head shaking movement, head nodding movement and mouth opening and closing movement repeatedly; the combined single movement or the circulating movement can be carried out according to the sequence of head shaking movement, head nodding movement and opening and closing movement of the mouth part; when the human head model moves to the initial position, the human head model is stopped, and the stopping time can be set; and automatically returning to the initial position after one movement period is finished.

When the intelligent human head model is used for detecting the mask for children, the clamping bracket 58 of the control box 5 is fixed outside the mask tester, the head model body is placed in the testing bin of the mask tester, the mask for children is worn on the head model body, the oral cavity hose 33 and the nasal cavity hose 34 are connected with the breathing simulator in the mask tester, and the head model body is connected with the control box 5 and then is electrified; the gaseous concentration of test that lets in the computer automatic test system control test storehouse of gauze mask tester clicks the instruction on 5 touch screen 51 of control box, controls head model body is according to shaking head motion, nod motion and the order that the oral area opened and shut the motion in the test storehouse and is periodic motion, and the work of breathing simulator makes simultaneously head model body simulation children are breathing under daily state, and the computer control system control test process of gauze mask tester, automatic acquisition test data to adopt special test software to carry out data processing, the data storage and the display system of gauze mask tester preserve, output, inquiry, show test data. The mask testing box is used for testing the inhalation resistance, the exhalation resistance and the protection effect of the children mask according to a testing method in the technical specification of the children mask of national standard GB/T38880-2020.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims

1. An intelligent human head model for testing a child mask comprises a head model body and a control box (5); the head die body comprises a head die outer sleeve (11), a head die inner shell, a head shaking mechanism, a head nodding mechanism, an opening and closing mechanism, a bottom plate (16), a bottom box (17), a nasal cavity hose (34) and an oral cavity hose (33); the head shaking mechanism, the head nodding mechanism and the opening and closing mechanism are all arranged in an inner cavity of the head die inner shell, and the head die inner shell is arranged on the bottom box (17); the shapes of the head model outer sleeve (11) and the head model inner shell are similar to the shapes of the head, the neck and the chest of a human body; the head die outer sleeve (11) is sleeved on the outer surface of the head die inner shell and is elastically attached; the head die inner shell comprises a head inner shell (12), a chin inner shell (13) and a chest inner shell (14), and the head inner shell (12), the chin inner shell (13) and the chest inner shell (14) are all hollow structures; the method is characterized in that:

the chest inner shell (14) is fixed on the bottom plate (16);

a power supply unit and a control unit are arranged in the control box (5); the power supply unit is connected with the head die body; the control unit is connected with the oscillating motor (29), the middle position sensor (27), the left limit switch (282), the right limit switch (281), the nodding motor (24), the steering engine (23) and the angle sensor (21).

2. The intelligent manikin for child mask testing according to claim 1, wherein the control unit comprises: the singlechip main control board and the motor drive board are connected with each other; the power supply unit includes: the power supply comprises a switching power supply, a first power supply voltage reduction module, a second power supply voltage reduction module, a power supply adapter plate and a level conversion plate;

the single chip microcomputer main control board outputs a motor control signal to the motor drive board, and the motor drive board outputs a motor drive signal to the oscillating motor (29) and the nodding motor (24) to drive the oscillating motor and the nodding motor to rotate; the single chip microcomputer main control board inputs a control signal to the steering engine (23) to control the steering engine (23) to swing; the angle sensor (21), the left limit switch (282) and the right limit switch (281) input signals to the singlechip main control board, so that the singlechip main control board can acquire the signals; the signal output end of the middle position sensor (27) is connected with the signal input end of the level conversion plate, and the signal output end of the level conversion plate is connected with the single chip microcomputer main control board through a signal line, so that the single chip microcomputer main control board can collect data of the middle position sensor;

3. The intelligent dummy head for the mask test of the children according to claim 2, wherein power lines of the middle position sensor (27), the left limit switch (282), the right limit switch (281), the steering engine (23) and the angle sensor (21) are integrated into a multi-core power line (531), the multi-core power line (531) passes through the wire guide hole (43) on the bottom plate (16) and is led out from a power line connecting port (171) arranged on the outer side surface of the bottom box (17); the signal lines of the head shaking motor (29), the middle position sensor (27), the left limit switch (282), the right limit switch (281), the nodding motor (24), the steering engine (23) and the angle sensor (21) are integrated into a multi-core signal line (532), and the multi-core signal line (532) passes through a guide wire guide hole (43) on the bottom plate (16) and is led out from a signal line connecting port (172) arranged on the outer side surface of the bottom box (17);

the connector of a multi-core power line (531) of the head die body is connected with a head die body power line interface (55) on the control box (5) to supply power to a steering engine (23), an angle sensor (21), a left limit switch (282), a right limit switch (281) and a middle position sensor (27) in the head die body; the connector of the multi-core signal wire (532) of the head die body is connected with a head die body signal wire interface (56) on the control box (5), so that signal transmission between the head die body and the control box (5) is realized.

4. The intelligent dummy head for the mask test of children according to claim 1, wherein the inner chest shell (14) is composed of a left inner chest shell and a right inner chest shell which are symmetrical, hollow upright posts are fixedly arranged in the left inner chest shell and the right inner chest shell, and stepped holes matched with bolts are arranged at the lower ends of the hollow upright posts; the thoracic cavity inner shell (14) is fixed on a bottom plate (16) through bolts, and the head shaking mechanism and the head nodding mechanism are both arranged in an inner cavity of the thoracic cavity inner shell (14);

the cross section of the bottom box (17) is the same as that of the bottom plate (16) in shape and size, and the bottom plate (16) is fixed on the upper surface of the bottom box (17) through bolts; a power line connecting port (171), a signal line connecting port (172) and two partition straight-through mounting holes (173, 174) are formed in the outer side surface of the bottom box (17), and two cylinders (1751, 1752) for mounting a right-angle elbow are fixedly arranged on the inner side surface of the bottom box (17); the bottom plate (16) is provided with an oral cavity hose guide hole (41), a nasal cavity hose guide hole (42) and a guide wire guide hole (43).

5. The intelligent human head model for the children mouth mask test according to claim 4, wherein the nasal cavity hose (34) passes through a first partition straight through (174) arranged on the outer side surface of the bottom box (17), is inserted into a first straight corner bent through arranged on the inner side surface of the bottom box (17) and is led out from the first straight corner bent through, passes through a nasal cavity hose guide hole (42) on the bottom plate (16) upwards and then extends into the nasal cavity guide tube (32) of the head inner shell (12) until the nasal cavity guide tube (32) extends out to be inserted into a through hole arranged in the nose bridge of the head model outer sleeve (11) and is communicated with two nostrils arranged on the head model outer sleeve (11); the oral cavity hose (33) penetrates through a second clapboard straight-through hole (173) arranged on the outer side surface of the bottom box (17), is inserted into a second right-angle bend arranged on the inner side surface of the bottom box (17) and is led out of the second right-angle bend, upwards penetrates through an oral cavity hose guide hole (41) on the bottom plate (16) and then extends into an oral cavity guide pipe (31) of the head inner shell (12) until the oral cavity guide pipe (31) extends out to be inserted into a round hole arranged at the mouth part of the head die outer sleeve (11).

6. The intelligent dummy head for a child mask test according to claim 1, wherein the dummy head cover (11) has eyes, a nose, a mouth, ears, a neck and a chest; the nose is provided with two nostrils, a through hole is formed along the inner part of the nose bridge, and the two nostrils are communicated with the through hole; an elastic film is arranged between the upper lip and the lower lip of the mouth part, and a round hole is formed in the middle of the elastic film; a circle of bolt holes are formed in the lower edge of the head die outer sleeve at intervals;

the lower edge of the head die outer sleeve (11) is bent outwards to be attached to the bottom plate (16), a metal pressing strip (15) is arranged on the surface of the part, bent outwards, of the lower edge of the head die outer sleeve (11), the metal pressing strip (15), the lower edge of the head die outer sleeve (11) and the bottom plate (16) are connected through bolts, and the head die outer sleeve (11) is fixed on the bottom plate (16); the contour of the metal pressing strip (15) is the same as that of the bottom plate (16).

7. The intelligent human head model for children mask testing according to claim 1, wherein the head model outer sleeve (11) is made of elastic silica gel material and is integrally formed through a mold.

8. The intelligent dummy head for a child mask test according to claim 1, wherein the inner diameter of the nasal cavity guide tube (32) is larger than the inner diameter of the oral cavity guide tube (31); reinforcing columns (2241, 2242) are further arranged between the inner side of the top of the head part inner shell (12) and the # -shaped plate (221).

9. The intelligent dummy head for the mask test of children according to claim 1, wherein bolts (2511, 2512) are respectively arranged at proper positions of both sides of the nodding motor fixing seat (25); when the head die body performs oscillating motion in the horizontal plane, the bolts (2511, 2512) on two sides of the nodding motor fixing seat (25) touch the left limit switch (282) or the right limit switch (281), the head die body stops oscillating motion firstly, and then begins to perform oscillating motion in the opposite direction.

10. The intelligent dummy head for the mask test of children according to claim 2, wherein the middle position sensor (27) comprises a sensor body and a metal induction sheet fixed on the nodding motor fixing seat (25); the sensor body is arranged on the bottom plate (16), is positioned along the axis of the oscillating rotating plate (26) and is positioned right behind the back brain of the head model body; the sensor body contacts with the metal induction sheet to send a trigger signal to the singlechip main control board, and the singlechip main control board controls the head die body to reset to return to an initial position.

11. The intelligent human head model for the children mask test according to claim 1, wherein the head shaking motor (29) and the head nodding motor (24) are both direct current speed reduction motors, and the steering engine (23) is an electric rotating steering engine.

12. The intelligent human head model for children mask test according to claim 1, wherein the head shaking mechanism makes the head model body rotate in the horizontal plane at an angle ranging from-75 ° to +75 ° relative to the axis of the head shaking rotating plate (26); the head nodding mechanism enables the rotation angle range of the head mould body relative to the transverse section of the neck part to be-45 degrees to +45 degrees; the opening and closing mechanism makes the jaw swing at an angle ranging from 0 DEG to +30 DEG relative to the upper and lower lip interfaces.

13. The intelligent human head model for the children mask test according to claim 2, wherein the touch screen (51) is provided with an instruction option, the instruction option is clicked to send a signal to the single chip microcomputer main control board, and the single chip microcomputer main control board controls the head model body to perform corresponding movement and collect the signal.

14. The intelligent dummy head for a children mask test according to claim 1, wherein the head inner shell (12), the chin inner shell (13), the chest inner shell (14) and the nodding motor fixing seat (25) are integrally formed by 3D printing, and the material is photosensitive resin.