JP2021178197A - Medical handpiece oil supply maintenance device and control method for the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a refueling maintenance device for a medical handpiece and a control method thereof, which can discharge excess oil remaining in the medical handpiece after refueling the medical handpiece by supplying air in a short time. do. A refueling maintenance device for a medical handpiece includes a housing, a manifold 30, and a control unit. The manifold 30 includes a first line P1, a second line P2, a third line P3, and a fourth line P4. In the manifold 30 to which the medical handpiece is connected, the control unit supplies air to the medical handpiece by the third pipe P3 and the fourth pipe P4, and then the first pipe P1 and the second pipe. Oil is supplied to the medical handpiece by the road P2. [Selection diagram] FIG. 4

Description

The present invention relates to a refueling maintenance device for a medical handpiece and a control method thereof.

A refueling maintenance device for a medical handpiece is proposed, for example, in Japanese Patent No. 4514713 (Patent Document 1). In the refueling maintenance device for the medical handpiece described in this publication, a first pipeline for supplying oil (lubricating oil) and air is connected to the medical handpiece. The first pipeline for supplying oil and air, the second pipeline for supplying oil, and the third pipeline for supplying air are connected to each other. At the time of maintenance, oil is supplied to the medical handpiece from the second pipe through the first pipe. After that, air is supplied to the medical handpiece from the third pipe through the first pipe. As a result, the oil remaining on the medical handpiece is discharged.

Japanese Patent No. 4514713

In the refueling maintenance device for the medical handpiece described in the above publication, when the length of the first pipe becomes long, the oil remaining in the first pipe due to the supply of air passes through the medical handpiece. It takes longer to be discharged. Therefore, it is difficult to discharge the excess oil remaining in the medical handpiece after refueling the medical handpiece by supplying air in a short time.

The present invention has been made in view of the above-mentioned problems, and an object thereof is to discharge excess oil remaining in the medical handpiece after refueling the medical handpiece by supplying air in a short time. It is to provide a refueling maintenance device for a medical handpiece and a control method thereof.

The refueling maintenance device for a medical handpiece of the present invention has a housing provided with a storage chamber for accommodating the medical handpiece, a manifold connected to the medical handpiece in the storage chamber of the housing, and a manifold connected to the manifold. It is equipped with a control unit that controls maintenance of the medical handpiece. The medical handpiece has a flow path for supplying air, a flow path for exhausting air, and a flow path for supplying water. The manifold consists of a first pipe that can supply oil and air to the medical handpiece, a second pipe that can supply oil to the first pipe, and a third pipe that can supply air to the first pipe. It includes a passage and a fourth pipeline connected to the third pipeline on the upstream side of the flow of air supplied from the third pipeline from the second pipeline. The second pipeline and the third pipeline are connected to the first pipeline. The manifold makes it possible to supply air from the third pipe to the water pipe that can supply water of the medical handpiece via the fourth pipe. In the manifold to which the medical handpiece is connected, the control unit supplies air to the medical handpiece by the third pipe and the fourth pipe, and then medical treatment is performed by the first pipe and the second pipe. Supply oil to the handpiece.

According to the refueling maintenance device for the medical handpiece of the present invention, the first pipe line, the second pipe line, and the third pipe line are connected in the manifold connected to the medical handpiece. Therefore, the length of the first pipeline can be shortened. Therefore, by supplying air to the excess oil remaining in the medical handpiece after refueling the medical handpiece, it can be discharged in a short time.

It is a perspective view schematically showing the structure of the refueling maintenance device of the medical handpiece in one embodiment of the present invention. FIG. 3 is a perspective view schematically showing a state in which the medical handpiece is attached to the refueling maintenance device for the medical handpiece shown in FIG. 1. It is a fluid circuit diagram of the refueling maintenance device of the medical handpiece shown in FIG. It is a perspective view which shows schematic structure of the manifold in one Embodiment of this invention. It is sectional drawing which shows schematically the inflow part of the 2nd pipeline of the manifold in one Embodiment of this invention. It is sectional drawing which shows schematically the outflow part of the 2nd pipeline of the manifold in one Embodiment of this invention. It is sectional drawing which shows schematically the inflow part of the 3rd pipeline of the manifold in one Embodiment of this invention. It is sectional drawing which shows schematic the outflow part of the 3rd pipeline of the manifold in one Embodiment of this invention. It is a perspective view which shows the manifold shown in FIG. 8 from the connection part side. It is a control block diagram of the refueling maintenance device of the medical handpiece in one Embodiment of this invention. It is a flowchart which shows an example of the maintenance process in one execution of this invention. It is a flowchart which shows the other example of the maintenance process in one Embodiment of this invention. It is a flowchart which shows the control method of the refueling maintenance apparatus of the medical handpiece in one Embodiment of this invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following figures, the same or corresponding parts are designated by the same reference numerals, and duplicate explanations will not be repeated.

First, the configuration of the refueling maintenance device for the medical handpiece according to the embodiment of the present invention will be described. In this embodiment, a dental handpiece will be described as an example of a medical handpiece.

With reference to FIGS. 1 and 2, the refueling maintenance device 1 of the medical handpiece HP in the present embodiment includes a housing 10, an opening / closing door 20, a manifold 30, a chuck maintenance unit 40, and a switch 60. It is equipped with a power switch 70. In FIG. 2, the medical handpiece HP is illustrated for convenience of explanation. The medical handpiece HP is subject to maintenance processing. The medical handpiece HP has drive air, water supply, spray air, and exhaust channels. Further, in FIG. 2, as the medical handpiece HP, the first handpiece HP1 to the fourth handpiece HP4 are shown.

The housing 10 has a front surface portion 11, a side surface portion 12, a ceiling portion 13, and a bottom portion 14. The housing 10 is provided with a storage room IS for accommodating the medical handpiece HP. The containment chamber IS has an opening OP that communicates the inside of the containment chamber IS and the outside of the containment chamber IS. The inside of the containment chamber IS is exposed from the opening OP.

The opening / closing door 20 is configured to be openable / closable with respect to the opening OP of the accommodation chamber IS. The opening / closing door 20 is configured to cover the accommodation chamber IS. The opening / closing door 20 is arranged on the front surface portion 11 of the housing 10. The opening / closing door 20 is supported by the bottom portion 14 of the housing 10 so as to be openable / closable at the lower end portion of the opening / closing door 20. The opening / closing door 20 is configured to open / close in the direction of the arrow A1 in FIGS. 1 and 2.

The manifold 30 is configured to be connected to the medical handpiece HP in the accommodation chamber IS of the housing 10. The manifold 30 has a connecting portion 31 and an adapter 50 connected to the connecting portion 31. In this embodiment, the manifold 30 has a plurality of connection portions 31 and a plurality of adapters 50. Each of the plurality of adapters 50 is connected to each of the plurality of connection portions 31. The connection portion 31 and the adapter 50 are arranged in the accommodation chamber IS. The connection portion 31 protrudes into the containment chamber IS from the top surface of the containment chamber IS. The adapter 50 is detachably attached to the connection portion 31. A flow path for flowing oil and air, which are maintenance fluids, is provided in the adapter 50. The adapter 50 has a configuration corresponding to the model of the medical handpiece HP.

The medical handpiece HP is connected to the manifold 30 by the adapter 50. The medical handpiece HP has a rotating body accommodating space in the head portion on the tip side. The rotating body accommodating space accommodates a rotating body (rotor and turbine) and a bearing portion that supports the rotating body. The rotating body has a chuck component. A rotary cutting tool is detachably inserted from the opening at one end of the chuck component.

The chuck maintenance unit 40 is configured to supply a maintenance fluid to the chuck component unit of the medical handpiece HP. The chuck maintenance unit 40 is provided on the rear surface of the accommodation chamber IS. Further, an opening HL communicating with the ejector EP (see FIG. 3) is provided on the rear surface of the accommodation chamber IS.

The switch 60 is configured to operate the refueling maintenance device 1 of the medical handpiece HP. The power switch 70 is configured to turn on or off the supply of electricity from the power source to the refueling maintenance device 1 of the medical handpiece HP.

FIG. 3 shows a fluid circuit of the refueling maintenance device 1 of the medical handpiece HP in the present embodiment. This fluid circuit is configured to supply oil and air, which are maintenance fluids, to the manifold 30 and the chuck maintenance unit 40. In FIG. 3, each flow path of the drive air D, the water supply W, the spray air S, and the exhaust E is shown for each of the first handpiece HP1 to the fourth handpiece HP4.

With reference to FIG. 3, the refueling maintenance device 1 of the medical handpiece HP in the present embodiment includes an air filter 102, a decompression device 103, flow paths 104 to 116, oil supply containers 121, 122, solenoid valves SV1, SV4. And further equipped with an ejector EP. Further, as will be described later, the refueling maintenance device 1 of the medical handpiece HP in the present embodiment includes a control unit 200 (see FIG. 10). The control unit 200 is configured to control the solenoid valves SV1 to SV12 to control the supply of oil and air.

An air filter 102 is connected to the compressed air supply source 101. The air filter 102 is connected to the decompression device 103. The decompression device 103 is configured to reduce the pressure of the air supplied from the compressed air supply source 101. The flow path 104 is connected to the decompression device 103. The flow path 104 is connected to the flow path 105 and the flow path 106. The solenoid valve SV1 is connected to the flow path 105. The flow path 105 is connected to the flow path 107 and the flow path 108. The flow path 107 is connected to the manifold 30. The flow path 108 is connected to the ejector EP.

The flow path 106 is connected to the flow path 111 and the flow path 112. The solenoid valve SV2 is connected to the flow path 111. The flow path 111 is connected to the on-off valve 121a of the oil supply container 121. The on-off valve 121a of the oil supply container 121 is connected to the flow path 113. The flow path 113 is connected to the flow path 114 and the flow path 115. The solenoid valve SV4 is connected to the flow path 114. The flow path 114 is connected to the chuck maintenance unit 40. The flow path 115 is connected to the manifold 30.

The solenoid valve SV3 is connected to the flow path 112. The flow path 112 is connected to the on-off valve 122a of the oil supply container 122. The on-off valve 122a of the oil supply container 122 is connected to the flow path 116. The flow path 116 is connected to the manifold 30. The manifold 30 has solenoid valves SV2 to SV12.

In the fluid circuit, the compressed air supply source 101 is connected to a plurality of solenoid valves SV1, SV2, SV3 via an air filter 102 and a decompression device 103. The solenoid valves SV2 and SV3 are connected to the on-off valves 121a and 122a of the oil supply containers 121 and 122, respectively. The on-off valves 121a and 122a are configured to be opened and closed by the solenoid valves SV2 and SV3.

The oil supply container 121 is connected to the chuck maintenance unit 40 via the solenoid valve SV4. The oil supply container 121 is connected to the first handpiece HP1 via the solenoid valve SV5, and is connected to the second handpiece HP2 via the solenoid valve SV6.

The oil supply container 122 is connected to the third handpiece HP3 via the solenoid valve SV7, and is connected to the fourth handpiece HP4 via the solenoid valve SV8.

The solenoid valve SV1 is connected to the solenoid valves SV9, SV10, SV11, and SV12, respectively. The solenoid valve SV9 is connected to the first handpiece HP1. The solenoid valve SV10 is connected to the second handpiece HP2. The solenoid valve SV11 is connected to the third handpiece HP3. The solenoid valve SV12 is connected to the fourth handpiece HP4.

Subsequently, the manifold 30 in the present embodiment will be described in more detail.

With reference to FIG. 4, the manifold 30 in the present embodiment has the first unit U1 to the fourth unit U4. The manifold 30 is configured such that the first unit U1 to the fourth unit U4 are joined to each other and integrated. Each of the first unit U1 to the fourth unit U4 is configured to perform a maintenance process on each of the first handpiece HP1 to the fourth handpiece HP4. Although the manifold 30 in the present embodiment is composed of four units as an example, it may be composed of one or more units.

Each of the first unit U1 to the fourth unit U4 has a connection portion 31, a main body portion 32, a first pipeline P1, a second pipeline P2, a third pipeline P3, and a fourth pipeline P4. , Each of the solenoid valves SV5 to SV8 and each of the solenoid valves SV9 to SV12.

The connecting portion 31 is provided for each of the first unit U1 to the fourth unit U4. The main body portions 32 of the first unit U1 to the fourth unit U4 are integrally molded and joined to each other.

The first line P1, the second line P2, the third line P3, and the fourth line P4 are provided for each of the first unit U1 to the fourth unit U4. The first pipeline P1 is configured to be able to supply oil and air to the medical handpiece HP. The second pipeline P2 is configured to be able to supply oil to the first pipeline P1. The third pipeline P3 is configured to be able to supply air to the first pipeline P1. The second line P2 and the third line P3 are connected to the first line P1. That is, in the manifold 30, the second line P2 and the third line P3 are connected to the first line P1.

The second line P2 of the first unit U1 and the second line P2 of the second unit U2 are connected to the flow path 115 (see FIG. 3). The second line P2 of the second unit U2 is connected to the second line P2 of the first unit U1. The second line P2 of the first unit U1 and the second line P2 of the second unit U2 have an oil inflow side line 30a shared with each other.

The second line P2 of the third unit U3 and the second line P2 of the fourth unit U4 are connected to the flow path 116 (see FIG. 3). The second line P2 of the third unit U3 is connected to the second line P2 of the fourth unit U4. The second line P2 of the third unit U3 and the second line P2 of the fourth unit U4 have an oil inflow side line 30b shared with each other.

Each of the third pipelines P3 of the first unit U1 to the fourth unit U4 is connected to the flow path 107 (see FIG. 3). The third line P3 of the first unit U1 is connected to the third line P3 of the second unit U2. The third line P3 of the second unit U2 is connected to the third line P3 of the third unit U3. The third line P3 of the fourth unit U4 is connected to the third line P3 of the third unit U3. Each of the third pipelines P3 of the first unit U1 to the fourth unit U4 has an air inflow side pipeline 30c shared with each other.

The oil inflow side pipeline 30a and the oil inflow side pipeline 30b extend in the same direction. That is, the oil inflow side pipeline 30a and the oil inflow side pipeline 30b are arranged in a straight line. The direction of the oil flowing through the oil inflow side pipeline 30a is opposite to the direction of the oil flowing through the oil inflow side pipeline 30b. That is, the oil flowing through the oil inflow side pipeline 30a flows so as to face the oil flowing through the oil inflow side pipeline 30b.

The air inflow side pipe 30c extends along the direction in which the oil inflow side pipe 30a and the oil inflow side pipe 30b extend. The air inflow side pipe 30c is arranged side by side with each of the oil inflow side pipe 30a and the oil inflow side pipe 30b.

The first unit U1 has a solenoid valve SV5 and a solenoid valve SV9. The second unit U2 has a solenoid valve SV6 and a solenoid valve SV10. The third unit U3 has a solenoid valve SV7 and a solenoid valve SV11. The fourth unit U4 has a solenoid valve SV8 and a solenoid valve SV12.

As the first valve, each of the solenoid valves SV5 to SV8 is connected to the second pipeline P2 of each of the first unit U1 to the fourth unit U4. Each of the solenoid valves SV5 to SV8 is configured to control the supply of oil to the first line P1 of each of the first unit U1 to the fourth unit U4.

As the second valve, each of the solenoid valves SV9 to SV12 is connected to the third pipeline P3 of each of the first unit U1 to the fourth unit U4. The solenoid valves SV9 to SV12 are configured to control the supply of air to the first pipeline P1 of each of the first unit U1 to the fourth unit U4.

With reference to FIGS. 5 and 6, the configuration of the first line P1 and the second line P2 will be described in more detail by taking the fourth unit U4 as an example. In FIGS. 5 and 6, the oil flow is indicated by solid arrows. The second pipeline P2 has an oil inflow portion P21 and an oil outflow portion P22. The oil inflow section P21 is composed of a short tube for allowing oil to flow into the solenoid valve SV8. The oil spill portion P22 is composed of a short tube for spilling oil from the solenoid valve SV8. The first pipeline P1 is connected to the oil spill portion P22 of the second pipeline P2. The first pipeline P1 is configured to reach the connecting portion 31.

With reference to FIGS. 7 and 8, the configuration of the first line P1 and the third line P3 will be described in more detail by taking the fourth unit U4 as an example. In FIGS. 7 and 8, the air flow is indicated by solid arrows. The third pipeline P3 has an air inflow portion P31 and an air outflow portion P32. The air inflow section P31 is composed of a short tube for allowing air to flow into the solenoid valve SV12. The air outflow portion P32 is composed of a short tube for allowing air to flow out from the solenoid valve SV12. The first pipeline P1 is connected to the air outflow portion P32 of the third pipeline P3. In the manifold 30, the second line P2 and the third line P3 are connected to the first line P1.

The control unit 200 opens the solenoid valve SV8 and closes the solenoid valve SV12 so as to supply oil to the fourth handpiece HP4 (see FIG. 3) via the first pipeline P1. It is configured. The control unit 200 passes through the first pipeline P1 by closing the solenoid valve SV8 and opening the solenoid valve SV12 in a state where oil is supplied to the fourth handpiece HP4 (see FIG. 3). Then, by supplying air to the fourth handpiece HP4 (see FIG. 3), the oil supplied to the fourth handpiece HP4 (see FIG. 3) is discharged.

With reference to FIGS. 8 and 9, the configuration of the fourth pipeline P4 will be described in more detail by taking the fourth unit U4 as an example. In FIGS. 8 and 9, the air flow is indicated by solid arrows and the oil flow is indicated by dashed arrows. The fourth pipeline P4 is connected to the third pipeline P3 on the upstream side of the air flow supplied from the third pipeline with respect to the second pipeline P2. The fourth pipeline P4 is connected to the air outflow portion P32 of the third pipeline P3. That is, the fourth pipeline P4 is connected between the solenoid valve SV12 and the first pipeline P1 on the pipeline of the air outflow portion P32. The fourth pipeline P4 is configured to reach the connecting portion 31. In the manifold 30, the fourth line P4 is connected to the third line P3.

The manifold 30 supplies air to the water pipe that can supply water from the fourth handpiece HP4 (see FIG. 3) from the third pipe P3 to the fourth handpiece HP4 (see FIG. 3). It is configured so that water is discharged from the water pipe (see FIG. 3).

The control unit 200 closes the solenoid valve SV8 and opens the solenoid valve SV12 before the oil is supplied to the fourth handpiece HP4 (see FIG. 3), whereby the first pipeline P1 It is configured to supply air to the fourth handpiece HP4 (see FIG. 3) via the above.

The control unit 200 closes the solenoid valve SV8 in a state where oil is supplied to the fourth handpiece HP4 (see FIG. 3), and opens and closes the solenoid valve SV12 to open and close the solenoid valve SV12 via the first pipeline P1. It is configured to intermittently supply air to the fourth handpiece HP4 (see FIG. 3).

The control unit 200 supplied air to the fourth handpiece HP4 (see FIG. 3) via the first pipeline P1 to discharge the oil supplied to the fourth handpiece HP4 (see FIG. 3). While the switch 60 is turned on in the state, it is configured to supply air to the fourth handpiece HP4 (see FIG. 3) via the first pipeline P1.

An air turbine handpiece driven by compressed air is preferably used as the medical handpiece HP. However, a contra-angle handpiece driven by an electric motor may be used as the medical handpiece HP. The adapter 50 connected to the contra-angle handpiece may have a rotation mechanism for rotating the contra-angle handpiece by the air supplied from the first pipeline P1.

Next, the operation of the refueling maintenance device 1 of the medical handpiece HP in the present embodiment will be described.

With reference to FIG. 10, the refueling maintenance device 1 of the medical handpiece HP in the present embodiment further includes a control unit 200. The control unit 200 is configured to control the entire refueling maintenance device 1 of the medical handpiece HP. The control unit 200 is configured to control the solenoid valves SV1 to SV12. The solenoid valves SV1 to SV12 are electrically connected to the control unit 200, respectively. The control unit 200 is configured to control each valve to control the supply of oil and air. The solenoid valves SV1 to SV12 operate as follows based on the program included in the control unit 200 by operating the switch 60.

As shown in FIG. 2, the first handpiece HP1 to the fourth handpiece HP4 are connected to the four adapters 50 of the manifold 30, respectively. The four first handpieces HP1 to the fourth handpiece HP4 are connected to the four adapters 50 in a state of being washed with water. Maintenance fluids are sequentially supplied to the four first handpieces HP1 to the fourth handpiece HP4, and the four first handpieces HP1 to the fourth handpiece HP4 are maintained.

Further, an example of the maintenance process will be described with reference to FIG. In one example of this maintenance process, each mode is carried out in the order of drainage blow, refueling, long blow, step blow, short blow, and ejector operation.

In the drain blow, when the switch 60 (see FIG. 1) is pressed, the solenoid valve SV9 is opened (step S1). As a result, the solenoid valve SV9 is in a state where air can be supplied. This state is held for 0.5 seconds (step S2). Then, the solenoid valve SV1 is opened (step S3). At this time, the solenoid valve SV9 is held in an open state. As a result, air is supplied from the compressed air supply source 101 to the solenoid valve SV9 via the solenoid valve SV1. Then, air is supplied to the first handpiece HP1 via the solenoid valve SV9. This state is held for 0.5 seconds (step S4). As a result, the water remaining in the first handpiece HP1 is discharged. After that, the solenoid valve SV1 is closed (step S5). This state is held for 0.5 seconds (step S6). After that, the solenoid valve SV9 is closed (step S7).

Next, in refueling, oil is supplied from the oil supply container 121 to the first handpiece HP1. The solenoid valve SV5 is opened (step S8). As a result, the solenoid valve SV5 is in a state where oil can be supplied. This state is held for 0.5 seconds (step S9). Then, the solenoid valve SV2 is opened (step S10). At this time, the solenoid valve SV5 is held in an open state. As a result, the on-off valve 121a is opened, and oil is supplied from the oil supply container 121 to the solenoid valve SV5. Then, oil is supplied to the first handpiece HP1 via the solenoid valve SV5. This state is held for 0.15 seconds (step S11). As a result, oil is sufficiently supplied to the first handpiece HP1. After that, the solenoid valve SV2 is closed (step S12). This state is held for 0.9 seconds (step S13). After that, the solenoid valve SV5 is closed (step S14).

Next, in the long blow, the solenoid valve SV9 is held in an open state for a long time. First, the solenoid valve SV1 is opened (step S15). As a result, the solenoid valve SV1 is in a state where air can be supplied from the compressed air supply source 101. After that, the solenoid valve SV9 is opened (step S16). As a result, air is supplied to the first handpiece HP1 via the solenoid valve SV9. This state is held for 8.0 seconds (step S17). As a result, most of the excess oil remaining in the first handpiece HP1 is discharged. After that, the solenoid valve SV9 is closed (step S18). This state is held for 0.5 seconds (step S19).

Next, in the step blow, the solenoid valve SV9 is intermittently opened, so that air is intermittently supplied to the first handpiece HP1 via the solenoid valve SV9. First, the solenoid valve SV9 is opened (step S20). As a result, air is supplied to the first handpiece HP1 via the solenoid valve SV9. This state is held for 0.5 seconds (step S21). After that, the solenoid valve SV9 is closed (step S22). This state is held for 0.5 seconds (step S23). The solenoid valve SV9 is opened again (step S24). This state is held for 0.5 seconds (step S25). After that, the solenoid valve SV9 is closed (step S26). This state is held for 0.5 seconds (step S27). The solenoid valve SV9 is opened again (step S28). This state is held for 0.5 seconds (step S29). After that, the solenoid valve SV9 is closed (step S30). This state is held for 0.5 seconds (step S31). The solenoid valve SV9 is opened again (step S32). This state is held for 0.5 seconds (step S33). After that, the solenoid valve SV9 is closed (step S34). This state is held for 0.5 seconds (step S35). As described above, by intermittently supplying air to the first handpiece HP1 via the solenoid valve SV9, the excess oil remaining in the first handpiece HP1 is further discharged. By intermittently supplying air to the first handpiece HP1, the excess oil remaining in the first handpiece HP1 swings. This makes it easier for the excess oil remaining in the first handpiece HP1 to be discharged.

Next, in the short blow, the solenoid valve SV9 is held in an open state for a short time. First, the solenoid valve SV9 is opened (step S36). As a result, air is supplied to the first handpiece HP1 via the solenoid valve SV9. This state is held for 1.0 second (step S37). After that, the solenoid valve SV9 is closed (step S38). As a result, the oil remaining on the first handpiece HP1 is surely discharged.

In ejector operation, oil is recovered from the containment chamber IS (see FIG. 1) by utilizing the ejector effect. In the ejector operation, the closed state of the solenoid valve SV9 is held for 2 seconds (step S39). Then, by operating the ejector EP (see FIG. 3) during this period, mist-like oil (oil mist) is discharged from the storage chamber IS (see FIG. 1). The ejector EP is operated by opening the solenoid valve SV1. Therefore, while the solenoid valve SV1 is open, the ejector EP operates in each mode of drainage flow, long blow, step blow, and short blow. The refueling maintenance device 1 of the medical handpiece HP is provided with a recovery container (not shown) for storing the recovered oil. The oil recovered from the containment chamber IS (see FIG. 1) is stored in a recovery container (not shown).

Next, the solenoid valve SV1 is closed (step S40). This state is held for 0.1 seconds (step S41). As a result, the maintenance process of the first handpiece HP1 is completed.

For the second handpiece HP2, the same processing as that for the first handpiece HP1 described above is performed. However, in the case of the first handpiece HP1, the solenoid valves SV5 and SV9 connected to the first handpiece HP1 were opened and closed, but in the case of the second handpiece HP2, they were connected to the second handpiece HP2. The solenoid valves SV6 and SV10 are opened and closed. The solenoid valve SV6 corresponds to the solenoid valve SV5, and the solenoid valve SV10 corresponds to the solenoid valve SV9.

For the third handpiece HP3, the same processing as that for the first handpiece HP1 described above is performed. However, in the case of the first handpiece HP1, the on-off valve 121a is opened by opening the solenoid valve SV2 and oil is supplied from the oil supply container 121, but in the case of the third handpiece HP3, the solenoid valve When the SV3 is opened, the on-off valve 122a is opened and oil is supplied from the oil supply container 122. Further, in the case of the first handpiece HP1, the solenoid valves SV5 and SV9 connected to the first handpiece were opened and closed, but in the case of the third handpiece HP3, they were connected to the third handpiece HP3. The solenoid valves SV7 and SV11 are opened and closed. The solenoid valve SV7 corresponds to the solenoid valve SV5, and the solenoid valve SV11 corresponds to the solenoid valve SV9.

For the 4th handpiece HP4, the same processing as that for the 3rd handpiece HP3 is executed. However, in the case of the third handpiece HP3, the solenoid valves SV7 and SV11 connected to the third handpiece HP3 were opened and closed, but in the case of the fourth handpiece HP4, they were connected to the fourth handpiece HP4. The solenoid valves SV8 and SV12 are opened and closed. The solenoid valve SV8 corresponds to the solenoid valve SV7, and the solenoid valve SV12 corresponds to the solenoid valve SV11.

If there is a large amount of foreign matter adhering to the medical handpiece HP, the solenoid valve SV2 may be held open for a long time during refueling. In this case, for example, the open state of the solenoid valve SV2 may be held for 3.0 seconds. As a result, the oil is supplied for a long time, so that the supplied oil facilitates the removal of foreign matter. Therefore, the oil can be reliably supplied.

Subsequently, another example of the maintenance process will be described with reference to FIG. Another example of this maintenance process is performed after the above example of the maintenance process. That is, in another example of this maintenance process, an additional blow mode is implemented.

In the additional blow, when the switch 60 is turned on, the solenoid valve SV1 and the solenoid valve SV9 are opened (step S50). This state is held while the switch 60 is turned on (step S51). Therefore, air is supplied while the switch 60 is on. This makes it possible to adjust the air supply time. After that, when the switch 60 is turned off, the solenoid valve SV1 and the solenoid valve SV9 are closed. From the above, the additional blow is completed.

Next, with reference to FIG. 13, a control method of the refueling maintenance device 1 of the medical handpiece HP in the present embodiment will be described.

The control method of the refueling maintenance device 1 of the medical handpiece HP in the present embodiment includes an oil supply process and an air supply process. First, the oil supply process is carried out. In the oil supply step, oil is supplied to the medical handpiece HP in the first pipeline P1 (step S60). After that, the air supply process is carried out. In the air supply step, air is supplied to the medical handpiece HP via the first pipeline P1 in a state where oil is supplied to the medical handpiece HP (step S61).

Next, the action and effect in this embodiment will be described.

According to the refueling maintenance device 1 of the medical handpiece HP in the present embodiment, the first pipe line P1, the second pipe line P2, and the third pipe line P3 are connected to each other in the manifold 30 connected to the medical handpiece HP. You are connected. Therefore, the length of the first pipeline P1 can be shortened. Therefore, by supplying air to the excess oil remaining on the medical handpiece HP after refueling the medical handpiece HP, it can be discharged in a short time.

According to the refueling maintenance device 1 of the medical handpiece HP in the present embodiment, the manifold 30 has the third pipe P3 to the fourth pipe P4 in the water pipe that can supply the water of the medical handpiece HP. It is configured so that water is discharged from the water pipe of the medical handpiece HP by supplying air via the medical handpiece HP. Therefore, water can be discharged from the water pipe of the medical handpiece HP. Further, if water remains in the water pipe, steam does not come into contact with the portion where water remains during steam sterilization, so that sterilization failure occurs. In the present embodiment, since water can be discharged from the water pipe, sterilization failure during steam sterilization can be suppressed.

According to the refueling maintenance device 1 of the medical handpiece HP in the present embodiment, the manifold 30 passes through the first pipeline P1 by opening the solenoid valve SV8 and closing the solenoid valve SV12. It is configured to supply oil to the fourth handpiece HP4. Further, the manifold 30 has a fourth handpiece HP4 via the first pipeline P1 by closing the solenoid valve SV8 and opening the solenoid valve SV12 in a state where oil is supplied to the fourth handpiece HP4. By supplying air to the handpiece HP4, the oil supplied to the fourth handpiece HP4 is configured to be discharged. Therefore, by opening and closing the solenoid valve SV8 and the solenoid valve SV12 of the manifold 30, oil can be supplied to the fourth handpiece HP4, and excess oil remaining in the fourth handpiece HP4 can be discharged. can.

According to the refueling maintenance device 1 of the medical handpiece HP in the present embodiment, the manifold 30 closes the solenoid valve SV8 and closes the solenoid valve SV12 before the oil is supplied to the fourth handpiece HP4. Is configured to supply air to the fourth handpiece HP4 via the first pipeline P1. Therefore, by supplying air to the 4th handpiece HP4 before the oil is supplied to the 4th handpiece HP4, foreign matter and moisture remaining in the 4th handpiece HP4 can be discharged. After that, the oil is supplied to the fourth handpiece HP4, so that the oil can be reliably supplied.

According to the refueling maintenance device 1 of the medical handpiece HP in the present embodiment, the manifold 30 closes the solenoid valve SV8 and opens and closes the solenoid valve SV12 in a state where oil is supplied to the fourth handpiece HP4. By doing so, it is configured to intermittently supply air to the fourth handpiece HP4 via the first pipeline P1. Therefore, by intermittently supplying air to the 4th handpiece HP4, the excess oil remaining in the 4th handpiece HP4 can be further discharged.

According to the refueling maintenance device 1 of the medical handpiece HP in the present embodiment, the manifold 30 is supplied to the fourth handpiece HP4 via the first pipeline P1 to supply air to the fourth handpiece HP4. It is configured to supply air to the fourth handpiece HP4 via the first pipeline P1 while the switch 60 is turned on with the supplied oil discharged. This allows additional air supply. Further, since the air is supplied while the switch 60 is turned on, the air supply time can be easily adjusted.

With reference to FIG. 13, according to the control method of the refueling maintenance device 1 of the medical handpiece HP in the present embodiment, in the refueling maintenance device 1 of the medical handpiece HP described above, the route is via the first pipeline P1. Then, oil is supplied to the medical handpiece HP, and air is supplied to the medical handpiece HP via the first pipeline P1 in a state where the oil is supplied to the medical handpiece HP. Therefore, by supplying air to the excess oil remaining on the medical handpiece HP after refueling the medical handpiece HP, it can be discharged in a short time.

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

1 Refueling maintenance device for medical handpieces, 10 chassis, 20 open / close doors, 30 manifolds, 31 connections, 32 main units, 40 chuck maintenance units, 50 adapters, 60 switches, 70 power switches, 101 compressed air supply sources, 102 air filter, 103 decompression device, 121,122 oil supply container, 121a, 122a on-off valve, 200 control unit, HP medical handpiece, HP1 1st handpiece, HP2 2nd handpiece, HP3 3rd handpiece, HP4 4th handpiece, IS containment chamber, OP opening, P1 1st pipeline, P2 2nd pipeline, P3 3rd pipeline, P4 4th pipeline, P21 oil inflow section, P22 oil outflow section, P31 air inflow Unit, P32 air outflow section, SV1 to SV12 solenoid valves, U1 1st unit, U2 2nd unit, U3 3rd unit, U4 4th unit.

Claims (6)

A refueling maintenance device for medical handpieces
The medical handpiece has a flow path for supplying air, a flow path for exhausting air, and a flow path for supplying water.
A housing provided with a storage chamber for accommodating the medical handpiece,
A manifold connected to the medical handpiece in the containment chamber of the housing,
A control unit that controls maintenance of the medical handpiece connected to the manifold is provided.
The manifold has a first pipe that can supply oil and air to the medical handpiece, a second pipe that can supply the oil to the first pipe, and the air to the first pipe. A third pipeline that can be supplied and a fourth pipeline that is connected to the third pipeline on the upstream side of the flow of air supplied from the third pipeline from the second pipeline are included.
The second pipeline and the third pipeline are connected to the first pipeline.
The manifold makes it possible to supply the air from the third pipeline to the water pipeline capable of supplying water of the medical handpiece via the fourth pipeline.
In the manifold to which the medical handpiece is connected, the control unit supplies air to the medical handpiece by the third pipe line and the fourth pipe line, and then connects to the first pipe line. A refueling maintenance device for a medical handpiece that supplies oil to the medical handpiece through the second pipeline. The manifold is a first valve connected to the second pipeline and controlling the supply of the oil to the first pipeline, and the air connected to the third pipeline and to the first pipeline. The refueling maintenance device for a medical handpiece according to claim 1, comprising a second valve for controlling the supply of the medical handpiece. The manifold passes through the first pipeline by closing the first valve and opening the second valve before the oil is supplied to the medical handpiece. The refueling maintenance device for a medical handpiece according to claim 2, wherein the air is supplied to the medical handpiece. With the oil supplied to the medical handpiece, the manifold closes the first valve and opens and closes the second valve to open and close the second valve for medical use via the first pipeline. The refueling maintenance device for a medical handpiece according to claim 2 or 3, which is configured to intermittently supply the air to the handpiece. Equipped with a switch
The switch is turned on in the manifold in a state where the oil supplied to the medical handpiece is discharged by supplying the air to the medical handpiece via the first pipeline. The refueling maintenance device for the medical handpiece according to any one of claims 1 to 3, which is configured to supply the air to the medical handpiece via the first pipeline. .. It is a control method for the refueling maintenance device for medical handpieces.
The medical handpiece has a flow path for supplying air, a flow path for exhausting air, and a flow path for supplying water.
The refueling maintenance device for the medical handpiece is
A housing provided with a storage chamber for accommodating the medical handpiece,
A manifold connected to the medical handpiece in the containment chamber of the housing,
A control unit that controls maintenance of the medical handpiece connected to the manifold is provided.
The manifold has a first pipe that can supply oil and air to the medical handpiece, a second pipe that can supply the oil to the first pipe, and the air to the first pipe. A third pipeline that can be supplied and a fourth pipeline that is connected to the third pipeline on the upstream side of the flow of air supplied from the third pipeline from the second pipeline are included.
The second pipeline and the third pipeline are branched from the first pipeline.
The manifold makes it possible to supply the air from the third pipeline to the water pipeline capable of supplying water of the medical handpiece via the fourth pipeline.
In the manifold to which the medical handpiece is connected, the control unit supplies air to the medical handpiece by the third pipe line and the fourth pipe line, and then connects to the first pipe line. A method for controlling a refueling maintenance device for a medical handpiece, which supplies oil to the medical handpiece through the second pipeline.

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