CN212382706U - Operation execution instrument - Google Patents

Abstract

A surgical executing instrument comprises an energy supplying part, an energy transmitting part and a signal switch part, wherein the energy supplying part is connected with the signal switch part to receive a switch signal, the energy supplying part is connected with a surgical workstation to transmit the switch signal, the surgical workstation controls the energy of a corresponding mode output by the energy supplying part according to the switch signal, the energy supplying part is connected with the energy transmitting part, and the energy transmitting part receives the energy and cuts or coagulates tissues. The utility model provides an operation execution apparatus, at the in-process of surgery operation, realized high frequency energy and ultrasonic energy and exported on this operation execution apparatus, the doctor only needs to carry out simple switch and can carry out the operation of tissue coagulation or tissue cutting very rapidly, and the structure is miniaturized and convenient operation, effectively promotes operation efficiency and success rate, benefits the patient.

Description

Operation execution instrument

Technical Field

The utility model relates to the technical field of medical equipment, in particular to an operation executing instrument.

Background

Ultrasonic surgical instruments have been increasingly used in surgery by virtue of their unique performance characteristics. The ultrasonic surgical instrument may be configured for open surgical use, laparoscopic or endoscopic surgery, and, depending on the particular instrument configuration and operating parameters, the ultrasonic surgical instrument is capable of tissue cutting and hemostasis, thereby facilitating minimization of patient trauma. Surgeons usually use ultrasonic surgical instruments to cut and coagulate tissues, while the existing tissue stripping and hemostasis operations in surgical operations respectively need to use different energy instruments, and the alternative use of various energy instruments causes the operation of medical staff to be very complicated, seriously affects the safety of the surgical operations, and even causes the failure of the surgical operations.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an operation execution apparatus solves the problem that above-mentioned prior art exists, and this operation execution apparatus has realized high-frequency energy and ultrasonic energy and has exported on this operation execution apparatus at the in-process of surgery operation, and the doctor only needs to carry out simple switch and can carry out the operation of tissue coagulation or tissue cutting very rapidly, and the structure is miniaturized and convenient operation effectively promotes operation efficiency and success rate, benefits the patient.

In order to achieve the above object, the present invention provides the following technical solutions:

a surgical instrument comprises an energy supply part, an energy transmission part and a signal switch part, wherein the energy supply part is connected with the signal switch part to receive a switch signal, the energy supply part is connected with a surgical workstation to transmit the switch signal, the surgical workstation controls the energy output of the energy supply part according to the switch signal, the energy supply part is connected with the energy transmission part, and the energy transmission part receives the energy and cuts or coagulates tissues.

Further, the energy provides the part including ultrasonic vibrator, transduction PCB board and conductive part, wherein, the conductive part connect in the transduction PCB board, ultrasonic vibrator's first end is equipped with piezoceramics, the transduction PCB board is fixed ultrasonic vibrator's second end, and connect switching signal is in order to receive switching signal, piezoceramics's the two poles of the earth the transduction PCB board is connected respectively the surgery workstation, ultrasonic vibrator's second end the conductive part is all connected energy transmission part, ultrasonic vibrator's first end with ultrasonic vibrator's second end is referred to respectively two looks remote terminals of ultrasonic vibrator axial direction.

Further, the energy transfer part comprises a switching PCB board, the switching PCB board is provided with a three-way loop circuit, one side of the transduction PCB board is provided with a connecting end, the connecting end is connected with the surgical workstation, the opposite side of the transduction PCB board is provided with at least three conductive columns, each loop circuit is correspondingly connected with at least one conductive column, and the switching PCB board is connected with the signal switch part to receive the switch signal; the surgical workstation controls the energy output of the energy supply part according to the switching signal, the surgical workstation is connected with two electrodes of the piezoelectric ceramic to output first energy, the energy transmission part receives the first energy and cuts tissue, the surgical workstation is connected with one electrode of the piezoelectric ceramic and the electric conduction part to output second energy, and the energy transmission part receives the second energy and coagulates the tissue.

The energy transfer part further comprises an amplitude transformer, an inner sheath and a tong head, wherein the amplitude transformer is connected with the front end of the ultrasonic vibrator, the inner sheath is sleeved outside the amplitude transformer and is electrically insulated from the amplitude transformer, the inner sheath can axially move along the amplitude transformer, and the tong head is rotatably connected to the outer end of the inner sheath and can be closed and opened relative to the amplitude transformer along with the axial movement of the inner sheath.

The energy transmission part further comprises a sleeve and a rod fixing sleeve, wherein the rod fixing sleeve is sleeved on the amplitude transformer and fixedly connected with the amplitude transformer, the sleeve is sleeved outside the rod fixing sleeve, the inner sheath is fixedly connected with the sleeve through a fixing piece, one end of the sleeve is connected with a boss at the end part of the inner sheath, and the sleeve drives the inner sheath to axially move in an avoiding groove formed in one end of the rod fixing sleeve.

Furthermore, the energy transmission part also comprises a sliding sleeve, an elastic part and a clamping and fixing part, the sliding sleeve, the elastic part and the clamping and fixing part are sequentially arranged on one side of the sleeve close to the ultrasonic vibrator, and the clamping and fixing part is fixedly connected to one side end of the sleeve to limit the elastic part.

Furthermore, the energy transfer part also comprises a rotating wheel, an outer sheath and a cutting sleeve, wherein the outer sheath is sleeved outside the inner sheath, the binding clip is rotatably connected to the inner sheath and positioned in front of the outer sheath, one end of the outer sheath is fixedly connected with the cutting sleeve, and the rotating wheel is sleeved outside the cutting sleeve and is fixedly connected with the cutting sleeve.

Furthermore, the energy transmission part also comprises a conductive piece which is clamped in the clamping groove at the other end of the rod fixing sleeve, one electric connection end of the conductive piece is connected with the conductive part, and the other electric connection end of the conductive piece is connected with the sleeve.

Further, the signal switch part comprises an FPC, a first switch key and a second switch key, wherein the circuit end at one end of the FPC is connected with the annular circuit of the switching PCB, and a switch elastic sheet connected with the other end of the FPC is clamped at the rear ends of the first switch key and the second switch key through clamping grooves respectively.

Further, the surgical executing instrument further comprises a housing part, the housing part comprises a trigger, a shifting block, an inner cavity structure with a handle, the inner cavity structure is formed by the first handle shell and the second handle shell, the rotating wheel and the rod fixing sleeve are installed in the inner cavity structure, the trigger is rotatably connected to the first handle shell, the shifting block is rotatably connected to the first handle shell, one end of the shifting block is connected with the trigger in a matched mode and driven by the trigger to rotate, and the other end of the shifting block is connected with the sliding sleeve to drive the sliding sleeve to move axially.

The utility model has the advantages that:

the utility model provides a surgical execution apparatus, including energy supply part, energy transmission part and signal switch part, wherein, the energy supply part is connected signal switch part in order to receive switching signal, and the energy supply part is connected surgical workstation in order to transmit switching signal, and surgical workstation is according to the energy of the corresponding mode of output of switching signal control energy supply part, and energy transmission part is connected to the energy supply part, and energy transmission part receives above-mentioned energy and cuts or the blood coagulation to the tissue. The utility model provides an operation execution apparatus, at the in-process of surgery operation, realized high frequency energy and ultrasonic energy and exported on this operation execution apparatus, the doctor only needs to carry out simple switch and can carry out the operation of tissue coagulation or tissue cutting very rapidly, and the structure is miniaturized, convenient operation and efficient, effectively promotes operation efficiency and success rate, benefits the patient.

Drawings

Fig. 1 is a schematic structural view of a surgical implement in an embodiment of the present invention;

FIG. 2 is an elevation view of a surgical implement in an embodiment of the present invention;

FIG. 3 is a top view of a surgical implement in an embodiment of the present invention;

fig. 4 is a sectional view taken along line a-a of fig. 3 according to an embodiment of the present invention;

fig. 5 is a schematic structural view of fig. 2 without a second handle shell installed in the embodiment of the present invention;

fig. 6 is a schematic structural diagram of an energy conversion PCB board in an embodiment of the present invention;

fig. 7 is a schematic structural view of another angle of the transduction PCB board in the embodiment of the present invention;

fig. 8 is an inside schematic view of an energy conversion PCB board according to an embodiment of the present invention;

fig. 9 is an inside view of the adapting PCB according to the embodiment of the present invention;

fig. 10 is a schematic view of a membrane switch and a flexible flat cable according to an embodiment of the present invention;

FIG. 11 is a schematic structural view of the energy supplying part and the energy transferring part according to the embodiment of the present invention;

fig. 12 is a sectional view taken along line B-B of fig. 11 according to an embodiment of the present invention.

In the figure, 10-energy supply part, 11-vibrator, 111-piezoelectric ceramic, 112-vibrator amplitude transformer, 12-shell body, 13-transduction PCB, 131-elastic column, 132-1/132-2/132-3/131-4-lead welding point, 133-lead, 133-1/133-2/133-3/133-4-connecting end, 134-copper sleeve, 14-cable fixing part, 15-screw, 20-energy transmission part, 21-switching PCB, 211-first line connecting end, 212-second line connecting end, 213-third line connecting end, 22-soft FPC, 221-first line connecting end, 222-second line connecting end, 223-third line connecting end, 23-inner sheath, 23-1-pin, 23-2-limit boss, 24-amplitude transformer, 25-sleeve, 26-rod fixed sleeve, 26-1-avoidance groove, 26-2-groove, 27-rotating wheel, 27-1-amplitude rod pin, 27-2-lug, 27-3-groove, 28-tong head, 28-1-high-temperature tissue pad, 29-sheath, 51-cutting sleeve, 51-1-bulge, 52-sliding sleeve, 53-wave spring, 54-phi 12 flat washer, 55-snap spring, 56-conducting strip, 30-switch and shell portion, 31-trigger, 311-circular arc groove, 32-shifting block, 321-semicircular convex ring, 322-circular end portion, 33-first handle shell, 331-convex shoulder, 332-convex shoulder, 35-handle, 36-bolt, 37-bolt, 38-pressure spring, 39-wrench, 41-A key, 42-B key, etc

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1 to 10, fig. 1 is a schematic structural diagram of a surgical operation performing instrument in an embodiment of the present invention, fig. 2 is a front view of the surgical operation performing instrument in an embodiment of the present invention, fig. 3 is a top view of the surgical operation performing instrument in an embodiment of the present invention, fig. 4 is a sectional view a-a of fig. 3 in an embodiment of the present invention, fig. 5 is a schematic structural diagram of fig. 2 without a second handle shell in an embodiment of the present invention, fig. 6 is a schematic structural diagram of a transducer PCB in an embodiment of the present invention, fig. 7 is a schematic structural diagram of another angle of the transducer PCB in an embodiment of the present invention, fig. 8 is a schematic internal side diagram of the transducer PCB in an embodiment of the present invention, fig. 9 is a schematic internal side diagram of a switch PCB in an embodiment of the present invention, fig. 10 is, fig. 11 is a schematic structural view of a connection between an energy supply part and an energy transmission part according to an embodiment of the present invention, and fig. 12 is a sectional view of fig. 11 taken along line B-B.

The surgical execution instrument provided by the embodiment belongs to the technical field of medical instruments, and is commonly used in surgical operations; at surgery's in-process, realized high frequency energy and ultrasonic energy and exported on this operation performance apparatus, the doctor only needs to carry out simple switch and can carry out tissue coagulation or tissue cutting operation very rapidly, and the structure is miniaturized and convenient operation effectively promotes operation efficiency and success rate, benefits the patient.

Referring specifically to fig. 1-5, the present embodiment provides a surgical instrument, which comprises the following three parts: an energy supply portion 10, an energy transfer portion 20, a switch and a housing portion 30.

In the present embodiment, the energy supply portion 10 of the surgical execution apparatus is specifically a transducer, and the transducer includes an ultrasonic vibrator 11 based on a piezoelectric ceramic 111, a housing body 12 for fixing the ultrasonic vibrator 11, a transduction PCB 13 for implementing switching signal transfer, and a cable fixing portion 14 for fixing a cable.

Referring to fig. 4-8 in particular, the vibrator 11 is fixed to one end of the housing body 12 in a penetrating manner, the vibrator 11 includes a piezoelectric ceramic 111 and a vibrator horn 112, the piezoelectric ceramic 111 is fixed to one end of the vibrator horn 112, the piezoelectric ceramic 111 is accommodated in the housing body 12, two electrodes of the piezoelectric ceramic 111 are respectively connected with two cables of the six-core cables, and one end of the vibrator horn 112 is connected with the horn 24 of the surgical execution apparatus through a screw 15, so as to output high-frequency energy.

With continued reference to fig. 4-8, the transducer PCB 13 is connected to the relay PCB 13 by six resilient posts 131 (conductive posts) disposed on its front side in a pairwise symmetry (ensuring reliable electrical connection) to receive switching signals, and transmits the switching signals to an external electrosurgical workstation by three of the wires 133 (connections 133-1/133-2/133-3) soldered to wire solder joints 132-1/132-2/132-3 disposed on the back side of the transducer PCB 13 and the other three of the six-core cables.

With continued reference to fig. 4-8, a copper sleeve 134 (conductive part) is welded to the central circular hole of the transduction PCB 13, the copper sleeve 134 is connected to a pad provided on the back side of the transduction PCB 13 and another wire 133 (connection terminal 133-4) welded to the wire welding point 132-4, the wire 133 is connected to the remaining one of the six-core cables, and the copper sleeve 134 can make uninterrupted electrical contact through the connection conductive sheet 56 (conductive part) to transmit high-frequency energy.

In this embodiment, referring to fig. 4-12, the energy delivery portion 20 of the surgical implement is described in greater detail below.

Specifically, the adapting PCB 21 is provided with three concentric ring circuits, every two axially symmetric elastic columns 131 on the transduction PCB 13 are in contact connection with each ring circuit (to ensure reliable electrical connection), and three switching signals controlled by the a button 41 and the B button 42 are connected to the back of the adapting PCB 21 through the flexible FPC 22. Specifically, the switching signals controlled by the a button 41 and the B button 42 can be transmitted to the external electrosurgical workstation by the circuit communication of the flexible FPC22, the adapting PCB 21 and the transduction PCB 13, the first line connecting end 221, the second line connecting end 222 and the third line connecting end 223 of the flexible FPC flexible flat cable of the flexible FPC22 are connected with the first line connecting end 211, the second line connecting end 212 and the third line connecting end 213 of the adapting PCB 21 in pairs (actually, typical three-wire switches), and the switching is convenient.

Referring specifically to fig. 4, 5, 11 and 12, the rotary wheel 27 and the rod fixing sleeve 26 are engaged with the shoulders (331, 332) formed by the first handle case 33 and the second handle case through the respective grooves (26-2, 27-3) provided at the outside thereof to perform positioning and installation. The outer sheath 29 is sleeved outside the inner sheath 23 and is clamped and fixed on the bulge 51-1 of the cutting sleeve 51 through the fixing grooves at two sides, the guide groove on the cutting sleeve 51 is matched and connected with the lug 27-2 inside the rotating wheel 27 for positioning and installation, and the rotation of the rotating wheel 27 can drive the cutting sleeve 51 and the outer sheath 29 to rotate together so as to accurately clamp tissues needing operation.

With continued reference to fig. 4, 5, 11 and 12, the sleeve 25 is sleeved outside the rod fixing sleeve 26, the inner sheath 23 is fixed on the sleeve 25 by the inner sheath pin, and the inner sheath 23 is driven by the inner sheath pin to move axially along the rod fixing sleeve 26, specifically, the limiting boss 23-2 thereof can move axially back and forth in the avoiding groove 26-1 of the rod fixing sleeve 26 under the traction of the sleeve 25. The sliding sleeve 52, the wave spring 53 and the phi 12 flat washer 54 are sequentially sleeved from the shoulder part of the sleeve 25, finally the snap spring 55 is clamped into the groove of the sleeve 25 for fixation, the elastic thrust is provided by the parts, when the sleeve 25 is pushed rightwards by the thrust, the wave spring 53 is compressed under the pressure to drive the inner sheath 23 to move rightwards, after the thrust is cancelled, the sleeve 25 drives the inner sheath 23 to reset, and the sleeve 25 is pushed to drive the inner sheath 23 to move backwards along the axial direction so as to close the forceps head 28.

With continued reference to fig. 4, 5, 11 and 12, the rod securing sleeve 26 is provided with two symmetrical slots, and a protrusion is provided in the slots for limiting the mounting positions of the two conductive strips 56, thereby ensuring stable mounting of the conductive strips 56. The sleeve 25 is made of a metal conductive material, and the conductive sheet 56 is respectively contacted with the wall surface of the copper sleeve 134 and the wall surface of the sleeve 25 through surface salient points so as to transmit the electric signal from the copper sleeve 134 to the sleeve 25 and further to sequentially transmit the electric signal to the inner sheath 23 and the tong head 28 through the inner sheath pin and the pin 23-1; the copper sleeve 134, the conductive sheet 56, the sleeve 25, the inner sheath 23 and the forceps head 28 are electrically connected at all times, and are used as one electrode for high-frequency energy transmission when high-frequency energy is transmitted.

With continued reference to fig. 4, 5, 11 and 12, the inner sheath 23 is sleeved outside the horn 24, and the horn 24 and the vibrator horn 112 are electrically insulated, and the inner sheath 23 can move back and forth relative to the horn 24 within a certain range along the axial direction of the horn 24, specifically, the inner sheath 23 is fixed on the sleeve 25 by an inner sheath pin, and the limit boss 23-2 at the end of the inner sheath 23 can move back and forth in the avoiding groove 26-1 of the rod fixing sleeve 26 under the traction of the sleeve 25.

With continued reference to fig. 4, 5, 11 and 12, the binding clip 28 is bolted into a pin hole provided at the end of the inner sheath 23 by a pin 23-1, and the binding clip 28 can rotate around the center of the pin 23-1; the square holes at the two sides of the front end of the inner sheath 23 are matched and connected with the salient points at the two sides of the tong head 28, when the inner sheath 23 moves back and forth along the axial direction under the driving of the sleeve 25, the tong head 28 can be pushed to rotate around the center of the pin 23-1, so that the tong head 28 is opened and closed, and when the tong head 28 is closed, the high-temperature tissue pad 28-1 clamped on the tong head 28 and the amplitude transformer 24 clamp tissues together to perform coagulation or cutting operation.

With continued reference to fig. 4, 5, 11 and 12, one end of the horn 24 is connected to the transducer through the screw 15, and is also fixed in the rotating wheel 27 and the rod fixing sleeve 26 through the horn pin 27-1, the rotating wheel 27 can drive the rod fixing sleeve 26 and the horn 24 to synchronously rotate through the horn pin 27-1, after the surgeon operates the surgical implement instrument to enter the surgical site, the rotating wheel 27 can be manually rotated to drive the horn 24 to synchronously rotate so as to accurately clamp the tissue to be operated, and the threaded connection between the transducer and the horn 24 can be conveniently tightened/loosened through the tool, so that the transducer can be conveniently installed and disassembled. The ends of the horn pin 27-1 are axially restrained by annular portions formed by the internal structures of the first and second handle cases 33, 33.

Specifically, the transduction PCB 13 receives an ultrasonic switching signal of the switching PCB 21, and transmits the switching signal to an external electrosurgical workstation through a wire 133 and a cable, the external electrosurgical workstation controls the operation execution instrument to operate in an ultrasonic mode, the external electrosurgical workstation applies a high-frequency electrical signal to two electrodes of the piezoelectric ceramic 111 through the cable, the piezoelectric ceramic 111 is driven to perform physical compression, the generated ultrasonic energy is subjected to amplitude amplification through the amplitude transformer 24 and then acts on a tissue, the ultrasonic energy does ultrasonic vibration relative to the high-temperature tissue pad 28-1 through the amplitude transformer 24, and the tissue is clamped between the two electrodes along with the ultrasonic vibration to perform cell lysis and protein denaturation, so that tissue vaporization, separation and coagulation are realized, and tissue cutting is realized.

Specifically, the transduction PCB 13 receives a high-frequency switching signal from the switching PCB 21 and transmits the switching signal to an external electrosurgical workstation through a wire 133 and a cable, the external electrosurgical workstation controls the operation execution apparatus to work in a high-frequency mode, and the external electrosurgical workstation transmits a path of high-frequency current to the amplitude transformer 24 through one of the electrodes on the vibrator 11 and the vibrator 11 itself; the other path of high-frequency current is transmitted to the sleeve 25 through the conductive copper sleeve 134 and the conductive sheet 56 at the central position of the transduction PCB (3-3), and finally transmitted to the forceps head 28 through the inner sheath 23, and when the surgical execution instrument works in a high-frequency mode, high-frequency energy acts on the amplitude transformer 24 and the forceps head 28 respectively to form high-frequency current between the two electrodes, so that tissue coagulation is realized.

In this embodiment, the switch of the surgical instrument and the housing portion 30 for holding the energy supply portion 10 and the energy transmission portion 20, the switch portion providing the switching function of the functional mode.

Referring specifically to fig. 5, the housing portions including trigger 31, paddle 32, and first and second handle shells 33 and 33 form an internal cavity structure having handle 35.

The rotating wheel 27 and the rod fixing sleeve 26 are clamped on shoulders (331, 332) formed by the first handle shell 33 and the second handle shell through grooves (26-2, 27-3) arranged outside the rotating wheel and the rod fixing sleeve respectively for positioning and installation; the adapting PCB 21 is engaged in the annular groove formed by the first handle case 33 and the second handle case for positioning and installation.

Specifically, a shaft hole is formed in the middle of the shifting block 32, the plug 37 is inserted to be connected to the first handle shell 33, a semicircular convex ring 321 is formed at one end of the shifting block 32, a circular end 322 is formed at the other end of the shifting block 32, the shifting block 32 is clamped in a groove formed in the sliding sleeve 52 through the semicircular convex ring 321, and the shifting block 32 can drive the sliding sleeve 52 to move axially along the sleeve 25. The upper end of the trigger 31 is provided with a circular arc groove 311, the circular end 322 of the half-containing shifting block 32, a shaft hole is arranged beside the circular arc groove 311 of the trigger 31, and the bolt 36 is inserted to be connected with the first handle shell 33; when the trigger 31 is pulled by a finger, the trigger 31 rotates around the pin 36 and is matched with the circular end 322 through the circular arc groove 311, so as to drive the shifting block 32 to rotate around the pin shaft 37, further push the sliding sleeve 52 to move axially back and forth along the sleeve 25, and further drive the inner sheath 23 to move axially back and forth, thereby realizing the opening and closing actions of the forceps head 28.

Furthermore, the compression spring 38 is sleeved on a boss arranged on the trigger 31, and one end of the compression spring 38 abuts against the inner cavity wall of the first handle shell 33, so that a damping effect is provided for operating the trigger 31, the hand feeling is enhanced, and the normal reset function of the trigger 31 is realized.

Further, the surgical executing instrument is also provided with a wrench 39, and the wrench 39 is sleeved at the end part of the rotating wheel 27 and used for screwing the threaded connection between the transducer and the amplitude transformer 24, so that the transducer can be conveniently mounted and dismounted.

In this embodiment, the switch portion includes a flexible FPC22, an a button 41 and a B button 42, wherein one end of the flexible FPC22 is inserted into an FPC socket provided on the adapting PCB 21, and a switch elastic piece portion at the other end of the flexible FPC22 is clamped at the tail portions of the a button 41 and the B button 42 through a clamping groove, so that when the a button 41 and the B button 42 are pressed, the a button 41 and the B button 42 slide along a guide groove formed by the first handle case 33 and the second handle case to control on/off of the switch, and the switching between the two modes (the high frequency mode and the ultrasonic mode) is realized by pressing the a button 41 or the B button 42.

The above embodiments are only used for illustrating the technical solutions of the present invention and not for limiting, the present invention has been described in detail with reference to the preferred embodiments, and those skilled in the art should understand that modifications or equivalent substitutions can be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions, and all the solutions should be covered in the scope of the claims of the present invention.

Claims (10)

1. A surgical implement, comprising:

the surgical executing instrument comprises an energy providing part, an energy transmitting part and a signal switch part, wherein the energy providing part is connected with the signal switch part to receive a switch signal, the energy providing part is connected with a surgical workstation to transmit the switch signal, the surgical workstation controls the energy output of the energy providing part according to the switch signal, the energy providing part is connected with the energy transmitting part, and the energy transmitting part receives the energy and cuts or coagulates tissues.

2. The surgical implement of claim 1, wherein: the energy provides the part including ultrasonic vibrator, transduction PCB board and conductive part, wherein, the conductive part connect in the transduction PCB board, ultrasonic vibrator's first end is equipped with piezoceramics, the transduction PCB board is fixed ultrasonic vibrator's second end, and connects switching signal is in order to receive switching signal, piezoceramics's the two poles of the earth the transduction PCB board is connected respectively surgery workstation, ultrasonic vibrator's second end the conductive part all connects energy transmission part, ultrasonic vibrator's first end with ultrasonic vibrator's second end is respectively referred to two looks opposites ends of ultrasonic vibrator axial direction.

3. The surgical implement of claim 2, wherein: the energy transmission part comprises a switching PCB, the switching PCB is provided with a three-way annular circuit, one side of the transduction PCB is provided with a connecting end, the connecting end is connected with the surgical workstation, the opposite side of the transduction PCB is provided with at least three conductive columns, each annular circuit is correspondingly connected with at least one conductive column, and the switching PCB is connected with the signal switch part to receive the switching signal;

the surgical workstation controls the energy output of the energy supply part according to the switching signal, the surgical workstation is connected with two electrodes of the piezoelectric ceramic to output first energy, the energy transmission part receives the first energy and cuts tissue, the surgical workstation is connected with one electrode of the piezoelectric ceramic and the electric conduction part to output second energy, and the energy transmission part receives the second energy and coagulates the tissue.

4. A surgical implement according to claim 3, wherein: the energy transfer part further comprises an amplitude transformer, an inner sheath and a tong head, wherein the amplitude transformer is connected with the second end of the ultrasonic vibrator, the inner sheath is sleeved outside the amplitude transformer and is electrically insulated from the amplitude transformer, the inner sheath can move axially along the amplitude transformer, and the tong head is rotatably connected to the outer end of the inner sheath and can be closed and opened relative to the amplitude transformer along with the axial movement of the inner sheath.

5. The surgical implement of claim 4, wherein: the energy transmission part further comprises a sleeve and a rod fixing sleeve, wherein the rod fixing sleeve is sleeved on the amplitude transformer and fixedly connected with the amplitude transformer, the sleeve is sleeved outside the rod fixing sleeve, the inner sheath is fixedly connected to the sleeve through a fixing piece, one end of the sleeve is connected with a boss at the end part of the inner sheath, and the sleeve drives the inner sheath to axially move in an avoiding groove formed in one end of the rod fixing sleeve.

6. The surgical implement of claim 5, wherein: the energy transmission part further comprises a sliding sleeve, an elastic piece and a clamping fixing piece, the sliding sleeve, the elastic piece and the clamping fixing piece are sequentially arranged on one side, close to the ultrasonic vibrator, of the sleeve, and the clamping fixing piece is fixedly connected to one side end of the sleeve to limit the elastic piece.

7. The surgical implement of claim 6, wherein: the energy transmission part further comprises a rotating wheel, an outer sheath and a clamping sleeve, wherein the outer sheath is sleeved outside the inner sheath, the forceps head is rotatably connected to the inner sheath and located in front of the outer sheath, one end of the outer sheath is fixedly connected with the clamping sleeve, and the rotating wheel is sleeved outside the clamping sleeve and fixedly connected with the clamping sleeve.

8. The surgical implement of claim 7, wherein: the energy transmission part also comprises a conductive piece which is clamped in the clamping groove at the other end of the rod fixing sleeve, one electric connection end of the conductive piece is connected with the conductive part, and the other electric connection end of the conductive piece is connected with the sleeve.

9. The surgical implement of claim 8, wherein: the signal switch part comprises an FPC, a first switch key and a second switch key, wherein the circuit end at one end of the FPC is connected with the annular circuit of the switching PCB, and a switch elastic sheet connected with the other end of the FPC is clamped at the rear ends of the first switch key and the second switch key through clamping grooves respectively.

10. The surgical implement of claim 9, wherein: the surgical executing instrument further comprises a housing part, the housing part comprises an internal cavity structure which is formed by a trigger, a shifting block, a first handle shell and a second handle shell and is provided with a handle, the rotating wheel and the rod fixing sleeve are installed in the internal cavity structure, the trigger is rotatably connected to the first handle shell, the shifting block is rotatably connected to the first handle shell, one end of the shifting block is connected with the trigger in a matched mode and driven by the trigger to rotate, and the other end of the shifting block is connected with the sliding sleeve to drive the sliding sleeve to move axially.

Images