JPS60106461A - Drive apparatus of medical machinery - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

Detailed Description of the Invention [Technical Field] The present invention relates to a device for driving medical equipment such as an artificial heart or an intra-aortic balloon pump, and particularly relates to a device for driving a medical device such as an artificial heart or an intra-aortic balloon pump, and particularly relates to a device for driving a medical device such as an artificial heart or an intra-aortic balloon pump. It relates to a drive device.

[Prior Art] From the viewpoint of safety, it is important for an artificial heart to be driven so as to provide blood with a pulsating flow that closely resembles the pulsation of a living heart. Various types of artificial hearts are known, such as a diaphragm type, a sack type, and a piston type, and these are generally driven by receiving a predetermined pressure from a fluid such as air. In order to drive an artificial heart under the best conditions depending on the condition of the living body, a drive device that outputs accurate pressure according to the conditions at a predetermined timing is required. In other words, the heart rate, positive pressure (positive pressure), depressurization (negative pressure), duration of applying positive pressure and depressurization to the artificial heart, duty ratio, etc. are all accurately and quickly set to predetermined values. A drive system that can In conventional artificial heart drive devices, mechanical pressure reducing valves and the like are used in the positive pressure system and the positive pressure system, respectively, as means for obtaining accurate pressure. In the artificial heart drive device, the output end of the positive pressure system and the output end of the positive pressure system are connected to each other in order to alternately apply positive pressure and depressurization to the artificial heart. For switching, electromagnetic valves for opening/closing control are provided at the output end of the positive pressure system and the output end of the positive pressure system, respectively. These electromagnetic valves are controlled by a control device to alternately open and close at predetermined timings according to a set heart rate. By the way, this type of artificial heart drive device has to be equipped with many devices such as a compressor, a vacuum pump, a tank (accumulator), a solenoid valve, and a control device, so the device becomes quite large.

Artificial hearts are used, for example, to assist a living body's heart during surgery, but because there are many doctors and surgical instruments around the operating table during surgery, a large artificial heart drive is required during surgery. The device cannot be placed near the operating table. However, the heart rate of the artificial heart must be able to be changed at any time depending on the patient's physical condition. For this reason, conventionally, the artificial heart drive device has been placed at a location away from the operating table, and the two artificial heart drive devices have been operated by a dedicated operating technician under the direction of a doctor. However, in order to drive the artificial heart under optimal conditions, it is desirable for a doctor to directly operate the artificial heart drive device.

Therefore, the applicant uses a solenoid valve to adjust the pressure.
Artificial heart drive device that is equipped with a remote control device on a drive device that can electrically control various parameters (Japanese Patent Application No. 57-5
No. 2143) was proposed. According to this, all necessary artificial heart drive parameters can be remotely controlled.

By the way, in this type of artificial heart drive device, positive pressure and depressurization are applied alternately to the artificial heart, so fluid must be alternately sucked in and discharged, and a large amount of driving fluid is required. It will be consumed.

Therefore, air is generally used as the driving fluid.

However, in a fluid-driven artificial heart, the driving fluid and blood are separated only by a thin membrane, so if a failure occurs in the membrane of the artificial heart, the membrane may be damaged. Drive fluid may leak into the blood through the section. In this case, if the driving fluid is air, blood will coagulate, putting the patient's life at risk. In particular, in the case of patients undergoing surgery, their physical strength is extremely low, so if even the slightest abnormality occurs in the patient's body, it becomes difficult to maintain the patient's life.

[Objective] The present invention provides a medical device drive device that allows a doctor to directly change the drive parameters of an artificial heart, etc., and that does not adversely affect the patient even if a failure such as fluid leakage occurs in the artificial heart. The purpose is to provide

[Configuration] In order to eliminate the risk of fluid leakage from the artificial heart, it is sufficient to use a driving fluid that is safe for blood, such as helium gas or carbon dioxide gas. However, since a large amount of fluid is consumed for pressure adjustment, if helium gas is used in all systems, a large helium tank must be prepared, which increases the size of the equipment. Therefore, in the present invention, at least one diaphragm is arranged in the drive system,
The fluid drive system is divided into multiple parts, air or the like is used for the pressure adjustment system, and a safe fluid such as helium gas is used for the direct drive system of the artificial heart. In addition, electromagnetic valves are used in the pressure adjustment system to enable electrical setting of various drive parameters, and a remote control unit is provided.

By the way, there are many medical devices that use electricity in operating rooms and the like, and some of them generate high voltage pulses. Therefore, large electrical noise may be generated, and if the remote control unit and the main body of the device are connected by a long electrical cable, the cable becomes an antenna, and the noise may cause the device to malfunction. Therefore, in one preferred embodiment of the present invention, the remote control unit and the device main body are provided with an electrical/optical converter and an optical/electrical converter, and the connection cable is an optical fiber.

Since light is not affected by electrical noise, malfunctions will not occur even if the cable is long.

Furthermore, according to experiments conducted by the present inventors, when the drive system is divided into multiple parts and an artificial heart is driven using air and gas such as helium, sufficiently favorable drive results cannot be obtained with a drive device having a conventional configuration. There wasn't. In other words, an artificial heart needs to quickly switch between positive pressure and positive pressure at a predetermined timing according to the heartbeat, but the rising edge (switching from positive pressure to positive pressure) and falling edge (switching from positive pressure to positive pressure) of this switching (switching from pressure to positive pressure)
It was found that the changes in the pressure waveform became gentler, and the amount of blood that could be delivered decreased.

The pressure adjustment system of this type of drive device consumes a large amount of air when switching between positive pressures, so an accumulator is generally used to prevent a large drop in pressure and to stabilize the pressure. Fluid is stored in both the positive pressure system and the positive pressure system.

However, unless a very large accumulator is used, it is difficult to prevent the pressure from decreasing, and conversely, since an accumulator is used, it takes time to restore the pressure if it changes. . Therefore, it is difficult to obtain a square-wave pressure waveform with rapid switching between positive pressures.

Therefore, in one preferred embodiment of the present invention, one compensating solenoid valve separated from the accumulator is connected in parallel with the pressure regulating mechanism at least in the positive pressure system of the pressure regulating mechanism, and the valve is opened and closed at a predetermined timing. control and compensate for pressure drops. According to this, even when a drive system using helium gas or the like is connected to the output side of a pressure adjustment mechanism that controls air pressure, a pressure drop can be sufficiently compensated for and a square wave-like pressure waveform can be obtained.

By the way, when driving an artificial heart using helium gas, etc., there will be no water inside the tube connected to the artificial heart immediately after the device is assembled, unless a special method is used, such as assembling the device in a room filled with gas. It has air in it. Therefore, even if the artificial heart is configured to be driven by helium gas, etc.
It has no effect immediately after the device is assembled. Therefore, in one preferred embodiment of the present invention, an operation mode is provided for removing air from the secondary side (artificial heart side) of the diaphragm.

12- In that mode of operation, the pressure on the primary side of the diaphragm is controlled to facilitate movement of the diaphragm, and gas is alternately supplied and discharged on the secondary side of the diaphragm. If you do this.

Due to the large displacement of the diaphragm, the air trapped in the tube etc. is automatically expelled.

Incidentally, for patients with heart disease, an intra-aortic balloon pump is used in addition to an artificial heart (temporary auxiliary heart), and these are used selectively depending on the patient's condition. Therefore, in this type of drive device, it is preferable that an artificial heart and a balloon pump can be selectively used. Therefore, in one preferred embodiment of the present invention, a plurality of gas control systems are commonly connected to the output side of the pneumatic control device, so that the artificial heart and the balloon pump can be selectively used with a switch.

Further, in one preferred embodiment of the present invention, the remote control unit has a configuration in which a switch means is provided inside a case whose operation surface is covered with a flexible material.

According to this, since the switch means is not exposed, it is possible to prevent blood, chemicals, etc. from entering the inside of the remote control unit and cause poor contact, etc., and it is also possible to use the remote control unit repeatedly by cleaning. Further, when the switch means is operated, a predetermined sound is emitted to notify that the switch is being operated.

According to this, it is possible to prevent the switch from being operated by mistake.

Hereinafter, the present invention will be described in detail with reference to the drawings.

FIG. 1 shows the appearance of an artificial heart drive device 1 (which can also drive a balloon pump). Referring to FIG. 1, 1a is an operating section, 1b is a display section, and Ic is a connecting section. Tubes 2a and 2b and an optical fiber cable FBO for remote control are connected to the connection IC on the right side when facing the device, and a remote control board REM is connected to the tip of the optical fiber FBO.
is connected.

The tubes 2a and 2b each contain an artificial heart 60L.
and 60R (see FIG. 4) are connected. Two optical fiber cables FBI and FB2 are connected to the connection section on the right side when facing the device. As described later, a video camera CAM is connected to the optical fiber cable FBI.

A lighting lamp LMP is connected to FB2. Video camera CAM and LMP are artificial heart 60L.

It is provided to monitor the actual operating status of 60R. Monitor TV T that displays the output of the video camera CAM
V is provided on the display section 1b. 3 is a caster.

2a and 2b, the remote operation board REV
The mechanical configuration of This will be explained with reference to FIGS. 2a and 2b. The case REa of the operation board is made of synthetic resin. In order to operate the switch, a rectangular hole is provided in the switch area on the top surface of the panel, and the hole is covered with a thin resin sheet REb. The printed circuit boards PWB 1 and PWB 2 are connected to each other and are integral. Printed circuit board PWB 1 and PWB2
On top are 17 switches SWI, BO-B15, battery, speaker SP, and optical/electrical converter.

Electrical/optical converters etc. are arranged.

15- Figures 3a and 3b show a part of an artificial heart 60L and a device for monitoring its operating state. Figures 3a and 3
This will be explained with reference to figure b. The artificial heart 60L is screwed to the monitoring case 100 at portions 60a and 60b. In this example, the optical fiber FBI for monitoring and the optical fiber FB2 for illumination are arranged so as to be orthogonal to each other at a position perpendicular to the thickness direction of one artificial heart 60L so as to face the movable part of one artificial heart 1M1160L.

Further, a reflecting mirror MRI is placed at a position facing the tips of the optical fibers FBI and FB2. Optical fiber F
As is well known in general medical equipment, the tip of the BI is tiltable and movable, and this can be controlled remotely.

FIG. 4 shows the system configuration of the apparatus shown in FIG. 1. Referring to FIG. 4, 60L and 60R are artificial hearts, and 60B is an intra-aortic balloon pump. The fluid drive unit FDU is equipped with three fluid drive output terminals, but in reality, it is impossible to imagine a situation where the artificial heart 6 and 60R and the balloon pump 60B are used at the same time, so only two of them are used. The structure is such that they can operate simultaneously. A remote operation board REV, a lighting lamp LMP, and a video camera CAM are connected to an electronic control unit ECU that controls the fluid drive unit FDU. The signal output end of the video camera is connected to a monitor TV. The remote operation board REM and the electronic control unit ECU are connected by the optical fiber cable FBO as described above.

FIG. 5 shows the configuration of the fluid drive unit FDU shown in FIG. 4. First, to explain the outline, this unit FDU has a compressor 71. Vacuum pump 72° pneumatic control mechanism AD
UL and ADUR, gas drive mechanism GDUL, GDUR
A, GDURB, helium gas tank HTA, and pressure reducing valve 61 are provided. The input end of the gas drive mechanism GDUL is connected to the output end of the pneumatic control mechanism ADUL,
The input ends of the gas drive mechanisms GDURA and (3DURB) are commonly connected to the output end of the pneumatic control mechanism ADUR.
The output ends of B are respectively connected to artificial hearts 60. L, 60R and the balloon pump 60B.

The air pressure control mechanism ADUL will be explained. This mechanism has 6
Three solenoid valves 51, 52, 53, 54, 55 and 56 are provided. Solenoid valves 51, 52 and 53 are used to generate positive pressure, and solenoid valves 54, 55 and 56 are used to generate negative pressure. Solenoid valves 51 and 52 are provided inside the accumulator ACI, and solenoid valves 54 and 5 are provided inside the accumulator ACI.
5 is provided inside the accumulator AC2. The input ends of the solenoid valves 51 and 53 are connected to the output end of the compressor 71, and the input ends of the solenoid valves 54 and 56 (
(downstream side in terms of the fluid flow direction) is connected to the negative pressure output end of the vacuum pump 72, and the solenoid valves 52, 53, 55
and 56 are connected to the output end of the pneumatic control mechanism ADUL.

PSl and PS2 are each accumulator AC
This is a pressure sensor for detecting the pressure inside I and AC2. The configuration of the air pressure control mechanism ADUR is the same as that of ADUL.

Next, the gas drive mechanism GDUL will be explained. This mechanism includes solenoid valves 57, 58, 59. It is equipped with a fluid isolator AGA, etc. The output end of the pneumatic control mechanism ADUL is connected to the primary side (air side) of the fluid isolator AGA via a mechanical valve VAI. The solenoid valve 57 has an input end connected to the primary side of the fluid isolator AGA, and an output end open to the atmosphere. The solenoid valve 59 has an input end connected to an output end of the pressure reducing valve 61, and an output end connected to the secondary side of the fluid isolator AGA. The solenoid valve 58 has an input end connected to the secondary side of the fluid isolator AGA, and an output end connected to the inside of the accumulator AC2. On the primary and secondary sides of the fluid isolator AGA,
Each is equipped with a pressure sensor PS3 and PS4. The configuration of gas drive mechanisms GDURA and GDURB is as follows:
It is similar to GDUL.

FIG. 6 shows the configuration of the fluid isolator AGA provided in the gas drive mechanism GDURB. This will be explained with reference to FIG. Simply put, in the AGA, a diaphragm 83 sandwiched between housings i1 and 82 separates a space communicating with the primary port 81a and a space communicating with the secondary port 82a, and the diaphragm 83 extends in the left-right direction in the figure. It is possible to shift.

At the center of the diaphragm 83 are plates 84 and 8.
5 is attached to sandwich it. 86 is a bolt for fixing the plates 85 and 86. A regulating member 63 for adjusting the amount of deviation of the plate 85 is attached to the center of the housing 81 . The regulating member 63 is formed with screws 63a and 63b, and is engaged with the housing 81 at the screw 63b.

When the regulating member 63 is rotated, the engagement position changes and the regulating member 63 moves left and right. If you move to the left, plate 8
The range of movement of plate 84.85 becomes larger, and if it moves to the right, the range of movement of plate 84.85 becomes smaller. Ml is a DC motor. A worm gear 62 is coupled to the drive shaft of the DC motor M1, and the worm gear 62 meshes with a screw 63a. Therefore, by driving motor M1,
The range of movement of the plates 84,85 changes. Motor Ml
is fixed to the flange portion 81b of the housing 81 via the base plate 90. 89 is O-ring, 87
and 88 are bolts for fixing the housings 81 and 82.

The fluid isolator AGA provided in the gas drive mechanisms GDUL and GDURA has the same configuration as that shown in FIG. 6, except that the motor M1 is omitted.

Solenoid valves 51, 52, 53, 54 used in this example
, 55, 56, 57, 58, and 59 all have similar configurations. A plan view of one of them, a right side view,
A left side view and an enlarged longitudinal cross-sectional view are shown in FIGS. 7a, 7b, 7c, and 7d, respectively. Figure 7a, 7th
This will be explained with reference to FIG. b, FIG. 7C, and FIG. 7d. A first port 12 and a second port 13 are formed in a valve housing 11 of the solenoid valve. The inner space of the housing 11 is a valve seat 14, and the first inner space 1 communicates with the first port 12.
5 and a second internal chamber 6 communicating with the second port 13. A magnetic coil case 18 is fixed to the valve housing 11 with a sealing material 17 interposed therebetween.

Inside the case 18 is a coil bobbin 2 on which a coil 19 is wound.
0 is inserted, and is supported by magnetic bases 21 and 22. A fixed magnetic core 23 is fixed to the base 21 . The core 23 is hollow, and a non-magnetic guide rod 24 passes through it. A movable magnetic core 25 is fixed to the rod 24 . One end of the rod 24 is pushed to the left by a coil spring 26. rod 2
The other end of 4 passes through the bearing 27 and the bellows 28, and a valve body 29 is fixed to the end. The interior space of the bellows 28 communicates with the first interior chamber 15 (as shown) or the second interior chamber 16 (when the rod 24 is driven to the right) through small holes 30 and 37.

When the coil 19 is energized, a magnetic flux is generated that circulates through the core 23 - core 25 - base 22 - case 18 - base 21 - core 23, and an attractive force acts on the core 25 toward the core 23, causing the rod 24 However, this attraction force and coil spring 2
The valve body 29 moves to the right to a point where the repulsion force of the valve body 29 is balanced with the repulsive force of the valve seat 14, and the valve body 29 moves in front of the valve seat 14 by a distance corresponding to the suction force. The end surface 23a of the core 23 is mountain-shaped, and the end surface 23a of the core 25 is
5a has a concave shape that receives the central protrusion, and the inner surfaces 23b of the chevron-shaped protrusions at both ends are tapered.

Due to the existence of this taper, the energization level and the amount of movement of the rod 24 (the gap between 23a and 25a) are in a proportional relationship over a wide range. Furthermore, this type of solenoid valve has a movable part that has good responsiveness and can perform opening/closing control at high speed.

FIG. 8 shows the configuration of the electronic control unit ECU shown in FIG. 4. Referring to FIG. 8, the electronic control unit ECU
are control units C0NI, CON2 and C0N3,
Receiving unit for remote control SRU, main unit side operation board MO
B. It consists of a display unit DSPU and a scope and lamp control unit 5LCU.

23- The control unit C0N1 is the pneumatic control mechanism ADUL
The solenoid valve 5 monitors the output signals of the pressure sensors PS1 and PS2 of the and ADUR, and controls the solenoid valve 5 so that the pressure inside the accumulators AC1 and AC2 matches the set pressure.
1 and 52 are opened and closed.

The control unit C01j2 is a pneumatic control mechanism AI) UL
The electromagnetic valves 52, 53, 55, and 56 of ADUR are controlled to open and close at predetermined timings according to the set heartbeat cycle, the left and right Systolic Duration (or duty), and the like.

The control unit C0N3 is a gas drive mechanism GDUL'.

Controls GDURA and GDURB solenoid valves 57, 58 and 59. However, GDURA and GDURB are not controlled simultaneously. GDUL and GDURA are controlled by pressure sensors PS3 and PS4 output signals (PGI,
PO2), but the output signal of the pressure sensor PS3 is not monitored in the GDURB control. Also GDUR
In control B-24~, the motor M1 is controlled.

The display unit DSPU consists of a number of 7-segment displays and is connected to the control units C0NI, CON2 and C
Connected to 0N3. The main unit side operation board MOB is
Control units C0NI, CON2. Connected to C0N3 and scope and lamp control unit 5LCU.

Each output line of the remote control receiving unit SRU is
It is connected in the same way as the corresponding signal line of the main body side operation board MOB.

FIG. 9 shows details of the control unit C0NI of FIG. 8. This will be explained with reference to FIG. This control unit C0N
1 is mainly configured with a microcomputer unit CPUI. Connector Jl to which the main unit side operation board MOB and remote control receiving unit SRU are connected
is the buffer BF1 and the chattering removal circuit CHI
It is connected to the input port of CPU1 via. The signal applied to connector J1 is R side (right side) positive pressure UP.
, R side positive pressure DOWN, R side negative pressure UP, R side negative pressure DOWN
, L side (left side) positive pressure UP, L side positive pressure DOWN, L side negative pressure UP, L side negative pressure DOWN, etc. are pressure setting instruction signals.

Solid state relays 5SR1 and 5SR2 are connected to the four output ports of CPUI through buffer z15, respectively.
, 5SR3 and 5SR4 are connected, and the output terminal of each solid state relay 5SR1 to 5SR4 is
It is connected to solenoid valves 51 (L, R) and 54 (L, R).

Z16 is an A/D (analog/digital) converter. This A/D converter z16 has eight input channels, four of which are used in this embodiment. Signals RPP, RNP.

LPP and LNP are right side positive pressure, right side negative pressure, respectively.
This is from a pressure sensor that detects left-side positive pressure and left-side negative pressure. The display output port of the CPUI is connected to the display driver DDV1, and the output end of the DDV1 is connected to the display unit DSPU.

FIG. 10 shows the configuration of the control unit CON2 of FIG. 8. This will be explained with reference to FIG. This control unit C
ON2 is mainly configured with a microcomputer unit CPU2. Connector J to which the main unit side operation board MOB and remote control receiving unit SRU are connected
8 is a buffer BF2 and a chattering removal circuit CH
2 to the input port of the CPU 2.

The signal applied to connector J8 is heart rate UP.

Heart rate DOWN, R side duty UP, R side duty DOWN, L side duty UP, L side duty DOW
This is a setting instruction signal such as N. Solid state relays 5SR5 to 5SRI2 are connected to eight output ports of CPU2 via buffers 215B and 215C, respectively. Solid state relay 5SR5~5SR
8 is a solenoid valve 52 (L, R) and 55 for applying air pressure.
(L, R) respectively, and 5SR9 to 5S
RI2 are air pressure compensation solenoid valves 53 (L, R) and 56
(L, R), respectively. A display driver DDV-27=2 is connected to the display signal output port of the CPU2, and a display unit DSPU is connected to the output end of the DDV2.

FIG. 11 shows the configuration of the control unit C0N3 in FIG. 8. This will be explained with reference to FIG. This unit C0N
3 is mainly composed of a microcomputer unit CPU3. A connector J12 to which the main body side operation board MOB and remote control receiving unit SRU are connected is connected to an input port of the CPU 3 via a buffer BF3 and a chattering removal circuit CH3. The signal applied to connector J12 is from the main unit side operation board MO.
These include an air vent instruction signal, an auxiliary heart/balloon pump selection signal, etc. from B.

CPU3 has an A/D converter 216B with the same configuration as 716.
is connected to the analog signal input terminal of Z16B, and the gas drive mechanisms GDUL, GDURA and GDURB are connected to the analog signal input terminal of Z16B.
The output terminal of the pressure sensor installed in the is connected. M
DI is a circuit for driving the stroke adjustment motor M1. By controlling the two input terminals of the MDI, the motor Ml can be controlled to rotate forward, reverse, or stop.

Buffers Z15D and Z are connected to the nine output ports of CPU3.
Solid state relays 5SR13 to 5SR21 are connected via 15E and Z15F. 5SR1
3. The output terminals of 5SR14 and 5SR15 are connected to the gas drive mechanisms GDUL, GDURA and GDURB, respectively.
It is connected to the solenoid valve 57 of 5SRI 6,5SR
The output terminals of I7 and 5SRI 8 are connected to the solenoid valves 59 of the gas drive mechanism GDUL, GDURA and GDURB, respectively, and the output terminals of 5SR19, 5SR20 and 5SR21 are connected to the gas drive mechanism GD, respectively.
It is connected to the solenoid valves 58 of UL, GDURA and GDURB.

FIG. 12 shows the scope & lamp control unit 5 of FIG.
The configuration of the LCU is shown. This unit 5CLU has buffer BF4. Solid state relay 5SR22, 5SR
23, Inverter INI.

IN2. AC/DC converter (i.e. DC power supply) P
The output terminal of 5SR22 is connected to the lighting lamp LMP, and the output terminal of POWI is connected to the video camera CAM. POW2 is
Buffer BF4. Inverter INI, IN2. Generates DC voltage for controlling solid state relays 5SR22 and 5SR23.

FIG. 13 shows the configuration of the main body side operation board MOB of FIG. 8. This will be explained with reference to FIG. The main body side operation board MOB consists of 20 switches SO to 319 and a resistor array REA. Switches 5o-815 each perform the same functions as switches BO-B15 provided on the remote operation board REV. Each switch SO~
The functions of S19 are remote 0N10FF (R
whether to enable EM), pause (solenoid valve 52
゜53. Stops the operation of 55 and 56), L side stop pressure U
P, R side stop pressure UP, L side stop pressure DOWN, R side stop pressure DOW
N, L side angular pressure UP, R side angular pressure UP, L side angular pressure DOWN,
R side negative pressure DOWN, L side duty UP, R side duty UP, L side duty DOWN, R side duty DO
WN, heart rate increased.

Heart rate down, video camera on, lights on.

These are an air venting instruction and an auxiliary heart/balloon selection instruction.

Figure 14 shows the circuit configuration of the remote control receiving unit SRU in Figure 8, and the remote operation board R connected to it.
The circuit configuration of EM is shown in FIG.

First, the remote operation board REM will be explained with reference to FIG.

z9 is an integrated circuit for transmitting remote control signals (Mitsubishi Electric M5
8484F). Roughly speaking, this integrated circuit z9 includes a key scan signal generation circuit, a key manual encoder,
It is equipped with an instruction decoder, an oscillation circuit, a timing generation circuit, a code modulation circuit, an output sofa, etc., and monitors the 6 x 5 key matrix input terminals to distinguish 30 types of instructions, and outputs 6-bit signals according to the instructions. Output PCM serial code data.

Key scan output terminals φa, φb of integrated circuit Z9.

31- φC1φd and φe and key input terminal If v I
2 16 key switches BO to tI3 and tI4
B15 are connected in a matrix. A battery is connected to the power terminal VCC of Z9 via a power switch SWI. A light emitting diode DI for indicating power on/off, capacitors C1 and C2 for voltage stabilization, an integrated circuit z10, a light emitting diode D3 for indicating voltage drop, etc. are connected to this power supply line.

The integrated circuit z10 is for voltage drop monitoring, and in this example, when the voltage VCC becomes 4.3v or less, the light emitting diode D3 is turned off.
lights up. An integrated circuit z11 is connected to the signal output terminal OUT of the integrated circuit Z9 via a logic gate G8.

The integrated circuit Zll is an electrical/optical conversion rod Joule (Toshiba T
OTX 70), which emits light in response to an electrical signal applied to input terminal A.

Connect the optical fiber cable F to the optical output terminal of the integrated circuit Zll.
One side of BO is connected. optical fiber cable FB
O consists of two sets of optical fibers, =32- The other optical fiber of FBO is connected to the optical input terminal of integrated circuit z12. The integrated circuit Z12 is an optical/electrical conversion module (TORX70 manufactured by Toshiba).

Logic gates G9 and G10 are connected to electrical signal output terminal B of integrated circuit z12 via logic gate Gll. A light emitting diode D2 is connected to the output terminal of the logic gate G9, and a speaker SP is connected to the output terminal of the logic gate GIO via a capacitor C8.

Next, referring to FIG. 14, the remote control receiving unit SR
Explain C. z3 is an integrated circuit for receiving remote control signals (M58481P manufactured by Mitsubishi Electric). This integrated circuit z
3 includes an input circuit, a demodulation circuit, a command decoder, a timing generation circuit, a channel control circuit 2, a flip-flop, etc., and demodulates and demodulates the signal applied to the transmission signal input terminal Sl. Decode and send the results to output terminals Po, PI, P2, P3, TR, Po
Set it to werONloFF etc. The output terminal IR is
It outputs a signal indicating whether a signal was received, that is, whether there was a key input on the transmitting side. Output terminal Pow
The signal level of erON10FF is determined by a predetermined signal (REM
(corresponding to the operation of the side switch BO) is set or reset.

This terminal is used here to control whether remote control is enabled or not.

Integrated circuits z1 and z2 are connected to each set of fibers of the fiber optic cable FBO. The integrated circuit z1 is an optical/electrical conversion module (identical to Zl2), and its optical input terminal is connected to the optical output terminal of the integrated circuit Zll via an FBO. The integrated circuit Z2 is an electrical/optical conversion module (same as Zll), and its optical output terminal is connected to the optical input terminal of the integrated circuit z12 via an FBO.

The received optical signal is converted into an electrical signal and applied from the output terminal B of Zl via the logic gate G1 to the signal input terminal SI of the integrated circuit Z3. Integrated circuit z4 is a D-type flip-flop, and Z5 is a decoder (74159). 4 obtained at the output terminal Po-P3 of the integrated circuit Z3
The bit code data is decoded into 15 types of instruction signals by a decoder z5 and supplied to each circuit via a connector CNI.

The decoder z5 has an open collector output, and each of these output lines is wired-OR connected to the corresponding signal line of the operation board MOB on the main body side.

The level of the output terminal PowerON10FF of the integrated circuit z3 is set to the flip-flop 24 every time an optical signal is received, and this output signal is applied to the gate input terminal G2 of the decoder Z5, so that when remote control is set to disabled, , decoder Z5 does not output a signal (transistor on).

Integrated circuit Z6. Z7 and Z8 are programmable pulse generators (8640 manufactured by Suwa Seiko Kin).

Roughly speaking, these pulse generators are equipped with internal crystal oscillators, programmable dividers, etc.
I~CTL6 are frequency setting terminals, 0υT is output terminal, E
XC is an input terminal for an external clock. In this example, upon receiving an optical signal while remote control is enabled, integrated circuit Z6
．． The reset 35- of Z7 and z8 is released and a pulse signal is output.

When the reset is released, z8 applies a relatively long fixed period pulse signal to the frequency control terminal CTL2 of 77. Further, a signal from output terminal P3 of Z3 is applied to frequency control terminals CTLI and CTL3 of 76. In this example, the transmission codes are classified according to the control parameters UP/DOWN, and the integrated circuit z3 The signal levels obtained at the output terminal P3 of the two are different.

Therefore, the division ratio of integrated circuit Z6 changes depending on the type of switch (UP/DOWN). As a result, in this example, when there is a parameter change instruction or pause instruction on the UP side, the 34KHz and 1.75KHz signals are alternately cursed at predetermined time intervals, and when there is a parameter change instruction on the DOWN side. , 1.70 KHz and 0°85 KHz signals appear alternately. This signal is applied from the output terminal OUT of integrated circuit Z7 to integrated circuit z2 via logic gates G5 and G4.

36- In other words, when a switch is operated on the remote operation board REM, a signal corresponding to the switch is transmitted as an optical signal from the remote control receiving unit SRU to the remote operation board R.
Transmitted to EM.

This optical signal is converted into an electrical signal at Zl2 and energizes the light emitting diode D2 and the speaker SP via logic gates Gll, G9 and GIO.

Therefore, on the remote control board REM side, you can use light and sound to check whether remote control is being performed or not.
You can check which switch is being operated.

FIGS. 16a and 16b schematically show the operation of the microcomputer unit CPUI. FIG. 16a shows the main routine, and FIG. 16b shows the interrupt processing routine. This will be explained with reference to FIGS. 16a and 16b.

When the power is turned on, the output port is first set to the initial level, the contents of the read/write memory (RAM) are cleared, the data previously stored in the read only memory (ROM) is read out, and the parameters are set to initial values. CPU
The parameters of I are 1. Right side positive pressure target value PI, right side negative pressure target value P2°, left side positive pressure target value P3. There is a left side negative pressure target value P4, etc., but in this embodiment, pressure P1. P2. P
The initial values of 3 and P4 are +30. -30°＋
100 and -50 (mmHg).

Also, after this processing, interrupts are enabled. In this example, an internal timer causes interrupts to occur periodically at a cycle of 4m5ec. After waiting for an interrupt, pressure data is sampled.

Check the sampled pressure data and determine whether there is abnormal data. That is, if the detected pressure is abnormally different from the target value, it is regarded as abnormal. In addition, in this embodiment, solenoid valves 53 and 56 are provided for pressure compensation, and the pressure may become relatively large temporarily, but sampling is performed multiple times and each pressure data is averaged. So I'm trying to mask this.

If an abnormality occurs, the abnormality data is converted into numerical code data, and this data and abnormality display data indicating the part where the abnormality has occurred are output to the display unit DSPU for display.

If there is no abnormality, the past m is stored in read/write memory.
The pressure data is averaged, the averaged data is converted into a numerical code, and the code data is sent to the display unit DSP.
Send to U. When a key is operated on the main body side operation board MOB or remote operation board REM, the right side positive pressure target pressure PI and the right side negative pressure target pressure P are set depending on the operated key.
2. The value of the left side positive pressure target pressure P3 or the left side negative pressure target pressure P4 is updated in predetermined steps. However, upper and lower limits are set, and pressure settings that exceed these limits are not possible.

The interrupt processing shown in Fig. 1.6b will be explained. First, check the positive pressure RPP of the right artificial heart drive system. If the pressure is lower than the predetermined pressure P1, the pressure regulating valve 51(R) is set to open; otherwise, the pressure regulating valve 51(R) is set to closed. Next, check the negative pressure RNP of the right artificial heart drive 39-system. RNP value (absolute value)
If " is smaller than P2, the pressure regulating valve 54 (R) is set to open; otherwise, the pressure regulating valve 54 (R) is set to closed. Next, the left side positive pressure LPP and negative pressure LNP
are compared with P3 and P4, respectively, and the pressure regulating valve 5
1 (L) and 54 (L) open or closed. That is, in this embodiment, the detected pressure (
Pressure regulating valve 51 or 5 only when the absolute value) becomes small.
It is designed to open 4.

The general operation of the microcomputer unit CPU2 is as follows.
This is shown in Figures 17a and 17b. FIG. 17a shows the main routine, and FIG. 17b shows the interrupt processing routine. This will be explained with reference to FIGS. 17a and 17b.

When the power is turned on, the microcomputer CPU2
Set the output port to the initial level and read/write memory (
Clears the contents of read-only memory (RO
M) reads the value stored in advance and sets the initial value to the parameter.

4O- The parameters of CPU2 include heart rate PR, duty DL of the left artificial heart, and duty DR of the right artificial heart.
etc., but in this example, the initial value is PR is 100rpv.
n, DL is 45% (duration 270m5), DR is 55
% (duration time 330 ms).

Next, a processing loop including processing such as waiting for an interrupt, checking the key input from the operation board, and displaying parameters is executed. If you have the key power, you can determine the type of input key and change the upper limit of the desired parameter value.

Comparison with the lower limit value and calculation are performed, and calculation processing of parameters related to the changed parameter is performed.

These processes are performed while executing various subroutines.

Interrupt processing will be explained. The values of counters COR and COL are incremented by one each time an interrupt process is performed. Furthermore, when the count value reaches PR (a time parameter determined by the heart rate), each count value is cleared to 0.

When the value of the counter COR becomes 0, the valves 52(R), 53
(R) and 55 (R) respectively open, open and close (
(positive pressure application mode). When the value of the counter COR reaches the reference value Refl (a value regulating the opening time of the positive pressure compensation solenoid valve 53), the solenoid valve 53 (R) is set to close. The value of counter COR is the value of duty parameter DR
Then, valves 55 (R), 56 (R) and 52
Open, open and close (R) respectively (negative pressure application mode)
Set to . When the value of the counter COR reaches Ref2 (a value regulating the opening time of the negative pressure compensation solenoid valve 56), the solenoid valve 56 (R) is set to close.

After this process, the counter COR is counted up.

Similarly, when the value of the counter COL becomes 0, the valve 52 (
L), 53 (L), and 55 (L) are set to open, open, and closed (positive pressure application mode), respectively, and the value of COL is the reference value Refl (regulating the opening time of the positive pressure compensation solenoid valve 53). value), the solenoid valve 53 (L) is set to close, and when the value of COL reaches the duty parameter value DL, the valves 55 (L), 56 (L) and 52 (L) are closed.
) are respectively set to open, open, and closed (negative pressure application mode), and when the value of COL reaches Ref2 (value that regulates the opening time of the negative pressure compensation solenoid valve 56), the solenoid valve 56 (L) is closed. Set it to count up COL.

That is, as shown in FIG. 19a, the solenoid valves 52, 53.5
5 and 56 are activated. After switching from negative pressure to positive pressure,
The solenoid valve 53 is temporarily opened, and after switching from positive pressure to negative pressure, the solenoid valve 56 is controlled to be temporarily opened.
The pressure rises and falls rapidly, and the pressure waveform becomes a square wave. Note that the solenoid valve 56 may be omitted because the speed at which the pressure is switched from positive pressure to negative pressure (falling) does not have a large effect on the drive of the artificial heart. Although not shown in FIGS. 17a and 17, when there is a temporary stop instruction (81 or B1 is on), the driving of the solenoid valves 52, 53, 55, and 56 is stopped only while the instruction is given. .

FIGS. 18a and 18b schematically show the operation of the microcomputer unit CPU3. FIG. 18a is the main routine, and FIG. 18b is the air purge subroutine.

-43= First, explanation will be given with reference to FIG. 18a. When the power is turned on, the memory unit initializes the output board, checks whether there is an air venting instruction (818 is on), and if there is an instruction, executes an air venting subroutine to be described later. The state of switch 819 is checked to determine whether the right drive system is in auxiliary heart mode or balloon pump mode.

In case of cardiac assist mode, read the output signals PGI and PO2 of pressure sensors PS3 and PS4. PGI level is P
When the predetermined value Ref3 is greater than O2, the solenoid valve 59 is set open to supply helium gas from the helium tank HTA to the secondary side of the fluid isolator AGA. The output of the pressure reducing valve 61 is relatively high (for example, 150 mmHg).
Since pressure appears, by opening the solenoid valve 59, the AG
The secondary pressure of A increases.

If the difference between PGI and PO2 is Ref3 or less, solenoid valve 5
Set 9 to close. Furthermore, when the level of PO2 is higher than PGI by Ref 4 or more, the solenoid valve 58 is set open to reduce the secondary side pressure of the AGA.

44- If the difference between PGI and PO2 is less than a predetermined value, the solenoid valve 58 is set to close.

The operation timing of the cardiac assist mode is shown in FIG. 19c. Usually the plate 84.8 of the fluid isolator AGA
5 (and diaphragm 83) is connected to the housing 81.8
2 or the regulating member 63, and vibrates in response to pressure changes from the air pressure control mechanism. In this state,
There is no large difference in pressure between the primary and secondary sides of the fluid isolator AGA.

However, fluid leakage (
When helium gas leaks to the atmosphere, the pressure on the secondary side decreases and the vibration position of the plates 84, 85 moves to the right in FIG. 6. When the movement exceeds a predetermined value, the plate 84 comes into contact with the housing 82. When the plate 84 contacts the housing 82, the fluid pressure on the secondary side of the fluid isolator AQA does not increase any further, so 1
A difference occurs between the pressure on the next side PGI and the pressure PG2 on the second side.

Also, after opening the solenoid valve 59, the AGA secondary pressure PG2
increases, the vibration position of the plates 84 and 85 moves to the left in FIG.
PGI<PO2.

Therefore, as described above, by controlling the solenoid valves 58 and 59 so that the difference between PGI and PO2 is maintained below a predetermined value, the secondary side pressure PG2 is maintained within a predetermined range.
The plates 84, 85 can be driven so as not to stop vibrating.

When the switch 819 is set to the balloon pump side, the balloon mode is entered. Roughly speaking, in balloon mode, only the secondary pressure PG2 is monitored, and the plate 8
The solenoid valve 5 is configured such that the strokes of the solenoid valve 5 and 85 vibrate within a position range regulated by the housing 82 and the regulating member 63.
8.59 and motor M1.

In this mode, pressure PQ2 has a waveform as shown in Figure 19b. That is, when the driving pressure changes from negative pressure to positive pressure, a pressure equal to PGI appears at PO2, and the pressure drops (saturates) when the plate 84 contacts the housing 82. Furthermore, when the driving pressure changes from positive pressure to negative pressure, a pressure equal to PGI appears at PO2, and when the plate 85 contacts the regulating member 63, the pressure increases (
absolute value decreases) (saturates).

Returning to Figure 18a, first, above PO2.

Calculate the unsaturation pressure difference, ie, PST in Figure 19b.

PST is the movement range (stroke) of plate 84.85
corresponds to If PST is larger than the stroke upper limit, the motor M1 is driven in the normal direction to drive the regulating member 63 to the right in FIG. The member 63 is driven to the left in FIG. In this way, the stroke of the plates 84, 85 is first adjusted within a predetermined range.

There is a reason for making stroke adjustments. That is,
One is that the capacity of the balloon pump differs depending on the patient (adult, child, etc.), so when driving a small-capacity 47-balloon pump, the stroke is shortened to eliminate unnecessary movements and the balloon pump is operated. The other reason is to limit the amount of gas flowing out in the event that the balloon pump ruptures.

Next, the negative side saturation pressure PG2L (absolute value) is compared with a predetermined upper and lower limit value. If PG2L is larger than the upper limit, the solenoid valve 59 is set to open, and if it is smaller than the upper limit, the solenoid valve 59 is set to close. Also PG2L
is smaller than the lower limit, the solenoid valve 58 is set to open,
If it is larger than the lower limit, the solenoid valve 58 is set to close.

As a result, PQ2L is maintained between the upper limit value and the lower limit value, and the helium gas amount on the secondary side of the fluid isolator AGA is controlled so as not to change significantly.

Next, the air venting operation will be explained. When switch 818 is turned on, an air purge subroutine is executed.

This will be explained with reference to FIG. 18b. In this example, first, the solenoid valves 57 (R, L) are opened to open the primary side of the fluid isolator AGA to the atmosphere. Next, a predetermined value (10 in this example) is set in the counter COX (internal register) of the car 48. The timer is cleared and started, and the solenoid valve 58 is closed and the solenoid valve 59 is set to open. When the timer times out, the timer is cleared and started, and then the solenoid valve 58 is opened and the solenoid valve 59 is set to close.

When the timer times out, the counter COX is decremented, and if COX is not 0, the above operation is repeated.

That is, at every predetermined time set in the timer, the solenoid valve 5
8 and 59, repeat opening and closing and closing and opening. Therefore, positive pressure and negative pressure are alternately applied to the secondary side of the fluid isolator AGA, and one side of the fluid isolator AGA is
Since the next side is at atmospheric pressure, plates 84 and 85
The housing moves between two positions regulated by the housing 81 and 82 and the regulating member 63, and as a result, a large amount of fluid flows in and out of the flow path on the secondary side of the AGA, and the fluid inside gradually changes from air to helium. turns into gas.

Therefore, even if an operation such as attaching the tube of the balloon pump 60B to the main body of the drive device is performed in a normal room, the two parts of the fluid isolator AGA can be easily connected with a simple switch operation.
Air can be removed from the next side.

In the above embodiment, a solenoid valve 57 is provided on the primary side of the fluid isolator AGA in order to remove air from the secondary side of the fluid isolator AGA.
However, the solenoid valves 52 and 5 of the pneumatic control mechanism
If the solenoid valves 58 and 59 are controlled to open and close in synchronization with the solenoid valve 5, the solenoid valve 57 is not necessary. The operation timing in that case is shown in FIG. That is, by opening the solenoid valve 52, the AG
At the timing when positive pressure is applied to the primary side of A, the solenoid valve 58 is opened to drive the plates 84 and 85 to the secondary side, and the solenoid valve 5
At the timing when 5 is opened to apply negative pressure to the primary side of the AGA, the solenoid valve 59 is opened and the plates 84 and 85 are connected to the 2 sides of the AGA.
Just drive it to the next side.

21a and 21b, and 22a and 22b show an embodiment in which the mounting positions of the optical fiber FBI connected to the video camera and the optical fiber FB2 connected to the illumination lamp are changed.

In the embodiment, a case has been described in which an artificial heart or the like is driven by helium gas, but instead of this, for example, carbon dioxide gas may be used.

[Effects] According to the embodiment described above, the artificial heart is driven using a fluid that is safe for the human body, such as helium gas, so even if a fluid leakage accident occurs during surgery, it is safe. Since various drive parameters can be set by remote control, the doctor can directly operate the device during a single surgery.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view showing the main body of one type of artificial heart drive device embodying the present invention. FIGS. 2a and 2b are a plan view and a front view, respectively, of the remote operation board REM. Fig. 3a is a plan view showing an artificial heart 60L equipped with optical fibers FBI, FB2, etc., and Fig. 3b is a plan view of the artificial heart 60L shown in Fig. 3a.
It is a sectional view taken on line b-III b. FIG. 4 is a block diagram showing the system configuration 51 of the apparatus shown in FIG. FIG. 5 is a block diagram showing the configuration of the fluid drive unit FDU of FIG. 4. FIG. 6 is a longitudinal sectional view showing the configuration of the fluid isolator AGA provided in the gas drive mechanism GDURB of FIG. 5. FIG. Figures 7a, 7b, 7eIi, and 7d are respectively a plan view, a right side view, a left side view, and an enlarged longitudinal sectional view showing the configuration of the electromagnetic valve used in the example. FIG. 8 is a block diagram showing the configuration of the electronic control unit ECU of FIG. 4. FIGS. 9, 10, and 11 are block diagrams showing the configurations of control units C0NI, CON2, and C0N3 in FIG. 8, respectively. FIG. 12 is a block diagram showing the configuration of the scope and lamp control unit 5LCU shown in FIG. 8. FIG. 13 is an electrical circuit diagram showing the configuration of the main body side operation board MOB shown in FIG. 8. 52- Figure 14 shows the remote control receiving unit SR shown in Figure 8.
FIG. 2 is an electric circuit diagram showing the configuration of U. FIG. 15 is an electrical circuit diagram showing the configuration of the remote operation board REM. 16a and 16b are flowcharts showing the general operation of the CPU 1 in FIG. 9. FIG. FIGS. 17a and 17b are flowcharts showing the general operation of the CPU 2 in FIG. 1O. FIGS. 18a and 18b are flowcharts showing the general operation of the CPU 3 in FIG. 11. FIGS. 19a, 19b, and 19c are waveform diagrams showing the operating timing of the device. FIG. 20 is a waveform diagram showing operation timing in another embodiment of the present invention. FIGS. 21a and 21b are a longitudinal cross-sectional view and a cross-sectional view showing the attachment positions of the artificial heart and the optical fibers FBI and FB2 in one modification. FIGS. 22a and 22b are a longitudinal cross-sectional view and a cross-sectional view showing the attachment positions of the artificial heart and the optical fibers FBI and FB2 in another modified example. Artificial heart drive device 2a, 2b: Tube 5I: Solenoid valve (first solenoid valve) 52: Solenoid valve (second solenoid valve) 53: Solenoid valve (sixth solenoid valve) 54: Solenoid valve (third solenoid valve) 55: Solenoid valve (fourth solenoid valve) 56: Solenoid valve (seventh solenoid valve) 57: Solenoid valve (eighth solenoid valve) 58.59: Solenoid valve (fifth solenoid valve) 60L, 60R: Artificial heart 60B = intra-aortic balloon pump 71: Compressor (positive pressure source) 72: Vacuum pump (negative pressure source) HTA: Helium tank 61: Pressure reducing valve AGA: Fluid isolator (medical device m drive means) Psi: Pressure sensor (
(first pressure detection means) PS2: Pressure sensor (second pressure detection means) PS3. PS4: Pressure sensor (third pressure detection means) CPUI, CPU2. CPU3:? Microcomputer unit (electronic control unit) MOB: Main unit side operation board (first setting means) REM:
Remote operation board (second setting means) FBQ: Fiber optic cable (flexible linear material) SP: Speaker (notification means) Patent applicant: Aisin Seiki Co., Ltd. and 1 other person East 12 Figure East 13 Figure East 19a Unpublished 111RGO-IDB4G1 (27) East 18b figure γ-n rose $57 (R, L) ik Hiiragigai color/9COX+=10tfa Soto timer and free g star valve 58 barbow, 59fl+=1 knit tie 4-batch chapter 19b figure Thailand VT clit γ body door 59 closed! Shiba Soto No. 21a Threshold No. 22a Figure East 22b Figure 1-1 = 52

Claims (15)

[Claims] (1) First setting means including a plurality of switches: a second setting means including a plurality of switches and connected to the main body of the device including the first setting means via a flexible linear material; positive pressure; a first solenoid valve whose input end is connected to the output end of the positive pressure source; first pressure detection means for detecting the pressure at the output end of the first solenoid valve; a second solenoid valve connected to its output end, a negative pressure source; a third solenoid valve whose input end is connected to the output end of the negative pressure source; a second solenoid valve that detects the pressure at the output end of the third solenoid valve; and a fourth solenoid valve whose input end is connected to the output end of the third solenoid valve and whose output end is connected to the output end of the second solenoid valve. a first pressure am device whose output end is a medical device drive means whose input end and output end are separated via a membrane that shifts within a predetermined range depending on the applied pressure; at least the output of the medical device drive means; a third pressure detection means disposed on the side, a gas supply means, and a fifth solenoid valve connected to the output side of the medical device drive means and the gas supply means, and the input end of the medical device drive means is connected to the gas supply means. a second pressure regulating device connected to the output end of the first pressure regulating device and having an output end of the medical device driving means connected to the medical device; and at least one of the first setting device and the second setting device. The first electromagnetic valve, the second electromagnetic valve, and the An electronic control device that controls a third solenoid valve, a fourth solenoid valve, and a fifth solenoid valve. (2) the flexible linear material has a plurality of regions having at least two types of properties, at least one of which has a light-transmitting property, and the second setting means includes an electric/optical conversion means; The medical device driving device according to claim 1, wherein the electronic control device includes optical/electrical conversion means. (3) The second setting means and the electronic control device each include an electric/optical conversion means and an optical/electrical conversion means, the second setting means includes a notification means, and the flexible linear material is The electronic control means has two optical paths, and when a signal is sent from the second setting means to the electronic control means, the electronic control means converts the predetermined electric signal into light and sends it to the second setting means. The medical device drive device according to item (2). (4) The first pressure regulating device includes a sixth solenoid valve connected between its output end and the output end of the positive pressure source, and the electronic control device includes a sixth solenoid valve and a fourth solenoid valve. The medical device driving device according to claim 1, wherein the sixth electromagnetic valve is controlled to open and close at a predetermined timing synchronized with the control timing of the sixth electromagnetic valve. (5) The first pressure regulating device includes a seventh solenoid valve connected between its output end and the output end of the negative pressure source, and the electronic control device controls the second solenoid valve and the fourth solenoid valve. The medical device driving device according to claim 4, wherein the seventh electromagnetic valve is controlled to open and close at a predetermined timing synchronized with the control timing of the seventh electromagnetic valve. (6) The first pressure regulating device includes at least two accumulators, and opens the output end of the first solenoid valve and the input end of the second solenoid valve into the first accumulator,
The medical device drive device according to claim 1, wherein the output end of the third solenoid valve and the input end of the fourth solenoid valve are opened into the second accumulator. (7) the fifth solenoid valve includes at least three boats;
the first boat is connected to the output end of the gas supply means;
a second boat is connected to the output end of the medical device drive means;
The medical device drive device according to claim 1, wherein the third boat is opened at a predetermined position. (8) The medical device driving device according to claim (7), wherein the third boat of the fifth solenoid valve is opened into an accumulator of a negative pressure system of the first pressure regulating device. (9) The second electronic control means sets the pressure on the input side of the medical device drive means to a state different from normal when receiving the third instruction from the setting means, and the fifth solenoid valve The medical device according to claim (7), which repeats a state in which a first boat and a second boat are brought into communication and a state in which a state in which the second boat and a third boat are brought into communication are repeated. Drive device. (10) The second pressure regulating device includes an eighth solenoid valve, one end of which is disposed on the input side of the medical device driving means, and the electronic control device controls the eighth solenoid valve when the first instruction is received. Claim No. 9, wherein the other end is open to the atmosphere or a negative pressure system.
The medical device drive device described in Section 1. (11) The electronic control device switches the state of the fifth solenoid valve in synchronization with the operations of the second solenoid valve and the fourth solenoid valve upon receiving the first instruction. (9)
The medical device drive device described in Section 1. (12) The input ends of two second pressure regulators are connected to the output end of one first pressure regulator, and the second electronic control means controls the second pressure regulator according to a predetermined instruction from the setting means. The medical device driving device according to claim 1, which selectively controls one of the pressure regulating devices. (13) The third pressure detection means includes a plurality of pressure detection means arranged on the primary side and the secondary side of the medical device drive means, and the second electronic control means is configured to detect the third pressure on the primary side. The medical device driving device according to claim 1, which controls the fifth solenoid valve according to the difference between the output signal of the means and the output signal of the third pressure detection means on the secondary side. . (14) The medical device driving means includes a movable part that regulates the deflection range of the membrane and an electric control drive means that drives the movable part, and the electronic control means 2 is on the secondary side of the medical device driving means. The medical device drive device according to claim 1, which drives the electric control drive means and the fifth solenoid valve in accordance with pressure. (15) Claim (1), comprising two sets of first pressure regulators and three sets of second pressure regulators;
Clauses (2), (3), (4), (5), (6), (7), (8), and (9). Clause (10), Clause (11), Clause (12), Clause (13)
) or (14).