JP3827046B2 - Medical device pipe cleaning method, Medical device with automatic pipeline cleaning function, And an anti-contamination auxiliary cap used therefor - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a medical device used for medical and dentistry in which a flexible tube connected with a treatment instrument represented by a dental medical device or the like is led out from an instrument holding unit, and water or air is used. A method for cleaning flexible tubes to be supplied and pipes in pipes built in the main body, medical devices with a new function for automatically cleaning such pipes, and pipe cleaning The present invention relates to an auxiliary cap for preventing contamination.
[0002]
[Prior art]
In medical devices such as dental medical devices, water and air are used to drive treatment instruments for treatment and treatment, and there are many pipes that supply water and air inside. is doing. Therefore, when these medical devices are left unused for a predetermined period, tap water or the like remains in the pipeline, and the chlorine component contained in the pipeline adheres to the bacteria. In addition, it is absorbed by the pipe material and the sterilization performance is reduced.
[0003]
For this reason, it is desirable to supply clean water to the water pipelines of these medical devices, but if these are left for a long time with residual water left in them, various germs And produce red water, which is unsanitary and extremely difficult to remove.
In order to prevent such a situation in advance, in this type of medical device, clean water such as fresh tap water is periodically sent from the water supply source into the pipeline and drained to clean the pipeline.
However, in the conventional pipe cleaning, treatment instruments are arranged in the drainage receiving part, and all the water supply pipes are opened at the same time to perform the pipe cleaning. Wash water preferentially flows into parts with a large discharge flow rate such as the cup water supply section and basin wash, and sufficient wash water flows into the thin and most prone to breeding bacteria such as the piping section of the flexible tube. However, there was a problem such as inadequate cleaning.
Therefore, it is conceivable to wash the pipelines by sequentially sending washing water to each of the flexible tubes. However, it takes a considerable amount of time to clean the entire pipeline of the medical device by such a method. Even if road cleaning is automated, it is difficult to put into practical use and difficult to adopt.
[0004]
[Problems to be solved by the invention]
The present invention has been made in view of such circumstances, and a method that can be performed easily and quickly even when the pipeline cleaning of a medical device is automated, and a case where such pipeline cleaning is automated. In addition, a medical device having a new function that can be safely performed, and also providing an auxiliary cap for pollution prevention used for performing pipe cleaning in a hygienic environment from the viewpoint of pollution prevention. It is aimed.
[0005]
[Means for Solving the Problems]
  In order to achieve the above object, the present invention proposes a pipe cleaning method having the following characteristics.
  That is, the pipe cleaning method proposed in claim 1 receives water supply means, a cup water supply section for supplying water supplied from the water supply means to the cup, and rinse water from gargle water or treatment instrument. At least one flexible tube having a drainage receiving portion and having a built-in water supply pipe for supplying water from the water supply means to a treatment instrument detachably connected to the joint portion; The structure is derived from the instrument holder., And the drainage flow rate of the cup water supply section is larger than the drainage flow rate of the flexible tube.In particular, the flexible medical device has at least a built-in water supply line for supplying water from a water supply means to a treatment instrument detachably connected to the joint portion as a flexible tube. Applies to medical devices.
In this piping cleaning method, each of the flexible tubes is set in the drainage receiving portion, and then the water supply means is operated, but the drainage cleaning of the cup water supply portion and the conduit cleaning of the flexible tube are not performed at the same time.Execute the pipe cleaning of the flexible tube after preferentially cleaning the pipe water supply section.It is characterized by.
[0006]
Such a method of the present invention extends to dental medical devices, otolaryngological medical devices, and other medical devices in general.
The flexible tube of the medical device may have at least a water supply pipe. In addition to the water supply line, the treatment instrument can be provided with an air supply line, an exhaust line, etc. If a dental medical device is taken as an example, a scaler, a three-way syringe, an air tabine A flexible tube that removably connects a handpiece, a micromotor handpiece, or the like to the joint is applied as it is.
[0007]
In such a pipe cleaning method of the present invention, the drainage cleaning of the cup water supply unit and the pipe cleaning of the flexible tube are performed separately. It can be performed in a stable state without causing a decrease.
When setting a flexible tube to the drainage receiving part, it is desirable to use a washing drainage tank so that the discharged washing drainage (residual water or fresh water) is not scattered, You may carry out in the state which connected the instrument. In addition to setting a flexible tube in the drainage receiving part and performing pipe cleaning by a conventional method, if an auxiliary cap for preventing contamination as described later is attached, pipe cleaning can be performed in a more hygienic environment.
[0008]
In pipe cleaning, fresh water supplied from the water supply source pushes out and discharges old residual water remaining in the water supply pipe system, so that residual water remaining in the water supply pipe is released first, and then fresh water is released. Is released.
Moreover, although such a medical device is provided with a water supply means, the water supply means here is a concept including a water supply pipe directly connected to a water supply source and provided with a control valve for supplying water to a handpiece or the like. In order to use tap water warmed to the body temperature for treatment and treatment, a water tank is widely used to supply water from there, but it is directly connected to the water supply source and directly from the water supply source. You may receive supply.
[0009]
  In claim 2The salaryWhen draining and washing the cup water supply unit preferentially by operating the water means, or immediately after that, the drainage washing to the drainage receiving part is also performed, and finally the flexible tube piping washing is performed. It is said.
[0010]
  Taking a dental medical device as an example, automatic cleaning of the basin is added as the pipe cleaning of the drainage receiving part. After such automatic cleaning of the basin, the cleaning drainage is discharged from the flexible tube. I am trying to clean the pipes.
  Claim3Then, claim 1Or 2In the above, each flexible tube is set in a washing drain tank placed in a drain receiving part to perform pipe line washing at the same time.
[0011]
  In this piping method, a cleaning drainage tank is used, and the drainage of the flexible tube is prevented from being scattered by discharging the cleaning drainage after setting the flexible tube in the cleaning drainage tank. The flexible tube may be performed with the treatment instrument connected as in the conventional method.
  Claim4This piping cleaning method is applied when the medical device is provided with a suction means and a flexible tube having a vacuum syringe connected to the tip as a treatment instrument is led out.
[0012]
In this piping method, a cleaning drainage tank is placed in the drainage receiving section, a flexible tube connected with a treatment instrument is set in the cleaning drainage tank, and when the cleaning drainage is discharged, the vacuum syringe is drained for cleaning. Set in the tank and activate the suction means.
Since the vacuum syringe sucks the inside of the washing drain tank, the washing drain discharged from the flexible tube into the washing drain tank is sucked as it is, and even when the washing drain contains scales etc. The drainage receiving part (for example, Basin) is not contaminated.
[0013]
  Claim5~8ThenIn performing the piping cleaning method of the medical device according to any one of claims 1 to 4, when cleaning the flexible tube,We have proposed an anti-contamination auxiliary cap that is attached to the joint of a flexible tube derived from a medical device.
  That is, the claim5In the flexible tube derived from the medical device, the flexible tube is used by being attached to a tube having a built-in water supply line.
  This auxiliary cap has a cylindrical main body that is attached by removing the treatment instrument from the joint portion of the flexible tube. The cylindrical main body has an opening at the tip, and the inner surface is flexible. When the joint part of the tube is attached, an inner peripheral wall is formed that allows the tip opening to communicate with the water supply conduit of the flexible tube in a watertight manner.
[0014]
  Claims6The anti-contamination auxiliary cap proposed in the above is used by being mounted on a flexible tube led out from a medical device and incorporating a water supply line and an air supply line.
  This auxiliary cap has a cylindrical main body that is attached by removing the treatment instrument from the joint portion of the flexible tube. The cylindrical main body forms a drainage hole in the outer peripheral wall, and has a tip. An opening is formed on the inner surface of the flexible tube, and when the joint portion of the flexible tube is mounted on the inner surface, the drain hole port is connected in a watertight manner to the water supply pipe line of the flexible tube, and the distal end opening is made flexible tube It is the structure which formed the inner peripheral wall which has the uneven | corrugated | grooved part made to isolate | separate and communicate with this air supply pipeline.
[0015]
  Further claims7,8Proposes an anti-contamination auxiliary cap that is provided with a backflow prevention valve body configured by inserting an elastic O-ring into the drain hole and a backflow prevention air valve, and further prevents pollution.
  That is, the claim7Then, the auxiliary cap is a cylinder with a closed end provided with a backflow prevention valve body formed by forming a ring-shaped concave groove on the outer peripheral wall having an opening of the drain hole, and inserting an elastic O-ring into the concave groove. The inner surface of the cylindrical main body has a concave and convex portion that allows the drain hole to communicate with the water supply conduit of the flexible tube in a watertight manner when the joint portion of the flexible tube is mounted. The inner wall is formed.
[0016]
According to this auxiliary cap, when the water supply means of the medical device is operated, the elastic O-ring is expanded in diameter by the drainage pressure of the cleaning drainage discharged from the water supply conduit of the flexible tube, and at that time, the elastic O-ring and the concave groove However, when the operation of the water supply means is stopped, the drainage pressure of the cleaning wastewater is lowered, so that the elastic O-ring whose diameter has been expanded is restored, and the above-described gap is closed. Therefore, the discharged cleaning wastewater is prevented from flowing back to the auxiliary cap.
[0017]
  Claims8Then, the auxiliary cap is provided with a backflow prevention valve body formed by forming a ring-shaped concave groove on the outer peripheral wall having an opening of the drain hole, and inserting an elastic O-ring into the concave groove. It has a cylindrical body with a normally closed backflow prevention air valve that opens the exhaust port by pressurizing air, and when the flexible tube joint is attached to the inner surface of the cylindrical body, Forms an inner peripheral wall with an uneven part that allows the drainage hole of the backflow prevention valve body to communicate with the water supply pipe of the flexible tube in a watertight manner, and separates the backflow prevention air valve from the air supply pipe of the flexible tube. It has a structure.
[0018]
According to such an auxiliary cap, when the water supply means and the air supply means of the medical device are operated, the elastic O-ring is expanded in diameter by the drainage pressure of the cleaning wastewater discharged from the water supply pipe of the flexible tube, and the elastic O A gap is formed between the ring and the concave groove, and cleaning waste water is discharged from the gap, and the backflow prevention air valve provided at the tip of the air flow pressure supplied from the air supply pipe of the flexible tube is opened, Air is discharged outside through the exhaust port.
[0019]
  Further, when the operation of the water supply means and the air supply means is stopped, the elastic O-ring returns to its original state, so that the above-mentioned gap is closed and the discharge of the washing waste water is stopped, and one normally closed type backflow prevention Since the air valve is also automatically closed as the exhaust pressure of the exhaust air decreases, the outside air is prevented from flowing into the cylindrical main body.
  Claim9~12Proposes a pipe cleaning method in which a treatment instrument is removed from a joint portion of a flexible tube led out from a medical device and an auxiliary cap is attached.
[0020]
  That is, the claim9Then, claims 1 toOne of 4When performing pipe cleaning with the method proposed in5It is carried out by wearing the auxiliary cap described in 1.
  In this piping cleaning method, the joint portion of the flexible tube is not only prevented from being contaminated by the auxiliary cap, but also discharged from the drain hole port formed in the outer peripheral wall of the auxiliary cap through the outer peripheral wall. The wastewater will not be scattered and contaminated.
[0021]
  Claim10Then, claims 1 toOne of 4When performing pipe cleaning with the method proposed in6It is carried out by wearing the auxiliary cap described in 1.
  In this pipe cleaning method, the treatment instrument is removed from the joint portion of the flexible tube having the joint portion connected to the treatment instrument having a built-in air supply pipe in addition to the water supply pipe, and the auxiliary cap is attached. Then, pipe cleaning is performed. The auxiliary cap according to claim 7, which is used in this method, has a cylindrical body having a drain hole hole formed in the outer peripheral wall and an opening formed at the tip thereof. By operating the air supply means, it is possible to discharge cleaning wastewater from the drain hole opening while discharging air from the opening of the tip of the auxiliary cap, thus preventing the cleaning wastewater from flowing back into the auxiliary cap. Is done.
[0022]
  Further claims11,12Claims7,8A pipe cleaning method has been proposed which uses a backflow prevention valve body constructed by inserting an elastic O-ring into the drainage hole opening proposed in, and an auxiliary cap having a structure provided with a backflow prevention air valve.
  That is, the claim11Then, claims 1 toOne of 4When performing pipe cleaning with the method proposed in7It is performed by attaching the auxiliary cap described in 1. In this pipe cleaning method, flexible tubes with built-in water supply pipes have a treatment instrument removed from each joint and, instead, a ring-shaped groove on the outer peripheral wall with a drain hole opening. A flexible body is formed by attaching the auxiliary cap according to claim 7 having a cylindrical body with a closed end provided with a backflow prevention valve body configured by inserting an elastic O-ring into the concave groove. The waste water from the tube is discharged from the backflow prevention valve of the auxiliary cap.
[0023]
  Claims12Then, claims 1 toOne of 4When performing pipe cleaning with the method proposed in8It is performed by attaching the auxiliary cap described in 1.
  In this pipe cleaning method, for flexible tubes with a built-in water supply line and air supply line, the instrument for treatment is removed from each joint, and instead, on the outer peripheral wall with an open drain hole. A normally-closed backflow prevention air that is provided with a backflow prevention valve body that is formed by forming a ring-shaped groove and inserting an elastic O-ring into the groove and opening the exhaust port by the pressure of pressurized air at the tip. Since an auxiliary cap having a cylindrical body with a valve is attached, pipe cleaning is performed by discharging cleaning wastewater from the backflow prevention valve body of the auxiliary cap while releasing air from the backflow prevention air valve of the auxiliary cap. If the operation of the water supply means and the air supply means of the medical device is stopped, the discharge of the cleaning waste water from the backflow prevention valve body of the auxiliary cap is stopped without causing a backflow, and at the same time Since also the discharge is stopped automatically closes the backflow prevention air valve, outside air into the flexible tube is also prevented from flowing through the auxiliary cap.
[0024]
  Further, the medical device of the present invention proposed at the same time has a function of fully automatically performing pipe cleaning, and is characterized by the following configuration.
  That is, the claim13Then, the medical device has a built-in water supply means, and a flexible tube having a joint portion for removably connecting a treatment instrument such as a handpiece, a scaler, or a three-way syringe at the tip is an instrument holding portion. It is held so that it can be pulled out more, and it is equipped with a cup water supply unit and a drainage receiving unit. Furthermore, it detects the pipe cleaning command switch and the drawing of all the flexible tubes to be cleaned from the instrument holding unit. A flexible tube drawing detection means and a pipe line washing sequence control means are provided.
[0025]
In this medical device, the pipeline cleaning sequence control means determines whether or not a pre-processing condition for performing safety safely is satisfied before executing automatic cleaning of the pipeline, and the condition is satisfied. Only when there is a pipe cleaning sequence.
And in this pipe line washing | cleaning sequence, the pipe line washing | cleaning of a cup water supply part is performed preferentially, and the pipe line washing | cleaning of a flexible tube is performed after that.
[0026]
  Claim14Then the medical device claims13Is further provided with a suction means and a vacuum syringe that performs suction by the operation of the suction means.
  In this medical device, when the flexible tube is set in the cleaning drainage tank, the cleaning syringe is set in the vacuum drainage and the suction means is further operated, so that the cleaning drainage discharged from the flexible tube into the cleaning drainage tank. Is configured to be sucked and discharged by a vacuum syringe.
[0027]
  In such a medical device, the vacuum syringe sucks the cleaning wastewater discharged from the flexible tube into the cleaning drainage tank as it is, so that even when the cleaning wastewater contains scales, the drainage receiving portion (for example, basin) Without being contaminated, it can be sucked into the vacuum tank, separated from the water and discharged.
  Claim15Then, the claim13,14In the treatment apparatus described in (1), the pipe cleaning sequence control means automatically performs further cleaning of the drainage receiving part when or immediately after the pipe cleaning of the cup feeding part.
[0028]
When the medical device is a dental medical device, the automatic cleaning of the basin or the like is performed at the same time as or immediately after the cleaning of the pipe water supply section, so that the pipe section with a high drainage flow rate is first cleaned. In addition, it is possible to prevent a decrease in water pressure when washing the pipes of flexible tubes having a small pipe diameter all at once, and all pipes can be washed quickly and sufficiently.
[0029]
  Claim16Then, the claim13~One of 15In the medical device described in 1), a drainage tank for washing is placed in the drainage receiving portion, a flexible tube is set in the drainage tank for washing, and the washing wastewater is discharged into the drainage tank for washing.
  By placing a washing drain tank in the drainage receptacle and setting a flexible tube in this washing drainage tank to discharge the washing drainage, even if the washing drainage contains scale or dirt, the drainage receptacle can be There is no contamination.
Moreover, since it is received by the waste water tank for washing, it is possible to prevent the washing waste water from being scattered to other parts.
[0030]
  Claim17Claims13~16In either of the above, a medical device further embodying the conduit cleaning sequence control means is proposed.
  In this pipe cleaning sequence control means,A further air supply means;A water supply pipe control system provided with an air operating valve for supplying water to various treatment instruments through a flexible tube from the water supply means and the air supply means, and for supplying air to various treatment instruments An air pipe control system provided with an air operation valve, and a logic control circuit for controlling opening and closing of the electromagnetic valves of the water supply pipe control system and the air pipe control system are provided.
[0031]
  The logic control circuit for controlling the opening and closing of the solenoid valves of the water supply pipe control system and the air pipe control system is controlled in sequence by a control program stored in advance in a microcomputer or the like, and the pipe cleaning method according to the present invention is performed.
  Claims18Claims17Has proposed a medical device in which the configurations of the air pipe control system and the water supply pipe control system described in 1 are further embodied.
[0032]
In this medical device, each of the air pipe control system and the water supply pipe control system includes an air main control valve and a water supply main control valve in addition to a common pilot air operation valve, and is provided upstream of the pilot air operation valve. The residual water discharge control valve is arranged in parallel between the water supply main control valve and the downstream side of the water supply main control valve.
According to such a configuration, each of the air pipe control system and the water supply pipe control system includes an air main control valve controlled by a common pilot air operation valve and a water supply main control valve. Double safety can be achieved even if the control system air operating valve breaks down. The pilot air operating valve, air main control valve, and water supply main control valve are all composed of solenoid valves. It is driven by the logic control circuit of the road cleaning sequence control means. In addition, when automatically cleaning the pipelines, the air operated valves provided in the water supply pipelines of the treatment instruments connected to each flexible tube are simultaneously controlled by simply controlling the residual water discharge control valve. Can be done to open.
[0033]
  Further claims19Then, the claim17,18In the medical device described in 1), the air piping control system is provided with a servo valve for controlling the flow rate of air supplied to the treatment instrument detachably connected to the joint of the flexible tube. An air supply line is included, and the servo valve is configured to open when the line cleaning sequence control means operates the air supply means. In this case, in order to send sufficient air to the air supply conduit, it is desirable to fully open it.
When the pipe cleaning sequence control means operates the air supply means, by opening this servo valve, sufficient air is sent to the air supply pipe line of the flexible tube and the cleaning wastewater discharged to the air supply pipe or the like flows backward. To prevent entry. This servo valve controls the rotation speed of the handpiece by adjusting the opening according to the amount of depression of the foot controller during normal treatment.
[0034]
  Claims20~22Proposed a medical device having various functions in order to safely execute fully automatic control by means of the conduit cleaning sequence control means.
  Claim20Claims13~Any one of 19In order to receive a command signal from the pipe cleaning command switch and start a pipe cleaning sequence only when all the instruments to be cleaned are pulled out from the instrument holder It is.
[0035]
  Claims21Then, the claim13~One of 20The conduit cleaning sequence control means includes at least one operation signal among an operation signal of an elevation operation switch of a medical table of a medical device, an operation signal of an operation switch of a tilting means of a backrest, and a pedal operation signal of a foot controller. Can be detected, and when the operation signal is detected, it further has a function of urgently stopping the pipe cleaning being performed. In Claim 23, in Claims 14 to 22, the pipe cleaning sequence control means includes: Even when receiving an operation signal such as an operation signal of the raising / lowering operation switch of the medical table of the medical device or an operation signal of the operation switch of the tilting means of the backrest, the instrument holding unit and the drain The configuration further includes a function of prohibiting an operation that changes the relative distance to the receiving portion.
[0036]
  Therefore, the claims21The function described in the item (1) is a function in which the pipe cleaning sequence control means performs an emergency stop of the pipe cleaning that is being performed when the operator performs an operation performed during normal medical care or treatment while the pipe cleaning is being executed. According to a twenty-third aspect of the present invention, when the operator performs a normal operation during medical treatment or treatment while the pipeline cleaning sequence is being executed, these operations are not accepted and invalidated. In this way, careless operation of the medical device at the time of pipe cleaning is prohibited, thereby further improving safety.
[0041]
【The invention's effect】
  As will be understood from the above description, the present invention has the following effects.
  Claims 1 to4According to the pipe cleaning method of the present invention proposed in the above, in any case, the flexible tube to be cleaned is set in the drainage receiving part, and then the water supply means is operated to drain the water in the cup water supply part having a large drainage flow rate. And the flexible tube with a small drainage flow rate are washed separately at different times, causing pressure drop when washing the flexible tube water supply pipeline.JisaIt is possible to simply and quickly perform the piping cleaning of the medical device in a stable state.
[0042]
  In particular, ExhaustThe drainage cleaning of the cup water supply section with a large water flow rate is performed first, and then the flexible tube with a small drainage flow rate is cleaned with a flexible tube. Therefore, the cleaning efficiency is high, and all pipeline cleaning is a fully automated sequence. Can be done smoothly.
  Claims2Then, when draining and washing the cup water supply section with a large drainage flow rate, or immediately after that, drainage washing to the drainage receiving section is also performed, and finally the pipes are washed from the flexible tube. Pipe cleaning can be performed easily and quickly in a stable state within a fully automated series of sequences.
[0043]
  Further claims3Then, claim 1Or2, each of the flexible tubes to be cleaned is set in a cleaning drain tank placed in the drain receiving part, and the pipes are cleaned all at once. It can be received by the washing drain tank without being directly discharged to the drain receiving part, and the washing drain discharged to the joint part of the flexible tube can be prevented from scattering.
[0044]
  Claim4Then, it is applied when the medical device is provided with a suction means and a flexible tube having a vacuum syringe connected to the tip as a treatment instrument is led out. Since the cleaning wastewater discharged all at once is sucked with a vacuum syringe, even if the cleaning wastewater contains water, it can be sucked into the vacuum tank and discharged without contaminating the drainage receiving part. The pipe can be washed in a more hygienic environment.
[0045]
  Claim5~Any of 8According to the anti-contamination auxiliary cap of the present invention proposed in, all are used by being attached to the joint portion of the flexible tube from which the instrument for treatment has been removed.
  Claim5Then, when the flexible tube led out from the treatment device has a built-in water supply conduit, it is attached to the joint portion of the flexible tube for cleaning the conduit, so the joint portion of the flexible tube is an auxiliary cap. Protected with and prevents contamination.
Pipes can be washed in a live environment.
[0046]
  Also, the cleaning wastewater is discharged from the drain hole opening formed in the outer peripheral wall of the auxiliary cap to the cleaning drainage tank through the outer peripheral wall, so that it is not scattered and contaminated, and in a sanitary environment. With this, pipe cleaning can be performed with peace of mind.
  Claim6Then, when the flexible tube led out from the treatment device has a built-in water supply line and an air supply line, it is used by being attached to the joint of the flexible tube, and is attached to the outer peripheral wall of the auxiliary cap. In addition to forming a drain hole, air is exhausted from the opening of the tip of the auxiliary cap, so even if the cleaning waste water is discharged with the treatment instrument attached, the auxiliary cap The washing waste water discharged from the drain hole port does not flow back into the air supply pipe line of the flexible tube, and the pipe washing can be performed in a hygienic environment with peace of mind.
[0047]
  Claim7Then, since the back cap valve body using the elastic O-ring is provided in the auxiliary cap, there is no possibility that the discharged cleaning waste water flows back to the flexible tube through the auxiliary cap at the end of the cleaning waste water.
  Claims8Then, since the backflow prevention air valve is further provided, even when the discharge of the air supplied from the air supply conduit of the flexible tube is finished, the outside air is not sucked. Therefore, even when the cleaning wastewater is discharged with the treatment instrument attached, the cleaning wastewater discharged from the drain hole of the auxiliary cap does not flow back into the air supply conduit of the flexible tube. Pipeline cleaning can be performed safely in a hygienic environment.
You can
[0048]
  Claim9~One of 12According to the pipe cleaning method of the present invention proposed in claim5~8Since the flexible tube is cleaned using the auxiliary cap for contamination described in 1., there is no possibility that the cleaning wastewater will scatter or flow back into the inside through the auxiliary cap. In addition, piping can be cleaned in a hygienic environment without fear of contaminating the flexible tube by inhaling outside air.
[0049]
  Claim13~Any of 16According to the medical device of the present invention proposed at the same time, the following effects are produced.
  That is, not only can the pipe cleaning according to the method of the present invention be performed automatically only by operating the pipe cleaning command switch, but the pipe cleaning is performed under various conditions for performing pipe cleaning in advance. Since it is executed after determining whether it is in place, it is highly secure.
[0050]
  Further, the pipe cleaning sequence control means can be simply configured by a control program stored in advance in a microcomputer or the like,4The pipe cleaning method according to the present invention described in 1) is carried out.
  Claims17, 18According to the medical device described in the above, each of the air pipe control system and the water supply pipe control system constituting the pipe cleaning sequence control means includes an air main control valve controlled by a common pilot air operating valve, Since it is equipped with a water supply main control valve, double safety can be achieved even if the air operation valve of each control system breaks down, and the pilot air operation valve, air main control valve, water supply main control valve are Since both can be configured by electromagnetic valves, control can be performed using a microcomputer or the like.
[0051]
  In addition, when automatic cleaning is performed, the air operation valves provided in the water supply pipes of the treatment instruments connected to each flexible tube are opened all at once by simple control that simply opens the residual water discharge control valve. The road can be washed.
  Further claims19According to the medical device described in the above, since the servo valve is opened when the sequence control means operates the air supply means, the air supply pipe of the flexible tube can be used when simultaneously cleaning the pipeline from the flexible tube. Sufficient air can be fed into the road, and the cleaning wastewater discharged into the air supply pipe or the like can be effectively prevented from flowing back.
[0052]
  Claims20According to the medical device described in the above, the pipe cleaning sequence control means detects that all the various instruments that perform cleaning detect the withdrawal from the instrument holder, and the pipe cleaning sequence is not prepared. As long as the command signal from the pipe cleaning switch is received, the pipe cleaning sequence is not started, so that further safety can be achieved.
[0053]
  Claims21According to the medical device described in the above, the pipe cleaning sequence control means is performed by the operator during normal medical care and treatment such as raising and lowering of the examination table and tilting operation of the backrest when the pipe washing is being performed. When the operation is performed, the pipe cleaning being performed can be stopped, so that the pipe cleaning can be easily performed even when the pipe cleaning is stopped urgently.
[0054]
  Further claims22According to the medical device described in the above, even when the operator performs operations during normal medical treatment and treatment, such as raising and lowering the examination table, tilting operation of the backrest, etc. while the pipeline cleaning sequence is being executed, Since the flexible tube extended from the instrument holding part to the drainage receiving part is moved for pipe cleaning, and the action that hinders pipe cleaning is prohibited, the medical device is not prepared for pipe cleaning. Safe operation can be prohibited.
[0058]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
First, the pipe cleaning method of the present invention will be described.
FIG. 1 is a flowchart showing a basic operation procedure of the pipe cleaning method of the present invention, and FIG. 2 is an external view showing a dental medical apparatus as a medical apparatus for carrying out the method of the present invention.
[0059]
As shown in FIG. 2, the medical device A includes a backrest 4 having a reclining function on a seat 1 that can be moved up and down, and drainage provided with a cup water supply unit 31 beside the seat 1. A basin 3 serving as a receiving portion is provided, and a plurality of treatment instruments necessary for treatment are detachably connected to the respective tips from the instrument holding portion 4a provided on the shoulder portion of the backrest 4. The flexible tubes D and D ′ are led out so as to be accommodated.
In addition, a flexible tube D ″ having a scaler connected to the tip is led out from the base 1a of the sheet 1.
[0060]
A pipe cleaning command switch SW is provided on one side of the backrest 4, and power is supplied to the base 1a of the seat from the outside by a cord (not shown). Here, the pipe cleaning command switch SW may be provided with a separate switch as in this example, or may be configured to be shared with a cleaning switch (not shown) for the cleaning drain tank 2 and the basin 3 described later. Good. In this case, for example, the tank cleaning may be performed in a normal operation, and the pipe cleaning command may be valid when the tank is pressed for 3 seconds.
[0061]
Further, a water supply conduit is drawn out from the base 1a of the seat 1 so that clean water is supplied from a water supply source such as a water supply, and further, an air compressor as an air supply source, and a suction means having a vacuum tank Etc. are built-in.
One basin 3 is connected to a drain pipe, and the washing drain discharged to the basin 3 is drained to the outside through the drain pipe.
[0062]
These flexible tubes D and D ′ are taken out from the shoulders of the backrest 4 and, as shown in FIG. 3, with the treatment instruments Ha and Hs being connected to their tips, as shown in FIG. The treatment instruments Ha and Hs are inserted into the holes 22 and 22 'of the washing drain tank 2 placed in the pipe to perform pipe washing.
In this embodiment, the basin receiving the gargle water has been described as the drainage receiving portion. However, as shown in FIGS. 4A and 4B, the treatment instrument Ha... Is removed. The cleaning tray 32 having the insertion hole 32a into which the joint portion 60 of the flexible tube D is inserted may be used.
[0063]
  This type of cleaning trayFIG.The so-called chair mount type as shown in Fig. 1 is used by detachably attaching to the instrument holding portion 4a provided on the side of the medical device main body A, and the cleaning tray 32 is removed after cleaning. The cleaning waste water in the tray 32 is discarded, but is not limited to this.
[0064]
  Next, the pipe cleaning method will be described. The basic procedure of this cleaning method is shown in steps 100 to 110 in FIG. Pipe cleaning is performed by discharging cleaning waste water from the tips of the flexible tubes D, D ′, D ″ led out from the medical device main body such as the shoulder of the backrest 4.Fly to otherIn order to prevent contamination, use a drainage tank for cleaning, or remove the treatment instruments Ha, Hs... From the joints of the flexible tubes D, D ′, D ″ to prevent contamination. Attach an auxiliary cap to clean.
[0065]
Details of the drainage tank for washing and the auxiliary cap used in this case will be described later.
After all of the flexible tubes D and D ′ to be cleaned are set in the cleaning drainage tank, the main switch (not shown) provided at an appropriate position of the backrest is turned on to turn on the power, and then the backrest 4 A pipe cleaning command switch SW provided on the side is pressed.
Then, the pipeline cleaning sequence control means built in the medical device A is operated, and the drainage cleaning is executed by sequentially controlling the piping control system in the procedure as described later.
[0066]
That is, in this pipeline cleaning sequence, when the water supply valve is first opened and then the cup water supply valve of the cup water supply unit 31 is opened, all the pipe lines leading from the water supply source to the cup water supply unit 31 are fresh. Since the cleaning water is supplied, the residual water in the pipeline is pushed out and replaced with fresh cleaning water.
The time required for such pipe cleaning can be set with a timer, etc., but in order to effectively remove germs and water adhering to the pipe, fresh cleaning water is passed through the pipe for a sufficient period of time. In addition, it is desirable that the washing water is appropriately mixed with a bactericidal agent as necessary and passed through the piping.
[0067]
FIG. 5 shows a state where the pipe water supply section 31 is being cleaned, and the cleaning drainage discharged from the cup water supply section 31 is received in the tank through the receiving hole 27 of the drainage cleaning tank 2.
Thus, when pipe washing of the cup water supply unit 31 is performed, if the flexible tubes D, D ′, D ″ led out from the medical device A include a built-in air supply conduit, In order to prevent the drained cleaning wastewater from flowing back from the water injection ports of the treatment instruments Ha, Hs..., The pipe cleaning sequence control means further opens the servo valve fully, etc. , D ′, D ″ are preferably discharged from the air discharge ports of the treatment instruments Ha, Hs.
[0068]
After drainage cleaning of the cup water supply unit 31 is completed, drainage cleaning of the drainage receiving unit 3 is performed as necessary, and all pipes related to the drainage receiving unit 3 are cleaned.
In this case, in the same manner as the pipe cleaning of the cup water supply section 31, the automatic basin cleaning valve is opened, fresh cleaning water is supplied from the water supply source to all the piping paths leading to the basin 3, and the residual water in the piping paths is pushed out. Instead, replace with fresh wash water.
In this case as well, the time required for replacement can be set with a timer, etc., but in order to effectively remove germs and water adhering to the pipeline, fresh washing water must be supplied for a sufficient amount of time. It is desirable to pass through the inside of the pipe line by appropriately mixing a bactericidal agent in the washing water.
[0069]
In particular, when using a disinfectant, open the valve of the water supply source and the tank of the tank that stores the disinfectant, supply the disinfectant and water sufficiently to the flexible tube and the water supply line inside the medical device, Hold the water supply valve and the tank valve closed for a predetermined time to allow sufficient disinfection, and then keep the tank valve closed and open the water supply valve to keep it fresh. Water can be introduced and rinsed.
[0070]
In this way, after the pipes other than the flexible tube and the pipe line related thereto are washed, the washing waste water is discharged from the flexible tubes D, D ′, D ″ set in the washing drain tank 2. Let
The simultaneous discharge of cleaning wastewater through the flexible tubes D, D ′, D ″ is a pipe control as described later in which the pipe cleaning sequence control means is incorporated in the medical device for air supply, water supply, suction, and drainage. This is done by opening and closing the main control valve of the system. In this case, unlike normal treatment, as described later, it is provided in all water supply lines connected to the flexible tubes D, D ′, D ″. What is necessary is just to provide the residual water discharge control valve which opens an air action valve all at once.
[0071]
  The time for discharging the washing wastewater from the flexible tubes D, D ', D "at the same time can be set with a timer, etc., in the same manner as the pipe washing of the cup water supply unit 31 and the drainage receiving unit 3, and adheres to the pipeline. In order to make effective removal of germs and water, it is desirable to allow fresh washing water to pass for a sufficient period of time, or mix the washing water with an appropriate disinfectant and pass it through the piping..
  In addition, when discharging washing waste water from flexible tubes D, D ', D ",As will be described laterBy inserting the vacuum syringe Hb into the suction hole portion 26 of the tank 2 and operating it, the cleaning wastewater and filth discharged into the tank 2 are sequentially sucked and discharged. In this way, since the drainage receiving part 3 is hardly contaminated, it is not necessary to drain and wash the drainage receiving part 3 and the like after discharging the cleaning wastewater.
[0072]
As described above, after the cleaning drainage is discharged from the flexible tubes D, D ′, D ″ for a predetermined time, all the flexible tubes D, D ′, D ″ are removed from the cleaning drainage tank 2, The cleaning drain tank 2 is cleaned up, and all the flexible tubes D, D ′, D ″ are returned to their original storage positions, that is, the instrument holders, etc., and all procedures are completed.
[0073]
  NextThe medical device of the present invention having a fully automatic type automatic line cleaning function will be described in detail based on the specific configurations of the line cleaning sequence control means and the piping control system.
Yes.
[0074]
FIG. 6 is a block diagram showing the main part of the pipe cleaning sequence control means configured using the microcomputer system, and FIG. 7 is a system diagram of a piping control system incorporated in the medical apparatus.
As shown in FIG. 6, the pipe cleaning sequence control means B is provided with a CPU 10 constituting a microcomputer, and is connected to the logic control circuit 11 by controlling the logic control circuit 11 in sequence by program control of the CPU 10. The pilot air actuated valve drive circuit 12, the air main control valve drive circuit 13, the feed water main control valve drive circuit 14 and the residual water control valve drive circuit 15 are driven, and the pilot air actuated valve provided as an electromagnetic valve, the air main The control valve, the water supply main control valve, and the residual water control valve are opened and closed, and the drive circuits 12 to 15 are supplied with 24 VDC power to control on and off of the respective electromagnetic valves.
[0075]
The piping control system shown in FIG. 7 is assumed to be incorporated in a dental medical device, and as treatment instruments, an air turbine handpiece Ha, a micromotor handpiece Hm, a three-way syringe H3, A vacuum syringe Hb, a scaler Hc, etc. are provided, and further, a cup water supply part 31 for supplying water supplied from the water supply means to the cup is provided, and as a drainage receiving part, gargle water or treatment instrument is provided. A basin 3 is provided for receiving cleaning water.
[0076]
The pipe cleaning according to the present invention is the pipe cleaning sequence control means B shown in FIG. 6 for the main electromagnetic valve incorporated in the water supply pipe, the air supply pipe, the suction pipe, the drain pipe and the like of such a pipe control system. (A) to (m) in FIG. 8 show the operation procedure of the main part of the piping control system.
Hereinafter, the configuration and operation of the piping control system will be described in more detail.
[0077]
First, the air supply line system will be described. This air supply line is indicated by a solid line (for driving) and a dotted line (for control) in the figure.
The main air supply line PA is connected to an air supply source and receives pressurized air, and is provided with an air supply source valve Va, a filter f, and a pressure reducing valve V10. Here, the filter f removes dust and bacteria in the air, and the pressure reducing valve V10 is provided to prevent the supply air pressure from becoming excessive.
[0078]
Further, the main air supply line PA branches a washing control bypass line PAd, and a residual water drainage control valve SVd is provided in the bypass line PAd via a bypass safety valve V.
Here, when the residual water drainage control valve SVd is off, it is switched to the exhaust port side, and an air supply line leading to air operation valves V2 to V4 described later is opened to the atmosphere. The pressurized water from the main air supply line is supplied to the air operating valves V2, V3, V4, and by opening these, the water supply line that leads to the scaler Hc, the micromotor handpiece Hm, and the air turbine handpiece Ha In addition, water can be supplied from a water supply source, and water is supplied to the flexible tubes D ″ and D connected with these instruments Hc, Hm, and Ha at the same time.
[0079]
The main air supply line PA further extends, one extending to the three-way syringe H3 through the flexible tube D via the flow rate adjusting valve Va, and the other branching further to the pilot air operation valve SVp and the three-way switching valve Leads to Vo.
The three-way syringe H3 is provided with a water discharge lever (not shown) that allows air supply and water supply at the same time. By operating the water discharge lever, water and air are mixed to form a spray. Can be discharged.
In the drainage tank 2 for cleaning, which will be described later, the water discharge lever of the three-way syringe H3 is held in a pressed state by the auxiliary protrusion 25 to discharge the cleaning wastewater.
[0080]
Further, a downstream side of the pilot air operation valve SVp is provided with a filter f that is open to the atmosphere, and a pipe line that is provided with a flow rate adjusting valve Vb is connected to the pipe. The main air control valve SVa is connected to this pipe line. The air main control valve SVa and the water supply main control valve SVw are branched and connected so that is upstream.
Moreover, since the pilot air operation valve SVp is located upstream of the main control valve SVa and the water supply main control valve SVw, the pilot air operation valve can be turned on regardless of which of the air main control valve SVa and the water supply main control valve SVw is turned on. As long as SVp is not turned on, these valves SVa and SVw are not turned on.
Therefore, even when these main control valves SVw and SVa are left in an open state, the supply air can be shut off by closing the control valve, and thereby water supply to the scaler Hc and other handpieces simultaneously due to malfunction. Without improving the safety.
[0081]
Here, the flow rate adjusting valve Vb functions as an escape hole for escaping a part of the air supplied from the main air supply line PA. By adjusting the flow rate control valve Vb, the air supply main control valve SVw is supplied with air. The amount of air flowing into the operation valves V2 to V4 is limited, and only one of these three air operation valves V2 to V4 is opened at the same time.
[0082]
According to such a structure, when one of the instruments is used at the time of medical treatment or the like, even if the other instrument is driven, the water-operated air operated valve does not operate. Water is not accidentally discharged from other instruments, and it is safe.
In addition, the downstream side of the three-way switching valve Vo is branched and connected to the flexible tubes D of the air turbine handpiece Ha and the micromotor handpiece Hm via the servo valve SVs and the flow rate adjusting valve Va. The three-way switching valve Vo and the scaler water supply restriction valve V1 described above are connected to the air main passage, and the air main control valve SVa is connected to the three-way switching valve Vo and the scaler water supply control valve V1. It is controlled by the valve SVa.
[0083]
Here, when the air main control valve SVa is off, the air main control valve SVa is switched to the exhaust port side. At this time, the three-way switching valve Vo and the scaler water supply control valve V1 are both off. When the three-way switching valve Vo is off, it is connected to the port b side, is open to the atmosphere through the trap filter F, and the scaler water supply control valve V1 is open when it is off, but the air main control valve When SVa is turned on, both the three-way switching valve Vo and the scaler water supply restriction valve V1 are turned on.
As a result, the three-way switching valve Vo is connected to the port a side, and the pressurized air supplied from the main air supply line PA is supplied to the micromotor handpiece Hm and the air turbine handpiece Ha (micromotor handpiece). Hm is supplied as cooling air or tip air), but the scaler water supply restriction valve V1 is closed, the control of the air operating valve V2 is disabled, and the closed state is maintained.
[0084]
Further, the water supply main control valve SVw is connected to the air operation valve V2 of the scaler Hc, the air operation valve V3 of the micromotor handpiece Hm, and the air operation valve V4 of the air turbine handpiece Ha via the water injection restriction valve V1. ing.
When the scaler water supply restriction valve V1 is turned off and opened, the supply air sent from the main air supply line PA is supplied to the air operation valve V2 through the water supply main control valve SVw and the residual water drainage control valve SVd. However, when it is turned on, the supply air is shut off from the main air supply line PA through the water supply main control valve SVw and the residual water drainage control valve SVd.
That is, when the air main control valve SVa is turned on, water supply to the scaler Hc can be prohibited by keeping the air operating valve V2 of the scaler Hc in an off state and disabling control.
[0085]
Therefore, according to such a structure, when the air main control valve SVa is turned on and air supply to the air turbine handpiece Ha and the micro motor handpiece Hm is started, water supply to the scaler Hc is prohibited. Can do.
The servo valves SVs can continuously increase or decrease the flow rate of air supplied to the air turbine handpiece Ha by stepping on a foot control pedal (not shown) of the medical device A. The number of rotations can be continuously changed.
[0086]
Further, when the water supply main control valve SVw is turned off, the supply water main control valve SVw is switched to the exhaust port side, so that the supply of pressurized air from the main air supply line PA to the air operating valves V2 to V4 is cut off. However, if it is turned on, the pressurized air supplied from the main air supply line PA through the pilot air operation valve SVp is supplied to the air operation valves V2 to V3, and the scaler Hc, micromotor handpiece Hm, air The flexible tubes D ″, D... Communicating with the turbine handpiece Ha are supplied with water through the water supply conduit. However, when the air supply main control valve SVw is on, the air main control valve SVa is turned on. As described above, since the water injection limiting valve V1 is closed, the control air is not sent to the air operating valve V2. Only 4 opens, micromotor handpiece Hm, flexible tube D of connecting the air turbine handpiece Ha, water supply only the water supply conduit of D is.
[0087]
In addition, spring-type suction cylinders V2 ′, V3 ′, and V4 ′ are provided in parallel to the air operation valves V2 ′ to V4 ′ provided in the water supply pipes of the scaler Hc, the micromotor handpiece Hm, and the air turbine handpiece Ha. ing.
In these cylinders V2 'to V4', when the air operating valves V2 to V4 are opened by the control air, the piston is pressed against the spring side against the elasticity of the spring by the control air, and the water supply pipe line When the control air is shut off and the air actuated valves V2 to V4 are closed, the piston is lifted by the elastic force of the spring to release the pressure applied to the water supply line, thereby the micro motor When the water injection from the handpiece Hm or the air turbine handpiece Ha is interrupted, the water remaining in the respective water supply pipes is sucked to prevent water from dripping from the water injection port at the tip of the water supply pipe. .
[0088]
Next, the water supply pipeline system, the suction pipeline system, and the drain pipeline system will be described.
The water supply line is indicated by a thick solid line, the suction line is indicated by a solid line with an arrow in the suction direction, and the drainage line system is indicated by a long dotted line.
The main water supply line is connected to a water supply source such as normal tap water or worm tank, and is provided with a manual water supply source valve Vw, a dust removal filter f, a check valve Vc, a pressure reducing valve V9, and a water supply source valve SVi. The main water supply pipe PW is further branched into a basin water supply pipe PWb and a cup water supply pipe PWc.
Here, the pressure reducing valve V9 prevents the supply water pressure to the main water supply pipeline PW from becoming excessive, and the water supply source valve SVi is constituted by an electromagnetic valve.
The basin water supply line PWb controls the water supply to the basin 3 by connecting a manual basin valve Vc provided with a flow rate adjusting valve Va and an automatic basin cleaning valve SVb in parallel. The path PWc is provided with a check valve Vc and a cup water supply valve SVc composed of an electromagnetic valve to control the cup water supply.
[0089]
The main water supply pipe PW further extends, one through the flow rate adjusting valve Va and the flexible tube D to the three-way syringe H3, and the other through the filter f, the air turbine handpiece Ha, the micromotor. The handpiece Hm and the scaler Hc communicate with the water supply pipes, and as described above, the air operation valves V2 to V4 provided with the spring type cylinders V2 ′ to V4 ′ and the flow rate adjusting valves are connected to these water supply pipes. Va is provided correspondingly.
[0090]
One suction pipe PV is connected to a suction source constituted by a vacuum pump or the like, and is branched into three sides: a suction control pipe PVc, a vacuum source pipe PVb, and a vacuum tank drainage control pipe PVa.
Here, the suction control pipe PVc is provided with a vacuum control valve SVe for controlling the opening and closing of the air operating valve V6 and a drainage control valve SVf for controlling the opening and closing of the draining air operating valve V5 of the cleaning drainage tank 2. These control valves SVe and SVf are turned on and off, and the air operating valves V6 and V5 are opened and closed, thereby supplying or blocking the suction force to the vacuum syringe Hb and the washing drain tank 2. .
[0091]
Further, the vacuum main pipe PVb is provided with an air operating valve V7 that is controlled to be opened and closed by a vacuum original control valve SVg, and is connected to a vacuum tank 5. By turning on and off the vacuum original control valve SVg, an air operating valve is provided. V7 is controlled to apply the suction force to the vacuum tank 5.
Further, the vacuum pipe line PVd branches downstream of the filter f described above and is connected to the scaler Hc through the flexible tube D.
[0092]
Further, the vacuum line PVd from the air operating valve V6 toward the vacuum syringe Hb is branched and connected to the trap filter F, and the water and oil stored in the filter F are sucked into the vacuum tank 5 and discharged. It is configured.
Here, the trap filter F is connected to the port b side of the above-described three-way switching valve Vo, connected to an air supply line leading to the air turbine handpiece Ha, the micromotor handpiece Hm, and the scaler Hc, and opened to the atmosphere. The oil and water mixed in the air supply pipe is collected and separated and removed.
[0093]
The drainage control line PVa is connected to the drainage control valve SVh. By opening / closing the control valve SVh, the air operating valve V8 is controlled to open / close, and the cleaning wastewater stored in the vacuum tank 5 is discharged.
The other drain pipe PH is a basin drain pipe PHb that collects drainage of the basin 3, a tank drain pipe PHa that collects drainage from the cleaning drain tank 2, and a drain pipe that collects drainage from the vacuum tank 5. PHc merges.
[0094]
  Here, the basin drain line PHb has a filter f, joins with the tank drain line PHa and flows into the trap 6, and the trap 6 separates and removes filth contained in the basin drain. ing.
  One vacuum tank drain line PHc is provided with an air operating valve V8 that is controlled to open and close by a tank drain control valve SVh, and is joined to the drain of the trap 6 and connected to the drain line PH. Next, the fully automatic pipe cleaning operation in the medical device of the present invention having the automatic pipe line cleaning function is shown in FIGS. 8 (a) to 8 (k).timeThis will be described based on the chart.
[0095]
First, the washing drain tank 2 is installed in the drain receiving part 3, and an auxiliary cap (not shown) is attached to the joint part of the flexible tube D and set in the tank 2 as necessary. At this time, the water discharge lever of the three-way syringe H3 is set to the ON state by the holding portion as described above. However, at this time point, the water supply main control valve SVw is turned off, so water is not discharged.
[0096]
Next, if the main switch is turned on and the vacuum syringe Hb is set in the tank 2, the vacuum source control valve SVg and the vacuum control valve SVe are turned on, and at that time, the vacuum syringe Hb starts suction (hereinafter, T1, T2).
In this way, when all the flexible tubes D, D ′, D ″ are set in the tank 2 and then the pipeline cleaning command switch SW is operated, the pipeline cleaning sequence control means includes the cup water supply valve and the automatic basin cleaning valve. Therefore, drainage cleaning of the cup water supply unit 31 is performed, and drainage cleaning of the basin 3 is performed at the same time.
At this time, the servo valve is fully opened in order to maximize the amount of air supplied to the air supply line leading to the air tabine handpiece Ha.
In this way, when the waste water cleaning of the cup water supply section and the automatic cleaning of the basin are completed, the sequence control means opens the residual water discharge control valve SVd, simultaneously turns on the pilot air operation valve SVp, and opens the air main control valve SVa. (T3, T4).
[0097]
As a result, since the flexible tubes D, D ′, D ″ set in the tank 2 are first injected with pressurized air from the exhaust port, the cleaning wastewater is discharged. There is no reverse flow from the exhaust port.
In FIG. 8 (j), the water supply main control valve SVw is also open at this time, but the air operation valve provided in the water supply pipe line of the flexible tube leading to various instruments is the residual water discharge control valve SVd. It is not always necessary.
[0098]
  The pipe cleaning sequence control means B holds the residual water discharge control valve SVd, the pilot air operation valve SVp, and the air main control valve SVa on for a preset time, and the flexible tube D,D ', D ''The washing waste water is discharged from all at once. As a result, wash water is supplied from the water supply source to all the main water supply pipelines, and water remaining in the pipelines is pushed out, so old water remaining in the pipelines is replaced with fresh water supplied from the water supply source. It will be washed (T5).
[0099]
In this way, after the pipe cleaning is completed, all the flexible tubes D are removed from the tank 2, returned to their respective storage positions, and then the main switch is turned off. Then, the water discharge lever of the three-way syringe H3 is also turned off, the discharge of water and air is stopped, the suction of the vacuum syringe Hb is also stopped, and finally the vacuum tank drainage control valve SVh is opened to open the vacuum tank 2 Washed wastewater separated and stored from oil, filth, etc. is discharged to the outside through the drainage pipe (T6).
[0100]
Next, the drainage cleaning tank and the pollution prevention auxiliary cap used in the pipe cleaning method of the present invention will be described.
The drainage cleaning tank is not an essential requirement for carrying out the present invention. However, if such a tank is used, the cleaning drainage discharged from the flexible tube is discharged to the drainage receiving part or other parts as described above. It is used from the viewpoint of preventing contamination because it does not scatter to the part.
[0101]
FIGS. 9A to 9C show an example of a washing drain tank.
As shown in these drawings, the washing drain tank 2 is formed in a shape that can be used by being attached to the bowl opening of the drain receptacle (or basin) 3. Holes 22A, 22A ', a cleaning drainage suction hole 26 for inserting and connecting a vacuum syringe, etc., a receiving hole 27 (see FIG. 5) of the cup water supply part 31, and an auxiliary protrusion for a water discharge lever of a three-way syringe 25 is provided.
[0102]
As shown in FIG. 10A, the cleaning drainage holes 22A and 22A ′ are treatment instruments such as an air turbine handpiece Ha, a micromotor handpiece Hm, a scaler Hc, and a three-way syringe H3. Instead, the auxiliary cap C attached to the joint portion of the flexible tube can be inserted with the tip facing downward, and the water discharge lever of the three-way syringe H3 is in a water discharge state on the auxiliary protrusion 25 The three-way syringe H3 is set in the hole so as to hold the operation.
[0103]
Moreover, an LED lighting bar configured by arranging a plurality of LEDs in the depth direction is provided as an indicator means 23 at an appropriate position on the side surface of the tank 2, and the amount of stored cleaning wastewater can be seen from the outside. As can be seen, a plurality of overflow holes 24 are drilled in the lateral direction at a position about half the depth of the tank 2.
Therefore, according to such a tank 2, if the water guide part of the cup water supply part 31 matches the receiving hole 27 and is hooked on the tank 2 as shown in FIG. It can be set on the top, and the drainage from the cup water supply section 31 can be received without splashing outside.
[0104]
Further, since the overflow hole 24 is perforated on the side wall of the tank 2, even if the cleaning wastewater is discharged to the tank 2, it is discharged from the overflow hole 24 without being full. Auxiliary cap C set to 'is not soaked in washing water and contaminated, and can be drained in a hygienic environment.
In the case of configuring such a cleaning / drainage tank, as shown in FIG. 10B, auxiliary caps may be formed integrally with the cleaning / drainage holes 22B and 22B '.
In such a case, since it is not necessary to replace the auxiliary cap C in the joint portion of the flexible tubes D and D ', the operation is easy and there is no possibility of losing the auxiliary cap.
[0105]
Next, the contamination prevention auxiliary cap will be described in detail.
Such an auxiliary cap is not an indispensable requirement for carrying out the present invention, like the drainage cleaning tank, but it does not cause cleaning drainage to adhere to the joint portion of the flexible tube, and the joint portion has electrodes and Even if the conductive portion is exposed, the joint portion is not directly exposed to the atmosphere, so that it can be effectively prevented from oxidation and dust adhesion.
[0106]
Such an auxiliary cap removes the treatment instrument from the joint portion of the flexible tube and is mounted instead. Therefore, various types of auxiliary caps are proposed as the present invention according to the structure of the joint portion of the flexible tube. ing.
FIG. 11 shows an example of the auxiliary cap C (# 1) attached to the joint portion connecting the air turbine handpiece Ha.
[0107]
As shown in FIG. 11, the flexible tube D has a joint portion 60 protruding from the tip, and the joint portion 60 has a water supply pipe 61 for supplying water, an air supply pipe 62 for driving an air turbine, An exhaust pipe 63 for exhausting the air tabine is formed, and these pipes 61 to 63 are respectively provided with water supply pipe openings in annular grooves separated by adjacent projecting outer walls to which O-rings 64 to 66 are externally fitted. 61a, an air supply line port 62a, and an exhaust line port 63a are opened. Note that a lamp 67 is provided at the distal end of the joint portion 60 so as to be housed inside the air turbine handpiece Ha and illuminate the inside of the cavity port.
[0108]
Here, the auxiliary cap C (# 1) has a cylindrical main body 16a in which a through hole 19 leading from the tip opening 16 to the joint insertion opening 17 is opened in the longitudinal direction, and the joint insertion opening of the cylindrical main body 16a. A flange portion 18 is provided on the 17 side, and a set of drainage hole ports 16 b communicating with the through hole 19 are opened on the outer peripheral wall of the cylindrical main body 16 a, and the through hole 19 has a different inner diameter. Inner peripheral walls 19a to 19d are coupled to form an uneven step.
[0109]
According to such an auxiliary cap C (# 1), when the joint portion 60 of the flexible tube D is inserted into the joint insertion port 17 as shown in FIG. The fitted two O-rings 64 and 65 are in contact with the inner peripheral walls 19b and 19c of the through-hole 19 and elastically deformed, so that a pair of drain hole 16b and water supply pipe port 61a opened in the inner peripheral wall 19b. Are communicated in a watertight manner through the annular groove. Therefore, the water discharged from the water supply pipe port 61a through the flexible tube D flows into the air supply pipe port 62a and the exhaust pipe port 63a of the joint portion 60, and does not leak to other parts, and does not leak into the outer peripheral wall of the cylindrical main body 16a. It is guided to the formed drain hole 16b and discharged along the outer peripheral wall.
[0110]
In addition, the air supply pipe port 62a formed in the joint portion 60 opens to the inner peripheral wall 19d side of the through hole 19 located at the tip of the water supply pipe port 61a beyond the protruding outer wall on which the O-ring 64 is fitted. Therefore, it is sealed with the water supply pipe port 61a.
Therefore, the air discharged from the air supply pipe port 62a is exhausted vigorously from the tip opening 16 as it is.
[0111]
In addition, since the lamp 67 described above is located in the portion of the inner peripheral wall 19d of the communication hole 19 that is located on the tip side of the air supply conduit port 62a of the joint portion 60, the air discharged from the air supply conduit port 62a. Has an effect of removing dust adhering to the surface of the lamp 67, and water discharged from the drain hole port 16 b through the outer peripheral wall and drained water stored and bounced in a cleaning discharge tank described later enter the through hole 19. Can also be prevented.
[0112]
One exhaust pipe port 63a opens to the inner peripheral wall 19a on the base end side further than the water supply pipe port 61a and communicates with the joint insertion hole 17, but a protrusion with an O-ring 65 fitted thereto. The outer wall separates the water supply conduit 61a in a watertight manner, and the joint insertion hole 17 is closed by the connection end face D11 of the joint part 60 closely attached to the collar part 18 of the cylindrical main body 16a. Therefore, the inflow of outside air is prevented. In the illustrated example, a gap is formed between the joint portion 60 and the inner peripheral wall 19a of the joint insertion hole 17. This gap is a so-called closed path in which the inflow of outside air is prevented by the collar portion 18. It is working.
[0113]
Therefore, the exhaust pipe port 63a does not suck in the outside air, and the water discharged from the drain hole port 16b, the rebound of the drained water stored in the cleaning discharge tank (not shown), and the like are this exhaust pipe port 63a. There is no such thing as an inflow.
If such an auxiliary cap C (# 1) for preventing contamination is used, the joint portion 60 of the flexible tube D is protected from the outside air while the cleaning water is drained, and the cleaning drainage passes through the drain hole 16b to the outer peripheral wall. Since the water is drained to the outside, the joint portion 60 is not contaminated.
[0114]
Further, since the air supplied through the flexible tube D is discharged from the tip opening 16 toward the cleaning discharge tank 2, adhesion of the discharged cleaning water to the joint portion 60 due to splashing up of the cleaning water is prevented and the exhaust gas is discharged. Since the inflow of outside air is prevented from flowing into the duct port 63a, there is no possibility that dust is mixed in or the discharged cleaning water is sucked into the pipe port 63a.
[0115]
FIG. 12 shows an example of the auxiliary cap C (# 2) attached to the joint portion connecting the micromotor handpiece Hm.
As shown in FIG. 12, the flexible tube D has a joint portion 70 protruding from the tip, and a water supply pipe 71 for supplying water to the joint portion 70 and tip air for supplying air for blowing off the cutting powder. A pipe 72 and a cooling air pipe 73 for supplying air for cooling the motor are formed. Among these, the pipes 71 and 72 are formed on an outer peripheral portion sandwiched between annular grooves in which O-rings 74 to 76 are fitted. The water supply pipe port 71a and the tip air pipe port 72a are opened, and the pipe line 73 penetrates the center of the joint portion 7 linearly, and the cooling air pipe port 73a is opened at the joint tip.
[0116]
Here, the auxiliary cap C (# 2) has a cylindrical main body 30a in which a through hole 34 leading from the tip opening 30 to the joint insertion port 32 is opened in the longitudinal direction, and the joint insertion port of the cylindrical main body 30a. A flange portion 33 is provided on the side 32, and a set of drainage hole ports 30b communicating with the through hole 34 are opened on the outer peripheral wall of the cylindrical main body 30a. The peripheral walls 34a and 34b are coupled to form an uneven step.
[0117]
According to such an auxiliary cap C (# 2), when the joint portion 70 of the flexible tube D is inserted into the joint insertion port 32 as shown in FIG. The two fitted O-rings 74 and 75 are in contact with the inner peripheral wall 34a of the through-hole 34 and elastically deformed, so that the drain hole 16b opened on the inner peripheral wall 34a and the water supply pipe port 71a communicate in a watertight manner. Let
[0118]
Therefore, the water discharged from the water supply pipe port 71a through the flexible tube D flows into the air supply pipe port 72a of the joint part 70, and does not leak to other parts, so that the drain hole formed in the outer peripheral wall of the cylindrical main body 30a. It is guided to the opening 30b and discharged along the outer peripheral wall.
Further, the air supply pipe port 72a formed in the joint portion 70 is airtightly blocked by the wall portion on which the O-ring 75 is fitted, and opens to the inner peripheral wall 34b located at the tip of the water supply pipe port 71a. Therefore, the air discharged from the air supply pipe port 72a is exhausted vigorously from the tip opening 30 as it is.
[0119]
Further, the air from the cooling air pipe 73 is discharged from the cooling air pipe port 73 a as it is toward the tip opening 30 through a path that passes through the center of the joint portion 70. Therefore, the air flow not only blows off dust adhering to the tip of the joint portion 70, but also drains the water discharged from the drain hole 30b through the outer peripheral wall and the water stored in the cleaning discharge tank 2 and bounced back. Can also be prevented from entering the through hole 34.
[0120]
If such an auxiliary cap is used, the joint portion 70 of the flexible tube D is protected from the outside air while draining the washing water, and the washing drainage is drained to the outside through the outer peripheral wall through the drain hole 30b. The joint part 70 is not contaminated. In addition, since the air supplied through the flexible tube D is discharged from the tip opening 30 toward the cleaning discharge tank, adhesion of the discharged cleaning water to the joint portion 70 due to splashing up of the cleaning water is also prevented.
[0121]
In addition, since an electrode terminal (not shown) for supplying power for driving the micro motor is exposed on the connection end surface D21 of the joint portion 70 on the connection end surface of the joint portion of the micro motor handpiece. If an auxiliary cap is used, such an electrode terminal can also be covered with the collar part 33, and can be protected without adhering discharged water or the like.
[0122]
FIG. 13 shows an example of an auxiliary cap attached to a joint portion that connects the scaler Hc.
The flexible tube D has a joint 80 projecting from the tip thereof, and a water supply pipe 81 for supplying water is formed in the joint 80, and the pipe 81 passes through the center of the joint 80, A water supply pipe port 81a is opened at the tip.
[0123]
Here, the auxiliary cap C (# 3) has a cylindrical main body 50a in which a through hole 54 leading from the tip opening 50 to the joint insertion opening 52 is opened in the longitudinal direction, and the joint insertion opening of the cylindrical main body 50a. A flange portion 53 is provided on the 52 side, and an inner peripheral wall 54 a into which the joint portion 80 is fitted is formed in the through hole 54.
According to such an auxiliary cap C (# 3), when the joint portion 80 of the flexible tube D3 is inserted into the joint insertion port 52 as shown in FIG. The O-ring 82 externally fitted in the formed outer peripheral groove contacts the inner peripheral wall 54a of the through hole 54 and elastically deforms, thereby allowing the water supply pipe port 81a and the tip opening 50 to communicate with each other in a watertight manner.
[0124]
Accordingly, the water discharged from the water supply pipe port 81a through the flexible tube D is guided to the tip opening 50 without entering the other part of the joint 80, and is discharged as it is.
In addition, when such an auxiliary cap C (# 3) for preventing contamination is used, the joint 80 of the flexible tube D is protected from the outside air while the cleaning water is drained, and the cleaning drainage is passed through the tip opening 50. Since the water is drained, the joint 80 is not contaminated with the cleaning waste water.
[0125]
Furthermore, as in this example, the joint 80 connecting the scaler is normally provided with an electrode terminal (not shown) for supplying power for the scaler. The flange portion 53 faces the connection end surface D31, and by covering and covering such an electrode terminal, the adhesion of dust and the like is prevented, and the drain terminal is not adhered and the electrode terminal is protected.
[0126]
An auxiliary cap having the structure shown in FIGS. 14 and 15 may be used. FIG. 14 shows an example of an auxiliary cap provided with a backflow prevention valve element using an elastic O-ring.
The auxiliary cap C (# 4) is formed by forming a ring-shaped concave groove 85 having a substantially V-shaped cross section in the outer peripheral wall 50a having the drain hole port 84 opened, and inserting an elastic O-ring 83 into the concave groove 85. The cylindrical main body 51 provided with the backflow prevention valve body 8 is provided, and the tip of the cylindrical main body 51 is closed.
[0127]
An inner peripheral wall 54 a is formed on the inner surface of the cylindrical main body 51, and when the joint 80 of the flexible tube D is attached, the drain hole 84 is connected to the water supply pipe 81 a of the water supply pipe 81 of the flexible tube D. It has a structure that matches and allows watertight communication.
Further, a flange 53 is provided on the side of the joint insertion opening 52 of the cylindrical main body 51, and dust is infiltrated by being brought into close contact with the connection end surface D31 of the joint 80 inserted into the joint insertion opening 52. The connection end face D31 of the part is not exposed to air and oxidized.
[0128]
According to such an auxiliary cap C (# 4), when the joint portion 80 of the flexible tube D3 is inserted into the joint insertion port 52 as shown in FIG. The O-ring 82 externally fitted in the outer peripheral groove formed on the part side makes contact with the inner peripheral wall 54a of the cylindrical main body 51 and elastically deforms the water supply pipe port 81a and the tip opening 50 in a watertight manner.
[0129]
Accordingly, when the water supply means of the medical device is activated and the cleaning wastewater is supplied from the water supply pipe port 81a through the flexible tube D, the cleaning wastewater does not enter the other part of the joint portion 80, and the drainage hole port. Since the elastic O-ring 83 inserted into the concave groove 85 from 84 is expanded and the diameter thereof is expanded by the hydraulic pressure, there is a gap between the elastic O-ring 83 and the concave groove 85 as shown in FIG. As shown in (b), a gap is formed, and the cleaning waste water is discharged from the gap without scattering.
On the other hand, when the operation of the water supply means is stopped and the water pressure of the cleaning wastewater supplied from the water supply pipe port 81a through the flexible tube D is lowered, the elastic O-ring 83 is restored to the original state, and between the concave groove 85 and Since the gap is closed, the discharge of the washing waste water is stopped at that time. For this reason, the washing waste water does not leak out or the discharged washing waste water does not flow backward.
[0130]
15 shows the auxiliary cap C (# 5) attached to the joint portion connecting the air turbine handpiece Ha, as in the case of FIG.
The structure of the joint portion of the flexible tube D is the same as that shown in FIG.
A water supply pipe 61 for supplying water, an air supply pipe 62 for driving the air turbine, and an exhaust pipe 63 for exhausting the air tabine are formed in the joint portion 60. In addition, a water supply pipe port 61a, an air supply pipe port 62a, and an exhaust pipe port 63a are opened in annular grooves divided by adjacent projecting outer walls to which O-rings 64 to 66 are fitted.
[0131]
Further, a lamp 67 made of an LED or the like is provided at the tip of the joint portion 60 so as to be housed inside the air turbine handpiece Ha and illuminate the inside of the cavity.
The tip of the cylindrical main body 16a is provided with a backflow preventing air valve 20 in which a ball valve 20a supported by a spring 20b is fitted into a tapered ball receiving portion 20c.
That is, the backflow preventing air valve 20 has a spring accommodating portion 21 formed around an exhaust port 21a attached to the distal end portion of the cylindrical main body 16a, and accommodates a spring 20b supported by the ball valve 20a therein.
[0132]
Therefore, when pressurized air is not sent from the air supply pipe 62, the ball valve 20a is pressed against the tapered ball receiving portion 20c by the elastic force of the spring 20b, so that the exhaust port 21a is closed and the supply air is supplied. When pressurized air is sent from the tracheal passage 62, the ball valve 20a is pushed down to the inside of the accommodating portion 21 against the elastic force of the spring 20b. Discharge the compressed air to the outside.
[0133]
Moreover, the cylindrical main body 16a is provided with a collar portion 18, and inner peripheral walls 19a to 19d having different inner diameters are formed on the inner surface thereof to form an uneven portion, like the auxiliary cap of FIG.
According to the auxiliary cap C (# 5) having such a structure, when the cleaning wastewater is discharged from the water supply pipe port 61a through the flexible tube D, it flows into the air supply pipe port 62a and the exhaust pipe port 63a of the joint portion 60. Without entering the other parts, it enters the drain hole port 16b formed in the outer peripheral wall of the cylindrical main body 16a. Therefore, the elastic O-ring 16 is expanded by the drain pressure of the cleaning waste water, and the diameter is enlarged. A gap is formed between the elastic O-ring 16 and the concave groove 16c, and the cleaning waste water is discharged from the gap, so that the cleaning waste water is not scattered.
Further, when the operation of the water supply means of the medical device is stopped, the drainage pressure of the cleaning drainage by the flexible tube D is lowered, so that the elastic O-ring 16 is restored by its elastic force and is fitted into the concave groove shape 16c. The above-mentioned gap is closed, so that leakage and backflow of cleaning waste water are prevented.
[0134]
Further, the pressurized air released from the air supply pipe port 62a pushes down the ball valve 20a elastically supported by the spring 20b to the inside of the spring accommodating portion 21, so that the exhaust port 21a is opened and pressurized. Air is exhausted vigorously from the exhaust port 21a. However, if the discharge of the pressurized air from the air supply pipe port 62a stops, the pressure of the pressurized air that has pushed down the ball valve 20a also decreases, so that the ball valve 20a is tapered by the elastic force of the spring 20b. Since the exhaust port 21a is automatically closed by returning to 20c, it is possible to prevent contamination without air flowing back in or outside air being mixed.
[0135]
Therefore, the exhaust pipe port 63a also does not suck in the outside air, and the drained cleaning wastewater, the rebound of the drained water stored in the cleaning discharge tank (not shown), or the like flows into the exhaust pipe port 63a. There is nothing wrong.
In addition, the same code | symbol is attached | subjected to the part corresponding to FIG. 11, and description is abbreviate | omitted.
Next, other features of the medical device having the automatic pipeline cleaning function of the present invention will be described.
[0136]
  Claim20~One of 22The medical device proposed in No. 1 sets the following pretreatment conditions in order to perform pipe cleaning in a fully automatic and safe state.
  16 and 17 are claims.20The gist of the medical device proposed in the above will be described.
  FIG. 16 shows a basic hardware configuration for executing the pipeline cleaning sequence.
[0137]
  This medical device includes a pipe cleaning command switch SW and a flexible tube drawing detection means FD, and the pipe cleaning sequence control means B receives these signals and supplies water supply control equipment including water supply means, air supply The air supply control device including the means is controlled, and the pipeline cleaning sequence as described above is executed.
  Pipe washing sequence control meansB 'When the pipe cleaning command switch SW is operated, the discriminating means 10 ′ is provided with reference to a detection signal from the flexible tube withdrawal detecting means FD, and all the flexible tubes D to be cleaned are ... Is determined from the instrument holding unit 4a as a pre-processing condition, and if the determination means 10 ′ determines that the pre-processing condition is satisfied, a pipeline cleaning sequence is started, and so on. If not, output a trouble signal, notify the lamp L or alarm BL, and work so that all the flexible tubes D to be cleaned are completely pulled out from the instrument holder 4a. It is supposed to prompt.
[0138]
  FIG. 17 shows an example of pretreatment conditions that are employed to start the pipeline cleaning sequence.
  Here, the medical device is an air turbine handpiece Ha, a microphoneRomotorHandpieceHm, Three-wiring syringe Hc, vacuum syringe Hb, and flexible tubes equipped with these instruments are to be cleaned, but these flexible tubes are drawn out from the instrument holder (a) to (d ) Is determined as a so-called logical product.
  In order to make the pretreatment conditions more stringent, devices other than the flexible tube and various operations may be added to the conditions.
  In addition, when using the above-mentioned contamination prevention auxiliary caps C (# 1)..., The mounting of these auxiliary caps C (# 1).
[0139]
  Next, another medical device will be described. When performing pipe cleaning of medical devices under fully automatic conditions, in addition to determining the pretreatment conditions as described above, pipe cleaning sequence control meansB 'When a medical device is operated during normal medical treatment while the pipe is being cleaned, for example, operating the elevation switch on the medical table of the medical device or tilting the backrest For this reason, when the operation switch is operated, the pipeline cleaning sequence may be stopped immediately.
  Claim21Has proposed a medical device having such an emergency stop function. In such an apparatus, the pipeline cleaning sequence may be urgently stopped even when an electric drive unit such as an illumination lamp, a micromotor, or a scaler drive source of the treatment instrument is driven. . Steps 200 to 207 in FIG. 18 show the basic operation in this case with a flowchart.
[0140]
  In the case of constituting a medical device, a conduit washing sequence control meansB 'Since the pipeline cleaning once started is not hindered during the operation, the operation switch for tilting the backrest or the operation of the operation switch for tilting the backrest or the treatment is performed during the pipeline cleaning sequence. When there is an instrument driving operation, ignoring these is also desired in order to further enhance safety in pipe cleaning under fully automatic conditions. The medical device proposed in claim 23 has such a function. The steps 300 to 311 in FIG. 19 show the basic operation in this case with a flowchart.
  When pipe cleaning is in progress when an operating switch on the clinic table is operated, an operation switch for tilting the backrest, or an electric drive of the instrument for treatment is operated. Clears these operations, but if not, allows the clinic to move up and down, tilt the backrest, or drive the electrical drive of the instrument for treatment.
[0141]
It should be noted that it is desirable to change the above conditions as appropriate according to the type of medical device, and the instrument holding unit can be operated even if the operation of the raising / lowering operation switch of the medical table or the tilting operation switch of the backrest is performed. In the case of an operation in which the flexible tube set in the drainage receiving part is not likely to be moved without changing the relative positional relationship between the drainage receiving part and the drainage receiving part, it may be received as it is.
[0142]
On the other hand, the instrument holding part can be changed by changing the relative positional relationship between the instrument holding part and the drainage receiving part without operating the raising / lowering switch of the medical table or the tilting operation switch of the backrest. You may make it the structure which prohibits the operation | movement which changes the distance and position of a flexible tube passed to a waste-water-receiving part.
For example, when the treatment apparatus is such that the instrument holding portion 4a is provided as an independent work table 34 beside the medical table sheet 1 as shown in FIG. Since the instrument for treatment attached to the tip of the tube D operates, the emergency stop may be performed. However, the doctor switch 36 and the nurse switch 37 are operated, and the medical table seat 1 and the backrest backrest 4 are operated. Even if it is operated, the instrument holding portion 3a does not move, so that it is not necessary to make an emergency stop. In such a case, it is only necessary to make an emergency stop when the work table 34 is operated.
[0143]
  Next, the medical device proposed from the viewpoint of safety in order to perform pipe cleaning fully automatically will be described.
  In FIG.The pipe cleaning sequence control means B is provided with a discriminating means 10 ', and inputs a pipe cleaning command switch SW and a flexible tube withdrawal detecting means FD to supply water control equipment and air supply control equipment for pipe cleaning. Is controlling.
  Here, the pipe cleaning method to be executed is not limited to the method proposed as the present invention, and is also applied to general pipe cleaning.
  The flexible tube pull-out detection means FD detects whether all the flexible tubes to be subjected to pipe line washing are pulled out from the holding portion 4a, and all the flexible tubes to be drawn are pulled out from the holding portion 4a. When the processing condition is satisfied, a command signal from the pipe cleaning command switch SW is received and the pipe cleaning sequence is started.
[0144]
Further, since the determination means 10 ′ sends a prohibition signal to the gates G1 and G2 when the pipeline cleaning sequence is started, if the elevating operation switch SWa and the backrest operation switch SWb are operated, A driving signal is prevented from being input to the medical table raising / lowering control means 11 ′ and the backrest tilt control means 12 ′.
Further, such a pipe cleaning sequence control means B may perform control in consideration of the structural features of the medical device.
That is, if the distance between the flexible tube and the drainage receiving portion does not change even when the backrest is raised or tilted by operating the elevation operation switch SWa or the backrest operation switch SWb, the determination means 10 ′ Does not have to prohibit the operation by the operation switches SWa and SWb.
However, it is not limited to the backrest lifting switch SWa and the backrest operation switch SWb. When the switch of the medical device is operated, the distance between the flexible tube D... In order to prevent the flexible tubes D... Set in the receiving part 3 from dropping off, the operation control of that part may be prohibited.
[0145]
  In FIG.The pipe cleaning sequence control means B includes a discrimination means 10 'for detecting and discriminating signals from the mode changeover switch SWm, the pipe cleaning switch SW, and the flexible tube withdrawal detection means FD, and the discrimination by the discrimination means 10'. The water supply control device and the air supply control device are controlled according to the operation to execute the pipeline cleaning sequence, and the determination means 10 ′ inputs operation signals such as the lifting operation switch SWa and the backrest operation switch SWb, It is configured to control the medical table elevation control means 11 ′ and the backrest tilt control means 12 ′. The flexible tube withdrawal detection means FD determines whether or not all flexible tubes to be subjected to pipeline cleaning have been pulled out from the instrument holding means 4a as a preprocessing condition. Even if is operated, the pipeline cleaning sequence is locked and not started unless this pretreatment condition is satisfied.
[0146]
Further, in this medical device, the mode switching switch SWm allows any one of the pipeline cleaning sequence priority mode and the pipeline cleaning sequence emergency stop priority mode to be freely selected according to the purpose of use. You may design to either mode specification.
The basic operation will be described. The mode selection switch SWm is used to select and set the pipe cleaning sequence priority mode, and the pipe cleaning switch SW is operated to operate the pipe cleaning sequence control means B to supply water control equipment and air supply. When the control device is activated, the discriminating means 10 ′ sends a prohibition signal to the gate circuits G1 and G2. Therefore, during the execution of the pipeline cleaning sequence, even if any one of the lifting operation switch SWa and the backrest operation switch SWb is operated, it is driven to the medical table lifting control means 11 ′ and the backrest tilt control means 12 ′. No signal is sent and these operations are prohibited.
[0147]
Therefore, if such a pipeline cleaning sequence priority mode is set and the pipeline cleaning sequence is executed, even if the elevator operation switch SWa, the backrest operation switch SWb, etc. are inadvertently operated, Since the operation is ignored, the pipe cleaning sequence control can be executed without interruption.
By the way, such a pipeline cleaning sequence priority mode can be controlled in consideration of the structural features of the medical device.
When the backrest is lifted or tilted by operating the lift operation switch SWa or the backrest operation switch SWb, the chair mount type medical device as shown in FIG. The distance from the drainage receiving portion 3 does not change, and the operation does not have to be invalidated.
Further, what invalidates the operation of the switch of the medical device is not limited to the lift switch SWa or the tilt operation switch SWb of the backrest, and when the switch is operated, the flexible tube D... What changes the distance may be configured so as to prohibit the operation thereof, and claims 24 and 25 propose a medical device with such safety measures.
[Brief description of the drawings]
FIG. 1 is a flowchart showing a basic operation procedure in a pipe cleaning method of the present invention.
FIG. 2 is a diagram for explaining the point of carrying out the pipe cleaning method of the present invention using a dental medical device.
FIG. 3 is a diagram for explaining a procedure for performing pipe cleaning using a cleaning drain tank;
FIG. 4 is a view showing another example of the drainage receiving part of the medical device.
FIG. 5 is a longitudinal sectional view of a main part for explaining drainage cleaning of a cup water supply part.
FIG. 6 is a diagram illustrating an example of an electric circuit of a pipe cleaning sequence control unit.
FIG. 7 is a system diagram showing a schematic configuration of a piping control system incorporated in the medical device of the present invention.
FIGS. 8A to 8M are time charts showing the operation of each part of the pipe control system when the pipe cleaning method of the present invention is carried out.
FIGS. 9A to 9C are views showing a drainage cleaning tank and a flexible tube used when carrying out the pipe cleaning method of the present invention. FIGS.
FIGS. 10A and 10B are diagrams showing an example of use of an auxiliary cap used when carrying out the pipe cleaning method of the present invention. FIGS.
FIG. 11 is a longitudinal sectional structural view of a main part showing an example of an auxiliary cap attached to a joint part of a flexible tube when the pipe cleaning method of the present invention is carried out.
FIG. 12 is a longitudinal sectional structural view of a main part showing an example of an auxiliary cap attached to a joint part of a flexible tube when the pipe cleaning method of the present invention is carried out.
FIG. 13 is a longitudinal sectional structural view of a main part showing an example of an auxiliary cap attached to a joint part of a flexible tube when the pipe cleaning method of the present invention is carried out.
FIG. 14A is a longitudinal sectional structural view of the main part showing an example of an auxiliary cap attached to the joint portion of the flexible tube when the pipe cleaning method of the present invention is carried out, and FIG. 14B is a backflow prevention valve. It is expansion explanatory drawing of the elastic O-ring which makes | forms.
FIG. 15 is a longitudinal sectional structural view of a main part showing another example of an auxiliary cap attached to the joint portion of the flexible tube when the pipe cleaning method of the present invention is carried out.
FIG. 16 is a block diagram showing a hardware configuration for realizing pre-processing determination of the medical device of the present invention.
FIG. 17 is a logical explanatory diagram showing an example of conditions determined by the preprocessing determination unit of the medical device of the present invention.
FIG. 18 is a flowchart showing a basic operation when an operation during normal medical treatment or treatment is performed in the medical device of the present invention having an automatic pipe cleaning function.
FIG. 19 is a flowchart showing the basic operation when stopping the pipeline cleaning sequence in the medical apparatus of the present invention having an automatic piping cleaning function.
FIG. 20 is a block diagram showing a basic configuration of a medical device having a pipeline automatic cleaning function for which safety measures are taken.
FIG. 21 is a block diagram showing another basic configuration of a medical device having an automatic pipe line cleaning function in which safety measures are taken.
FIG. 22 is a diagram showing an example of a medical device in which an instrument holding unit is provided on a work table.
[Explanation of symbols]
A Medical device body
B Waste water washing sequence control means
C Auxiliary cap
D, D ', D "Flexible tube
Ha Air Turbine Handpiece
Hm Micromotor handpiece
Hc scaler
H3 three-way syringe
Hb vacuum syringe
SVa Air main control valve
SVb Automatic Basin Wash Valve
SVc cup water supply valve
SVd Residual water drainage control valve
SVe vacuum control valve
SVf Drain tank drain control valve for cleaning
SVg Vacuum source control valve
SVh Vacuum tank drain control valve
SVi water supply valve
SVp pilot air operated valve
SVs servo valve
SVw Water supply main control valve
SW Pipe cleaning command switch
1 treatment device
2 Waste water tank for cleaning
3 Drainage receiving part (basin)
31 cup water supply
4 Backrest
5 Vacuum tank
6 traps
60, 70, 80 Flexible tube joint
16, 30, 50 Auxiliary cap tip opening
17, 32, 52 The joint insertion port
16a, 30a, 50a its cylindrical body
16b, 30b, 50b Drainage hole
19a-19d, 34a, 34b, 54a Its inner wall
10 CPU
11 Logic control circuit
12 Pilot air operated valve drive circuit
13 Air main control valve drive circuit
14 Water supply main control valve drive circuit
15 Residual water drainage control valve drive circuit

Claims (22)

A water supply means, a cup water supply section for supplying water to the cup with water supplied from the water supply means, and a drainage receiving section for receiving gargle water or washing water from the treatment instrument,
At least one flexible tube having a built-in water supply pipe for supplying water from the water supply means to a treatment instrument detachably connected to the joint is derived from the instrument holder. and is not a structure,
And in the medical device in which the drainage flow rate of the cup water supply unit is larger than the drainage flow rate of the flexible tube ,
After setting the flexible tube containing the water supply pipe in the drainage receiving part, the water supply means is operated,
A pipe cleaning method for a medical device, wherein the pipe cleaning of the flexible tube is performed after the pipe cleaning of the cup water supply unit is preferentially performed . In claim 1 ,
The medical device pipe cleaning method, wherein the drainage cleaning of the drainage receiving portion is further performed when the water supply means is operated to preferentially perform the pipe cleaning of the cup water supply portion or immediately thereafter. . In claim 1 or 2 ,
A pipe cleaning method for a medical device, wherein after the flexible tube is set in a drainage tank for cleaning placed in a drainage receiving portion, cleaning drainage is discharged from the flexible tube all at once and pipe cleaning is performed. In any one of Claims 1-3 ,
The medical device further includes suction means and a vacuum syringe,
When setting a flexible tube with a treatment instrument detachably connected to the distal end of the cleaning instrument placed in the drain receiving part, the vacuum syringe is set in the cleaning drain tank. A method of cleaning a pipe of a medical device, wherein a suction device is operated to thereby discharge cleaning wastewater from the flexible tube into the cleaning drainage tank while suctioning the cleaning wastewater tank from the vacuum syringe. . In performing the piping cleaning method for a medical device according to any one of claims 1 to 4, when cleaning a flexible tube containing a water supply pipe led out from the medical device , the flexible tube is attached to a joint portion of the flexible tube. An anti-contamination auxiliary cap,
It has a cylindrical main body with an opening formed at the tip, and when the joint portion of the flexible tube is attached to the inner surface of the cylindrical main body, the opening is made water-tightly communicated with the water supply conduit of the flexible tube. Contamination prevention auxiliary cap with a structure that forms an inner wall. In performing the piping cleaning method for a medical device according to any one of claims 1 to 4, when the flexible tube incorporating the water supply conduit and the air supply conduit led out from the medical device is cleaned, the flexible tube An anti-contamination auxiliary cap attached to the joint part of
A drainage hole opening is formed in the outer peripheral wall, and a cylindrical main body having an opening at the tip is formed. When the joint portion of the flexible tube is attached to the inner surface of the cylindrical main body, the drainage hole opening An auxiliary cap for preventing pollution having a structure in which an inner peripheral wall having an uneven portion is formed so that the opening at the tip is separated and communicated with the air supply conduit of the flexible tube. . In performing the piping cleaning method for a medical device according to any one of claims 1 to 4, when cleaning a flexible tube containing a water supply pipe led out from the medical device , the flexible tube is attached to a joint portion of the flexible tube. An anti-contamination auxiliary cap,
It has a cylindrical main body with a closed end, which is provided with a backflow prevention valve body formed by forming a ring-shaped concave groove on the outer peripheral wall opening the drainage hole port, and inserting an elastic O-ring into the concave groove, On the inner surface of the cylindrical main body, when the joint portion of the flexible tube is mounted, an inner peripheral wall having an uneven portion that allows the drainage hole port to communicate with the water supply conduit of the flexible tube in a watertight manner is formed. Auxiliary cap to prevent contamination. In performing the piping cleaning method for a medical device according to any one of claims 1 to 4, when the flexible tube incorporating the water supply conduit and the air supply conduit led out from the medical device is cleaned, the flexible tube An anti-contamination auxiliary cap attached to the joint part of
A ring-shaped concave groove is formed in the outer peripheral wall having the drain hole opening, and a backflow prevention valve body configured by inserting an elastic O-ring into the concave groove is provided. A cylindrical body having a normally closed backflow prevention air valve that opens the opening, and the inner surface of the tubular body has a flexible tube joint attached to the drainage hole of the backflow prevention valve body. Contamination prevention auxiliary with a structure that has an inner peripheral wall with an uneven portion that allows the backflow prevention air valve to be separated and communicated with the flexible tube air supply conduit. cap. In any one of Claims 1-4 ,
Remove the instrument for treatment from the joint portion of the flexible tube to be cleaned, instead of attaching the auxiliary cap for contamination prevention according to claim 5 , in that state, operating the water supply means of the medical device, A medical device pipe cleaning method, characterized in that pipe cleaning is performed by discharging cleaning wastewater from the tip opening of the contamination prevention auxiliary cap. In any one of Claims 1-4 ,
The instrument for treatment is removed from the joint portion of the flexible tube to be cleaned, and instead the auxiliary cap for contamination prevention according to claim 6 is attached, and in this state, the water supply means and the air supply means of the medical device A pipe cleaning method for a medical device, wherein the pipe is cleaned by discharging air from the tip opening while discharging the cleaning drainage from the drain hole of the auxiliary cap for preventing pollution. In any one of Claims 1-4 ,
Remove the instrument for treatment from the joint portion of the flexible tube to be cleaned, and instead, attach the auxiliary cap for contamination prevention according to claim 7 , and in that state, operate the water supply means of the medical device, A pipe cleaning method for a medical device, characterized in that cleaning drainage is discharged from the backflow prevention valve body of the contamination prevention auxiliary cap to perform pipe cleaning. In any one of Claims 1-4 ,
The instrument for treatment is removed from the joint portion of the flexible tube to be cleaned, and instead the auxiliary cap for contamination prevention according to claim 8 is attached, and in this state, the water supply means and the air supply means of the medical device Is operated, and the discharge water is discharged from the backflow prevention valve body of the auxiliary cap for pollution prevention, and the backflow prevention air valve is opened, and air is discharged from the exhaust port to clean the pipe. Pipe cleaning method for medical equipment. At least a water supply means is incorporated, and at least one flexible tube having a treatment instrument such as a handpiece, a scaler, or a three-way syringe detachably connected to the tip is detachably held from the instrument holding portion, And it is a medical device comprising a cup water supply unit and a drain receiving part, wherein the drainage flow rate of the cup water supply unit is larger than the drainage flow rate of the flexible tube ,
A pipe cleaning command switch;
For the flexible tube to be cleaned, flexible tube withdrawal detection means for detecting withdrawal from the instrument holder,
When the pipe washing command switch is operated, the drawing detection means is referred to determine the drawing from the instrument holder for all the flexible tubes to be washed as a pretreatment condition. When the processing conditions are established, by operating the water supply means, the pipe water supply section is first cleaned, and then the flexible tubes to be cleaned are simultaneously cleaned. A medical device having an automatic line cleaning function, characterized in that it comprises a line cleaning sequence control means. In claim 13 ,
The medical device further includes suction means and a vacuum syringe,
When setting the flexible tube to be cleaned in the cleaning drainage tank, the vacuum syringe is set in the cleaning drainage tank and the suction unit is operated, whereby the pipeline cleaning sequence control unit is The automatic pipe line cleaning function that continuously performs the operation of sucking the cleaning wastewater discharged into the cleaning drainage tank by the vacuum syringe while discharging the cleaning wastewater from the flexible tube to be cleaned. Medical device with In claim 13 or 14 ,
The pipe cleaning sequence control means operates the pipe cleaning command switch to automatically clean the drain water receiving section when the pipe water feeding section is cleaned or immediately thereafter. Medical device with automatic pipe line cleaning function. In any one of Claims 13-15 ,
A drainage tank for washing is placed in the drainage receiving section, a flexible tube to be washed is set in the washing drainage tank, and the washing drainage is discharged into the washing drainage tank. A medical device with a cleaning function. In any one of Claims 13-16 ,
The water supply means further comprising an air supply means, wherein the pipe line washing sequence control means is provided with an air operation valve for supplying water to various treatment instruments from the water supply means and the air supply means through the flexible tube. A piping control system, an air piping control system provided with an air actuated valve for supplying air to various treatment instruments, and a logic control for opening and closing the electromagnetic valves of these water supply piping control system and air piping control system A medical device equipped with a circuit automatic cleaning function having a circuit. In claim 17 ,
Each of the air pipe control system and the water supply pipe control system includes an air main control valve and a water supply main control valve in addition to a common pilot air operation valve.
A medical device having an automatic pipe line cleaning function in which a residual water discharge control valve is arranged in parallel between the upstream side of the pilot air operation valve and the downstream side of the water supply main control valve. In claim 17 or 18 ,
The air piping control system includes an air supply pipe provided with a servo valve for controlling the air flow rate supplied to the treatment instrument detachably connected to the joint portion of the flexible tube. Is a medical device provided with an automatic line cleaning function that opens when the pipe cleaning sequence control means is operated by operating the pipe cleaning command switch and operates the air supply means. In any of claims 13-19,
The pipe cleaning sequence control means accepts a command signal from the pipe cleaning switch only when it is detected that various instruments to be cleaned are pulled out from the instrument holder. The medical device provided with the automatic pipe line cleaning function, which is further provided with the function of starting the operation. In any of claims 13-20,
The conduit cleaning sequence control means includes at least one operation signal among an operation signal of an elevation operation switch of a medical table of a medical device, an operation signal of an operation switch of a tilting means of a backrest, and a pedal operation signal of a foot controller. A medical device having an automatic line cleaning function that further includes a function of stopping the pipe cleaning that is being performed when an operation signal is detected. In any of claims 13-21,
The above-mentioned line washing sequence control means can be used when the pipe washing is being performed even if the operation signal such as the operation signal of the raising / lowering operation switch of the clinical table and the operation signal of the operation switch of the backrest tilting means is received. A medical device having an automatic pipe line cleaning function that further includes a function of prohibiting an operation of changing the relative positional relationship between the mentment holding part and the drainage receiving part.

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