JP5585713B2 - Fluid ejection device - Google Patents

Description

  The present invention relates to a fluid ejection device capable of switching between pulse flow ejection and continuous flow ejection, and a control method for the fluid ejection device.

  2. Description of the Related Art Conventionally, there is a surgical apparatus that supplies a liquid from a pump to a tube introduced into a body cavity at a high pressure, ejects the liquid from a nozzle at the distal end of the tube, and resects the tissue in the body cavity by fluid pressure (see, for example, Patent Document 1). ).

  In addition, a fluid ejecting apparatus has been proposed in which the volume of a fluid chamber is rapidly changed by a volume changing means, fluid is converted into a pulsating flow, the nozzle is pulsed at high speed, and a living tissue is excised or incised by impact pressure. (For example, refer to Patent Document 2).

JP 63-99853 A JP 2008-82202 A

  In Patent Document 1, since the high-pressure liquid is guided to the nozzle with a flexible tube, even if a pulsating flow is generated by a pump, the liquid is jetted continuously. When incising a living tissue by continuous flow jetting, the incision is performed so as to expand the surgical site by fluid pressure, and thus the liquid supply pressure must be increased in order to obtain sufficient excision ability.

  According to Patent Document 2, the fluid is converted into a pulsating flow by the volume changing means, and the pulse flow is ejected from the nozzle. At this time, since the incision and excision are performed so as to scrape the living tissue by the leading wave of the pulsed fluid or the impact pressure of the fluid particles, the fluid supply pressure may be low and the liquid supply amount may be small.

  As described above, the continuous flow injection and the pulse flow injection have different ablation ability and resection characteristics of living tissue, and therefore it is desirable to use the continuous flow and the pulse flow properly according to the surgical site and resection characteristics.

  Therefore, it is conceivable to use two types of fluid ejection devices for continuous flow ejection and pulse flow ejection. However, it is troublesome to use the fluid ejection device each time, and the workability is significantly reduced.

  Moreover, if the drive of the volume changing means is stopped in the fluid ejecting apparatus of Patent Document 2, continuous flow ejection becomes possible. However, the fluid supply pressure cannot be sufficiently obtained as it is, and there is a problem that the resecting capability is reduced. is there. In particular, in the configuration in which a high-pressure pulse flow is realized by the fluid inertance effect without the check valve as in Patent Document 2, the pipe cross-sectional area is very large in order to increase the inertance in a part of the flow path. Since it is made smaller or longer, the flow resistance becomes high, and even if the drive of the volume changing means is simply switched, it is difficult to obtain injection at a desired pressure by continuous flow injection.

  SUMMARY An advantage of some aspects of the invention is to solve at least a part of the problems described above, and the invention can be implemented as the following forms or application examples.

  Application Example 1 A fluid ejecting apparatus according to this application example includes a fluid chamber, a volume changing unit that changes the volume of the fluid chamber, a fluid supply unit that supplies fluid to the fluid chamber at a predetermined pressure, By operating the volume changing means to change the volume of the fluid chamber, the pulse flow injection for injecting the fluid in a pulsed manner and the pulse flow injection with the volume changing means stopped are more than the case of the pulse flow injection. Injecting command switching means for switching between continuous flow injection for increasing the fluid supply pressure from the fluid supply means and injecting the fluid is provided.

  Application Example 2 A method for controlling a fluid ejection device according to this application example includes supplying fluid to a fluid chamber, and pulse flow ejection that ejects the fluid in pulses by changing the volume of the fluid chamber. And switching the continuous flow injection for injecting the fluid by maintaining the volume of the fluid chamber, and the switching supplies the fluid chamber more than in the case of the pulse flow injection. The continuous flow injection is performed by increasing the pressure of the fluid.

  According to the configuration and the control method of the fluid ejecting apparatus according to the application example described above, one fluid ejecting apparatus can be switched to the pulse flow ejection or the continuous flow ejection by the ejection command switching unit. Therefore, even during the operation, the operation can be easily switched between the continuous flow injection and the pulse flow injection in accordance with the resection characteristics.

  Therefore, in the case of pulse flow injection, a high excision ability can be obtained with a small flow rate (low pressure), and an operation can be performed without obstructing the surgical field of view.

  Further, in the case of continuous flow injection, it is possible to perform an operation suitable for continuous flow injection, such as exfoliation of a living tissue, while increasing excision ability by increasing fluid supply pressure.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a configuration explanatory view showing a fluid ejecting apparatus as a surgical instrument according to a first embodiment. Sectional drawing which shows the cut surface which cut | disconnected the pulsating flow generation part which concerns on Embodiment 1 along the injection direction of the fluid. FIG. 2 is an explanatory block diagram illustrating a schematic configuration of a drive control unit according to the first embodiment. It is explanatory drawing which shows typically the ablation characteristic of continuous flow injection and pulse flow injection, (a) shows pulse flow injection, (b) shows continuous flow injection. Flow explanatory drawing which shows the control method of a fluid injection apparatus.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
The fluid ejecting apparatus according to the present invention can be applied in various ways such as drawing using ink or the like, washing of fine objects and structures, surgical scalpels, etc., but is suitable for incising or excising living tissue. An example will be described. Therefore, the fluid used in the embodiment is a liquid such as water or physiological saline.
(Embodiment 1)

  FIG. 1 is a configuration explanatory view showing a fluid ejecting apparatus as a surgical instrument according to the first embodiment. In FIG. 1, a fluid ejecting apparatus 1 includes a fluid supply container 2 that contains a fluid, a pump 10 as a fluid supply means, and a fluid supplied from the pump 10 in a pulsating flow (hereinafter sometimes referred to as a pulse flow). A pulsating flow generation unit 20 that converts the pulsating flow generation unit 20, a pump 10, and a drive control unit 15 that controls driving of the pulsating flow generation unit 20. The pump 10 and the pulsating flow generation unit 20 are connected by a fluid supply tube 4.

  The pulsating flow generation unit 20 is connected with a thin pipe-shaped connection flow channel tube 90, and a nozzle 95 having a fluid ejection opening 96 with a reduced flow channel diameter is inserted into the distal end portion of the connection flow channel tube 90. ing. The connection channel tube 90 has such a rigidity that it does not deform during fluid ejection.

  Further, the pulsating flow generation unit 20 has an injection command switching means 25, and in this embodiment, a pulse flow command switch 26 that selects pulse flow injection as the injection command switching means, and a continuous flow command that selects continuous flow injection. A switch 27 and an OFF switch 28 for stopping fluid ejection are provided.

  The flow of fluid in the fluid ejecting apparatus 1 configured as described above will be briefly described. The fluid stored in the fluid supply container 2 is sucked by the pump 10 and supplied to the pulsating flow generation unit 20 through the fluid supply tube 4 at a constant pressure. The pulsating flow generation unit 20 includes a fluid chamber 80 (see FIG. 2), a piezoelectric element 30 as a volume changing unit that changes the volume of the fluid chamber 80, and a diaphragm 40. Is driven to generate a pulsating flow in the fluid chamber 80, and the fluid is ejected from the fluid ejection opening 96 in a pulsed manner at a high speed via the connection channel tube 90 and the nozzle 95.

  Note that when the pulsating flow generation unit 20 stops driving, the fluid supplied from the pump 10 passes through the fluid chamber 80 and is continuously ejected from the fluid ejection opening 96.

  Here, the pulsating flow means a fluid flow in which the fluid flow direction is constant and the fluid flow rate or flow velocity is accompanied by periodic or irregular fluctuations. The pulsating flow includes an intermittent flow in which the flow and stop of the fluid are repeated. However, since the flow rate or flow velocity of the fluid only needs to fluctuate periodically or irregularly, the pulsating flow is not necessarily an intermittent flow.

  Similarly, ejecting fluid in pulses means ejecting fluid in which the flow rate or movement speed of the fluid to be ejected varies periodically or irregularly. An example of pulsed injection is intermittent injection in which fluid injection and non-injection are repeated. However, since the flow rate or moving speed of the fluid to be injected only needs to fluctuate periodically or irregularly, it is not always intermittent injection. Need not be.

Next, the structure of the pulsating flow generation unit 20 according to this embodiment will be described.
FIG. 2 is a cross-sectional view illustrating a cut surface obtained by cutting the pulsating flow generation unit according to the present embodiment along the fluid ejection direction. Note that FIG. 2 is a schematic diagram in which the vertical and horizontal scales of members or portions are different from actual ones for convenience of illustration. The pulsating flow generation unit 20 includes an inlet channel 81 that supplies a fluid from the pump 10 to the fluid chamber 80 via the fluid supply tube 4, a piezoelectric element 30 that serves as a volume changing unit that changes the volume of the fluid chamber 80, and the diaphragm 40. And an outlet channel 82 communicating with the fluid chamber 80. The fluid supply tube 4 is connected to the inlet channel 81.

  The diaphragm 40 is made of a disk-shaped thin metal plate and is in close contact with the case 50 and the case 70. In the present embodiment, the piezoelectric element 30 is an example of a laminated piezoelectric element, and one of both end portions is fixed to the diaphragm 40 and the other is fixed to the bottom plate 60.

  The fluid chamber 80 is a space formed by a recess formed on the surface of the case 70 facing the diaphragm 40 and the diaphragm 40. An outlet channel 82 is opened at a substantially central portion of the fluid chamber 80.

  The case 70 and the case 50 are joined and integrated on opposite surfaces. In the case 70, a connection flow channel pipe 90 having a connection flow channel 91 communicating with the outlet flow channel 82 is fitted, and a nozzle 95 is inserted in the tip of the connection flow channel pipe 90. The nozzle 95 has a fluid ejection opening 96 having a reduced flow path diameter.

Next, the configuration of the drive control unit of the present embodiment will be described.
FIG. 3 is a block diagram illustrating a schematic configuration of the drive control unit according to the present embodiment. The drive controller 15 includes a pump drive circuit 152 that controls the drive of the pump 10, a piezoelectric element drive circuit 153 that controls the drive of the piezoelectric element 30, and a control circuit 151 that controls the pump drive circuit 152 and the piezoelectric element drive circuit 153. And a main switch 24.

  The control circuit 151 includes a drive frequency of the pump 10 that determines the fluid supply amount (that is, supply pressure) from the pump 10 and a volume change amount (excluded volume) of the fluid chamber 80 that determines the excision force of one pulse. And a program for setting the frequency of volume change of the fluid chamber 80 (corresponding to the drive frequency of the piezoelectric element 30) for determining the resection speed.

  Next, the function of each switch will be described. The main switch 24 has a function of starting and stopping the fluid ejecting apparatus 1. Specifically, the main switch 24 turns on (starts up) and turns off (stops) the control circuit 151.

  The pulse flow command switch 26 activates the low pressure drive of the pump 10 and the pulsating flow generation unit 20, and the continuous flow command switch 27 performs high pressure drive of the pump 10 and stops the pulsating flow generation unit 20. When switching from pulse flow injection to continuous flow injection in the middle of driving of the fluid ejection device 1, the continuous flow command switch 27 may be operated (ON). When switching from continuous flow injection to pulse flow injection, the pulse flow command switch 26 may be operated (ON). Furthermore, when the injection is stopped, the OFF switch 28 may be operated.

  Next, the pulse flow ejection operation of the pulsating flow generation unit 20 in this embodiment will be described with reference to FIGS. The fluid discharge of the pulsating flow generation unit 20 of the present embodiment is performed by the difference between the synthetic inertance L1 on the inlet flow path 81 side and the synthetic inertance L2 on the outlet flow path 82 side.

First, inertance will be described.
The inertance L is expressed by L = ρ × h / S, where ρ is the density of the fluid, S is the cross-sectional area of the flow path, and h is the length of the flow path. When the pressure difference in the flow path is ΔP and the flow rate of the fluid flowing through the flow path is Q, the relationship of ΔP = L × dQ / dt is derived by modifying the equation of motion in the flow path using the inertance L. It is.

  That is, the inertance L indicates the degree of influence on the time change of the flow rate. The larger the inertance L, the less the time change of the flow rate, and the smaller the inertance L, the greater the time change of the flow rate.

  Here, the combined inertance L1 on the inlet channel 81 side is calculated in the range of the inlet channel 81. At this time, the fluid supply tube 4 that connects the pump 10 and the inlet channel 81 has flexibility, and may be deleted from the calculation of the combined inertance L1.

  The synthetic inertance L2 on the outlet flow channel 82 side is an inertance in the range of the outlet flow channel 82 and the connection flow channel 91 in the present embodiment. In addition, the thickness of the pipe wall of the connection flow path pipe 90 has sufficient rigidity with respect to fluid pressure propagation.

  In this embodiment, the flow path length and cross-sectional area of the inlet flow path 81 and the outlet flow path 82 are set so that the synthetic inertance L1 on the inlet flow path 81 side is larger than the synthetic inertance L2 on the outlet flow path 82 side. Set the channel length and cross-sectional area.

  A fluid is supplied to the inlet flow path 81 at a predetermined pressure by the pump 10. In addition, the fluid supply amount from the pump 10 may be an amount substantially equal to the pulse flow injection amount. Here, when the piezoelectric element 30 does not operate, the fluid flows into the fluid chamber 80 due to the difference between the discharge force of the pump 10 and the channel resistance on the entire inlet channel 81 side.

  When a drive signal is input to the piezoelectric element 30 and the piezoelectric element 30 suddenly extends in a direction perpendicular to the surface of the diaphragm 40 on the fluid chamber 80 side (arrow A direction), the volume of the fluid chamber 80 is reduced, and the fluid If the combined inertances L1 and L2 on the inlet channel 81 side and the outlet channel 82 side have a sufficient size, the pressure in the chamber 80 rises rapidly and reaches several tens of atmospheres.

  Since this pressure is much larger than the pressure by the pump 10 applied to the inlet channel 81, the inflow of fluid from the inlet channel 81 into the fluid chamber 80 is reduced by the pressure, and the pressure from the outlet channel 82 is reduced. Outflow increases.

  Furthermore, since the synthetic inertance L1 on the inlet flow path 81 side is larger than the synthetic inertance L2 on the outlet flow path 82 side, the amount of decrease in the flow rate flowing into the fluid chamber 80 from the inlet flow path 81 is larger than that of the outlet flow path 82. Since the increase amount of the discharged fluid is larger, pulsed liquid discharge, that is, pulsating flow is generated in the connection channel 91. The pressure fluctuation at the time of discharge propagates in the connection flow channel pipe 90 (connection flow channel 91), and the fluid is ejected from the fluid ejection opening 96 of the nozzle 95 at the tip.

  Here, since the flow path diameter of the fluid ejection opening 96 is smaller than the flow path diameter of the outlet flow path 82, the fluid has a higher pressure and is ejected at high speed as pulsed droplets.

  On the other hand, the fluid chamber 80 is in a low pressure state (close to a vacuum) immediately after the pressure rises due to the interaction between the decrease in the amount of fluid inflow from the inlet channel 81 and the increase in fluid outflow from the outlet channel 82. . When the piezoelectric element 30 is restored to its original shape, the fluid in the inlet flow path 81 flows before the operation of the piezoelectric element 30 (before expansion) after a lapse of a certain time due to both the pressure of the pump 10 and the low pressure state in the fluid chamber 80. ) Returns to the fluid chamber 80 at the same speed.

  If the piezoelectric element 30 is expanded after the fluid flow in the inlet channel 81 is restored, pulsed droplets are continuously ejected from the fluid ejection opening 96.

  When the pulsating flow generation unit 20 is stopped while the fluid supply from the pump 10 is continued at a predetermined pressure, the fluid passes through the inlet channel 81, the fluid chamber 80, and the outlet channel 82 and reaches the fluid ejection opening 96. At this time, since the piezoelectric element 30 is stopped, the fluid is ejected from the fluid ejection opening 96 as a continuous flow. In addition, since the flow path diameter of the fluid ejection opening 96 is much smaller than the flow path diameters of the outlet flow path 82 and the connection flow path 91, high-speed ejection is performed at a pressure higher than the supply pressure from the pump 10.

Next, ablation characteristics between continuous flow injection and pulse flow injection will be described.
FIGS. 4A and 4B are explanatory views schematically showing the ablation characteristics of continuous flow injection and pulse flow injection. FIG. 4A shows pulse flow injection, and FIG. 4B shows continuous flow injection. In the case of pulse flow injection, the body tissue is excised so as to be scraped off mainly by the leading wave of the pulsed fluid or the impact pressure of the fluid particles (indicated by arrow C in the figure). At this time, the factors that determine the excision force due to the impact pressure of one pulse determine the volume change amount (exclusion volume) of the fluid chamber 80 that determines the size of the fluid particle of the pulse flow and the velocity of the fluid particle of the pulse flow. The fluid supply pressure may be a low pressure because the speed of the volume of the fluid chamber 80 is reduced (corresponding to the driving time of the piezoelectric element 30 when the volume of the fluid chamber 80 is reduced).

  In the case of continuous flow injection, excision (incision) is performed while expanding the living tissue with the fluid pressure of the fluid that is continuously injected (indicated by arrow D in the figure). Therefore, the excision force due to the fluid pressure is affected by the fluid supply pressure by the pump 10. That is, in order to make the excision force due to the fluid pressure equal to or greater than the excision force due to the impact pressure, the fluid supply pressure of the pump 10 must be higher than in the case of pulse flow injection.

  As described above, it is possible to deal with various surgical objects by properly using the ablation characteristics of the pulse flow injection and the continuous flow injection.

Next, a control method in the case of using one fluid ejecting apparatus 1 by switching between pulse flow ejection and continuous flow ejection will be described.
(Control method of fluid ejection device)

  FIG. 5 is a flowchart illustrating a method for controlling the fluid ejection device. Reference is also made to FIGS. Table 1 shows the function of each switch related to the control command.

まず、メインスイッチ２４を操作して流体噴射装置１を起動させる（Ｓ１０）。つまり、制御回路１５１を立ち上げておく。次にパルス流噴射にするか連続流噴射にするかを選択する（Ｓ２０）。

First, the fluid ejection device 1 is activated by operating the main switch 24 (S10). That is, the control circuit 151 is started up. Next, whether to use pulse flow injection or continuous flow injection is selected (S20).

  When selecting the pulse flow injection, the pulse flow command switch 26 is operated to input the injection command 1 to the control circuit 151 (S21). When selecting the continuous flow injection, the continuous flow command switch 27 is operated to input the injection command 2 to the control circuit 151 (S40).

  First, the case of pulse flow injection will be described. With the input of the injection command 1, a drive command is input from the control circuit 151 to the pump drive circuit 152, and the pump 10 starts low pressure driving (S22). Then, fluid supply to the pulsating flow generation unit 20 is started at a constant pressure. Subsequently, a drive command is input from the control circuit 151 to the piezoelectric element driving circuit 153, the pulsating flow generation unit 20 (specifically, the piezoelectric element 30) is activated (S23), and pulse flow ejection is started.

  After the pulse flow injection is continued, the process proceeds to the next step when switching to the continuous flow injection is desired. Therefore, it is determined whether to switch to the continuous flow injection (S24). If the continuous flow injection is not performed, the pulse flow injection is continued as it is, and if it is stopped thereafter, the OFF switch 28 is operated to control the injection command 3. The data is input to the circuit 151 (S25). A stop command is input from the control circuit 151 to the piezoelectric element drive circuit 153 in accordance with the injection command 3, and the drive of the pulsating flow generation unit 20 (that is, the piezoelectric element 30) is stopped (S26), and the control circuit 151 transfers to the pump drive circuit 152. A stop command is input, and the pump 10 stops driving (S27), and the fluid ejection operation ends. Then, the main switch 24 is operated to stop the entire system of the fluid ejection device 1 (S50).

  When switching from pulse flow injection to continuous flow injection, the continuous flow command switch 27 is operated to input an injection command 2 to the control circuit 151 (S30). With the input of the injection command 2, a command is input from the control circuit 151 to the pump drive circuit 152 to drive the fluid supply pressure of the pump 10 higher than in the case of the pulse flow injection, and the pump 10 is driven at a high pressure (S31). .

  The fluid supply pressure in the case of continuous flow injection is preset to an appropriate pressure based on the object to be cut and the cutting characteristics, and the program is stored in the control circuit 151. The pulsating flow generation unit 20 stops driving almost simultaneously with the start of high-pressure driving of the pump 10 (S32), and starts continuous flow injection.

  After continuing the continuous flow injection, if it is desired to switch back to the pulse flow injection, it is determined whether to switch to the pulse flow injection (S33). In order to stop the operation, the OFF switch 28 is operated to input the injection command 3 to the control circuit 151 (S43). A pump drive stop command is input from the control circuit 151 to the pump drive circuit 152 in accordance with the injection command 3, and the pump 10 stops driving (S44), and the fluid injection is terminated. The entire system of the device 1 is stopped (S50).

  When switching from continuous flow injection to pulse flow injection again in step 33 (S33), the pulse flow command switch 26 is operated to input the injection command 1 to the control circuit 151 (S21). The pump 10 is switched to low pressure driving by the injection command 1 (S22), and then the pulsating flow generation unit 20 (that is, the piezoelectric element 30) is activated (S23), and the flow shifts to pulse flow injection. After that, selection control is performed on whether the continuous flow injection or the pulse flow injection is performed along the control steps after step 24 (S24).

  Next, a control method in the case of performing continuous flow injection after starting the fluid injection device 1 (S10) will be described. After the fluid ejection device 1 is activated, continuous flow ejection is selected (S20). Next, the continuous flow command switch 27 is operated to input the injection command 2 to the control circuit 151 (S40). In response to the input of the injection command 2, a command is input from the control circuit 151 to the pump drive circuit 152 to increase the fluid supply pressure of the pump 10 to drive it, and the pump 10 is driven at a high pressure (S41). Here, the fluid supply pressure from the pump 10 in the case of continuous flow injection is set higher than the supply pressure in the case of pulse flow injection.

  After continuing the continuous flow injection, it is determined whether to switch to the pulse flow injection (S42). If the flow does not shift to the pulse flow injection, the continuous flow injection is continued as it is. Then, the injection command 3 is input to the control circuit 151 (S43). A pump drive stop command is input from the control circuit 151 to the pump drive circuit 152 along with the injection command 3, and the pump 10 stops driving (S44), and the fluid injection ends. Then, the main switch 24 is operated to stop the entire system of the fluid ejection device 1 (S50).

  When switching from continuous flow injection to pulse flow injection in step 42 (S42), the pulse flow command switch 26 is operated to input the injection command 1 to the control circuit 151 (S21). The pump 10 is switched to low pressure driving by the injection command 1 (S22), and then the pulsating flow generation unit 20 (that is, the piezoelectric element 30) is activated (S23), and the flow shifts to pulse flow injection. After that, selection control is performed on whether the continuous flow injection or the pulse flow injection is performed along the control steps after step 24 (S24).

  According to the configuration and the control method of the fluid ejecting apparatus described above, one fluid ejecting apparatus can be used by selectively switching the pulse flow ejection or the continuous flow ejection by the ejection command switching means 25. Therefore, even during the operation, the operation can be easily switched between the continuous flow injection and the pulse flow injection in accordance with the resection characteristics.

  In the case of pulse flow injection, the body tissue is excised so as to be scraped off mainly by the leading wave of the pulsed fluid or the impact pressure of the fluid particles. Therefore, the factors that determine the ablation force due to the impact pressure of one pulse determine the volume change amount (exclusion volume) of the fluid chamber 80 that determines the size of the fluid particle of the pulse flow and the velocity of the fluid particle of the pulse flow. Since the speed of reducing the volume of the fluid chamber 80 (corresponding to the driving time of the piezoelectric element 30 when the volume of the fluid chamber 80 is reduced), the fluid supply pressure may be low.

  Therefore, in the case of pulse flow injection, a high excision ability can be obtained with a small flow rate (low pressure), and an operation can be performed without obstructing the surgical field of view.

  In the case of continuous flow injection, excision (incision) is performed while being expanded by the fluid pressure of the continuously injected fluid. Therefore, the excision force due to the fluid pressure is affected by the fluid supply pressure by the pump 10. That is, in order to make the excision force due to the fluid pressure equal to or greater than the excision force due to the impact pressure, the fluid supply pressure of the pump 10 must be higher than in the case of pulse flow injection. In particular, the present invention is effective in a configuration that realizes a high-pressure pulse flow by an inertance effect of a fluid without having a check valve, as in JP 2008-82202 A and this embodiment.

  Therefore, in the case of continuous flow injection, it is possible to perform an operation suitable for continuous flow injection such as exfoliation of a living tissue, while increasing the excision ability by increasing the fluid supply pressure.

  In this way, it is possible to deal with various surgical objects by properly using the ablation characteristics of the pulse flow injection and the continuous flow injection.

  The surgeon grasps the fluid ejection device 1 and performs an operation. Since the injection command switching means 25 is composed of a switch group provided in the fluid ejecting apparatus 1, the operator can select at hand whether to perform pulse flow injection, continuous flow injection, or injection stop, and workability is improved. Very good.

  In addition, when the pulse flow injection is selected, when the continuous flow injection is selected, and when the injection is stopped, the dedicated pulse flow command switch 26, the continuous flow command switch 27, and the OFF switch 28 are provided. A person can control the fluid ejecting apparatus to a desired fluid ejecting state by one operation, and can further improve workability.

  In the embodiment described above, the pulse flow injection and the continuous flow injection are switched by a switch. However, a sensor such as a camera is provided at the tip of the nozzle 65, and the pulse flow injection and the continuous flow injection are continuously performed according to the detection result of the sensor. You may switch between flow injection.

  For example, until the sensor detects the living tissue to be excised by the image recognition technique, the continuous flow injection is performed and the excision is performed while expanding the living tissue so that the nozzle 65 can easily enter the living body. By switching to pulse flow injection when detecting a tumor, it is possible for the surgeon to perform excision with a small amount of fluid for a living tissue that has a high risk of metastasis or the like when scattered, such as a malignant tumor, without requiring a switch operation. be able to.

  In the embodiment, the pulse flow injection and the continuous flow injection are switched by the switch. However, the pulse flow injection and the continuous flow injection may be switched according to the remaining amount of the fluid in the fluid supply container 2. For example, continuous flow injection is performed because a large amount of fluid can be used when the remaining amount of fluid is a predetermined amount or more, and pulse flow injection that can be excised with a small amount of fluid is performed when the remaining amount of fluid is less than a predetermined amount. It may be. In particular, in a region where a fluid such as a desert is precious, it is difficult to use the fluid indefinitely. Therefore, a configuration in which the pulse flow injection and the continuous flow injection are switched according to the remaining amount of the fluid is preferable.

  In the above-described embodiment, the diaphragm 40 is pressed by the piezoelectric element 30 to generate the pulsating flow. However, the present invention is not limited to this, and any other configuration may be used as long as the pulsating flow is generated. For example, the volume of the fluid chamber 80 may be reduced by driving a piston (plunger) using a piezoelectric element to generate a pulsating flow. Further, the liquid in the fluid chamber 80 may be formed into a bubble (bubble) by laser induction, and a pulsating flow may be generated by ejecting the bubble.

  DESCRIPTION OF SYMBOLS 1 ... Fluid injection apparatus, 10 ... Pump as fluid supply means, 20 ... Pulse flow generation part, 25 ... Injection command switching means, 26 ... Pulse flow command switch, 27 ... Continuous flow command switch, 28 ... OFF switch, 30 ... Piezoelectric element as volume changing means, 40 ... diaphragm, 80 ... fluid chamber, 96 ... fluid ejection opening.

Claims (5)

  A fluid chamber;
  Fluid supply means for supplying fluid to the fluid chamber;
  Pulsating flow imparting means for imparting pulsating flow to the fluid in the fluid chamber;
    An injection command input means for selectively inputting a pulse flow injection command for injecting a fluid in pulses and a continuous flow injection command for injecting a fluid continuously;
  Changing the flow rate or supply pressure of the fluid supplied by the fluid supply means to the fluid chamber based on the input to the injection command input means;
A fluid ejecting apparatus.   The fluid ejection device according to claim 1,
  When the input to the injection command input means is changed from the pulse flow injection command to the continuous flow injection command,
    Increasing the flow rate or supply pressure of the fluid supplied to the fluid chamber by the fluid supply means;
A fluid ejecting apparatus.   The fluid ejection device according to claim 1,
  When the input to the injection command input means is changed from the continuous flow injection command to the pulse flow injection command,
    Reducing the flow rate or supply pressure of the fluid supplied to the fluid chamber by the fluid supply means;
A fluid ejecting apparatus.   The fluid ejecting apparatus according to any one of claims 1 to 3,
  When the input to the injection command input means is the continuous flow injection command,
    Stopping the pulsating flow imparting means;
A fluid ejecting apparatus.   The fluid ejecting apparatus according to any one of claims 1 to 3,
  When the input to the injection command input means is the pulse flow injection command,
    Activating the pulsating flow imparting means;
A fluid ejecting apparatus.

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