JPH08639A - Small fluid drive turbine hand piece - Google Patents

Abstract

PURPOSE:To provide a small fluid drive turbine hand piece for medical care such as dentistry by which entrance and suction of a pollutant such as cutting chips inside of a head part can be prevented at operation stopping time needless to say at operating time. CONSTITUTION:In a small fluid drive turbine hand piece A composed of a head part H having a turbine blade 31 of a turbine rotor shaft 3 rotatably supported by a bearing part 2 arranged in the head part in a chamber 12 of a head body 1 of the head part and a hand piece body B which is continuously arranged in the head part H and has inside a supply passage to supply pressurized fluid to the turbine blade 31 arranged in the chamber 12 by this constitution mentioned above and a discharge passage to discharge pressurized fluid in the chamber 12, the head part H is constituted so as to have a communicating passage 4 communicated with a shaft receiving part 2 from an inner wall surface part of the chamber 12 of the head body 1.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a small fluid-driven turbine type handpiece which is useful for machining work, medical treatment and the like. More specifically, the present invention is directed to contaminants such as cutting debris in the vicinity of the tool axis of a cutting tool fixed to the head portion of the handpiece when the handpiece is in operation or stopped, and these contaminants The present invention relates to a small fluid-driven turbine handpiece that prevents the suction of air into the head.

[0002]

2. Description of the Related Art Conventionally, small fluid-driven turbine handpieces have been used, for example, for cutting materials or for medical purposes. In orthopedic surgery (surgery (brain surgery, plastic surgery, oral surgery, otolaryngology)). It is widely used in the oral cavity treatment in dentistry such as cutting, cutting, and cutting of bones and teeth.

Among the small fluid-driven turbine handpieces described above, a small-sized dental fluid-driven turbine handpiece that uses pressurized air as a pressurized fluid that is a drive medium for a turbine is called a dental air turbine handpiece. The external shape is as shown in FIG. 1 cited in the description of the technical configuration of the present invention described later.
That is, as shown in FIG. 1, the dental air turbine handpiece (A) comprises a head portion (H) and a neck portion (N) connected to the head portion (H). The neck portion (N) has therein a mechanism for supplying / exhausting pressurized air to / from the air turbine arranged in the head portion (H). In FIG. 1, (G) shows a grip portion (grip portion), and (B) shows a tool fixedly held on a rotor shaft of an air turbine. For convenience of description, the conventional art and the present invention will be described by taking the dental air turbine handpiece using pressurized air as a driving medium of a turbine as a typical example of a small fluid-driven turbine handpiece.

Needless to say, in the present invention, the drive medium for the turbine is not limited to the pressurized air. For example, the pressurized fluid as the drive medium for the turbine is not limited to pressurized air, and various types of pressurized fluid, pressurized gas including pressurized steam, and the like may be used. Therefore, in the following description, the terms air supply / air supply port and exhaust / exhaust port used in relation to pressurized air refer to supply / supply port and exhaust / exhaust port in the case of applying other pressurized fluid. It goes without saying that we have to read it again. Further, the application field of the small fluid-driven turbine handpiece of the present invention is not limited to the above-mentioned dentistry, but is widely applied to fields such as cutting of materials and medical applications. Furthermore, it goes without saying that in these application fields, the handpiece is not limited to the one in the form of being gripped and used by the hand, and may be used as one component (member, part) of a device. Is.

Regarding the structure of a conventional dental air turbine handpiece, particularly the internal structure of the head portion and the neck portion (N) connected to the head portion, a dental air turbine handpiece (A of the present invention described later 2) for explaining the first embodiment of FIG. In addition,
The structure of a conventional dental air turbine handpiece will be described with reference to FIG. 2 according to the first embodiment of the present invention. Because there is. Specifically, in FIG.
Those excluding the communication passages (reference numbers: 4, 41, 42 ...) belong to the prior art.

As shown in FIG. 2, the head portion (H) of this type of air turbine handpiece is a turbine having a turbine blade (31) at the peripheral portion in a chamber (12) inside the head body (1). While disposing the turbine blade (31) of the rotor shaft (3),
The turbine rotor shaft (3) is rotatably supported in the head body (1) through a bearing portion (2).

As shown in FIG. 2, the head body (1) has a head cap (13) on the upper part, and has a lower surface part (14) on the lower part and the lower surface part (14). The turbine rotor shaft (3) has an opening (141) for projecting and arranging the lower part thereof. Further, as shown in FIG. 2, the head cap (13) is for fixing the head cap (13) to the head body (1) and for removing the tool shaft (5) from the turbine rotor shaft (3). Hole (13
1).

As shown in FIG. 2, a tool shaft (5) such as a dental cutting tool is fixedly held at the axial center of the turbine rotor shaft (3) to perform various kinds of medical treatment. A chuck (51) for gripping the tool shaft (5) is disposed on the peripheral side of the tool shaft (5) as shown in the figure. Although the illustrated chuck (51) is of a friction type chuck mechanism, it goes without saying that it may be of a known one-touch chuck mechanism. When the chuck mechanism is of the one-touch type, a head cap (13) having no hole (131) is used, but a slight gap (machine) is provided between the head body (1) and the one-touch chuck mechanism. Including component tolerances).

As shown in FIG. 2, the bearing portion (2)
Is the inner ring (inner race) (21), the outer ring (outer race) (2
2), a ball (23) and a retainer (24). It should be noted that a well-known mechanism such as the above-mentioned wave washer for increasing the shaft rigidity or an O-ring for centering the shaft may be provided at the end or side of the bearing portion (2). Needless to say.

As shown in FIG. 2, the neck portion (N) connected to the head portion (H) has a main body (6).
An air supply / exhaust system for the chamber (12) is provided inside the chamber. Specifically, in the air supply / exhaust system, pressurized air is injected into the chamber (12) from the air supply port (7a) of the air supply passage (7), and the pressurized air in the chamber (12) is From the exhaust port (8a) to the exhaust passage (8),
It is configured to be exhausted outside the system. Although not shown, it goes without saying that a water supply channel, a lighting pipeline, or the like may be provided in the main body (6) of the neck portion (N).

In FIG. 2, which shows the structure of a conventional dental air turbine handpiece, a point to be particularly noted is that, when the handpiece is stopped, contaminants such as cutting chips are introduced from the outside of the periphery of the head body into the inside of the head. The point is that it is easy to inhale. As is clear from the above-described structure, the entry route of the contaminants into the head body is such that the turbine rotor shaft (3) is arranged in the opening (141) of the lower surface (14) of the head body (1). The gap (141a) formed when the head cap (13), the gap (2a, 2b) formed between the bearing (2) and the head cap (13) and the head body (1) member,
The opening (131) and the like.

The suction of the pollutants into the head body has been regarded as a problem in the conventional dental air turbine handpiece. The suction of the pollutants into the chamber inside the head body (1) is for the following reason. That is, when the handpiece is stopped, even if the air supply system is shut off, the turbine rotor continues to rotate for a short period of time, so that the inside of the chamber becomes a negative pressure and contaminants such as cutting debris near the tool shaft are generated. It will be sucked into the inside of the head body (1).

One method for preventing the above-mentioned contaminants from being sucked into the handpiece is disclosed in Japanese Patent Application Laid-Open No. 5-42169. This is particularly related to the prevention of foreign matter such as cutting dust from entering the inside of the head body during the operation of operating the dental handpiece. The concrete measures for preventing the invasion of pollutants by the above proposal are as follows. (i) An opening for projecting one end of a bar sleeve (corresponding to the turbine rotor shaft) is provided at the lower end surface of the cartridge case (corresponding to the head body), and the outer peripheral surface of the bar sleeve is provided. And the inner peripheral surface of the opening is concentrically separated. (ii) Then, in the concentric space, a predetermined member, that is, a fixed partition member, a rotary partition member (dust-proof disk), and a disk cover are used. It is arranged so that a gap, a second gap, and a third gap are formed. With the configurations (i) and (ii), the radius of gyration of the member varies with the rotation of the bar sleeve, so that the airflows located in the first to third gaps become faster in this order. In other words, the air pressure in the third gap can be the lowest. Therefore, contaminants such as cutting chips are sucked into the third gap, but are prevented from entering the first and second gaps. The sucked contaminants are discharged to the outside from the opening provided in the disc cover.

The measures for preventing contaminants from entering the inside of the head body according to the above proposal are complicated in structure and insufficient in operational effect. For example, it is not effective for the problem of invasion from the head cap portion above the head main body, and particularly for the problem of contaminant invasion in a negative pressure state in the chamber when the operation is stopped.

[0015]

SUMMARY OF THE INVENTION The present invention is intended to solve the above-mentioned problems of the prior art. The inventors of the present invention have diligently studied the prevention of contaminants such as cutting debris from entering the inside of the head main body in a small-sized fluid-driven turbine handpiece for dentistry or the like during operation as well as during operation stop.

As a result, when the operation of the handpiece is stopped, there is a difference in the pressure distribution in the chamber inside the head body, more specifically, a negative pressure in the center of the chamber,
A slight positive pressure is applied to the chamber peripheral side, and when the bypass is disposed from the chamber peripheral side to the bearings arranged above and below the chamber, the difference in the pressure distribution inside the head body is canceled. It was found that the air flow generated in the head effectively prevents the invasion of contaminants into the inside of the head body. The present invention has been completed on the basis of the above-mentioned findings, and according to the present invention, it is possible to prevent the entry of contaminants such as cutting chips into the inside of the head body, and especially to prevent the entry of the contaminants into the bearing portion and the chamber. It is intended to provide a small fluid-driven turbine handpiece for medical use such as.

[0017]

SUMMARY OF THE INVENTION The present invention will be described in brief. The present invention provides a chamber (1) of a head body (1) of a head portion.
2) a head portion (H) having a turbine blade (31) of a turbine rotor shaft (3) rotatably supported by a bearing portion (2) arranged in the head portion, and the head portion (H). H) and a supply passage for supplying a pressurized fluid to the turbine blade (31) arranged in the chamber (12) and an exhaust passage for discharging the pressurized fluid in the chamber (12). In a small fluid-driven turbine handpiece (A) including a handpiece body (B) inside, (i) the head portion (H) is a bearing from the inner wall surface portion of the chamber (12) of the head body (1). The present invention relates to a small fluid-driven turbine handpiece having a communication passage (4) communicating with the portion (2).

The technical constitution and embodiments of the present invention will be described below in detail with reference to the drawings, taking the above-mentioned dental air turbine handpiece as an example. Needless to say, the present invention is not limited to the illustrated one.

FIGS. 1 to 3 are views for explaining a dental air turbine handpiece (A) according to a first embodiment of the present invention. As described above, FIG. 1 is a perspective view, FIG. 2 is a longitudinal sectional view taken along the axial direction of the tool shaft (C) of FIG. 1, and FIG.
2 is a cross-sectional view taken along line I-I of FIG. Here, in the dental air turbine handpiece, the cause of contamination of the inside of the head body of the handpiece by contaminants such as tooth cutting waste will be described. During operation of the handpiece (A), the inside of the chamber (12) formed inside the head body (1) of the head portion (H) is connected to the air supply port (7) through the air supply port (7a). Due to the injection of pressurized air and the rotation of the turbine rotor shaft (3), a slight positive pressure (+) is obtained. Therefore, the chamber (12), the two sets of bearings (2) arranged above and below the chamber (12), and the bearing (2) and the head cap (13) or the lower surface (14) of the head body. The inside of the head body (1) will not be contaminated by the contamination path composed of the opening (141) and the like arranged in (1). This is because the positive pressure (+) is applied to the contamination path. However, as described below,
It goes without saying that when the positive pressure (+) is positively applied to the contamination path during the operation of the handpiece, the contamination by the contaminant is surely prevented.

On the other hand, when the operation of the handpiece (A) is stopped, the turbine rotor shaft (3) continues to rotate inertially even after the air supply from the air supply passage (7) is cut off. Air is pressed against the inner wall surface (123) of the chamber peripheral side by centrifugal force, and the air supply passage (7) and the exhaust passage (8)
Both have a slight positive pressure (+), and the chamber (1
The central part of 2) becomes a negative pressure (-). As described above, since the central portion of the chamber (12) has a negative pressure (-), contaminants such as cutting chips are sucked into the inside of the head body (1) and the like through the above-mentioned contamination path, and, for example, the bearing portion (2). ) The bearing (23) of the bearing (23) passes between the inner ring (21) and the outer ring (22) of the bearing, so that the contaminants are sucked into the center of the chamber (12) and the inside of the chamber (12) is contaminated. Needless to say, the bearing process (2) also becomes more contaminated and damaged during the contamination process.

The present invention was devised from the clarification of the cause of the above-mentioned contaminants being sucked into the head body (1), and its main points are the circumferential side portion of the chamber (12) and the bearing portion (2). Bypass is provided, and positive pressure (+) and negative pressure (-)
To prevent the inhalation of the pollutants so that they cancel each other out. In the present invention, the bypass described above is provided in the chamber (12) of the head body (1) as shown in FIG.
It is constituted by a communication passage (4) that communicates from the inner wall surface of the bearing to the bearing (2).

More specifically, the communication passage (4) is provided in the chamber (1) of the head body (1) as shown in FIG.
The inner wall surface of 2), in particular, the upper and lower inner wall surface parts (121, 122) of the chamber peripheral side inner wall surface part (123) which are positive pressure (+), are arranged in the upper and lower parts of the chamber (12). Two sets of communication passages (41
42, 43 and 44) are provided. In addition,
In the present invention, the communication passages (4) are arranged such that a set of communication passages are arranged from the chamber (12) to the end surface portions of the upper and lower bearing portions (2) as in the second embodiment described later. It goes without saying that it is good. FIG. 3 shows FIG.
2 is a cross-sectional view taken along line I-I of FIG. FIG. 3 particularly illustrates the air supply / exhaust system in the dental handpiece (A) of the first embodiment. The features of the air supply / exhaust system of the first embodiment will be described later in connection with the handpiece of the second embodiment.

4 to 5 illustrate a dental air turbine handpiece (A) according to a second embodiment of the present invention. FIG. 4 is a view corresponding to FIG. 2, and FIG. 5 is a sectional view taken along line II-II of FIG. The major differences between the air turbine handpiece (A) of the second embodiment shown in FIGS. 4 to 5 and that of the first embodiment shown in FIGS. 2 to 3 are as follows. Is. (i) The distance between the turbine blade (31) arranged in the chamber (12) of the head body (1) and the inner wall surface of the chamber (12) is greatly different. That is, FIG. 4 and FIG.
As shown in FIG. 3, d ₁ (the distance between the turbine blade and the inner wall surface on the upper and lower sides of the chamber) in the second embodiment (FIG. 3) is extremely smaller than d ₁ ′ in the first embodiment (FIG. 2). . The intervals between the turbine blade and the inner wall surface of the chamber are substantially the same (d ₂ =
d ₂ ').

(Ii) The structure of the air supply / exhaust system for the chamber (12) is greatly different. That is, in the air supply / exhaust system of the second embodiment (FIGS. 4 to 5), the air supply passage (7) has compressed air at the center of the turbine blade (31) arranged in the chamber (12). It is arranged to inject a stream. Further, the exhaust passage is located in the vicinity of the air supply port (7a) of the air supply passage (7), specifically, the chamber (1
2) Two exhaust passages having exhaust ports (8a, 9a) in the vertically adjacent portions of the air supply port (7a) so that the pressurized air injected into the chamber (12) is not circulated (non-circulated). It is composed of (8, 9). The non-circulation of the pressurized air flow in the chamber (12) is indicated by the arrow (b) in FIG.

On the other hand, the air supply / exhaust system of the first embodiment (FIGS. 2 to 3) shows a typical example applied to the conventional handpiece of this type. That is, the supply of the pressurized air into the chamber (12) is performed by the air supply passage (7) through the air supply port (7) arranged on one side of the chamber (12).
Air is supplied via a). The exhaust of the pressurized air in the chamber (12) is performed on the same side as the air supply port (7a) and in the region where the supplied pressurized air circulates in the chamber (12). As shown in FIG. 3, the gas is exhausted to the outside of the system by the exhaust passage (8) through the exhaust port (8a) arranged at a distance (D) from the air supply port (7a). The fact that the pressurized air flow in the chamber (12) is of the circulating type is indicated by the arrow (a) in FIG. The arrangement positional relationship between the air supply port (7a) and the exhaust ports (8a, 9a) of the second embodiment (FIG. 3) is the same as that of the air supply port (7a) of the first embodiment (FIG. 2). Compared with the arrangement positional relationship of the exhaust port (8a), the former is arranged at a position extremely closer than the latter.

(Iii) The second embodiment (FIG. 3) reflecting the configuration of (ii) above, that is, considering the strength of the neck portion (N).
In the above, a set of communication passages (4) is arranged.

In the second embodiment (FIG. 3) of the present invention, the dental air turbine handpiece having a structure in which a set of communication passages (4) is not provided was previously proposed by the present inventors. A handpiece with a new structure (Japanese Patent Application No. 6-36
No. 404). In the handpiece of the new structure previously proposed by the present inventors, for example, (1) the distance (d ₁ )
Is 500 μm or less (for conventional products, for example, d ₁
'Is known to be 1150 μm), and (2) the air supply / exhaust system has the above-described configuration (configuration in which the exhaust port is arranged in the vicinity of the air supply port). In this case, the pressurized air supplied into the chamber (12) as in the conventional case does not circulate in the chamber (12) (non-circulation, see FIG. 5) but immediately after transmitting the momentum to the turbine blade. Be exhausted. In other words, the supplied pressurized air is non-circulating. The significance of this is great, and in the conventional revolving type (see FIG. 3), the pressurized air suppresses the rotation of the blade in the chamber, whereas in the new non-circulating type, such disadvantages occur. Are eliminated. Specifically, among the handpieces of the same shape, the maximum rotation speed of the conventional orbiting type was 4
Maximum rotation speed of non-circulating type ⁴ against 2.0 × 10 ⁴ rpm
7.5 × 10 ⁴ rpm is achieved.

That is, in the dental air turbine handpiece (A) of the second embodiment, since the rotational force is extremely large and the inertial rotation at the time of the operation stop is large, the head body of the pollutant particularly during the operation stop is Preventing inhalation into the interior is important. Further, even during operation, since the rotation speed is higher than that of the conventional one, it is important to prevent the contaminants from being sucked into the inside of the head body. In order to meet the above-mentioned needs, the present invention provides an inner wall surface portion of the chamber (12) of the head body (1), in particular, a chamber peripheral side inner wall surface portion (123) having a positive pressure (+) as shown in FIG. From the upper and lower inner wall surfaces (121, 122) closer to the chamber (1
2) A set of communication passages (41, 42) is arranged in the end surface portion of the bearing portion (2) arranged in the upper and lower parts.

The present invention can be variously modified. FIG. 6 is for explaining the dental air turbine handpiece (A) of the third embodiment of the present invention. The third embodiment is greatly different from the second embodiment in that the receiving shaft portion (2) and the turbine rotor shaft (3) mounted inside the head body (1) are bearings. This is a point that the cartridge (C) is integrated by the pressers (C _{1 to} C ₂ ). In the third embodiment, the upper communication passage (41) has a hole in the inner peripheral surface of the cartridge (C) and / or the head body (1), or the bearing portion (2) side of the head cap (13). Alternatively, it may be formed by forming a groove. Further, the lower communication passage (42) may be formed by forming a hole or a groove in the inner peripheral surface of the cartridge (C) and / or the head body (1).

As another embodiment of the present invention, although not shown, the structure of the bearing portion (2) is replaced with that of the ball bearing mechanism using the ball bearing shown in the first to third embodiments. It goes without saying that the air bearing mechanism may be used.

[0031]

The small-sized medical fluid-driven turbine handpiece used for dentistry or the like according to the present invention effectively prevents the inside of the head body from being contaminated by contaminants such as cutting chips found in this type of handpiece. It is something you can do. That is, in this type of handpiece, the turbine rotor shaft continues to rotate inertially even when the air supply system is shut off during the operation of the handpiece, particularly when the operation is stopped. Then, a difference occurs in the pressure distribution (distribution of positive pressure and negative pressure) in the chamber, and the central portion of the chamber becomes negative pressure. Therefore, a turbine rotor shaft portion to which a cutting tool or the like is fixed, a bearing portion that supports the rotor shaft, Air is sucked into the inside of the head body from the head cap part and the like together with pollutants, and the inside of the head is contaminated.

In the present invention, attention is paid to the difference in the pressure distribution in the chamber when the operation of the head is stopped, and a communication passage communicating from the chamber to the bearing is provided in the head. It has been solved by this. Further, the contamination prevention means of the present invention is a suppressing factor (negative
Pressurized air acting as a factor) is positively guided to the bearing portion, so positive pressure (+) is reliably applied to the bearing portion, etc., and contaminants enter the inside of the head body even during operation of the handpiece. Can be prevented.

[Brief description of drawings]

FIG. 1 is a perspective view of a dental air turbine handpiece according to a first embodiment of the present invention.

FIG. 2 is a vertical cross-sectional view of the dental air turbine handpiece according to the first embodiment of the present invention.

3 is a cross-sectional view taken along line I-I of FIG.

FIG. 4 is a vertical sectional view of a dental air turbine handpiece according to a second embodiment of the present invention.

5 is a sectional view taken along line II-II of FIG.

FIG. 6 is a vertical sectional view of a dental air turbine handpiece according to a third embodiment of the present invention.

[Explanation of symbols]

A ……… Dental air turbine handpiece G ……… Grip part B ……… Tool H ……… Head part 1 ……… Head body 12 ……… Chamber 121 ……… Chamber upper inner wall surface part 122 ……… Inner wall surface of the chamber 123 123 Inner wall of the chamber 13 13 Head cap 14 Lower surface of the main body 2 Bearing section 3 Turbine rotor shaft 31 Turbine blade 32 … Blade support 4, 41, 42 ……… Communication path 5 ……… Tool axis 51 ……… Chuck N ……… Neck part 6 ……… Neck body 7 ……… Air supply path 7a ……… Supply Vents 8 and 9 Exhaust passages 8a and 9a Exhaust port C ... Cartridges C ₁ and C ₂ ... Bearing retainer

Claims (6)

[Claims] 1. A turbine rotor shaft (3) rotatably supported in a chamber (12) of a head body (1) of a head section (H) by a bearing section (2) arranged in the head section. (H) having a turbine blade (31), and supply for supplying a pressurized fluid to a turbine blade (31) arranged in the chamber (12) and connected to the head portion (H). A discharge passage (8) for discharging the pressurized fluid in the passage (7) and the chamber (12)
In a small fluid-driven turbine handpiece (A) comprising a neck portion (N) having and inside, (i) the head portion (H) is from an inner wall surface portion of the chamber (12) of the head body (1). A small fluid-driven turbine handpiece, characterized in that it has a communication passage (4) communicating with the bearing portion (2). 2. A head body, wherein the head portion (H) has a lower surface portion (14) and an opening portion (141) for projecting a lower portion of the turbine rotor shaft (3) on the lower surface portion (14). And / or a head cap (13) having a hole (131) in an upper portion of the head body, and the small fluid-driven turbine handpiece according to claim 1. 3. The communication passage (4) has an upper inner wall surface portion (121) and / or a lower inner wall surface portion (12) of the chamber (12).
The small fluid-driven turbine handpiece according to claim 1, which communicates with the end surface portion of the bearing portion (2) from a portion near the inner wall surface portion (123) side of 2). 4. The communication passage (4) extends from the vicinity of the upper inner wall surface portion (121) and / or the lower inner wall surface portion (122) of the circumferential inner wall surface portion (123) of the chamber (12) to the bearing portion (2). ) The small fluid-driven turbine handpiece according to claim 1, which communicates with the end face portion of FIG. 5. The bearing part (2) is arranged in two sets of upper and lower parts with respect to a turbine rotor shaft (3) extending upward and downward of the chamber (12). A small fluid-driven turbine handpiece as described. 6. The communication passage (4) is such that one set or two or more sets of communication passages are provided from the chamber (12) for the upper and lower two sets of bearing portions (2). The small fluid-driven turbine handpiece according to item 1.