CN111870317B - Control device, surgical instrument, and control method thereof - Google Patents

Abstract

The invention discloses a control device of an end effector, wherein a motor drives the end effector through a transmission mechanism; the control device comprises a signal source module and a control module; the signal source module is electrically connected with the control module, and the control module is electrically connected with the motor; and the control module receives the signal sent by the signal source module, analyzes and processes the signal, and instructs the motor to rotate or stop rotating according to the analyzed and processed signal so as to control the end effector. The invention realizes simple and effective control of the end effector by receiving the signal to control the rotation or stop the rotation of the motor.

Description

Control device, surgical instrument, and control method thereof

Technical Field

The present invention relates to a control device for an end effector, a control device for a cutting blade assembly, a control device for a surgical instrument, and a control method for a surgical instrument.

Background

Endoluminal staplers are well known and have found widespread use in intra-luminal procedures such as abdominal cavity.

Existing endoluminal cutting staplers generally include an operating assembly, a cutting blade assembly, a shaft assembly extending longitudinally from the operating assembly, and an end effector disposed at a distal end of the shaft assembly. The stapler also includes a motor. The end effector includes a cartridge housing for operably supporting a cartridge therein and a staple abutment pivotally connected to the cartridge housing, the staple abutment being selectively movable between an open position and a closed position to effect opening and closing of the end effector. The operation assembly comprises a body and a transmission mechanism arranged on the body. The motor drives the drive mechanism to operate, which drives the end effector to open or close and drive the cutter assembly forward or backward. However, the prior art controls for the end effector and the cutter assembly have drawbacks of complex construction. The existing anastomat comprises two motors, one motor drives an end effector and one motor drives a cutting knife assembly, but the two motors can lead the size and the weight of the anastomat to be large, and bring adverse effects to the operation convenience of the anastomat. If two motors are changed to one motor to drive both the end effector and the cutting blade assembly, and the action logic relationship therebetween needs to be satisfied with a relatively simple control device, the prior end effector and cutting blade assembly control device cannot satisfy the above-mentioned requirements.

Disclosure of Invention

The invention aims to provide a control device of a surgical instrument, which has a simple structure and is easy to realize.

In order to achieve the above purpose, the present invention is realized by the following technical scheme:

a control device of an end effector, wherein a motor drives the end effector through a transmission mechanism; the control device comprises a signal source module and a control module; the signal source module is electrically connected with the control module, and the control module is electrically connected with the motor; and the control module receives the signal sent by the signal source module, analyzes and processes the signal, and instructs the motor to rotate or stop rotating according to the analyzed and processed signal so as to control the end effector.

Further, the signal source module comprises a key, and the key is electrically connected with the control module; triggering the key, and after receiving a signal sent by the key, instructing the motor to rotate in a first direction or a second direction by the control module, wherein the motor rotates in the first direction to drive the end effector to be closed through the transmission mechanism, and the motor rotates in the second direction to drive the end effector to be opened through the transmission mechanism; the first direction is opposite to the second direction.

Further, the signal source module comprises a travel switch, and the travel switch is electrically connected to the control module; the transmission mechanism comprises a matching part, the motor rotates to drive the transmission mechanism to move, the matching part triggers the travel switch, and the control module receives signals sent by the travel switch and then instructs the motor to stop rotating.

Further, the travel switch comprises a third travel switch and a fourth travel switch; when the matching part triggers the third travel switch, the end effector is closed in place, and when the matching part triggers the fourth travel switch, the end effector is opened in place.

Further, the signal source module comprises a Hall sensor, and the Hall sensor is electrically connected with the control module; the transmission mechanism is provided with a magnet; the control module stores a predetermined value of magnetic field strength.

Further, the control module comprises a micro control unit, and the micro control unit analyzes and processes the signals received by the control module and then sends out low-level signals.

Further, the micro-control unit stores an action logic relationship between the end effector and the cutter assembly.

Further, the control module further includes a motor driving unit that converts the received low level signal into a high level signal and emits the high level signal.

Further, the control module further comprises a motor control unit, the motor control unit receives the high-level signal and recognizes a motor control signal in the high-level signal, and the motor control unit controls the running state of the motor according to the motor control signal.

Further, the control module further comprises a detection unit, and the detection unit is used for receiving the signal sent by the signal source module and transmitting the signal to the micro control unit.

A control device of a cutting knife assembly is characterized in that a motor drives the cutting knife assembly through a transmission mechanism; the control device comprises a signal source module and a control module; the signal source module is electrically connected with the control module, and the control module is electrically connected with the motor; and the control module is used for analyzing and processing the signals after receiving the signals sent by the signal source module, and instructing the motor to rotate or stop rotating according to the analyzed and processed signals so as to control the cutting knife assembly.

Further, the signal source module comprises a key, and the key is electrically connected with the control module; triggering the key, and after receiving a signal sent by the key, the control module instructs the motor to rotate along a first direction and releases the key, and after receiving the signal sent by the key, the control module instructs the motor to rotate along a second direction; the motor rotates in the first direction to drive the cutter assembly to move forwards through the transmission mechanism, and rotates in the second direction to drive the cutter assembly to move backwards through the transmission mechanism; the first direction is opposite to the second direction.

Further, the signal source module comprises a travel switch, and the travel switch is electrically connected to the control module; the transmission mechanism comprises a matching part, the motor rotates to drive the transmission mechanism to move, the matching part triggers the travel switch, and the control module receives signals sent by the travel switch and then instructs the motor to stop rotating.

Further, the travel switch comprises a first travel switch and a second travel switch; when the matching part triggers the first travel switch, the cutter assembly reaches a front dead point, namely a position where cutting is finished, and when the matching part triggers the second travel switch, the cutter assembly reaches a rear dead point, namely a position where retracting is finished.

Further, the signal source module comprises a Hall sensor, and the Hall sensor is electrically connected with the control module; the transmission mechanism is provided with a magnet; the control module stores a predetermined value of magnetic field strength.

Further, the signal source module comprises a key, the key is triggered, the control module receives a signal sent by the key, and no matter whether the control module receives a signal which is intended to drive the cutter assembly or not, the control module does not send a signal to instruct the motor to rotate, and then does not drive the cutter assembly within a preset time period from the time of receiving the signal; after a predetermined length of time has elapsed since the receipt of the signal, the control module sends a signal to instruct the motor to rotate and thereby drive the cutter assembly when the control module receives a signal intended to drive the cutter assembly.

Further, the signal source module includes a key, after the key is triggered, the control module receives a signal sent by the key, the key is triggered again in a preset time length, after the control module receives the signal sent by the key again, when the control module receives a signal which is intended to drive the cutter assembly, the control module sends a signal to instruct the motor to rotate, and then drives the cutter assembly.

Further, the predetermined time period is 15 seconds.

Further, the control module comprises a micro control unit, and the micro control unit analyzes and processes the signals received by the control module and then sends out low-level signals.

Further, the micro-control unit stores a logical relationship of motion between the end effector and the cutter assembly.

Further, the control module further includes a motor driving unit that converts the received low level signal into a high level signal and emits the high level signal.

Further, the control module further comprises a motor control unit, the motor control unit receives the high-level signal and recognizes a motor control signal in the high-level signal, and the motor control unit controls the running state of the motor according to the motor control signal.

Further, the control module further comprises a detection unit, and the detection unit is used for receiving the signal sent by the signal source module and transmitting the signal to the micro control unit.

A control device for a surgical instrument, the surgical instrument comprising an end effector, a cutting blade assembly, a transmission mechanism, and a motor that drives the end effector through the transmission mechanism and the cutting blade assembly through the transmission mechanism; the control device comprises a signal source module and a control module; the signal source module is electrically connected with the control module, and the control module is electrically connected with the motor; the control module analyzes and processes the signals after receiving the signals sent by the signal source module, and instructs the motor to rotate or stop rotating according to the analyzed and processed signals so as to control the end effector and the cutting knife assembly; the number of motors is one.

Further, the signal source module comprises a key, and the key is electrically connected with the control module; triggering the key, and after receiving a signal sent by the key, the control module instructs the motor to rotate in a first direction or a second direction so as to release the key, and after receiving the signal sent by the key, the control module instructs the motor to rotate in the second direction; the motor rotates in the first direction to drive the end effector to close through the transmission mechanism or drive the cutter assembly to move forwards through the transmission mechanism, and rotates in the second direction to drive the end effector to open through the transmission mechanism or drive the cutter assembly to move backwards through the transmission mechanism; the first direction is opposite to the second direction.

Further, the signal source module comprises a travel switch, and the travel switch is electrically connected to the control module; the transmission mechanism comprises a matching part, the motor rotates to drive the transmission mechanism to move, the matching part triggers the travel switch, and the control module receives signals sent by the travel switch and then instructs the motor to stop rotating.

Further, the signal source module comprises a Hall sensor, and the Hall sensor is electrically connected with the control module; the transmission mechanism is provided with a magnet; the control module stores a predetermined value of magnetic field strength.

Further, the signal source module comprises a key, the key is triggered, the control module receives a signal sent by the key, and no matter whether the control module receives a signal which is intended to drive the cutter assembly or not, the control module does not send a signal to instruct the motor to rotate, and then does not drive the cutter assembly within a preset time period from the time of receiving the signal; after a predetermined length of time has elapsed since the receipt of the signal, the control module sends a signal to instruct the motor to rotate and thereby drive the cutter assembly when the control module receives a signal intended to drive the cutter assembly.

Further, the signal source module includes a key, after the key is triggered, the control module receives a signal sent by the key, the key is triggered again in a preset time length, after the control module receives the signal sent by the key again, when the control module receives a signal which is intended to drive the cutter assembly, the control module sends a signal to instruct the motor to rotate, and then drives the cutter assembly.

Further, the predetermined time period is 15 seconds.

Further, the control module comprises a micro control unit, and the micro control unit analyzes and processes the signals received by the control module and then sends out low-level signals.

Further, the micro-control unit stores an action logic relationship between the end effector and the cutter assembly.

Further, the control module further includes a motor driving unit that converts the received low level signal into a high level signal and emits the high level signal.

Further, the control module further comprises a motor control unit, the motor control unit receives the high-level signal and recognizes a motor control signal in the high-level signal, and the motor control unit controls the running state of the motor according to the motor control signal.

Further, the control module further comprises a detection unit, and the detection unit is used for receiving the signal sent by the signal source module and transmitting the signal to the micro control unit.

A surgical instrument comprising an end effector, a motor and a transmission through which the motor drives the end effector, the surgical instrument further comprising a control device for the end effector of any one of the above.

A surgical instrument comprising a cutting blade assembly, a motor and a transmission mechanism, the motor driving the cutting blade assembly through the transmission mechanism, the surgical instrument further comprising a control device for the cutting blade assembly of any one of the preceding claims.

A surgical instrument comprising an end effector, a cutting blade assembly, a transmission mechanism, and a motor that drives the end effector via the transmission mechanism and the cutting blade assembly via the transmission mechanism, the surgical instrument further comprising a control device of the surgical instrument of any of the preceding claims.

A method of controlling a surgical instrument comprising an end effector, a control device, a transmission, and a motor, the control device comprising a signal source module and a control module; the signal source module is electrically connected with the control module, and the control module is electrically connected with the motor; the motor drives the end effector through the transmission mechanism; the signal source module comprises a first key, a second key, a third stroke signal element and a fourth stroke signal element; the control method comprises the following steps:

(1) Pressing the first key and keeping the first key pressed, and after receiving a signal sent by the first key, the control module instructs the motor to rotate, and the motor drives the end effector to be closed through the transmission mechanism;

(2) In the process of driving the end effector to close, the transmission mechanism triggers the third stroke signal element, the third stroke signal element sends a signal to the control module, the control module receives the signal sent by the third stroke signal element and then instructs the motor to stop rotating, and the end effector is closed in place;

(3) Pressing the second key and keeping the second key pressed, and after receiving a signal sent by the second key, the control module instructs the motor to rotate, and the motor drives the end effector to be started through the transmission mechanism;

(4) In the process of driving the end effector to be started, the transmission mechanism triggers the fourth stroke signal element, the fourth stroke signal element sends a signal to the control module, the control module receives the signal sent by the fourth stroke signal element and then instructs the motor to stop rotating, and the end effector is started in place.

Further, the surgical instrument further comprises a cutter assembly, the motor drives the cutter assembly through the transmission mechanism, the control method further comprises a step S1, and the step S1 is positioned between the step (2) and the step (3); the step S1 is as follows: the first key is pressed and kept pressed, the control module receives a signal sent by the first key and then instructs the motor to rotate, and the motor drives the cutter assembly to move forwards through the transmission mechanism.

Further, the signal source module further comprises a first travel signal element; the step S1 further includes: in the process of driving the cutter assembly to move forwards, the transmission mechanism triggers the first travel signal element, the first travel signal element sends a signal to the control module, the control module receives the signal sent by the first travel signal element and then instructs the motor to stop rotating, and the cutter assembly reaches a front dead point, namely a position where cutting is finished.

Further, the step S1 further includes: and after the cutter assembly reaches a front dead point, the first key is released, the control module receives a signal sent by the first key and then instructs the motor to rotate, and the motor drives the cutter assembly to move backwards through the transmission mechanism.

Further, the signal source module further comprises a second stroke signal element; the step S1 further includes: in the process of driving the cutter assembly to move backwards, the transmission mechanism triggers the second stroke signal element, the second stroke signal element sends a signal to the control module, the control module receives the signal sent by the second stroke signal element and then instructs the motor to stop rotating, and the cutter assembly reaches a rear dead center, namely a position where the cutter is retracted.

Further, the surgical instrument further comprises a press retention mechanism; the control method further includes a step S2, the step S2 is located between the step (2) and the step S1, and the step S2 is: and operating the pressing and maintaining mechanism, and implementing the step S1 after the pressing and maintaining mechanism is operated or the operation of the pressing and maintaining mechanism is terminated.

Further, the travel signal element is a travel switch, the transmission mechanism comprises a matching part, the matching part triggers the travel switch, and the control module receives a signal sent by the travel switch to instruct the motor to stop rotating.

Further, the stroke signal element is a hall sensor, the transmission mechanism comprises a magnet, and the control module judges that the control module instructs the motor to stop rotating after receiving that the magnetic field intensity of the magnet sensed by the hall sensor reaches a preset value.

Further, the signal source module further comprises a third key, the surgical instrument further comprises an indicating mechanism electrically connected with the control module, the third key is pressed and released instantly, the control module receives a signal sent by the third key to instruct the indicating mechanism to start working, and the operation of the pressing and holding mechanism is completed and comprises: pressing the third key and releasing instantly, wherein the indicating mechanism starts to work until the work is completed.

Further, the signal source module further includes a third button, the surgical instrument further includes an indication mechanism electrically connected to the control module, the third button is pressed and released immediately, the control module receives a signal sent by the third button to instruct the indication mechanism to start working, and the operation of the pressing and holding mechanism is terminated, including: pressing the third key and releasing instantly, and pressing the third key again and releasing instantly before the indicating mechanism works.

The beneficial effects of the invention are as follows: the surgical instrument comprises an end effector, a cutting knife assembly and a control device, wherein the control device comprises a motor, a signal source module and a control module, the control module analyzes and processes signals sent by the signal source module, and instructs the motor to rotate in a first direction, rotate in a second direction and stop rotating according to the analyzed and processed signals, so that the end effector and the cutting knife assembly are simply, conveniently and effectively controlled, and the action logic relation between the end effector and the cutting knife assembly is met.

Drawings

FIG. 1 is a schematic view of the construction of the stapler of the present invention;

FIG. 2 is an enlarged view of the circled portion illustrated in FIG. 1;

FIG. 3 is a schematic view of a portion of the stapler of FIG. 1 from another perspective;

fig. 4 is an enlarged view of the circled portion a shown in fig. 3;

fig. 5 is an enlarged view of the circled portion B shown in fig. 3;

FIG. 6 is a schematic view of a portion of the stapler of FIG. 3;

FIG. 7 is a schematic view of the first component of FIG. 6;

FIG. 8 is a schematic view of the third component of FIG. 6;

FIG. 9 is a schematic diagram of the circuit board assembly of FIG. 1;

fig. 10 is a schematic view of the motor drive unit shown in fig. 9;

FIG. 11 is an assembled view of the end effector and sleeve of FIG. 1;

FIG. 12 is an enlarged view of the circled portion illustrated in FIG. 11;

Detailed Description

The present invention will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present invention more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The terms "proximal", "posterior" and "distal", "anterior" are used herein with respect to a clinician manipulating a surgical instrument. The terms "proximal", "posterior" and "anterior" refer to portions relatively closer to the clinician, and the terms "distal" and "anterior" refer to portions relatively farther from the clinician. The "left" and "right" are referenced to the position of the surgical instrument shown in FIG. 1, e.g., the end effector is "left" and the cannula is "right". The terms "upper" and "lower" refer to the relative positions of the staple abutment and the cartridge seat of the end effector, specifically the staple abutment being "upper" and the cartridge seat being "lower". It is to be understood that these orientations of "near", "rear", "far", "front", "left", "right", "up" and "down" are defined for convenience of description, however, surgical instruments may be used in many orientations and positions, and the terms describing relative positional relationships are not intended to be limiting and absolute.

Referring now to fig. 1-12, a surgical instrument, and more particularly to a stapler 100, according to the present invention, includes an operating assembly 10, a shaft assembly 20 extending lengthwise from the operating assembly 10, and an end effector 30 disposed at one end of the shaft assembly 20. The end effector 30 includes a cartridge housing 31 and a staple abutment 32 pivotally connected to the cartridge housing 31, the cartridge housing 31 for operably supporting a staple cartridge (not shown) therein, the staple abutment 32 being selectively movable between an open position and a closed position. The shaft assembly 20 includes a mandrel 21 and a sleeve 22 sleeved on the mandrel 21. The operating assembly 10 includes a body (not shown) and a transmission mechanism 11 mounted to the body. The sleeve 22 includes a first end 23 connected to the drive mechanism 11 and a second end 24 movably connected to the abutment 32 of the end effector 30, with rearward movement of the sleeve 22 causing the abutment 32 to pivot upwardly to open the end effector 30 and forward movement of the sleeve 22 causing the abutment 32 to pivot downwardly to close the end effector 30. Referring to fig. 11 and 12, the abutment 32 is rotatably connected to the second end 24 of the sleeve 22, i.e., the abutment 32 is connected to the second end 24 of the sleeve 22 and the abutment 32 is rotatable relative to the second end 24 of the sleeve 22. It should be noted that the nail holder 32 is rotatably connected to the second end 24 of the sleeve 22, so that the forward and backward movement of the sleeve 22 drives the nail holder 32 to pivot as in the prior art.

Stapler 100 further includes a cutter assembly 40, cutter assembly 40 including a cutter 41 disposed in cartridge 33 and a pusher member 42 detachably coupled to cutter 41. Referring to fig. 4 and 5, the push cutter 42 is provided with a recess (not numbered) and the cutter 41 is provided with a protrusion (not numbered), and the recess and the protrusion are fitted to each other so that the push cutter 42 and the cutter 41 are assembled together. One end of the mandrel 21 is connected to the transmission mechanism 11, and the other end is located in the sleeve 22. A portion of the push-blade 42 extends into the end effector 30 and is detachably connected to the cutting blade 41, and another portion of the push-blade 42 is located within the sleeve 22 and is connected to the other end of the mandrel 21. The forward movement of the spindle 21 causes the cutter assembly 40 to move forward to cut tissue and the rearward movement of the spindle 21 causes the cutter assembly 40 to move rearward to return to the original position.

The anastomat 100 further comprises a circuit board assembly 50, a trigger 60 and a motor 70, wherein the trigger 60 is electrically connected to the circuit board assembly 50, the motor 70 drives the transmission mechanism 11 to work, and the number of the motors 70 is one. The circuit board assembly 50 includes a circuit board 51 and a control module 52 disposed on the circuit board 51, wherein the control module 52 is used for controlling the operation state of the motor 70. Stapler 100 further includes a press retention mechanism (not shown) that an operator must operate before driving cutter assembly 40 forward, and after the press retention mechanism is completed or the press retention mechanism is terminated, the operator can drive cutter assembly 40 forward through trigger 60, control module 52, and motor 70. The pressing holding mechanism holds the end effector 30 in the closed state (i.e., the pressed state) for a certain period of time, and by holding the pressed tissue for the certain period of time, the tissue fluid in the pressed target tissue is caused to be sufficiently discharged to the surrounding tissue that is not pressed.

The trigger 60 includes a first key 61, a second key 62, a third key 63, a fourth key 64, a first travel switch 65, a second travel switch 66, a third travel switch 67, and a fourth travel switch 68. The trigger 60 is also referred to as a signal source module. The first key 61 and the second key 62 are electrically connected to the control module 52.

The first travel switch 65 and the second travel switch 66 are electrically connected to the control module 52, and the first travel switch 65 and the second travel switch 66 are used for detecting the position of the cutter assembly 40 and stopping the movement of the cutter assembly 40 by the control module 52. The transmission mechanism 11 is provided with a mating portion including a third bump (not numbered) and a fourth bump (not numbered). When the transmission mechanism 11 drives the cutter assembly 40 to advance to a certain position through the mandrel 21, a third lug on the transmission mechanism 11 triggers the first travel switch 65, and the control module 52 receives a signal sent by the first travel switch 65 and instructs the motor 70 to stop rotating; the first travel switch 65 is located at a front dead center of the forward movement of the cutter assembly 40, i.e., a cut-out position. When the transmission mechanism 11 drives the cutter assembly 40 to retreat to a certain position through the mandrel 21, a fourth lug on the transmission mechanism 11 triggers the second travel switch 66, and the control module 52 receives a signal sent by the second travel switch 66 and instructs the motor 70 to stop rotating; the second travel switch 66 is positioned at a rear dead center of the rearward movement of the cutter assembly 40, i.e., a retracted position.

The anastomat 100 further comprises an indicating mechanism (not shown) electrically connected with the control module 52, wherein the indicating mechanism comprises five indicating lamps, and the indicating lamps are LED lamps. The third key 63 and the fourth key 64 are electrically connected to the control module 52, and the third key 63, the fourth key 64, the control module 52 and the indicating mechanism form a pressing and holding mechanism, which can enable the end effector 30 to press the target tissue for a certain period of time, so that the tissue fluid is discharged more fully, that is, the pressing and holding mechanism can not allow the cutter assembly 40 to move forward and hold the end effector 30 closed within a certain period of time, so as to promote the pressing effect of the end effector 30 on the tissue. The third key 63 and the fourth key 64 are symmetrically arranged, and an operator can perform the same function regardless of which of the third key 63 and the fourth key 64 is pressed. The operation modes of the press holding mechanism include a first operation mode and a second operation mode. The first mode of operation: the operator presses the third key 63 or the fourth key 64 and immediately releases the third key 63 or the fourth key 64, i.e. presses the third key 63 or the fourth key 64, the control module 52 receives the signal sent by the third key 63 or the fourth key 64 and instructs the indication mechanism to start working, one LED lamp is turned on every three seconds, when the indication mechanism is in the on state after 15 seconds, the indication mechanism is completed, at this time, the operator can operate the first key 61 to drive the cutter assembly 40 to move forward, and before the indication mechanism is completed, even if the operator operates the first key 61 to send a signal, the control module 52 does not instruct the motor 70 to rotate to drive the cutter assembly 40 to move forward. If the operator considers the tissue to be cut and stapled suitable for direct cutting and stapling without having to press for a certain length of time, a second mode of operation may be employed in order to save time by attempting to drive the cutter assembly 40 forward before the indicating mechanism is completed: pressing the third button 63 or the fourth button 64 and releasing it immediately, pressing the third button 63 or the fourth button 64 again and releasing it immediately within 15 seconds, at this time, the operator can operate the first button 61 to drive the cutter assembly 40 to move forward. In summary, the pressing effect can be enhanced by operating the press retention mechanism in a first mode of operation and the press retention mechanism in a second mode of operation such that the operator can operate the first key 61 to drive the cutter assembly 40 forward without waiting. The operation of the pressing and holding mechanism comprises the following steps: pressing the third key 63 or the fourth key 64 and releasing immediately, and starting the indicating mechanism until the operation is completed; the press retention mechanism operation is terminated including: the third key 63 or the fourth key 64 is pressed and released immediately, and the third key 63 or the fourth key 64 is pressed again and released immediately within 15 seconds. The press hold time exceeds 15 seconds and the operator may feel that the waiting time is too long, affecting the operator's use experience. The press holding time was set to 15 seconds, which is a balance point obtained between the waiting time and the press effect.

The third travel switch 67 and the fourth travel switch 68 are electrically connected to the control module 52, and the third travel switch 67 and the fourth travel switch 68 are used for detecting whether the end effector 30 is in place or closed. The motor 70 drives the transmission 11, and the transmission 11 drives the sleeve 22 to move forward or backward, thereby pivoting the anvil 32 downward or upward to close or open the end effector 30. The transmission mechanism 11 includes a mating portion including a first bump 12 and a second bump 13. In the process of driving the sleeve 22 to move forwards, the transmission mechanism 11 triggers the third travel switch 67 by the first lug 12, and the control module 52 receives a signal sent by the third travel switch 67 and instructs the motor 70 to stop rotating, and at the moment, the end effector 30 is closed in place; during the rearward movement of the drive sleeve 22, the second tab 13 activates the fourth travel switch 68 and the control module 52 receives a signal from the fourth travel switch 68 and instructs the motor 70 to stop rotating, at which point the end effector 30 is turned on. It should be noted that, the first bump 12 and the second bump 13 may be replaced by one bump, and the one bump triggers the third travel switch 67 during the forward movement and triggers the fourth travel switch 68 during the backward movement. In this case, the fitting portion includes the one projection.

The control module 52 includes a detection unit 53, a micro control unit 54, a motor driving unit 55, and a motor control unit 56. The micro control unit 54 is a single chip microcomputer. The first key 61, the second key 62, the third key 63, the fourth key 64, the first travel switch 65, the second travel switch 66, the third travel switch 67 and the fourth travel switch 68 are all electrically connected to the detecting unit 53, the detecting unit 53 is electrically connected to the micro-control unit 54, the micro-control unit 54 is electrically connected to the motor driving unit 55, and the motor driving unit 55 is electrically connected to the motor control unit 56. The detecting unit 53 is configured to detect the triggering states of the first key 61, the second key 62, the third key 63, the fourth key 64, the first travel switch 65, the second travel switch 66, the third travel switch 67, and the fourth travel switch 68, receive signals sent by the above keys and travel switches, and send the signals to the micro-control unit 54. The micro control unit 54 receives the signal from the detection unit 53 and analyzes the signal, the micro control unit 54 transmits the analyzed signal to the motor driving unit 55, the motor driving unit 55 receives the signal and analyzes the signal, the motor driving unit 55 transmits the analyzed signal to the motor control unit 56, and the motor control unit 56 controls the operation state of the motor 70 according to the high-level PWM wave signal from the motor driving unit 55. The motor driving unit 55 includes a first motor driving unit 57 and a second motor driving unit 58, and the first motor driving unit 57 and the second motor driving unit 58 are integrated circuits. The first motor driving unit 57 and the second motor driving unit 58 are each configured to convert a PWM wave signal of a low level, which is emitted from the micro control unit 54, into a PWM wave signal of a high level, which is used to drive the motor control unit 56. The motor driving unit 55 completes the conversion of the low level signal to the high level signal, enhancing the driving capability of the micro control unit 54. The first motor drive unit 57 and the second motor drive unit 58 share the tasks of the motor drive unit 55, avoiding overload of a single motor drive unit. The motor control unit 56 controls the operation state of the motor 70 according to the PWM wave signal of the high level emitted from the motor driving unit 55, that is, the motor control unit 56 recognizes motor operation information including motor rotation direction information and stop rotation information in the PWM wave signal of the high level while driving the motor 70 to rotate in the recognized rotation direction, or instructs the motor 70 to stop rotation, the rotation direction including a first direction and a second direction, the first direction being opposite to the second direction, using the high level signal. The motor 70 rotates in a first direction to drive the end effector 30 closed, or to drive the cutter assembly 40 forward; the motor 70 rotates in a second direction to drive the cutter assembly 40 rearward or to drive the end effector 30 open. The control module is provided with a pressing and holding mode, wherein the pressing and holding mode is started, namely, the pressing and holding mechanism operates, and the time for maintaining the pressing and holding mode is namely, the pressing and holding time. The value of the length of time for which the press is maintained is stored in the micro-control unit 54. From the start of operation of the press-holding mechanism, the micro-control unit 54 starts timing while sending a signal to the indicating mechanism to indicate the progress or state of press-holding. If the operator operates the first key 61 to send a signal during the operation of the press holding mechanism, the detection unit 53 transmits the received signal to the micro control unit 54, and the micro control unit 54 does not analyze and process the signal transmitted from the detection unit 53, i.e., the control module 52 does not instruct the motor 70 to operate to drive the cutter assembly 40, that is, although the intention of the signal sent from the first key 61 is to cause the control module 52 to instruct the motor 70 to operate to drive the cutter assembly 40, the intention is not achieved during the operation of the press holding mechanism; when the micro-control unit 54 counts the time to reach the predetermined time length value of the press holding, the press holding mechanism is operated, the micro-control unit 54 sends a signal to the indicating mechanism to indicate the press holding is finished, and the micro-control unit 54 returns to a state where the signal sent from the first key 61 can be analyzed and processed. During the operation of the press holding mechanism, if the operator presses the third key 63 or the fourth key 64 again and releases it instantaneously, the micro control unit 54 ends the timer and returns to a state in which the signal sent from the first key 61 can be analyzed and processed, i.e., the operation of the press holding mechanism is terminated. After the press holding mechanism is operated or the press holding mechanism is terminated, the intention of the signal from the first key 61 is fulfilled.

The stapler 100 operates as follows: (1) The operator presses the first button 61 and keeps the pressing state, the control module 52 receives a signal sent by the first button 61 and then instructs the motor 70 to work, the motor 70 drives the transmission mechanism 11 to work, the transmission mechanism 11 drives the nail supporting seat 32 to pivot downwards so as to close the end effector 30, when the transmission mechanism 11 triggers the third travel switch 67 in the working process, the control module 52 receives the signal sent by the third travel switch 67 and instructs the motor 70 to stop working, and at the moment, the end effector 30 is closed completely, and the first button 61 is released; (2) an operator operates the press retention mechanism; (3) After the operation of the pressing and holding mechanism is finished or after the operation of the pressing and holding mechanism is terminated, an operator presses the first key 61 and keeps the pressing state, the control module 52 instructs the motor 70 to work after receiving a signal sent by the first key 61, the motor 70 drives the transmission mechanism 11 to work, the transmission mechanism 11 drives the cutting knife assembly 40 to move forwards to cut tissues (namely feed), when the transmission mechanism 11 triggers the first travel switch 65 in the working process, the control module 52 instructs the motor 70 to stop working after receiving the signal sent by the first travel switch 65, and at the moment, the cutting knife assembly 40 stops moving forwards to cut the tissues; (4) Releasing the first key 61, the control module 52 receives the signal sent by the first key 61 and instructs the motor 70 to continue to start working, the motor 70 drives the transmission mechanism 11 to work, and the transmission mechanism 11 drives the cutter assembly 40 to move backwards (namely retract); when the transmission mechanism 11 triggers the second travel switch 66 in the working process, the control module 52 receives a signal sent by the second travel switch 66 and then instructs the motor 70 to stop working, at this time, the cutter assembly 40 stops moving backwards, and the cutter assembly 40 moves backwards into place; (5) The operator presses the second key 62 and keeps the pressing state, the control module 52 receives a signal sent by the second key 62 and then instructs the motor 70 to start working, the motor 70 drives the transmission mechanism 11 to work, the transmission mechanism 11 drives the nail supporting seat 30 to pivot upwards so as to open the end effector 30, when the transmission mechanism 11 triggers the fourth travel switch 68 in the working process, the control module 52 receives a signal sent by the fourth travel switch 68 and instructs the motor 70 to stop working, and at the moment, the end effector 30 is completely started. The operation of the motor 70 means that the motor 70 is operated, and the stop of the operation of the motor 70 means that the motor 70 is stopped.

In other embodiments, both the first and second travel switches 65, 66 may be replaced by hall sensors. The transmission mechanism 11 is provided with a magnet, and the position of the magnet relative to the Hall sensor changes in the process that the transmission mechanism 11 drives the mandrel 21 to move forwards or backwards, and the intensity of a magnetic field sensed by the Hall sensor also changes. The micro control unit 54 of the control module 52 previously sets and stores a first predetermined value and a second predetermined value. During the forward movement of the spindle 21 driven by the transmission 11, the hall sensor always sends a signal representing the magnetic field strength to the detection unit 53 of the control module 52, which detection unit 53 transmits to the micro-control unit 54. When the magnetic field strength sensed by the hall sensor reaches a first preset value, the micro control unit 54 of the control module 52 judges and instructs the motor 70 to stop running, at this time, the cutter assembly 40 stops moving forwards, and the tissue cutting is completed; during the rearward movement of the spindle 21 driven by the transmission 11, the hall sensor always sends a signal representing the magnetic field strength to the detection unit 53 of the control module 52, which detection unit 53 transmits to the micro control unit 54. When the magnetic field strength sensed by the hall sensor reaches a second predetermined value, the micro control unit 54 of the control module 52 makes a judgment and instructs the motor 70 to stop operating, at which time the cutter assembly 40 stops moving backward. The first predetermined value may be equal to the second predetermined value.

In other embodiments, the third and fourth travel switches 67 and 68 may each be replaced by a hall sensor. The transmission mechanism 11 is provided with a magnet, and the position of the magnet relative to the hall sensor changes in the process that the transmission mechanism 11 drives the sleeve 22 to move forwards or backwards, and the intensity of the magnetic field sensed by the hall sensor also changes. The micro control unit 54 of the control module 52 previously sets and stores a third predetermined value and a fourth predetermined value. During the forward movement of the sleeve 22 driven by the transmission 11, the hall sensor always sends a signal representing the magnetic field strength to the detection unit 53 of the control module 52, which detection unit 53 transmits to the micro-control unit 54. When the magnetic field strength sensed by the hall sensor reaches a third preset value, the micro control unit 54 of the control module 52 judges and instructs the motor 70 to stop running, and at this time, the end effector 30 is closed; during the backward movement of the sleeve 22 driven by the transmission 11, the hall sensor always sends a signal representing the magnetic field strength to the detection unit 53 of the control module 52, and the detection unit 53 transmits the signal to the micro control unit 54. When the magnetic field strength sensed by the hall sensor reaches a fourth predetermined value, the micro control unit 54 of the control module 52 determines and instructs the motor 70 to stop operating, and at this time, the end effector is turned on. The third predetermined value may be equal to the fourth predetermined value.

In the invention, the micro control unit (Microcontroller Unit, MCU for short) is a single chip microcomputer, and the micro control unit is an integrated chip integrating an internal processor (CPU), a memory (RAM, ROM), a counter and an I/O port. On the basis of the hardware circuit, the data to be processed, the calculation method, the steps and the operation commands are programmed and stored in the internal or external memory of the MCU, and the MCU can be automatically and continuously fetched from the memory and executed during operation. In the present invention, the operation and stop of the motor 70 are controlled by the micro control unit. The micro-control unit stores the action logic relation between the end effector and the cutter assembly, and sends out signals for controlling the motor after analyzing and processing signals sent by the keys, the travel switch or the Hall sensor according to the action logic relation. Simple and effective control of the end effector and the cutter assembly is achieved, and the action logic relationship between the end effector and the cutter assembly is satisfied.

The stapler 100 of the present invention may be provided with a buzzer (not shown) or an indicator light (not shown) to facilitate an operator in determining whether the motor 70 is stopped. The buzzer and the indicator lamp are electrically connected to the control module 52, and when the control module 52 instructs the motor 70 to stop running, the control module 52 also instructs the indicator lamp to light or the buzzer to sound. In addition, the operator may determine whether or not the motor 70 has stopped operating based on whether or not the sound generated when the motor 70 is operating can be heard.

In the present invention, as shown in connection with fig. 6-8, the transmission 11 includes a drive mechanism including a first drive mechanism for driving the end effector 30 closed and open and a second drive mechanism for driving the cutter assembly 40 forward and rearward. The number of motors 70 is one. The first drive means comprises a first part 81 and a second part 82, the first part 81 comprising a first active transition structure and a first idle transition structure, the first active transition structure driving the second part 82 in motion, the second part 82 driving the end effector 30 closed and open, the first idle transition structure not driving the second part 82. The first part 81 is a gear, the first part 81 is meshed with the gear 71 fixed on the output shaft of the motor 70, the first effective rotating path structure is a linear groove 83, the first idle rotating path structure is an arc groove 84 communicated with the linear groove 83, the second part 82 is a compression ring assembly comprising a convex column 85, the convex column 85 can move in the linear groove 83 and the arc groove 84, and the compression ring assembly 82 is connected with the sleeve 22. The second drive means includes a third member 91 and a fourth member 92, the third member 91 including a second active transition structure that drives the fourth member 92 in motion, the fourth member 92 driving the cutter assembly 40 forward and rearward, and a second idle transition structure that does not drive the fourth member 92. The third member 91 is a gear including a full-toothed portion 93 and a no-toothed portion 94, the no-toothed portion 94 includes a toothed portion 95 and a no-toothed portion 96, the full-toothed portion 93 is of a second effective revolution structure, the no-toothed portion 96 is of a second idle revolution structure, the toothed portion 95 and a portion of the full-toothed portion 93 parallel to the toothed portion 95 are meshed with the gear 71 fixed to the output shaft of the motor 70, the fourth member 92 is a gear meshed with a rack 97, and the rack 97 is connected to the spindle 21. The first drive means and the second drive means are driven by a single motor 70. In the present invention, the idle stroke means that the driving device has no motion output, i.e., does not drive the cutting blade or the end effector, when the driving device is driven with a motion input. The idle stroke structure is a structure that can realize an idle stroke and is provided in a component of the drive device. An effective transition means that the drive has a motion output, i.e. drives the cutting blade or the end effector, if the drive has a motion input, i.e. is driven. The effective transfer structure is a structure which is provided in a part of the driving device and can realize effective transfer.

In summary, the present invention can achieve simple and effective control of the end effector 30 and the cutter assembly 40 by receiving signals to control the operation state of the motor 70, i.e., rotation in the first direction, rotation in the second direction, and stopping rotation, and satisfy the action logic relationship therebetween. On the other hand, the transmission mechanism 11 triggers the third travel switch 67 in the process of driving the end effector 30 to close, so that the motor 70 stops running, and at this time, the end effector 30 is already closed; the transmission mechanism 11 triggers the fourth travel switch 68 in the process of driving the end effector 30 to be started, so that the motor 70 stops running, and at the moment, the end effector 30 is started completely; the provision of the third and fourth travel switches 67, 68 facilitates operator identification of whether the end effector 30 is in place or open. The third and fourth travel switches 67 and 68 may be replaced by hall sensors having the same function as the third and fourth travel switches 67 and 68.

While embodiments of the present invention have been shown and described above, it should be understood that the above embodiments are illustrative and not to be construed as limiting the present invention, and that variations, modifications, alternatives and variations may be made to the above embodiments by those skilled in the art within the scope of the present invention, all of which are within the scope of the present invention.

Claims (10)

1. A surgical instrument comprising an end effector, a motor, and a transmission mechanism through which the motor drives the end effector, characterized in that the surgical instrument further comprises a control device of the end effector, the control device comprising a signal source module and a control module; the signal source module is electrically connected with the control module, and the control module is electrically connected with the motor; the control module analyzes and processes the signals after receiving the signals sent by the signal source module, and instructs the motor to rotate or stop rotating according to the analyzed and processed signals so as to control the end effector; the transmission mechanism comprises a first driving device and a sleeve, wherein the first driving device is used for driving the end effector, the first driving device comprises a gear and a compression ring assembly, the compression ring assembly is connected with the first end part of the sleeve and the compression ring assembly, and the second end part of the sleeve is connected with the end effector; the gear drives the sleeve to move through the compression ring assembly, so as to drive the end effector to move; the gear comprises a first effective transfer structure and a first idle transfer structure, the first effective transfer structure drives the compression ring assembly to move, and the first idle transfer structure does not drive the compression ring assembly to move; the first effective transfer structure is a linear groove, and the first idle transfer structure is an arc groove communicated with the linear groove; the compression ring assembly comprises a convex column which is movably accommodated in the linear groove and the circular arc groove.

2. The surgical instrument of claim 1, wherein the signal source module comprises a key electrically connected to the control module; triggering the key, and after receiving a signal sent by the key, instructing the motor to rotate in a first direction or a second direction by the control module, wherein the motor rotates in the first direction to drive the end effector to be closed through the transmission mechanism, and the motor rotates in the second direction to drive the end effector to be opened through the transmission mechanism; the first direction is opposite to the second direction.

3. The surgical instrument of claim 1, wherein the signal source module comprises a travel switch electrically connected to the control module; the transmission mechanism comprises a matching part, the motor rotates to drive the transmission mechanism to move, the matching part triggers the travel switch, and the control module receives signals sent by the travel switch and then instructs the motor to stop rotating.

4. The surgical instrument of claim 3, wherein the travel switch comprises a third travel switch and a fourth travel switch; when the matching part triggers the third travel switch, the end effector is closed in place, and when the matching part triggers the fourth travel switch, the end effector is opened in place.

5. The surgical instrument of claim 1, wherein the signal source module comprises a hall sensor electrically connected to the control module; the transmission mechanism is provided with a magnet; the control module stores a predetermined value of magnetic field strength.

6. The surgical instrument of claim 2, wherein the control module includes a micro-control unit that analyzes and processes signals received by the control module to emit a low level signal.

7. The surgical instrument of claim 6, wherein the micro-control unit stores an action logic relationship between the end effector and the cutter assembly.

8. The surgical instrument of any one of claims 6, 7, wherein the control module further comprises a motor drive unit that converts the received low level signal to a high level signal and issues a high level signal.

9. The surgical instrument of claim 8, wherein the control module further comprises a motor control unit that receives the high level signal and that recognizes a motor control signal in the high level signal, the motor control unit controlling an operating state of the motor in accordance with the motor control signal.

10. The surgical instrument of any one of claims 6 and 7, wherein the control module further comprises a detection unit for receiving signals from the signal source module and transmitting the signals to the micro-control unit.