DE102016113392A1 - AIR MOTOR FOR A COMPRESSED AIR TOOL - Google Patents

Abstract

An air motor has a housing (10), a shaft (20) and a plurality of turbine blades (30). The shaft (20) is rotatably mounted in the housing (10) and has a plurality of turbine blade recesses (22). The turbine blades (30) are movably mounted in the turbine bucket recesses (22). Each turbine bucket recess (30) has an inner side edge mounted in a corresponding one of the turbine bucket recesses (22). The inner side edge of each of at least half of the plurality of turbine blades (30) has a straight segment (32) and a rectangular strip (34). Each of the turbine blades (22) holding the turbine blade (30) with the straight segment (32) and the rectangular strip (34) has a bottom with a straight segment (222) and a strip hole (224).

Description

1. Field of the invention

The present invention relates to a pneumatic motor (pneumatic motor) and more particularly to a pneumatic motor for a pneumatic tool (pneumatic tool).

2. Description of the related art

An air motor is mounted in a pneumatic tool. When compressed air is directed into the air motor, the air motor rotates to drive a tool to rotate. Regarding 9 to 11 For example, a conventional air motor has a housing 50 , a wave 60 and a plurality of blades or turbine blades 70 on. The housing 50 has an inlet opening 51 and an exit opening 52 on. The inlet opening 51 is connected to a compressed air source. The wave 60 is rotatable in the housing 50 mounted and is eccentric to the housing 50 , The wave 60 has several turbine blade recesses 62 on that radially in the shaft 60 are defined. The turbine blades 70 are each movable in the blade or turbine blade recesses 62 the shaft mounted. When compressed air enters the housing via the inlet port 51 The turbine blades are guided 70 pushed by the compressed air to the shaft 60 to rotate to output a driving force to a tool.

However, every turbine bucket points 70 the conventional pneumatic motor has a curved side edge 72 on, leaving the floors 622 the turbine blade recesses 62 are also curved to the curved side edges 72 the turbine blades 70 correspond to. Therefore, the thickness of the shaft 60 at a position adjacent to an axis of the shaft 60 is, thin, but the section that is adjacent to the axis of the shaft 60 is, has to carry a big load while the shaft 60 pushed by the compressed air to rotate. Hence the wave 60 slightly damaged and the service life of the air motor is reduced. Accordingly, the conventional air motor normally has six turbine blades 70 on, leaving the case 50 in six air chambers through the turbine blades 70 is split. However, each air chamber has a large volume, and the amount of compressed air in each air chamber, around a corresponding turbine blade 70 to push is big.

Therefore, this will cause a drop in the use of the compressed air and the torque provided by the compressed air is also limited.

In addition, to increase the number of air chambers and increase the volume of each air chamber by increasing the number of turbine blades 70 to reduce what will cause the thickness of the shaft 60 at a position adjacent to the axis of the shaft 60 is, will be thinner. Therefore, the structural strength of the shaft 60 reduces and can not carry a large load, so that the conventional air motor is easily damaged and the service life of the conventional air motor is shortened.

To overcome the shortcomings, the present invention tends to provide a pneumatic motor to alleviate or avoid the aforementioned problems.

The main object of the invention is to provide a pneumatic motor which can increase the number of air chambers and has improved structural strength.

The air motor has a housing, a shaft and a plurality of blades or turbine blades (in short: turbine blades). The housing has an inlet opening and an outlet opening. The shaft is rotatably mounted in the housing and has a plurality of turbine blade recesses defined radially in the shaft. The turbine blades are correspondingly mounted and movable in the turbine bucket recesses in the shaft. Each turbine bucket has an inner side edge and an outer side edge. The inner side edge is mounted in a corresponding one of the turbine bucket recesses. The outer side edge is opposite to the inner side edge and extends out of the corresponding turbine blade recess. The inner side edge of each of at least half of the plurality of turbine blades has a straight segment and a rectangular strip. The straight segment is formed on the inner side edge. The rectangular strip is formed on a middle of the straight segment and protrudes from it. Each of the turbine bucket recesses holding the turbine blade with the straight segment and the rectangular strip has a bottom having a straight segment and a strip hole. The straight segment corresponds to the straight segment in position and shape. The strip hole has a rectangular cross-section, is defined at a center of the straight segment of the bottom of the turbine blade recess, and selectively retains the rectangular strip on the corresponding turbine blade.

Other objects, advantages and novel features of the invention will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings.

IN THE DRAWINGS

1 Fig. 12 is a perspective view of a compressed air motor in accordance with the present invention;

2 Fig. 11 is an exploded perspective view of a first embodiment of a pneumatic motor in accordance with the present invention;

3 is an enlarged cross-sectional end view of the air motor from 2 ;

4 Fig. 10 is an enlarged cross-sectional end view of a second embodiment of a pneumatic motor in accordance with the present invention;

5 is an enlarged cross-sectional side view of a shaft with turbine blades of the air motor 4 ;

6 is an enlarged cross-sectional end view of the shaft along the line 6-6 5 ;

7 is an enlarged cross-sectional end view of the shaft taken along the line 7-7 5 ;

8th Fig. 12 is a cross-sectional side view of a third embodiment of a shaft of a pneumatic motor in accordance with the present invention;

9 is an exploded perspective view of a conventional pneumatic motor;

10 is an enlarged cross-sectional side view of a shaft of the conventional pneumatic motor 9 ; and

11 is an enlarged cross-sectional end view of the conventional pneumatic motor 9 ,

Regarding 1 and 2 For example, an air motor in accordance with the present invention includes a housing 10 , a wave 20 and several turbine blades 30 on.

The housing 10 has an inlet opening 11 and an exit opening 12 on. The wave 20 is rotatable in the housing 10 mounted and can be coaxial or eccentric with respect to the housing 10 be. The wave 20 has several turbine blade recesses 22 on that radially in the shaft 20 are defined. The turbine blades 30 are movable in the turbine blade recesses 22 in the wave 20 assembled. Every turbine blade 30 has an inner side edge and an outer side edge. The inner side edge is in a corresponding one of the turbine blade recesses 22 assembled. The outer side edge is opposite the inner side edge and extends from the corresponding turbine blade recess 22 out. The inner side edge of each turbine blade 30 has a straight segment 32 and a rectangular strip 34 on. The straight segment 32 is formed on the inner side edge. The rectangular strip 34 is on a middle of the straight segment 32 formed and stands out from it. Preferably, the rectangular strip 34 a length less than one third of a length of the turbine blade 30 on which the rectangular strip 34 is formed. Each turbine bucket recess 22 has a bottom which is a straight segment 222 and a strip hole 224 having. The straight segment 222 corresponds to the straight segment 32 in position and shape. The strip hole 224 has a rectangular cross section, is in a middle of the straight segment 222 the bottom of the turbine bucket recess 22 formed and optionally holds the rectangular strip 34 the corresponding turbine blade 30 Inside.

Regarding 5 to 7 because the bottom of each turbine bucket recess 22 a straight segment 222 has, the shaft has 20 a sufficient thickness at a position adjacent to the axis of the shaft 20 is. Although the shaft has a thin thickness at a position corresponding to the strip hole, the shaft faces 20 still a sufficient thickness of positions on the two sides of the strip hole 224 correspond. Therefore, the shaft points 20 a sufficient structural strength, so that the number of turbine blade recesses 22 and the turbine blades 30 can be increased. Based on the inventor's experiment, the number of turbine blades 30 be increased to ten or twelve, as shown in 4 , Even if twelve turbine blades 30 are implemented, rejects the wave 20 still enough structural strength to carry a large load.

Accordingly, the number of air chambers in the housing 10 be increased so that the volume of compressed air in each chamber and discharged from the outlet 12 can be effectively reduced. The shaft may actually be pushed by the compressed air to rotate, and the torque provided by the air motor may be increased, and the operating efficiency of the air motor may be improved.

Regarding 8th has a part of the turbine bucket recesses 22 one floor each, which is a straight segment 222 and the other turbine blade recesses 22A have no bottom, which is a straight segment 222 and each has a curved bottom. Therefore, turbine blades can 30 with a straight segment 32 and turbine blades 30 with a curved inner side edge into the turbine bucket recesses 22 . 22A with or without a straight segment 222 be assembled to fit different operating requirements. Preferred is a number of the turbine blade recesses 22 that the straight segment 222 have half of the multiple turbine blade recesses 22 , The turbine blade recesses 22 that is a straight segment 222 and the turbine blade recesses 22A without the straight segment 222 are arranged in an alternating way.

Claims (7)

An air motor comprising: a housing ( 10 ); the one inlet opening ( 11 ) and an exit opening ( 12 ) having; a wave ( 20 ) rotatable in the housing ( 10 ) and a plurality of turbine blade recesses ( 22 ) which radially in the shaft ( 20 ) are defined; several turbine blades ( 30 ) movable in the turbine blade extensions ( 22 ) in the wave ( 20 ) are mounted, each turbine blade ( 30 ) has an inner side edge formed in a corresponding one of the turbine blade recesses ( 22 ) is mounted; an outer side edge, which is opposite to the inner side edge, and from the corresponding turbine blade recess ( 22 ), wherein the inner side edge of each of at least half of the plurality of turbine blades (FIGS. 30 ): a straight segment ( 32 ) formed on the inner side edge; and a rectangular strip ( 34 ) located on the middle of the straight segment ( 32 ) is formed and protrudes therefrom; each of the turbine blade recesses ( 22 ), which is a turbine blade ( 30 ) with the straight segment ( 32 ) and the rectangular strip ( 34 ) has a bottom comprising: a straight segment ( 222 ), which is the straight segment ( 32 ) in position and shape; and a strip hole ( 224 ), which has a rectangular cross-section which is located in a middle of the straight segment (FIG. 222 ) of the bottom of the turbine blade recess ( 22 ), and optionally a rectangular strip ( 34 ) on the corresponding turbine blade ( 30 ) holds inside. The air motor of claim 1, wherein more than six turbine blades ( 30 ) are implemented. The compressed air motor according to one of the preceding claims, wherein twelve turbine blades ( 30 ) are implemented. The pneumatic motor according to one of the preceding claims, wherein each rectangular strip ( 34 ) a length less than one third of a length of the turbine blade ( 30 ) on which the rectangular strip ( 34 ) is formed. The pneumatic motor according to any one of the preceding claims, wherein a number of the turbine blade recesses ( 22 ) with the straight segment ( 222 ) half of the multiple turbine blade recesses ( 22 ). The air motor according to claim 5, wherein the turbine blade recesses ( 22 ) with the straight segment ( 222 ) and the turbine blade recesses ( 22A ) without the straight segment ( 222 ) are arranged in an alternating manner. The air motor according to any one of the preceding claims, wherein each of the turbine blade recesses ( 22A ) without the straight segment ( 222 ) has a curved bottom; and the inner side of each of the turbine blades ( 30 ) without the straight segment ( 34 ) is curved.

Images