JP2023020820A - Dental suction device, and ejector pump - Google Patents

Abstract

To provide a dental suction device that is sanitary and has high operability, and an ejector pump.SOLUTION: A micro vacuum device 100 comprises: a hand piece 10 provided with a suction part 10a; a tube 20 connected to the hand piece 10; and an ejector pump 30 provided in a dental treatment unit, and connected to the tube 20. The ejector pump 30 comprises: an introduction port for introducing air from an air supply source of the dental treatment unit; a nozzle for decompressing and injecting the air introduced from the introduction port; a main body for generating a negative pressure around the nozzle by using the injection of the air; a connection part (suction port) connected to the tube, and for using the negative pressure generated by the main body part as a suction force; and a discharge port for discharging an object sucked from the connection part together with the air from the introduction port.SELECTED DRAWING: Figure 1

Description

The present disclosure relates to dental suction devices and ejector pumps.

2. Description of the Related Art In dental treatment, especially root canal treatment, it is necessary to remove the used washing solution from the root canal after injecting the washing solution into the root canal to wash the inside of the root canal. A dental suction device using an ejector pump is known as a dental suction device for sucking cleaning fluid from the inside of a root canal. Specifically, Patent Document 1 (Japanese Patent Publication No. 61-50456) describes a dental vacuum handpiece having an ejector pump built in the body of the handpiece. Further, Patent Document 2 (Japanese Unexamined Patent Application Publication No. 2002-248117) describes a dental vacuum handpiece having an ejector pump built in the head of the handpiece.

Japanese Patent Publication No. 61-50456 Japanese Patent Application Laid-Open No. 2002-248117

In the dental vacuum handpiece described in Patent Document 1, it is necessary to attach two tubes to the handpiece, one for supplying compressed air to the ejector pump and the other for discharging air from the ejector pump. Handling of the tube is inconvenient, and there is a possibility that the operability may deteriorate. Further, in the dental vacuum handpiece described in Patent Document 2, the washing liquid sucked from the inside of the root canal is discharged from the head of the handpiece into and out of the oral cavity. In particular, if the handpiece is not properly sterilized, the source of infection may be expelled from the head of the handpiece into and out of the oral cavity, causing a sanitary problem.

The present disclosure has been made in view of the above problems, and an object thereof is to provide a hygienic and highly operable dental suction device and an ejector pump.

The dental suction device of the present disclosure is a dental suction device that connects to a dental treatment device. A dental suction device includes a handpiece provided with a suction portion, a suction line connected to the handpiece, and an ejector pump provided within the dental treatment apparatus and connected to the suction line. The ejector pump consists of an inlet that introduces air from the air supply source of the dental treatment device, a nozzle that reduces the pressure of the air introduced from the inlet and ejects it, and a main body that creates a negative pressure around the nozzle by ejecting the air. a suction port that is connected to the suction channel and uses the negative pressure generated in the main body as a suction force; and a discharge port that discharges the sucked matter sucked from the suction port together with the air from the introduction port.

The ejector pump of the present disclosure is an ejector pump that is provided in a dental treatment device and connected to a suction line of a dental suction device. The ejector pump consists of an inlet that introduces air from the air supply source of the dental treatment device, a nozzle that reduces the pressure of the air introduced from the inlet and ejects it, and a main body that creates a negative pressure around the nozzle by ejecting the air. a suction port that is connected to the suction pipe line and uses the negative pressure generated in the main body as a suction force;

According to the dental suction device and the ejector pump of the present disclosure, the ejector pump is provided in the dental treatment device, the suction port of the ejector pump is connected to the suction channel, and the aspirated matter sucked from the suction port is removed. Since it is discharged from the discharge port, it is hygienic and can realize high operability.

1 is a schematic diagram showing the configuration of a dental suction device according to an embodiment of the present disclosure; FIG. 1 is a cross-sectional view schematically showing a peripheral configuration including an ejector pump according to an embodiment of the present disclosure; FIG. FIG. 4 is a cross-sectional view for explaining the opening of the ejector pump according to the embodiment of the present disclosure; 1 is a schematic diagram showing the configuration of a dental suction device housed in a chair according to an embodiment of the present disclosure; FIG. 1 is a schematic diagram of a dental suction device placed in a dental examination unit in one embodiment of the present disclosure; FIG. FIG. 6 is a schematic diagram showing the configuration of the handpiece holder shown in FIG. 5; FIG. 4 is a schematic diagram showing the configuration of a dental suction device in a modified example of the present disclosure; FIG. 11 is a block diagram showing the configuration of a dental diagnostic unit according to a modified example of the present disclosure; FIG. 11 is a timing chart for explaining cleaning timings of the dental suction device in the modified example of the present disclosure; FIG.

Embodiments of the present disclosure will be described below with reference to the drawings.
FIG. 1 is a schematic diagram showing the configuration of a dental suction device according to one embodiment of the present disclosure. FIG. 2 is a cross-sectional perspective view schematically showing the configuration of the suction unit in one embodiment of the present disclosure. The dental suction device according to the present disclosure is, for example, a microvacuum 100 that removes used cleaning liquid from the root canal after cleaning the inside of the root canal of the tooth. The microvacuum 100 is an example of a dental suction device, and can be applied to any suction device as long as it is a suction device that can be used in dentistry.

The microvacuum 100 includes a handpiece 10 provided with a suction portion 10a, a tube 20 as a suction conduit, and an ejector pump 30. As shown in FIG.

The handpiece 10 has a cylindrical grasping portion 10b that can be easily grasped by the operator, and a suction portion 10a is provided at one end of the grasping portion 10b. The suction part 10a has, for example, an inner diameter of 0.3 mm and an outer diameter of 0.5 mm. The suction part 10a may be of any size as long as it can be inserted into the root canal to remove the used washing liquid from the root canal. 7 mm is sufficient. Moreover, the shape of the suction part 10a is a shape bent from the longitudinal direction of the grip part 10b so that it can be easily inserted into the root canal.

A tube 20 is connected to the other end of the grip portion 10b. The tube 20 is a flexible tube, and is made of a material such as silicone, polypropylene, polyethylene, vinylidene chloride, polyvinylidene fluoride, perfluoroalkoxy copolymer, tetrafluoroethylene-ethylene copolymer, or tetrafluoroethylene.

The tube 20 is connected to an ejector pump 30 that uses drive air supplied to an air turbine handpiece or the like to generate a suction force. As will be described later, the ejector pump 30 is provided inside the back plate of the chair, which is the examination table. Therefore, when an ejector pump is provided in the handpiece like a conventional micro vacuum, two tubes, one for supplying compressed air to the ejector pump and the other for discharging air, etc. from the ejector pump, must be installed in the handpiece. However, in the microvacuum 100 of the present disclosure, only the tube 20 needs to be connected to the handpiece 10 . Therefore, the microvacuum 100 can easily handle the tube 20 and has high operability.

Further, when an ejector pump is provided on the head of the handpiece as in the conventional microvacuum, the washing liquid sucked from the inside of the root canal is discharged from the head of the handpiece into and out of the oral cavity. However, with the micro-vacuum 100 of the present disclosure, the sucked cleaning liquid can be discharged to a drain pipe through the outlet of the ejector pump 30 provided on the back of the chair. Therefore, the microvacuum 100 of the present disclosure is hygienic.

Specifically, the ejector pump 30 introduces air supplied to the air turbine handpiece or the like from an air supply source through the introduction pipe 40, and causes the suction portion 10a of the handpiece 10 to generate a suction force for sucking the cleaning liquid. .

The introduction pipe 40 has one end connected to the air solenoid valve 50 and the other end connected to the introduction port 33 of the ejector pump 30 . The introduction port 33 is an opening for introducing air from an air supply source (for example, an air compressor). A supply line 55 from an air supply source is connected to the air solenoid valve 50 . Therefore, when the air solenoid valve 50 is opened, drive air is supplied from the air supply source to the introduction pipe 40, causing the ejector pump 30 to generate a suction force. The air electromagnetic valve 50 may be a proportional valve that is provided between the air supply source and the inlet 33 of the ejector pump 30 and adjusts the amount of air introduced into the inlet 33 . By adopting a proportional valve as the air solenoid valve 50, the suction force of the ejector pump 30 can be adjusted as compared with the case where the air solenoid valve 50 is simply an on-off valve.

The ejector pump 30 is a type of jet pump that generates a suction force by ejecting high-pressure fluid from a nozzle and utilizing a pressure drop (negative pressure) around the nozzle. Specifically, as shown in FIG. 2, the ejector pump 30 has a nozzle 31 that reduces the pressure of the air introduced from the inlet 33 and ejects it, and uses the negative pressure generated around the nozzle 31 by the ejection of the air as a suction force. and a body portion 32 . The nozzle 31 presses the air introduced from the inlet 33 and jets it. The body part 32 is provided with a connection part 34 connected to the tube 20 around the nozzle 31, and the negative pressure generated around the nozzle 31 is transmitted to the suction part 10a of the handpiece 10 via the tube 20 to suck the washing liquid. power. The connecting portion 34 is a suction port that uses the negative pressure generated in the main body portion 32 as a suction force.

The ejector pump 30 further includes an exhaust port 35 for exhausting air introduced from the introduction pipe 40 . A discharge pipe 60 is connected to the discharge port 35 . As shown in FIG. 2, the discharge port 35 is provided on a straight line in the jetting direction of the nozzle 31 and directly discharges the air jetted from the nozzle 31 . Further, around the nozzle 31 , the cleaning liquid sucked by the suction portion 10 a of the handpiece 10 is contained in the air jetted from the nozzle 31 and discharged from the discharge port 35 to the discharge pipe 60 . The discharge tube 60 has one end connected to the ejector pump 30 and the other end connected to a drain (not shown) of the dental treatment apparatus, as shown in FIG. Therefore, the micro vacuum 100 can directly discharge the cleaning liquid sucked by the suction section 10a of the handpiece 10 to the drainage section using the exhaust from the ejector pump 30. FIG.

The suction force of the ejector pump 30 is determined by the amount of air introduced from the introduction pipe 40 . In other words, the sizes of the openings (introduction port 33, connecting portion 34 (suction port), discharge port 35) of the ejector pump 30 are important. FIG. 3 is a cross-sectional view for explaining the opening of ejector pump 30 in one embodiment of the present disclosure. The ejector pump 30 has, for example, an inlet port 33 with a diameter A of 1.5 mm, a connection portion 34 (suction port) with a diameter B of 1.2 mm, and an outlet port 35 with a diameter C of 2.5 mm. In addition, the size of the opening described above is an example, and in order to obtain the required suction force in the microvacuum 100, the diameter A of the introduction port 33 is at least 1.1 to 2.0 mm, and the connection portion 34 (suction The diameter B of the port) should be at least 0.8-1.6 mm, and the diameter C of the outlet 35 should be at least 1.8-3.3 mm.

Microvacuum 100 is housed in the back of the chair. FIG. 4 is a schematic diagram showing the configuration of a dental suction device housed in a chair according to one embodiment of the present disclosure; As shown in FIG. 4, the chair 1, which is an examination table, is provided with an instrument holder 11 for holding a handpiece 10 of a microvacuum 100 on the shoulder on the left side of the back plate 1c. On the other hand, an instrument holder 12 for holding a three-way syringe 80 is provided on the shoulder on the right side of the back plate 1c in the figure.

When the handpiece 10 of the microvacuum 100 is held by the instrument holder 11, the tube 20 is housed inside the back plate 1c. A rail 70 and a pulley 71 for storing the tube 20 are provided in the back plate 1c. When the tube 20 is stored in the back plate 1c, a pulley 71 for hooking the tube 20 is positioned on the lower side in the drawing. When using the microvacuum 100, when the handpiece 10 of the microvacuum 100 is picked up from the instrument holder 11 on the back plate 1c, the tube 20 stored in the back plate 1c is pulled out, and the pulley 71 moves along the rail 70 in the figure. lifted upwards. Alternatively, when the pulley 71 is pulled up, the air solenoid valve 50 opens and the micro vacuum 100 starts suction. That is, a sensor (not shown) provided on the rail 70 and the opening/closing operation of the air solenoid valve 50 may be interlocked.

When the handpiece 10 of the microvacuum 100 is held by the instrument holder 11 of the back plate 1c, an ejector pump 30 and an air solenoid valve 50 are provided inside the back plate 1c as shown in FIG. The ejector pump 30 and the air solenoid valve 50 are fixed, for example, to a column (not shown) supporting the headrest 1d. A tube 20, an introduction pipe 40, and a discharge pipe 60 are connected to an ejector pump 30 fixed to a column. By housing the ejector pump 30 in the back plate 1c, the ejector pump 30 can be provided near the micro vacuum 100, and the loss of suction force from the ejector pump 30 to the suction portion 10a of the handpiece 10 can be minimized. output can be suppressed.

The introduction pipe 40 is connected to the supply pipe line 55 via the air solenoid valve 50 . The supply line 55 is connected to the air compressor 51 as an air supply source. The supply pipe line 55 is provided with a pressure reducing valve 52, a sterilization filter 53, and the like in this order from the upstream side. The pressure reducing valve 52, for example, feeds back the air pressure of the supply pipeline 55 and keeps the air pressure supplied to the supply pipeline 55 at a constant value. The sterilization filter 53 filters the air supplied to the supply pipe line 55 so that bacteria and the like are not contained therein.

A branch pipeline 54 is provided downstream of the sterilization filter 53 , and the branch pipeline 54 is connected to the three-way syringe 80 via a supply pipeline 56 . Three-way syringe 80 is connected to air compressor 51 via supply line 56 and branch line 54 . The supply line 56 is not provided with an electromagnetic valve. The three-way syringe 80 has an air control lever (not shown) in its grip. When the doctor or assistant presses the air control lever, air is ejected from the tip nozzle portion.

Furthermore, a water supply line 81 is connected to the three-way syringe 80 . The water supply pipe 81 is connected to a water source (tap water), not shown. The three-way syringe 80 has a water supply control lever (not shown) arranged in parallel with the air control lever. Water is jetted out from the tip nozzle portion when the doctor or assistant presses the water supply control lever. The air control lever and the water supply control lever 34b are pressed selectively or simultaneously.

(Modification 1)
In the above embodiment, the micro vacuum 100 is housed while being held by the instrument holder 11 of the back plate 1c. However, the place to store the microvacuum 100 is not limited to the instrument holder 11 of the back plate 1c, and for example, the microvacuum 100 may be stored in a tray table.

FIG. 5 is a perspective view schematically showing the configuration of a dental diagnostic unit according to one embodiment of the present disclosure. Referring to FIG. 5, dental diagnostic unit 200 according to the present embodiment includes chair 1, diagnostic main body 10A, and medium conduit 20A. Additionally, the dental practice unit 200 may include a practice handpiece 30A that is removably connectable with the media conduit 20A. In addition, the medium conduit 20A is detachable from the medical main unit 10A.

The chair 1 is configured so that a patient can receive medical treatment in a seated or supine state. The chair 1 includes a base 1a, a seat plate 1b, a back plate 1c, a headrest 1d, and armrests 1e. The seat plate 1b is installed on the base 1a so as to be vertically movable. The back plate 1c is attached to one end of the seat plate 1b so that it can be raised and lowered. The headrest 1d is tiltably attached to the upper end of the back plate 1c. The armrest 1e is installed on the side of the seat plate 1b.

The medical examination main unit 10A includes a spittoon 2, an illumination device 3, an illumination device arm 4, a tray table 5, and a tray table arm 6. FIG. A spittoon 2 is installed on the side of the chair 1. - 特許庁The spittoon 2 includes a body 2a, a basin 2b, and a water supply tube 2c. A basin 2b is installed at the upper end of the body portion 2a, and a cup hydrant (cup water supply portion) is installed inside the body portion 2a. Further, the basin 2b is provided with a water supply tube 2c extending from the cup water tap. The lighting device 3 is connected to the spittoon 2 via the lighting device arm 4 . The illumination device 3 is, for example, a shadowless lamp.

Further, the body portion 2a of the spittoon 2 is provided with a supply pipe line 55 connected to an air compressor 51 provided in a room separate from the dental examination room. Air is supplied to the tube 40 or the like. Note that the air compressor 51 is an air supply source. The driving air supplied from the air compressor 51 drives an instrument for dental treatment such as an air turbine handpiece. The supply pipe line 55 connected to the air compressor 51 is not limited to being provided in the body portion 2a of the spittoon 2, and may be provided in the base 1a of the chair 1.

The body portion 2a of the cuspidor 2 is provided with a suction pipe line 59 connected to a vacuum motor 58 provided in a room separate from the dental examination room. and the suction pipe line 59 are connected. Therefore, a negative pressure is supplied to the vacuum syringe provided on the tray table 5, the back plate 1c, or the like, and the saliva or the like can be sucked by the vacuum syringe. In addition, the suction pipe line 59 connected to the vacuum motor 58 is not limited to being provided in the body portion 2a of the spittoon 2, and may be provided in the base 1a of the chair 1.

The tray table 5 is connected to the base 1a via a tray table arm 6. As shown in FIG. The tray table 5 is used to place and hold medical instruments, medicines and medical handpieces (instruments) 30A. The tray table 5 also includes an operation setting section 5a for setting operations of the chair 1 and the medical handpiece 30A. Furthermore, the tray table 5 includes an ejector pump 30 of the microvacuum 100 .

The medium conduit 20A is configured to supply a working medium such as electricity, air, water, etc. from the medical main unit 10A to the medical handpiece 30A. The medium conduit 20A is connected to the medical treatment main body 10A and the medical treatment handpiece 30A. Specifically, a part of the plurality of medium conduits 20A connects the spittoon 2 and the medical handpiece 30A, and the doctor-side handpiece holder 5b forming the other part of the plurality of medium conduits 20A is located below the tray table 5. and connects the tray table 5 and the medical handpiece 30A. Furthermore, the tube 20 of the microvacuum 100 is connected to an ejector pump 30 provided on the tray table 5 .

The ejector pump 30 is connected to the introduction pipe 40 and the discharge pipe 60 inside the tray table 5 . The introduction pipe 40 is connected to an air compressor 51 that supplies air by being connected to a supply pipe line 55 passing through the tray table arm 6 and the base 1a. Also, the discharge pipe 60 is connected to a conduit for discharging water from the medium conduit 20A to the medical main unit 10A. Since the tray table 5 is provided with a pipe line for connecting to the medical handpiece 30A, by providing the ejector pump 30 in the tray table 5, the pipe used for the other medical handpiece 30A can be used. Easier to use roads. The material of the introduction pipe 40 and the discharge pipe 60 is, for example, urethane. The introduction pipe 40 and the discharge pipe 60 may have, for example, a two-layer structure, the material of the inner layer of this two-layer structure being fluororesin, and the material of the outer layer being urethane.

The air compressor 51 and the vacuum motor 58 used in the dental treatment unit 200 are usually installed in an equipment room separate from the dental treatment room. A supply line 55 connected to the air compressor 51 and a suction line 59 connected to the vacuum motor 58 are respectively routed from the equipment room to the dental practice unit 200 . The supply line 55 and the suction line 59 are drawn from the bottom of the spittoon 2 of the dental care unit 200 and connected to the pipes inside the dental care unit 200 .

Since the vacuum motor 58 generates relatively weak negative pressure, the longer the suction pipe 59, the smaller the suction force. On the other hand, since the air compressor 51 generates relatively strong pressure, it is possible to maintain the air pressure to some extent even if the supply pipe line 55 is lengthened. Therefore, if the vacuum motor 58 is adopted as the suction source of the micro vacuum 100, the suction pipe 59 to the back plate 1c of the chair 1 and the tray table 5 becomes long, and the micro vacuum 100 cannot obtain the required suction force. . On the other hand, when the ejector pump 30 is employed as the microvacuum 100, even if the supply pipe line 55 to the ejector pump 30 is long, sufficient air pressure can be supplied to the introduction pipe 40, so the ejector pump 30 needs the microvacuum 100. You can get good suction power. That is, by adopting the ejector pump 30 for the micro vacuum 100, the micro vacuum 100 can be arranged at any position such as the back plate 1c of the chair 1 or the tray table 5 without worrying about the distance from the vacuum motor 58. can be done.

Referring to FIG. 5, a medical handpiece 30A is an instrument for dental care. The medical handpiece 30A may include multiple handpieces. The medical handpiece 30A is, for example, a first air turbine handpiece (high speed handpiece) 31A, a second air turbine handpiece (high speed handpiece) 32A, a three-way syringe 34A, and the like. The medical handpiece 30A is configured to be engaged with a doctor-side handpiece holder 5b provided on the tray table 5. As shown in FIG.

Furthermore, the handpiece 10 of the microvacuum 100 is locked to the handpiece holder 5b on the doctor side. FIG. 6 is a schematic diagram showing the configuration of the handpiece holder 5b shown in FIG. As shown in FIG. 6, the handpiece 10 of the microvacuum 100 is engaged with the handpiece holder 5b, and in this state the air electromagnetic valve 50 is closed. On the other hand, when the operator picks up the handpiece 10 of the microvacuum 100 from the handpiece holder 5b, the air electromagnetic valve 50 is opened, and the microvacuum 100 can suck the cleaning liquid. That is, a sensor (not shown) for detecting the handpiece 10 of the microvacuum 100 provided in the handpiece holder 5b and the opening/closing operation of the air electromagnetic valve 50 are interlocked.

(Modification 2)
In Modification 1 described above, the micro vacuum 100 is housed in the tray table 5 . However, the place where the micro vacuum 100 is stored may be stored in the basin pole (body portion 2a). A handpiece holder 2d on the side of the dental assistant is provided on the body 2a shown in FIG. 5, and the handpiece 10 of the micro vacuum 100 may be locked to the handpiece holder 2d on the side of the dental assistant. A tube 20 of the microvacuum 100 is connected to an ejector pump 30 provided on the body portion 2a. The ejector pump 30 is connected to the introduction pipe 40 and the discharge pipe 60 within the body portion 2a.

(Modification 3)
The microvacuum 100 sucks, for example, the used washing liquid after washing the inside of the root canal of the tooth from the root canal. The cleaning liquid sucked from the suction part 10 a passes through the inside of the ejector pump 30 and is discharged from the discharge pipe 60 . However, since the cleaning liquid used for cleaning the inside of the root canal contains chemicals such as sodium hypochlorite, disodium edetate, and oxidol, it is conceivable that some materials of the ejector pump 30 accelerate internal corrosion. Therefore, a cleaning device 90 for cleaning the inside of the ejector pump 30 is provided in a micro vacuum 100a (dental suction device) according to a modification of the present disclosure shown in FIG.

The microvacuum 100a includes a handpiece 10 provided with a suction portion 10a, a tube 20 as a suction conduit, an ejector pump 30, and a cleaning device 90 provided in the middle of the tube 20. FIG. In the microvacuum 100a shown in FIG. 7, the same components as those of the microvacuum 100 shown in FIG. 1 are denoted by the same reference numerals, and detailed description thereof will not be repeated.

The cleaning device 90 supplies water to the ejector pump 30 to clean the inside of the ejector pump 30 . The cleaning device 90 uses the suction force of the ejector pump 30 to supply water to the middle of the tube 20, thereby cleaning the inside of the ejector pump 30 with the supplied water. Although not shown in FIG. 7, the cleaning device 90 is connected to a pipe for supplying water from a water source, wiring for inputting a signal from a control unit, and a power line from a power supply. The cleaning device 90 includes an electromagnetic valve (not shown) connected to the pipe. By opening the electromagnetic valve based on a signal from the control unit, water pressure from the water source causes water to flow from the pipe to the tube 20. supply water. Note that the cleaning device 90 may be configured to provide a pump and supply water from the pipe to the middle of the tube 20 based on a signal from the control unit.

Further, by providing the cleaning device 90 closer to the handpiece 10 side, the inside of the tube 20 can also be cleaned. The liquid supplied by the cleaning device 90 to clean the inside of the ejector pump 30 is not limited to water. For example, when an alkaline cleaning liquid such as sodium hypochlorite is sucked, the cleaning device 90 may supply an acidic liquid to the inside of the ejector pump 30 as a cleaning liquid.

Next, control of the cleaning device 90 and cleaning timing will be described in detail. FIG. 8 is a block diagram showing the configuration of a dental diagnostic unit 200 according to a modified example of the present disclosure. The dental diagnostic unit 200 has a control section 160 that controls the chair 1, the cuspidor 2, the diagnostic handpiece 30A, and the like.

The control unit 160 includes a CPU (Central Processing Unit), RAM (Random Access Memory), and ROM (Read Only Memory). The CPU comprehensively controls the entire dental diagnostic unit 200 by executing operating programs stored in the ROM or the like. The ROM stores programs executed by the CPU and other data. The RAM serves as a work area when the CPU executes a program, and temporarily stores the program and data used when the program is executed. The control unit 160 includes a first air turbine handpiece 31A, a second air turbine handpiece 32A, a three-way syringe 34A, a micro vacuum 100a, an air solenoid valve 50, an air compressor 51, a vacuum motor 58, a cleaning device 90, and an operation unit. 161, display unit 162, and notification unit 163 are connected.

FIG. 9 is a timing chart for explaining cleaning timings of the micro vacuum 100a in the modified example of the present disclosure. First, when the operation unit 161 receives an operation to start suctioning the microvacuum 100a, the control unit 160 controls the air electromagnetic valve 50 to open. Specifically, when the microvacuum 100a is housed in the chair as shown in FIG. not shown) as an operation for the operation unit 161 to start suctioning the microvacuum 100a.

When the operation unit 161 receives an operation to stop the suction of the microvacuum 100a, the control unit 160 does not immediately close the air solenoid valve 50, but closes the air solenoid valve 50 for a certain period of time (for example, 5 seconds). remain open. As a result, the microvacuum 100 a can perform suction immediately before stopping the suction operation, and the cleaning liquid remaining in the handpiece 10 and the tube 20 can be reliably discharged from the discharge port of the ejector pump 30 to the discharge pipe 60 .

Cleaning of the inside of the ejector pump 30 is performed using this fixed period. That is, when the operation unit 161 receives an operation to stop the suction of the microvacuum 100 a , the control unit 160 activates the cleaning device 90 to supply water to the middle of the tube 20 . Since the suction force of the ejector pump 30 is maintained for a certain period of time during which the control unit 160 controls the air solenoid valve 50 to open, the water supplied to the middle of the tube 20 is removed by using this suction force. The inside of the ejector pump 30 can be washed by suction.

Specifically, when the microvacuum 100a is housed in the chair as shown in FIG. not shown) as an operation for stopping the suction of the microvacuum 100a. When receiving the operation, the control unit 160 activates the cleaning device 90 and supplies water to the middle of the tube 20 . After a certain period of time has passed, the control unit 160 controls the air solenoid valve 50 to be closed.

The controller 160 cleans the inside of the ejector pump 30 for a certain period of time after the operation to stop the suction. No need to control. Also, while the user is sucking with the microvacuum 100a, if the cleaning device 90 supplies water to the middle of the tube 20, the suction force of the microvacuum 100a will decrease. A decrease in the suction force of the vacuum 100a does not pose a problem.

In FIG. 9, the cleaning device 90 intermittently supplies water to the middle of the tube 20 . Therefore, the control unit 160 repeats control to turn on the cleaning device 90 and control to turn off the cleaning device 90 . As a result, the control unit 160 can supply the amount of water necessary for cleaning the inside of the ejector pump 30 from the cleaning device 90 to the ejector pump 30, and supply an excessive amount of water from the cleaning device 90 to the ejector pump 30. controlled not to. Of course, depending on the suction power of the ejector pump 30, the amount of water that can be supplied by the cleaning device 90, and the like, the cleaning device 90 may be controlled to be ON for a certain period after the operation to stop the suction.

As the timing for the cleaning device 90 to clean the inside of the ejector pump 30, a certain period after the operation to stop the suction has been described, but the timing is not limited to this. The user may wash the inside of the ejector pump 30 using the washing device 90 at any timing. Further, if the suction force of the ejector pump 30 is high, the inside of the ejector pump 30 may be cleaned by the cleaning device 90 during the suction by the micro vacuum 100a.

Although the cleaning device 90 is provided in the microvacuum 100a, it can be provided in the same manner as long as it is a dental suction device that uses an ejector pump, other than the microvacuum.

It should be considered that the embodiments disclosed this time are illustrative in all respects and not restrictive. The scope of the present invention is indicated by the scope of the claims rather than the above description, and is intended to include all modifications within the meaning and range of equivalents of the scope of the claims.

Reference Signs List 1 chair, 1a base, 1b seat plate, 1c backboard, 1d headrest, 1e armrest, 2 spittoon, 2a trunk, 2b basin, 2c water bottle, 3 lighting device, 4 arm for lighting device, 5 tray table, 5a Operation setting part 5b Handpiece holder 6 Tray table arm 10 Handpiece 10A Medical treatment main body 10a Suction part 10b Grip part 11 Instrument holder 20 Tube 20A Medium conduit 30 Ejector pump 30A Medical treatment hand piece 31 nozzle 32 main body 33 introduction port 34 connection portion 35 discharge port 40 introduction pipe 50 air solenoid valve 55 supply pipe line 60 discharge pipe 70 rail 71 pulley 90 washing device, 100, 100a microvacuum, 200 dental practice unit.

Claims (9)

A dental suction device that connects to a dental treatment device, comprising:
a handpiece provided with a suction part;
a suction line connected to the handpiece;
an ejector pump provided in the dental diagnostic apparatus and connected to the suction line;
The ejector pump is
an introduction port for introducing air from an air supply source of the dental treatment apparatus;
a nozzle for depressurizing and injecting the air introduced from the inlet;
a main body that generates a negative pressure around the nozzle by jetting air;
a suction port that is connected to the suction conduit and uses negative pressure generated in the main body as a suction force;
A dental suction device, comprising air from the introduction port and a discharge port for discharging the aspirated matter sucked from the suction port. The dental suction device according to claim 1, wherein the inner diameter of the suction portion provided in the handpiece is at least 0.2 mm to 0.4 mm. 3. A dental suction apparatus according to claim 1 or claim 2, further comprising a proportional valve provided between said air supply and said inlet for regulating the amount of air introduced into said inlet. a control unit that controls the proportional valve;
a supply unit provided in the middle of the suction pipeline for supplying liquid to the suction pipeline;
The control unit
When the suction by the dental suction device is stopped by the user's operation, the proportional valve is controlled to introduce air into the inlet port, and the supply unit is controlled to control the suction tube for a predetermined period after the stop. 4. A dental suction device according to claim 3, wherein the channel is supplied with liquid. The ejector pump is
the inlet has a diameter of at least 1.1 mm to 2.0 mm;
The suction port has a diameter of at least 0.8 mm to 1.6 mm,
A dental suction device according to any preceding claim, wherein the outlet has a diameter of at least 1.8 mm to 3.3 mm. The dental treatment apparatus includes a treatment table on which a patient is placed,
The dental suction device according to any one of claims 1 to 5, wherein the ejector pump is provided inside the backrest portion of the treatment table. the dental treatment apparatus includes a tray table holding the handpiece;
The dental suction device according to any one of claims 1 to 5, wherein the ejector pump is provided inside the tray table. An ejector pump provided in a dental diagnostic device and connected to a suction line of a dental suction device,
an introduction port for introducing air from an air supply source of the dental treatment apparatus;
a nozzle for depressurizing and injecting the air introduced from the inlet;
a main body that generates a negative pressure around the nozzle by jetting air;
a suction port that is connected to the suction conduit and uses negative pressure generated in the main body as a suction force;
and an ejector pump for ejecting the sucked material sucked from the suction port together with the air from the introduction port. the inlet has a diameter of at least 1.1 mm to 2.0 mm;
The suction port has a diameter of at least 0.8 mm to 1.6 mm,
The ejector pump of claim 8, wherein the outlet has a diameter of at least 1.8 mm to 3.3 mm.

Images