CN213249860U - Hand-held type gas drive medical equipment - Google Patents

Abstract

The utility model provides a hand-held type gas drive medical equipment, includes the aircraft nose, the aircraft nose include the shell and set up with rotating in wind wheel in the shell, be formed with the holding chamber in the shell and accept the wind wheel, be formed with the intercommunication on the shell the main gas port and the gas vent in holding chamber, the shell is equipped with a plurality of recesses on encircleing the internal face in holding chamber, the circumference interval distribution of shell is followed to the recess, the utility model discloses a rotatory air current of recess reflection directive recess causes the change of air current direction and speed and forms the interference air current, can effectively reduce the rotational speed of aircraft nose when idling, can effectively guarantee the torsion output when aircraft nose grinding tooth again, overall structure is simple moreover, easily shaping, cost are controllable.

Description

Hand-held type gas drive medical equipment

Technical Field

The utility model relates to the technical field of medical equipment, especially, relate to a hand-held type gas drive medical equipment.

Background

The turbine handpiece blows a wind wheel to rotate by compressed air to generate power, and is often used for grinding teeth and the like. Generally, the cutting rotating speed of the machine head of the turbine hand piece is about 20 ten thousand revolutions per minute, so that the machine head can generate enough torque force when teeth are ground, and the problem that the machine head is blocked and does not rotate or the rotating speed is too low to influence the working efficiency is avoided.

However, in order to ensure the cutting rotating speed of the turbine hand piece, the no-load rotating speed of the machine head reaches 30-45 ten thousand revolutions per minute, and the service life of a machine head bearing is shortened to a great extent. Therefore, high-quality high-speed bearings are adopted in the industry to bear the high rotating speed of the machine head so as to prolong the service time of the bearings, but the high-speed bearings are expensive, so that the cost is greatly increased; in addition, the flow velocity of compressed air at the main air hole is limited by limiting the pressure of the main air hole of the handpiece, so that the aims of reducing the rotating speed of the handpiece and prolonging the service life of the bearing are fulfilled, but the torque force of the handpiece is insufficient, and the work of a doctor is influenced.

SUMMERY OF THE UTILITY MODEL

In view of the above, a handheld gas driven medical device is provided that effectively solves the above problems.

The utility model provides a hand-held type gas drive medical equipment, includes the aircraft nose, the aircraft nose include the shell and set up with rotating in wind wheel in the shell, be formed with the holding chamber in the shell and accept the wind wheel, be formed with the intercommunication on the shell the main gas port and the gas vent in holding chamber, the shell is equipped with a plurality of recesses on the wall that surrounds the holding chamber, the circumference interval distribution of shell is followed to the recess.

In one embodiment, the groove is located between the main air port and the exhaust port in the circumferential direction of the wall surface of the accommodating cavity, and the interval between the groove and the main air port in the circumferential direction is larger than the interval between the groove and the exhaust port in the circumferential direction.

In one embodiment, the number of grooves is 3-150. The arc length corresponding to the interval of the centers of any two adjacent grooves in the circumferential direction is not more than half of a circumference.

In one embodiment, the recess is recessed radially with respect to the wall surface of the receiving cavity by a depth of not more than 1.0 mm.

In one embodiment, the axial length of the grooves is less than 10mm, each groove being a continuous or discontinuous straight groove parallel to the axis of the housing. Alternatively, each groove is a continuous or discontinuous chute angled with respect to the axis of the housing. Each groove is a spiral groove which extends spirally along the wall surface of the accommodating cavity.

In one embodiment, the radial cross section of the groove is circular arc, parabolic, triangular or trapezoidal.

In one embodiment, the wall surface of the groove is arc-shaped, and the corresponding arc radius is larger than the radial depth of the groove.

Compared with the prior art, the utility model discloses hand-held type gas drive medical equipment is sunken to form the recess on its wall that the shell surrounds the wind wheel, and the rotatory air current of reflection directive recess causes the change of air current direction and speed and forms the interference air current, can effectively reduce the rotational speed when the aircraft nose idles, can effectively guarantee the torsion output when aircraft nose grinding tooth again, overall structure is simple moreover, easily shaping, cost are controllable.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the handheld gas-driven medical device of the present invention.

FIG. 2 is a radial cross-sectional view of the hand-held, gas-driven medical device of FIG. 1, with the internal gas flow direction indicated by the arrows.

Fig. 3 is an axial cross-sectional view of the hand-held gas-driven medical device of fig. 1.

FIG. 4 is an axial cross-sectional view of a handpiece housing of the handheld gas-driven medical device of FIG. 1.

Fig. 5 is a cross-sectional view of the housing of fig. 4 taken along line a-a.

Fig. 6 is a cross-sectional expanded view of the housing of fig. 5 taken along line B-O-B.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. One or more embodiments of the present invention are illustrated in the accompanying drawings to provide a more accurate and thorough understanding of the disclosed embodiments. It should be understood, however, that the present invention may be embodied in many different forms and is not limited to the embodiments described below.

As shown in fig. 1, a handheld gas powered medical device according to an embodiment of the present invention includes a handpiece 10 and a handle 20 connected to the handpiece 10. The handle 20 is convenient for a user, such as a doctor, to hold. Referring to fig. 2 and fig. 3, the handpiece 10 includes a housing 12, a rear cover 14 connected to the housing 12, a central shaft 16 rotatably disposed in the housing 12, and a wind wheel 18 sleeved on the central shaft 16. As shown in fig. 4, the housing 12 has a cylindrical structure as a whole, and a shaft hole 120 is formed therein. The rear cover 14 covers one axial side end of the housing 12, the middle shaft 16 is rotatably disposed in the shaft hole 120, one end of the middle shaft 16 is supported on the rear cover 14, and the other end of the middle shaft passes through the other axial side end of the housing 12 and extends outward. The wind wheel 18 is fixedly sleeved on the center shaft 16 and drives the center shaft 16 to rotate synchronously, and the wind wheel and the center shaft can be in tight fit, bonding, buckling fit and the like.

The axial middle part of the inner wall surface of the outer shell 12 is recessed along the radial direction to form a containing cavity 122 surrounding the shaft hole 120 for arranging the wind wheel 18. Referring to fig. 2, the diameter of the wind wheel 18 is slightly smaller than the diameter of the accommodating cavity 122, and after the wind wheel 18 is assembled in the housing 12, the outer edge of the wind wheel 18 is radially spaced from the wall 123 of the housing 12 surrounding the accommodating cavity 122, and a flow passage 125 surrounding the wind wheel 18 is formed between the outer edge of the wind wheel and the wall. Preferably, the inner wall surface of the housing 12 is recessed radially at both axial ends of the receiving cavity 122 to form a receiving space 124 surrounding the shaft hole 120, and a bearing 19 is disposed in each receiving space 124 to support the middle shaft 16 to rotate at a high speed. The bearing 19 is preferably a ball bearing, and a seal ring 11 is provided between a radially outer wall surface 129 of the bearing 19 and an inner wall surface of the housing 12.

Referring to fig. 4 to 6, a main air hole 126 and an exhaust hole 127 communicating with the accommodating cavity 122 are formed on the housing 12 for respectively flowing in and out of the compressed air. In this embodiment, the main air hole 126 and the exhaust hole 127 are formed at the position where the housing 12 is connected to the handle 20, and face the wind wheel 18 in the housing 12. The compressed air enters the accommodating cavity 122 of the casing 12 through the main air hole 126, flows to the air discharge hole 127 along the flow path 125 between the wind wheel 18 and the wall surface 123 surrounding the accommodating cavity 122 (clockwise in fig. 2) to form the rotating airflow 30, and is finally discharged outwards through the air discharge hole 127. During the process of the rotating airflow 30 flowing through the housing 12, the wind wheel 18 is driven to drive the central shaft 16 pivoted thereto to rotate clockwise. In other embodiments, the compressed air may also form a rotating airflow rotating in a counterclockwise direction, so as to drive the wind wheel 18 and the central shaft 16 to rotate in the counterclockwise direction, which is not limited in this embodiment.

As shown in fig. 2 and 3, the housing 12 has a plurality of grooves 128 around the wall 123 of the receiving cavity 122. In the illustrated embodiment, the grooves 128 are formed by radially recessing the wall 123. The recess 128 is recessed radially with respect to the wall 123 by a depth T that is substantially less than the radial thickness of the housing 12, i.e. the recess 128 is a blind recess that does not extend through the housing 12 and has a radial depth of no more than 1.0mm, preferably 0.1-0.5 mm. The grooves 128 may have a variety of configurations in shape, such as arcuate, trapezoidal, triangular, irregular, etc. in radial cross-section. In this embodiment, the cross section of each groove 128 is circular arc, the radius R of the circular arc is 0.5mm, and the depth T of the concave groove 128 recessed with respect to the wall surface 123 is less than the radius R, and is 0.3mm at most.

Each groove 128 extends parallel to the axial direction of the housing 12, has an axial length similar to the axial height of the rotor 18, and axially faces the rotor 18. Preferably, the axial length L of the groove 128 is less than 10 mm. In this embodiment, the groove 128 is a continuous straight groove parallel to the axial direction of the housing 12, and has an axial length L of about 3 mm. In other embodiments, the groove 128 may be a tapered groove inclined at an angle with respect to the axis of the housing 12, a spiral groove extending spirally along the wall surface 123 of the receiving cavity 122, or the like. Additionally, in some embodiments, each of the grooves 128 may also be discontinuous.

The grooves 128 are arranged in order from the primary air port 126 to the exhaust port 127 along the circumferential direction of the inner wall surface of the casing 12, and the number is preferably 3 to 150. To enhance the interference effect on the compressed air, the circumferential spacing between the centers of any two adjacent grooves 128 corresponds to an arc length of no more than half a circumference. In the present embodiment, as shown in fig. 5, the grooves 128 are ten in number and are uniformly spaced from each other, the groove 128 at the head end in the airflow direction is circumferentially spaced from the main air hole 126, and the groove 128 at the tail end is circumferentially relatively close to the exhaust air hole 127, that is, the circumferential distance between the groove 128 and the main air hole 126 is greater than the circumferential distance between the groove 128 and the exhaust air hole 127. In the present embodiment, the arc length occupied by the ten grooves 128 in the circumferential direction of the housing 12 is about half a circumference, i.e., corresponding to a central angle of 180 degrees; the circumferential spacing of the centers of two adjacent grooves 128 corresponds to an arc length of about 1/18 circles, i.e., 20 degrees of central angle.

The groove 128 is formed by recessing the wall surface 123 of the housing 12 surrounding the receiving cavity 122, the curvature of the wall surface 129 surrounding the groove 128 is different from the curvature of the wall surface 123 surrounding the receiving cavity 122, so that the tangential direction of each point of the wall surface 129 is different from the tangential direction of the wall surface 123, and in this embodiment, an included angle α is formed between the tangential direction of the wall surface 129 and the tangential direction of the wall surface 123 at the connection between the wall surface 129 of the groove 128 and the wall surface 123 of the receiving cavity 122, and the included angle α is about 52 degrees. When the compressed air flows along the flow path 125 in the housing 12, and flows substantially along the wall 123 surrounding the receiving cavity 122, part of the air flow enters the groove 128 and is reflected at the wall 129 of the groove 128, as shown in fig. 2, the reflected air flow passing through the groove 128 not only changes in direction, but also loses energy to cause a speed drop, and becomes a disturbance air flow 32.

The utility model discloses hand-held type gas drive medical equipment is when using, and compressed air warp main air vent 126 gets into in the holding chamber 122 of aircraft nose 10, follows wind wheel 18 and the high-speed flow of runner 125 between the wall 123 that encircles holding chamber 122 form rotatory airflow 30 drive wind wheel 18 and drive axis 16 and rotate at a high speed. Because the groove 128 is formed on the wall surface 123 surrounding the wind wheel 18, part of the rotating airflow 30 enters the groove 128 and is reflected by the groove 128 in the process of flowing along the wall surface 123, so that the interference airflow 32 with inconsistent direction and speed is formed, the interference airflow 32 forms a barrier to the high-speed rotation of the wind wheel 18, and the rotating speed of the wind wheel 18 is reduced. The larger the number of the grooves 128, the more the disturbing air flow 32 is formed, and the more obvious the speed reduction of the wind wheel 18 is; in addition, the higher the speed of the rotating airflow 30, the more influenced by the disturbance airflow 32, the more obvious the speed reduction of the wind wheel 18.

In order to guarantee the utility model discloses hand-held type gas drive medical equipment can produce sufficient torsion when the grinding tooth, can improve the velocity of flow or the atmospheric pressure of the compressed air through main gas port 126 as far as possible, lets wind wheel 18 can obtain bigger drive power. When the handheld air-driven medical equipment idles, the wind wheel 18 has no load, the rotating speed is relatively higher, and theoretically, the rotating speed can reach 30-45 ten thousand revolutions per minute. The influence of the disturbing air flow 32 formed by the grooves 128 on the rotational air flow 30 forms an obstacle to the wind wheel 18, so that the actual idling rotational speed of the hand-held gas-driven medical device is significantly reduced, thereby allowing a longer service life of the bearing 19. Hand-held type gas drive medical equipment is when the grinding tooth, and its wind wheel 18 roughly can reduce to about 20 ten thousand revolutions per minute because the influence rotational speed of load, and the rotational speed of wind wheel 18 is less than the rotational speed of rotatory air current 30 far away this moment, because the influence of the effect formed of recess 128 air current 32 to wind wheel 18 can be ignored basically, guarantees hand-held type gas drive medical equipment exports sufficient torsion, avoids aircraft nose 10 card to stop not changeing or the rotational speed is low excessively, guarantees the utility model discloses hand-held type gas drive medical equipment's work efficiency.

The handheld air-driven medical equipment of the utility model is provided with the groove 128 on the wall surface 123 of the shell 12 surrounding the wind wheel 18, the rotating airflow 30 which is emitted to the groove 128 is reflected to cause the change of direction and speed and form the interference airflow 32, the interference airflow 32 causes obvious interference to the wind wheel 18 when the handpiece 10 idles, the rotating speed of the wind wheel 18 is effectively reduced, and the service life of the bearing 19 is prolonged; meanwhile, the rotating speed of the wind wheel 18 of the handpiece 10 is obviously reduced under the influence of the load when the handpiece 10 grinds the teeth, and the influence of the interference air flow 32 on the wind wheel 18 is far lower than the influence of the load, so that the interference air flow 32 basically does not respond to the rotating speed of the handpiece 10 when the teeth are ground, and sufficient torque output is ensured. The utility model discloses a torsion output when recess 128's setting can guarantee the grinding, can effectively reduce the rotational speed when empty load simultaneously, extension bearing 19's life. The groove 128 can be inserted out by reciprocating motion of a forming slotting tool for a numerical control lathe, and can also be machined by a power head with a milling function for the numerical control lathe, and the manufacturing process is simple and basically does not affect the whole cost.

It should be noted that the present invention is not limited to the above embodiments, and other changes can be made by those skilled in the art according to the spirit of the present invention, and all the changes made according to the spirit of the present invention should be included in the scope of the present invention.

Claims (10)

1. The utility model provides a hand-held type gas drive medical equipment, includes the aircraft nose, the aircraft nose include the shell and set up with rotating in wind wheel in the shell, its characterized in that, be formed with the holding chamber in the shell and accept the wind wheel, be formed with the intercommunication on the shell the main gas port and the gas vent in holding chamber, the shell is equipped with a plurality of recesses on the wall that surrounds the holding chamber, the circumference interval distribution of shell is followed to the recess.

2. The hand-held gas-driven medical device according to claim 1, wherein the groove is located between the main gas port and the gas discharge port in a circumferential direction of the wall surface of the housing chamber, and a circumferential interval between the groove and the main gas port is larger than a circumferential interval between the groove and the gas discharge port.

3. The hand-held, gas-driven medical device of claim 1, wherein the number of grooves is 3-150.

4. The hand-held, gas-driven medical device of claim 1, wherein the centers of any two adjacent grooves are circumferentially spaced by an arc length no greater than one-half of a circumference.

5. The hand-held, gas-driven medical device of claim 1, wherein the recess is recessed radially relative to the wall of the receiving cavity by a depth of no more than 1.0 mm.

6. The hand-held, gas-driven medical device of any of claims 1-5, wherein the axial length of the grooves is less than 10mm, and each groove is a continuous or discontinuous straight groove parallel to the axis of the housing.

7. The hand-held gas driven medical device of any one of claims 1-5, wherein the grooves have an axial length of less than 10mm, each groove being a continuous or discontinuous chute angled with respect to the axis of the housing.

8. The hand-held gas-driven medical device of any one of claims 1-5, wherein the axial length of the grooves is less than 10mm, and each groove is a helical groove extending helically along the wall of the receiving cavity.

9. The hand-held, gas-driven medical device of claim 1, wherein the groove has a radial cross-section in the shape of a circular arc, a parabola, a triangle, or a trapezoid.

10. The handheld gas driven medical device of claim 8, wherein the wall of the recess is arcuate with a corresponding radius of the arc greater than the radial depth of the recess.

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