JP5358066B2 - Drive circuit for preventing internal contamination of handpiece - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a driving circuit for preventing internal contamination of a handpiece, preventing patient's saliva and cutting pieces of a tooth from being sucked into the handpiece when stopping to use the handpiece. <P>SOLUTION: A proportional control valve 5 is provided on an air supply pipe 4 for supplying compressed air from a compressed air source 3 to an air turbine 2; an exhaust valve 7 is provided on an air discharge pipe 6; and when stopping to use the air turbine, and if the exhaust valve 7 is closed, the air supply flow of the proportional control valve 5 is simultaneously adjusted not to rotate the air turbine by electric control from a control circuit 8, whereby the interior of the handpiece is always kept at the positive pressure state. <P>COPYRIGHT: (C)2009,JPO&amp;INPIT

Description

The present invention relates to a device for preventing internal contamination of a handpiece equipped in a dental treatment apparatus.

Conventionally, when a foot controller is used, compressed air is supplied to the air supply pipe of the handpiece to drive an air turbine built in the tip of the handpiece, and the handpiece is configured to stop when the foot controller is released. Widely used.

4, the compressed air from the compressed air source 3 passes through the three-way valve 20 interlocked with the pedal 10 of the foot controller, passes through the air supply line 4, and the inside of the handpiece 1 as shown in FIG. The air turbine 2 is rotated. The compressed air after rotating the air turbine 2 is discharged from the exhaust pipe 6 into the outside air.

However, the rotational speed of the air turbine 2 is very high at 400,000 rpm, and the bearings of the air turbine 2 are configured to use a precision ball bearing to minimize the loss, and even if the supply of compressed air is cut off The air turbine 2 rotates due to inertia, and stops while gradually reducing its rotational speed. At this time, the air turbine 2 from which the supply of compressed air is cut off starts the suction pump action by the action of the case (head part of the handpiece 1) in which it is stored, and cutting powder, contaminants, etc. There is a high possibility of entering the head 1, the air supply pipe 4, and the exhaust pipe 6. Once contaminated, complete disinfection is very difficult.

Therefore, as a method for solving the above drawbacks, for example, in the invention of Patent Document 1, when the handpiece is stopped, the compressed air is sent back to the exhaust circuit to keep the handpiece at a high pressure, thereby preventing entry of contaminants. An invention has been proposed.
In the invention of Patent Document 2, as shown in FIG. 5, the tank 21 provided on the air supply line 4 is filled with compressed air when the handpiece 1 is used, and the exhaust valve 7 is closed after the use of the handpiece 1 is stopped. Then, until air is supplied from the tank 21 and the compressed air accumulated in the tank 21 is discharged and emptied, the inside of the case (head portion of the handpiece 1) in which the air turbine 2 is stored is made positive pressure, Inventions have been proposed to prevent filth from entering the air supply circuit.
Japanese Patent Laid-Open No. 3-140151 Patent No. 2912092

However, in the invention of Patent Document 1, the supply of air to the exhaust circuit continues longer than the supply of air to the supply circuit. Therefore, there is a possibility that the contaminant is pushed into the air supply circuit through the gap between the head portions of the handpiece when the handpiece is completely stopped. Moreover, in patent document 2, the tank 21 for accumulating pressure on an air supply circuit is required, the space for accommodating the tank 21 is needed, and the extra cost for it was needed.

In order to achieve the above object, the following present invention is proposed.
That is, claims 1 to 3 propose a drive circuit for preventing contamination of the handpiece.

According to the first aspect of the present invention, the air supply line for supplying the compressed air from the compressed air source to the air turbine and the exhaust line for exhausting the air are provided, and the voltage applied to the control circuit is varied in the supply line. A hand control circuit for preventing internal contamination of the handpiece, which is configured by providing a proportional control valve capable of adjusting the supply air flow rate and providing an exhaust valve in the exhaust pipe, and electrically connecting the foot controller to the control circuit. Connect and adjust the air supply amount of the proportional control valve according to the voltage output according to the movement amount of the pedal of the foot controller to control the rotation speed of the air turbine, and close the exhaust valve when the handpiece stops using At approximately the same time, the voltage adjusted to the air flow rate at which the air turbine does not rotate is applied to the control circuit for the time until the rotation of the air turbine stops. In adjusting the supply flow rate of the proportional control valve to the flow rate of air turbine is not rotated, and the inside of the handpiece, characterized in that the positive pressure.

According to the second aspect of the present invention, the air supply line for supplying the compressed air from the compressed air source to the air turbine and the exhaust line for exhausting the air are provided, and the voltage applied to the control circuit is varied in the supply line. A hand control circuit for preventing internal contamination of the handpiece, in which a proportional control valve capable of adjusting the supply air flow rate is provided and an exhaust valve is provided in the exhaust pipe, and a wireless foot controller is provided in the control circuit. Connect and adjust the air supply amount of the proportional control valve according to the voltage output according to the movement amount of the pedal of the wireless foot controller to control the rotation speed of the air turbine. At the same time when the exhaust valve is closed, the time until the rotation of the air turbine stops and the voltage adjusted to the air flow rate at which the air turbine does not rotate in the control circuit. Adjust the supply air flow rate of the proportional control valve by adding the flow rate air turbine is not rotated, and the inside of the handpiece, characterized in that the positive pressure.

According to the first aspect of the present invention, the time until the rotation of the air turbine stops almost simultaneously with closing of the exhaust valve when the use of the air turbine is stopped is adjusted to an air flow rate at which the air turbine does not rotate in the control circuit. By adjusting the supply flow rate of the proportional control valve to a flow rate at which the air turbine does not rotate by applying voltage , the handpiece is always kept at a positive pressure without causing negative pressure. In addition to preventing internal contamination, it is possible to prevent contamination of metal fittings and supply / exhaust hoses connected to the handpiece. Moreover, a space for storing a tank for accumulating pressure is not required, and an extra cost for that purpose can be suppressed.

According to the third aspect of the present invention, the proportional control valve can electrically control the air flow rate. Therefore, by changing the electrical signal to a wireless signal, the wireless foot controller can also be controlled inside the handpiece. A drive circuit for preventing contamination can be easily achieved.

The best mode of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram for explaining the first embodiment.
In this embodiment, a proportional control valve 5 is provided in an air supply line 4 that supplies compressed air from a compressed air source 3 to the air turbine 2, and an exhaust valve 7 is connected to the exhaust line 6. .
The proportional control valve 5 can adjust the supply air flow rate by varying the voltage applied to the control circuit 8. Further, a foot controller 9 is connected to the control circuit 8, and the rotational speed of the air turbine 2 is controlled by adjusting the supply air flow rate of the proportional control valve 5 by the voltage output corresponding to the movement amount of the pedal 10. be able to.

When rotating the air turbine 2, the number of rotations corresponding to the amount of movement can be obtained by moving the pedal 10 of the foot controller 9 from a predetermined stop position.
Compressed air from the compressed air source 3 is adjusted to an air flow rate corresponding to the amount of movement of the pedal 10 by the proportional control valve 5, flows into the handpiece 1, and rotates the air turbine 2. Most of the compressed air after rotating the air turbine 2 passes through the exhaust pipe 6, enters the exhaust valve 7, and is released into the outside air.

When stopping the air turbine 2, it can be stopped by returning the pedal 10 of the foot controller 9 to a predetermined stop position. At this time, when the exhaust valve 7 is closed, the pressure in the exhaust pipe 6 increases. Further, the inside of the air supply line 4 can be maintained at a positive pressure by adjusting the air supply flow rate of the proportional control valve 5 to a flow rate at which the air turbine 2 does not rotate almost simultaneously with closing the exhaust valve 7. For this reason, the differential pressure with respect to the exhaust pipe 6 is reduced, and the air turbine 2 does not cause the suction pump action by the action of the case housing it, and cutting powder, contaminants, etc. There is no intrusion into the air supply line 4 or the exhaust line 6. In order to adjust the supply air flow rate of the proportional control valve 5 to a flow rate at which the air turbine 2 does not rotate, the control circuit 8 is adjusted to a flow rate at which the air turbine 2 does not rotate for the time until the rotation of the air turbine 2 stops. Apply voltage.

FIG. 2 is a diagram for explaining the second embodiment.
In the second embodiment, an air supply valve 11 for controlling the opening and closing of the air supply of the air turbine 2 is provided on a pipe line connecting the air turbine 2 and the proportional control valve 5. When the exhaust valve 12 for residual pressure relief is provided branching from the pipe line and the air supply valve 11 is closed, the exhaust valve 12 for residual pressure relief is opened and the air supply line 4 of the proportional control valve 5 and the air supply valve 11 is connected. In this embodiment, the residual pressure is released.

Here, the air supply valve 11 is synchronized with the holder 13 for storing the handpiece 1. When the handpiece 1 is removed from the holder 13, the air supply valve 11 opens, and when the handpiece 1 is stored in the holder 13, the air supply valve 11 is closed. It is configured. The synchronization with the holder 13 detects the presence or absence of the handpiece 1 with a sensor and sends an electric signal 14 to the air supply valve 11 to control opening and closing. The air supply valve 11 may be one that opens and closes with an air signal. In that case, the presence or absence of the handpiece 1 may be sent with an air signal. In the case of a dental treatment unit, a plurality of handpieces are stored in a holder, and only the handpiece removed from the holder can be rotated. The selected handpiece rotates by moving the foot controller pedal.

The rotation and stop of the air turbine 2 are the same as in the first embodiment, but when the pedal 10 of the foot controller 9 is returned to the stop position and stored in the holder 13 before the stop of the air turbine 2 is completed, The air supply valve 11 is closed. At this time, since the proportional control valve 5 is supplied with a flow rate at which the air turbine 2 does not rotate, the residual pressure relief solenoid valve is opened to exhaust the residual pressure.
Even in this case, since the exhaust valve 7 of the exhaust pipe 6 is closed, the pressure of the exhaust pipe 6 rises and the differential pressure with respect to the air supply pipe 4 decreases, and the exhaust pipe 6 sucks contaminants. There is nothing. In this embodiment, the residual pressure relief solenoid valve 12 is used, but a proportional control three-way valve may be used instead of this.

FIG. 3 is a diagram for explaining the third embodiment.
In the third embodiment, the proportional control valve is controlled by a wireless foot controller. In the first embodiment or the second embodiment, the control circuit 8 and the foot controller 9 are electrically connected. Therefore, it is possible to realize a handpiece internal contamination prevention driving circuit using a wireless foot controller by converting an electrical signal into a wireless signal and transmitting / receiving it.

Here, the radio circuit 15 as shown in FIG. 3 is configured between the control circuit 8 and the foot controller 9 of FIG. 1 or FIG. In the radio circuit, the voltage corresponding to the movement amount of the pedal 10 output from the foot controller 9 is converted into a digital signal by the A / D conversion circuit 16 and converted into a radio wave or infrared radio signal by the transmission circuit 17 to receive circuit. 18 is transmitted. The receiving circuit 18 receives radio waves or infrared radio signals, detects or decodes them, converts them into digital signals, converts them into voltages with a D / A conversion circuit 19, and inputs them to the control circuit 8. The foot controller 9 does not need to supply power by wire by mounting a battery or the like.

From the above, in the prior art of FIG. 4 or FIG. 5, the foot controller had to be connected by air piping, but in this embodiment, a wireless foot controller is used to realize the handpiece internal contamination prevention drive circuit. It becomes possible.
In the embodiment of FIG. 1 or FIG. 2, the foot controller 9 is connected by an electric wire. However, in this embodiment, it is possible to realize a handpiece internal contamination prevention drive circuit using a wireless foot controller.

It is a schematic structure figure showing a 1st embodiment of the present invention. It is a schematic block diagram which shows the 2nd Embodiment of this invention. It is a schematic block diagram which shows the radio | wireless circuit of the 3rd Embodiment of this invention. It is a schematic block diagram which shows a prior art example. It is a schematic block diagram which shows a prior art example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Handpiece 2 Air turbine 3 Compressed air source 4 Supply line 5 Proportional control valve 6 Exhaust line 7 Exhaust valve 8 Control circuit 9 Foot controller 10 Pedal 11 Supply valve 12 Residual pressure relief exhaust valve 13 Holder 14 Electric signal 15 Wireless Circuit 16 A / D conversion circuit 17 Transmission circuit 18 Reception circuit 19 D / A conversion circuit 20 3-way valve 21 Tank

Claims (2)

It has an air supply line that supplies compressed air from the compressed air source to the air turbine and an exhaust line that exhausts the air, and the supply air flow rate is adjusted by varying the voltage applied to the control circuit. A handpiece internal contamination prevention drive circuit comprising a proportional control valve that can be configured and an exhaust valve provided in the exhaust line,
A foot controller is electrically connected to the control circuit, and by adjusting a supply amount of the proportional control valve according to a voltage output according to a movement amount of a pedal of the foot controller, a rotational speed of the air turbine is controlled.
When the exhaust valve is closed when the handpiece is stopped, the proportional control valve is supplied to the control circuit by applying a voltage adjusted to the air flow rate at which the air turbine does not rotate. A drive circuit for preventing contamination inside a handpiece, wherein the airflow is adjusted to a flow rate at which the air turbine does not rotate, and the inside of the handpiece is made positive pressure.
It has an air supply line that supplies compressed air from the compressed air source to the air turbine and an exhaust line that exhausts the air, and the supply air flow rate is adjusted by varying the voltage applied to the control circuit. A handpiece internal contamination prevention drive circuit comprising a proportional control valve that can be configured and an exhaust valve provided in the exhaust line,
A wireless foot controller is connected to the control circuit, and the amount of rotation of the air turbine is adjusted by adjusting the amount of air supplied to the proportional control valve according to the voltage output according to the amount of movement of the pedal of the wireless foot controller. Control
When the exhaust valve is closed when the handpiece is stopped, the proportional control valve is supplied to the control circuit by applying a voltage adjusted to the air flow rate at which the air turbine does not rotate. A drive circuit for preventing contamination inside a handpiece, wherein the airflow is adjusted to a flow rate at which the air turbine does not rotate, and the inside of the handpiece is made positive pressure.

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