CN107862961B - Surgical operation basic operation simulation training device based on medical field - Google Patents
Surgical operation basic operation simulation training device based on medical field Download PDFInfo
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- CN107862961B CN107862961B CN201711277841.7A CN201711277841A CN107862961B CN 107862961 B CN107862961 B CN 107862961B CN 201711277841 A CN201711277841 A CN 201711277841A CN 107862961 B CN107862961 B CN 107862961B
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- 238000004088 simulation Methods 0.000 title claims abstract description 38
- 238000001514 detection method Methods 0.000 claims abstract description 23
- 230000007246 mechanism Effects 0.000 claims abstract description 16
- 230000001681 protective effect Effects 0.000 claims abstract description 15
- 230000006698 induction Effects 0.000 claims abstract description 10
- 230000005540 biological transmission Effects 0.000 claims description 37
- 230000001012 protector Effects 0.000 claims description 10
- 230000009471 action Effects 0.000 abstract description 9
- 230000029058 respiratory gaseous exchange Effects 0.000 abstract description 5
- 238000001356 surgical procedure Methods 0.000 abstract description 4
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- 230000008859 change Effects 0.000 description 3
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- 230000005611 electricity Effects 0.000 description 2
- 230000007547 defect Effects 0.000 description 1
- 230000005674 electromagnetic induction Effects 0.000 description 1
- 230000005484 gravity Effects 0.000 description 1
- 230000023597 hemostasis Effects 0.000 description 1
- 238000007670 refining Methods 0.000 description 1
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Abstract
The invention discloses a basic operation simulation training device for surgical operation based on the medical field, which structurally comprises a real-time display screen, a screen support frame, a distribution box, a sensing wire, a protective frame, a platform supporting foot, a universal wheel, a pedal plate, a frame base, a working platform, a simulation prosthesis, a detection power wire, a detection sensor, a connecting fixing frame, a placing platform, a support base and an induction vibration mechanism, wherein the lower end of the real-time display screen is mechanically connected to the upper end of the screen support frame, and the lower end of the screen support frame is screwed to the upper end of the support base, so that the basic operation simulation training device has the beneficial effects: through having increased response vibration mechanism on equipment, make the student when carrying out the basic operation of simulation training surgery, can simulate the patient and produce some actions or vibrations when carrying out the operation, and have some physiological vibration such as breathing to more be favorable to the student to simulate the surgery condition, make the great increase of student the ability in the face of emergency, it is comparatively practical.
Description
Technical Field
The invention discloses a basic operation simulation training device for a surgical operation based on the medical field, and belongs to the field of medical training simulation equipment.
Background
The basic functions of the surgeon are incision, hemostasis and suture, which are three key operations of success and failure of the operation. However, it is difficult to successfully complete the practical operation for the first time without practical refining, even if the learning is better, the manipulation and the back is normalized and ripened. Without practice, even multiple failed experiences, a real surgeon never takes off grains and grows.
Among the prior art, the basic operation simulation trainer of surgery is when going on student's study training, the state of intelligent display false body, and among the actual state, operating personnel is when performing the operation, and the patient can produce some actions or vibrations, and has some physiological vibration such as breathing, these change medical personnel's that will be great operation action, equipment can't simulate human vibration, the student of will great influence is to the cognition of surgery, lead to student's wrong nature memory easily, comparatively inconvenient.
Disclosure of Invention
Aiming at the defects in the prior art, the invention aims to provide a basic operation simulation training device for a surgical operation based on the medical field, so as to solve the problems that in the prior art, the basic operation simulation training device for the surgical operation intelligently displays the state of a prosthesis when students are subjected to learning and training, and in an actual state, when an operator performs an operation, a patient can generate certain actions or vibration and some physiological vibrations such as respiration, which greatly change the operation actions of medical workers, equipment cannot simulate the vibration of a human body, the cognition of the students on the surgical operation is greatly influenced, and the wrong memory of the students is easily caused and the students are inconvenient.
In order to achieve the purpose, the invention is realized by the following technical scheme: a basic operation simulation training device for surgical operation based on the medical field structurally comprises a real-time display screen, a screen supporting frame, a distribution box, sensing lines, a protective frame, platform supporting legs, universal wheels, pedals, a rack base, a working platform, a simulation prosthesis, detection power lines, detection sensors, a connecting and fixing frame, a placing platform, a supporting base and an induction vibration mechanism, wherein the lower end of the real-time display screen is mechanically connected to the upper end of the screen supporting frame, the lower end of the screen supporting frame is screwed to the upper end of the supporting base, the lower end of the supporting base is adhered to the middle of the upper end of the placing platform, the connecting and fixing frame is provided with four ends and is arranged on the distribution box, the lower end of the distribution box is arranged at the rear end of the rack base, the rear side of the upper surface of the working platform is connected to the lower side of the front end of the connecting and, the left end and the right end of the working platform are attached to the protective frame, the middle of the upper end of the working platform is provided with an induction vibration mechanism, the lower end of the simulation prosthesis is in clearance fit with the upper end of the working platform, the middle of the upper end of the simulation prosthesis is attached to the lower end of the detection sensor, the left end of the upper end of the detection sensor is mechanically connected to the right end of a sensing line, the lower end of the detection power line is electrically connected with a control main board inside the detection sensor, four platform supporting legs are provided with four ends which are connected to the four ends of the rack base in a screwed mode, the lower side of the front end of the rack base is welded to the rear end of the pedal plate, the universal wheel is provided with four ends which are connected to the lower ends of the pedal plate and the rack base in a screwed mode, and the, The vibration sensor comprises a vertical conductive rod, a right conductive plate, a power line, an overload protector, a right transmission gear, a long transmission rod, a central fixed shaft, a right connecting gear, a helical gear, a right micro motor, a power distribution guide plate, a connecting conductive plate, a left micro motor, a left connecting gear, a short transmission rod, a rotary circular gear, a left transmission gear, a motor, a rotary fixed plate, a transmission conductive plate, a lower conductive plate and an upper conductive plate, wherein the upper end of the overload protector is matched with the lower end of the vibration sensor through the power line, the left end of the overload protector is electrically connected with the right end of the power distribution guide plate through the power line, the lower end of the power distribution guide plate is welded at the upper end of the connecting conductive plate, the left end and the right end of the connecting conductive plate are connected with, the right end of the helical gear is meshed with the left side of the right side connecting gear, the front end of the right side connecting gear is matched with the upper end of a rotary circular gear through a right side transmission gear, the left end and the right end of the lower end of the rotary circular gear are welded at the upper ends of a long transmission rod and a short transmission rod, the middle part of the lower end of the rotary circular gear is in screw connection with the upper end of a central fixed shaft, the left end of a left side micro motor is meshed with the right end of the left side connecting gear, the front end of the left side connecting gear is matched with the upper end of the left side transmission gear, the left end of a power distribution guide plate is electrically connected with the right end of a motor through a power cord, the left end of the motor is adhered at the middle part of the right end of a rotary fixed plate, the upper end and the lower end, the utility model discloses a vibration sensor, including the I-shaped current conducting plate, downside current conducting plate, power distribution baffle, power cord, vibration sensor, power cord, vibration sensor, distribution baffle, power cord and pressure button, downside current conducting plate is connected with the lower extreme of upside current conducting plate through the power cord with vibration sensor, the upper end clearance fit of electricity conducting montant is in the lower extreme of electricity conducting montant, the left and right sides both ends of I-shaped current conducting plate are equipped with left side current conducting plate and right side current conducting plate respectively, the right-hand member of right side current conducting plate matches through the lower extreme of power cord with vibration sensor, the upper end of I-shaped current conducting plate cooperatees through button bracing piece and pressure button, the stretch cord is.
Further, the lower extreme of place the platform weld in the upper end of block terminal and be the integral structure.
Furthermore, the vibration sensor comprises a massage raised head, a piston shell, a piston conducting plate, an annular protective shell, a piston base and a telescopic rod.
Further, it is characterized in that: the lower end of the massage raised head is welded at the upper end of the telescopic rod and is of an integrated structure.
Furthermore, the lower end of the piston base is mechanically connected to the upper end of the piston conducting plate, and the middle part of the outer surface of the piston conducting plate is bonded to the inner wall of the annular protective shell.
Further, the outer surface clearance fit of telescopic link is inboard in the piston shell, the lower extreme of piston shell welds the upper end at the piston base.
Furthermore, the detection sensor is connected with the real-time display screen through a sensing line, so that the human body condition can be displayed in real time, and the simulation training can be carried out.
Advantageous effects
According to the basic operation simulation training device for the surgical operation based on the medical field, the induction vibration mechanism is additionally arranged on the device, so that students can simulate certain actions or vibrations of patients during the operation and certain physiological vibrations such as breathing when the students simulate the basic operation of the surgical operation, the students can simulate the surgical operation condition, the capability of the students for meeting emergency conditions is greatly improved, and the device is practical.
Drawings
Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:
fig. 1 is a schematic structural diagram of a surgical basic operation simulation training device based on the medical field.
Fig. 2 is a schematic diagram of a normal placement state of the surgical basic operation simulation training device based on the medical field.
Fig. 3 is a schematic structural diagram of an induced vibration mechanism of a surgical basic operation simulated training device based on the medical field.
FIG. 4 is a schematic view of the placement of a simulated prosthesis of the induced vibration mechanism of the present invention.
FIG. 5 is a schematic view of the state of the simulated surgical operation of the induced vibration mechanism of the present invention.
Fig. 6 is a schematic structural diagram of a vibration sensor of the induced vibration mechanism according to the present invention.
In the figure: real-time display screen-1, screen support frame-2, distribution box-3, sensing line-4, protective frame-5, platform support foot-6, universal wheel-7, foot board-8, frame base-9, working platform-10, simulation prosthesis-11, detection power line-12, detection sensor-13, connecting fixing frame-14, placing platform-15, support base-16, induction vibration mechanism-17, vibration sensor-1701, shunt-1702, left side conductive plate-1703, elastic rope-1704, pressure button-1705, button support rod-1706, I-shaped conductive plate-1707, conductive vertical rod-1708, right side-1709, power line-17010, overload protector-17011, overload protector-1709, A right transmission gear-17012, a long transmission rod-17013, a central fixed shaft-17014, a right connecting gear-17015, a bevel gear-17016, a right micro motor-17017, a power distribution guide plate-17018, a connecting conductive plate-17019, a left micro motor-17020, a left connecting gear-17021, a short transmission rod-17022, a rotary circular gear-17023, a left transmission gear-17024, a motor-17025, a rotary fixed plate-17026, a transmission conductive plate-17027, a lower side-17028, an upper conductive plate-17029, a massage conductive plate-170101, a piston shell-170102, a piston conductive plate-170103, a ring type protective shell-170104, a piston base-170105 and a telescopic rod-170106.
Detailed Description
In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.
Referring to fig. 1 to 6, the present invention provides a basic operation simulation training device for surgical operation based on the medical field: the structure of the device comprises a real-time display screen 1, a screen supporting frame 2, a distribution box 3, a sensing wire 4, a protective frame 5, platform supporting legs 6, universal wheels 7, a pedal plate 8, a frame base 9, a working platform 10, a simulation prosthesis 11, a detection power wire 12, a detection sensor 13, a connecting and fixing frame 14, a placing platform 15, a supporting base 16 and an induction vibration mechanism 17, wherein the lower end of the real-time display screen 1 is mechanically connected to the upper end of the screen supporting frame 2, the lower end of the screen supporting frame 2 is screwed to the upper end of the supporting base 16, the lower end of the supporting base 16 is adhered to the middle part of the upper end of the placing platform 15, the connecting and fixing frame 14 is provided with four ends which are arranged on the distribution box 3, the lower end of the distribution box 3 is arranged at the rear end of the frame base 9, the rear side of the, the upper end of the frame base 9 is mechanically connected to the lower end of the working platform 10, the left end and the right end of the working platform 10 are attached to the protective frame 5, the middle of the upper end of the working platform 10 is provided with an induction vibration mechanism 17, the lower end of the simulation prosthesis 11 is in clearance fit with the upper end of the working platform 10, the middle of the upper end of the simulation prosthesis 11 is attached to the lower end of the detection sensor 13, the left end of the upper end of the detection sensor 13 is mechanically connected to the right end of the sensing line 4, the lower end of the detection power line 12 is electrically connected with a control main board inside the detection sensor 13, the platform support legs 6 are provided with four ends screwed to the frame base 9, the lower side of the front end of the frame base 9 is welded to the rear end of the pedal plate 8, the universal wheels 7 are provided with four ends screwed to the lower ends of the pedal plate 8 and the, A shunt 1702, a left side conductive plate 1703, a bungee 1704, a pressure button 1705, a button support 1706, an I-shaped conductive plate 1707, a conductive vertical bar 1708, a right side conductive plate 1709, a power cord 17010, an overload protector 17011, a right side transmission gear 17012, a long transmission rod 17013, a center fixed shaft 17014, a right side connection gear 17015, a helical gear 17016, a right side micro motor 17017, a power distribution plate 17018, a connection conductive plate 17019, a left side micro motor 17020, a left side connection gear 17021, a short transmission rod 17022, a rotary circular gear 17023, a left side transmission gear 17024, a motor 17025, a rotary fixed plate 17026, a transmission conductive plate 17027, a lower side conductive plate 17028, an upper side conductive plate 17029, an upper end of the overload protector 17011 is matched with a lower end of the vibration sensor 1701 through the power cord 17010, a left end of the overload protector 17011 is electrically connected with a right end of the power distribution plate 17018 through, the left end and the right end of the connecting conductive plate 17019 are connected with the right micro motor 17017 and the left micro motor 17020 through a power cord 17010, the right end of the right micro motor 17017 is adhered to the middle of the helical gear 17016, the right end of the helical gear 17016 is meshed with the left side of the right connecting gear 17015, the front end of the right connecting gear 17015 is matched with the upper end of the rotary circular gear 17023 through a right transmission gear 17012, the left end and the right end of the lower end of the rotary circular gear 17023 are welded on the upper ends of the long transmission rod 17013 and the short transmission rod 17022, the middle screw of the lower end of the rotary circular gear 17023 is connected with the upper end of the central fixed shaft 17014, the left end of the left micro motor 17020 is meshed with the right end of the left connecting gear 17021, the front end of the left connecting gear 17021 is matched with the upper end of the left transmission gear 17024, and the left end of the power, the left end of the motor 17025 is bonded to the middle of the right end of the rotating fixing plate 17026, the upper and lower ends of the rotating fixing plate 17026 are welded to the right end of the transmission conductive plate 17027, the upper and lower ends of the right end of the transmission conductive plate 17027 are respectively bonded to the upper conductive plate 17029 and the lower conductive plate 17028, the lower conductive plate 17028 and the upper conductive plate 17029 are connected to the lower end of the vibration sensor 1701 through a power cord 17010, the upper end of the power distribution conductive plate 17018 is welded to the lower end of a conductive vertical rod 1708, the upper end of the conductive vertical rod 1708 is in clearance fit with the lower end of the i-shaped conductive plate 1707, the left and right ends of the i-shaped conductive plate 1707 are respectively provided with a left conductive plate 1703 and a right conductive plate 1709, the right end of the right conductive plate 1709 is matched with the lower end of the, the elastic rope 1704 is provided with two ends, the lower ends of the elastic rope are welded to the left side and the right side of the upper end of the I-shaped conductive plate 1707, the left end of the left conductive plate 1703 is electrically connected to the lower end of the shunt 1702, the left end and the right end of the shunt 1702 are electrically connected to the lower end of the vibration sensor 1701 through a power cord 17010, the lower end of the placement platform 15 is welded to the upper end of the distribution box 3 and is of an integrated structure, the vibration sensor 1701 comprises a massage raised head 170101, a piston shell 170102, a piston conductive plate 170103, an annular protective shell 170104, a piston base 170105 and an: the lower end of the massage raised head 170101 is welded to the upper end of the telescopic rod 170106 and is of an integrated structure, the lower end of the piston base 170105 is mechanically connected to the upper end of the piston conductive plate 170103, the middle part of the outer surface of the piston conductive plate 170103 is bonded to the inner wall of the annular protective shell 170104, the outer surface of the telescopic rod 170106 is in clearance fit with the inner side of the piston shell 170102, the lower end of the piston shell 170102 is welded to the upper end of the piston base 170105, and the detection sensor 13 is connected with the real-time display screen 1 through the sensing wire 4, so that the human body condition can be displayed in real time, and simulated.
The electric machine 17025 of this patent is commonly referred to as a "motor" and refers to an electromagnetic device that converts or transmits electric energy according to the law of electromagnetic induction. The circuit is represented by a letter M (old standard is represented by D), the main function of the circuit is to generate driving torque which is used as a power source of electrical appliances or various machines, the generator is represented by a letter G, and the main function of the circuit is to convert electric energy into mechanical energy.
When the device is used, a worker firstly confirms whether the basic operation simulation training device based on the surgical operation in the medical field can be normally used and senses whether the vibration mechanism 17 is damaged, after no problem is confirmed, the device can be normally used, when the device is used, the worker firstly switches on the device, then places the simulation prosthesis 11 on the working platform 10, installs the detection sensor 13 on the simulation prosthesis 11, connects the simulation prosthesis with the real-time display screen 1 by using the sensing wire 4, when the simulation prosthesis 11 is placed on the working platform 10, the pressure button 1705 moves downwards due to the gravity of the simulation prosthesis 11, so as to drive the conductive plate 1707 to move downwards, so that the right conductive plate 1709 is connected with the left conductive plate 1703, when the right conductive plate 1709 is connected with the left conductive plate 1703, the vibration sensor 1701 moves, so as to simulate the breathing vibration of a patient in a normal state, when the learner performs the operation on the prosthesis 11, the pressure button 1705 will move down again to contact the vertical conductive rod 1708, so that the left micro motor 17020 and the right micro motor 17017 move, and finally the long transmission plate 17013 and the short transmission plate 17022 reciprocate, so that the device vibrates slightly, and when the I-shaped conductive plate 1707 contacts the vertical conductive rod 1708, the overload protector 17011 and the motor 17025 will operate normally, so that the device simulates the vibration of the patient during the treatment.
The invention solves the problems that in the prior art, when a basic operation simulation training device for a surgical operation is used for learning and training students, the state of a prosthesis is intelligently displayed, and in the actual state, when an operator performs the operation, a patient can generate some actions or vibrations and some physiological vibrations such as breath and the like, which greatly change the operation actions of medical personnel, equipment can not simulate the vibration of a human body, the cognition of the student to the surgical operation is greatly influenced, and the error memory of the student is easy to cause and is inconvenient, through the mutual combination of the components, an induction vibration mechanism is added on the equipment, so that when the basic operation of the surgical operation is simulated by the student, the patient can be simulated to generate some actions or vibrations during the operation, and some physiological vibrations such as breath and the like can be generated, thereby being more beneficial to the students to simulate the condition of the surgical operation, the ability of facing to emergency is greatly increased to the student, and the student is practical.
While there have been shown and described what are at present considered the fundamental principles and essential features of the invention and its advantages, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.
Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.
Claims (5)
1. The utility model provides a surgical operation basic operation simulation trainer based on medical field, its structure includes real-time display screen (1), screen support frame (2), block terminal (3), sensing line (4), protective frame (5), platform supporting legs (6), universal wheel (7), running-board (8), frame base (9), work platform (10), simulation false body (11), survey power cord (12), survey sensor (13), connect mount (14), place the platform (15), support base (16), response vibration mechanism (17), its characterized in that:
the lower end of the real-time display screen (1) is mechanically connected to the upper end of a screen support frame (2), the lower end of the screen support frame (2) is screwed to the upper end of a support base (16), the lower end of the support base (16) is adhered to the middle of the upper end of a placement platform (15), four connection fixing frames (14) are arranged at four ends of a distribution box (3), the lower end of the distribution box (3) is arranged at the rear end of a frame base (9), the rear side of the upper surface of the working platform (10) is connected to the lower side of the front end of the connection fixing frame (14) in a threaded manner, the upper end of the frame base (9) is mechanically connected to the lower end of the working platform (10), the left end and the right end of the working platform (10) are adhered to a protective frame (5), an induction vibration mechanism (17) is arranged in the middle of the upper end of the working platform (10), and the lower end of the simulation prosthesis (11, the middle part of the upper end of the simulated prosthesis (11) is attached to the lower end of the detection sensor (13), the left end of the upper end of the detection sensor (13) is mechanically connected to the right end of the sensing wire (4), the lower end of the detection power wire (12) is electrically connected with a control main board inside the detection sensor (13), four platform supporting legs (6) are arranged and screwed to four ends of the rack base (9), the lower side of the front end of the rack base (9) is welded to the rear end of the pedal plate (8), and four universal wheels (7) are arranged and screwed to the lower ends of the pedal plate (8) and the rack base (9);
the induction vibration mechanism (17) comprises a vibration sensor (1701), a shunt (1702), a left side conductive plate (1703), an elastic rope (1704), a pressure button (1705), a button supporting rod (1706), an I-shaped conductive plate (1707), a conductive vertical rod (1708), a right side conductive plate (1709), a power line (17010), an overload protector (17011), a right side transmission gear (17012), a long transmission rod (17013), a central fixed shaft (17014) and a right side connecting gear (17015), the device comprises a bevel gear (17016), a right micro motor (17017), a power distribution guide plate (17018), a connecting conductive plate (17019), a left micro motor (17020), a left connecting gear (17021), a short transmission rod (17022), a rotary circular gear (17023), a left transmission gear (17024), a motor (17025), a rotary fixing plate (17026), a transmission conductive plate (17027), a lower conductive plate (17028) and an upper conductive plate (17029);
the upper end of the overload protector (17011) is matched with the lower end of the vibration sensor (1701) through a power line (17010), the left end of the overload protector (17011) is electrically connected with the right end of the power distribution guide plate (17018) through the power line (17010), the lower end of the power distribution guide plate (17018) is welded at the upper end of the connecting conductive plate (17019), the left end and the right end of the connecting conductive plate (17019) are connected with the right micro motor (17017) and the left micro motor (17020) through the power line (17010), the right end of the right micro motor (17017) is adhered to the middle of the helical gear (17016), the right end of the helical gear (17016) is meshed at the left side of the right connecting gear (17015), the front end of the right connecting gear (17015) is matched with the upper end of the rotary circular gear (17023) through the right transmission gear (17012), the left end and the right end of the lower end of the rotary circular gear (17023) are welded at the upper ends of the long transmission rod, the middle part of the lower end of the rotary circular gear (17023) is in screw connection with the upper end of a central fixed shaft (17014), the left end of the left miniature motor (17020) is meshed with the right end of the left connecting gear (17021), the front end of the left connecting gear (17021) is matched with the upper end of a left transmission gear (17024), the left end of the power distribution guide plate (17018) is electrically connected with the right end of the motor (17025) through a power cord (17010), the left end of the motor (17025) is bonded with the middle part of the right end of the rotary fixing plate (17026), the upper end and the lower end of the rotary fixing plate (17026) are welded at the right end of a transmission conductive plate (17027), the upper end and the lower end of the right end of the transmission conductive plate (17027) are respectively bonded with the upper conductive plate (17029) and the lower conductive plate (17028), the lower conductive plate (17028) and the upper conductive plate (17029) are connected with the lower end, the upper end of the power distribution guide plate (17018) is welded to the lower end of the vertical conductive rod (1708), the upper end of the vertical conductive rod (1708) is in clearance fit with the lower end of the I-shaped conductive plate (1707), the left and right ends of the I-shaped conductive plate (1707) are respectively provided with a left conductive plate (1703) and a right conductive plate (1709), the right end of the right conductive plate (1709) is matched with the lower end of the vibration sensor (1701) through a power line (17010), the upper end of the I-shaped conductive plate (1707) is matched with the pressure button (1705) through a button supporting rod (1706), the elastic rope (1704) is provided with two elastic ropes, the lower ends of the two elastic ropes are welded on the left side and the right side of the upper end of the I-shaped conductive plate (1707), the left end of the left conductive plate (1703) is electrically connected to the lower end of the shunt (1702), the left end and the right end of the shunt (1702) are electrically connected with the lower end of the vibration sensor (1701) through power lines (17010); the vibration sensor (1701) comprises a massage raised head (170101), a piston shell (170102), a piston conductive plate (170103), an annular protective shell (170104), a piston base (170105) and a telescopic rod (170106).
2. The medical field-based surgical basic operation simulation training device as claimed in claim 1, wherein: the lower end of the placing platform (15) is welded to the upper end of the distribution box (3) and is of an integrated structure.
3. The medical field-based surgical basic operation simulation training device as claimed in claim 1, wherein: the lower end of the massage raised head (170101) is welded to the upper end of the telescopic rod (170106) and is of an integrated structure.
4. The medical field-based surgical basic operation simulation training device as claimed in claim 1, wherein: the lower end of the piston base (170105) is mechanically connected to the upper end of the piston conductive plate (170103), and the middle part of the outer surface of the piston conductive plate (170103) is bonded to the inner wall of the annular protective shell (170104).
5. The medical field-based surgical basic operation simulation training device as claimed in claim 1, wherein: the outer surface of the telescopic rod (170106) is in clearance fit with the inner side of the piston shell (170102), and the lower end of the piston shell (170102) is welded to the upper end of the piston base (170105).
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201711277841.7A CN107862961B (en) | 2017-12-06 | 2017-12-06 | Surgical operation basic operation simulation training device based on medical field |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201711277841.7A CN107862961B (en) | 2017-12-06 | 2017-12-06 | Surgical operation basic operation simulation training device based on medical field |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| CN107862961A CN107862961A (en) | 2018-03-30 |
| CN107862961B true CN107862961B (en) | 2020-07-31 |
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| CN201711277841.7A Expired - Fee Related CN107862961B (en) | 2017-12-06 | 2017-12-06 | Surgical operation basic operation simulation training device based on medical field |
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| CN108986585A (en) * | 2018-08-28 | 2018-12-11 | 上海光韵达数字医疗科技有限公司 | A kind of surgical operation number training platform |
| CN113012674A (en) * | 2021-03-15 | 2021-06-22 | 王海燕 | Device and method for interfering operation noise |
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| DE10130485C2 (en) * | 2001-06-25 | 2003-06-26 | Robert Riener | Programmable joint simulator |
| CN202694655U (en) * | 2012-05-28 | 2013-01-23 | 北京日正华瑞科技发展有限公司 | Endovascular intervention training simulator |
| CN105206153A (en) * | 2014-06-08 | 2015-12-30 | 刘健飞 | Holographic projection jet-propelled real-feeling simulation operation system |
| CN204423801U (en) * | 2015-02-09 | 2015-06-24 | 广东工业大学 | Abdominal touch teaching simulation people |
| CN106943272A (en) * | 2016-01-06 | 2017-07-14 | 王继文 | It is a kind of applied to being passive exercise device with of respectively organizing of human body |
| CN106420138A (en) * | 2016-10-27 | 2017-02-22 | 福建中医药大学 | Three-dimensional action control device capable of individually adjusting curvature sectional spine traction bed |
| CN206711474U (en) * | 2017-03-28 | 2017-12-05 | 杭州爱卓科技有限公司 | A kind of medical simulation integrated machine equipment |
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