DE202010013938U1 - Hand tool with a designed as a handle housing - Google Patents

Abstract

A hand tool (10) having a housing (12) arranged as a handle for handling and a rotor (32) rotatably mounted in the housing (12), rotatably coupled to a tool holder (14) and adapted to be driven by a supply of compressed air to be, characterized in that the hand tool (10) has at least two mutually identical radial turbines (46, 48), which are arranged axially one behind the other and on a part of the rotor (32) within the housing (12) arranged as a handle part axial direction approximately in the middle of the housing (12), and that the housing (12) at a first, the tool holder (14) facing the end (15) is circular and there has a first, relatively smaller diameter, that it at a second, the tool holder (14) opposite end (20) is circular and there has a second, relatively larger diameter, that it from its first end (15) au going and tapering towards the second end (20) initially tapered, where ...

Description

The The present invention relates to a hand tool with a grip part for handling furnished housing according to the preamble of claim 1.

Such a hand tool is from the DE 201 03 600 U1 known and has a rotatably mounted in the housing rotor which is rotatably coupled to a tool holder and adapted to be driven by a supply of compressed air.

Of the Rotor is part of a radial turbine, which is a comparatively large Radius has and facing away from the tool holder end of the housing is arranged in the housing. The Tool holder protrudes from a front end of the hand tool out and is rotatably mounted in the front end.

The Housing has substantially circular cross-sections, their diameter over the length of the housing vary. Starting from the tool holder, the housing diameter increases first, to be sufficient inside the case To provide space for said storage. To the the storage surrounding housing part closes a middle housing part with a constant diameter at. This diameter is smaller than the housing diameter in the area of the front storage. Behind the middle area rises the diameter of the housing cross-section again in order to Inside to provide sufficient space for the radial turbine.

The Radial turbine is relatively large and therefore requires a correspondingly large housing diameter. The diameter is in particular so large that this housing section not very good as a handle for manual handling the known hand tool is suitable. He is taller too as the diameter of the housing in the area of the front Storage. For this reason, this housing section arranged with the radial turbine behind the middle handle part, that is therefore between the tool holder and the radial turbine extends. This complicates the handling of the known hand tool, because of the comparatively thick housing section with the radial turbine with a comparatively large lever arm on the tool tip attacks what the well-known hand tool so to speak top-heavy power.

In front In this background, the object of the invention in the specification a hand tool of the type mentioned, which is characterized by a characterized improved handling.

These The object is achieved with the features of claim 1. Compared with the known hand tool mentioned above the hand tool according to the invention thereby from that there are at least two identical radial turbines comprising axially one behind the other and on a part of the rotor are arranged, which is set up within the handle part Housing in the axial direction approximately in the middle of the housing lies, and that the housing at a first, a tool holder facing end is circular and there a first, comparatively smaller diameter has that on a second, the tool holder opposite end is circular and there is a second, has comparatively larger diameter, that it is starting from its first end and the second At the end tapering first tapered, being Cross-section of the circular shape merges into a first rounded triangular shape, that it is starting from its second end and the first At the end tapering first tapered, being Cross section of the circular shape merges into a second rounded triangular shape, their cross-sectional area on further run on the first end initially slightly larger and then continuously decreasing to even more on the first end the surface formed by the first triangular shape for penetrate, and that the first triangular shape opposite the second triangular shape is rotated by 60 °.

Thereby, that at least two mutually identical radial turbines used whose diameter can be made smaller than the diameter of a single turbine, as in the known Hand tool is used. The housing can then in particular be designed slimmer. The possibility of the radius to shrink down, it results from the fact that each one of the two smaller radial turbines only about half of the torque must produce, in the known hand tool by the individual and sole radial turbine is generated. The same applies if more than n = 2 mutually equal radial turbines are used.

The reduction of the radius of the turbine allows an arrangement of the drive in the axially middle region of the housing designed as a handle part. As a result, the top-heavy arrangement of the drive and a large single turbine surrounding and correspondingly large and heavy housing is avoided. The middle part of the housing is used several times, namely as a housing for the at least two turbines and as a handle part. Due to this multiple use, the housing can be shorter overall, which is advantageous for handling. This advantage results from the fact that the tool itself acts as a lever with which the weight of the compressed air hose pulls at the pressure connection. This forms in the tool holder 14 clamped tool to a certain extent the point at which the lever attacks. The shorter the tool, the shorter the lever and the lower are the disturbances emanating from the weight of the compressed air hose.

By the remaining features of claim 1 is a housing defines its ergonomic shape and dimensions on the one hand allow handling of the hand tool in a pen holder and which moreover allow handling in which the hand tool between the palm and the four fingers One hand lies and the thumb of the hand is ergonomically favorable the front of the case against the index finger suppressed. Just this handling would be in the known Hand tool ergonomically rather unfavorable because of its large Turbine radius would disturb here.

In the sum results from these features a much improved Handling.

Further Advantages result from the dependent claims, the description and the attached figures.

It it is understood that the above and the following yet to be explained features not only in each case specified combination, but also in other combinations or can be used in isolation, without the scope of the present To leave invention.

drawings

embodiments The invention are illustrated in the drawings and in the following description. Show, in schematic form:

1 An embodiment of a hand tool according to the invention;

2 a side view of a housing of the hand tool together with eight housing cross-sections;

3 a longitudinal section through the hand tool 10 ;

4 a perspective view of a control sleeve;

5 a plan view of the front end of the control sleeve;

6 a longitudinal section through the control sleeve;

7 a cross section through the control sleeve;

8th an embodiment of a brake;

9 another view of the subject of 8th ; and

10 Control Angle Angle Curves of the Control Sleeve.

In detail, the shows 1 An embodiment of a hand tool according to the invention 10 , The hand tool 10 has a designed as a handle part housing 12 on, from the front end of a tool holder 14 protrudes. The tool holder 14 is rotatably connected to a rotor in the housing 12 is rotatably mounted and can be driven by a pressurized fluid. Compressed air is in particular compressed air in question. The compressed air becomes the hand tool 10 via a connection part 16 fed, which has a valve for controlling the compressed air supply. The actuation of the valve via a rotatable control sleeve 18 at a rear end 20 of the housing 12 between the case 12 and the connector 16 is arranged. The control sleeve 18 has a front end 22 and a back end 24 on.

2 shows a side view of the housing 12 along with eight cross sections AA to HH. The housing 12 is at its the tool holder 14 facing first page 15 circular and also at its the tool holder 14 opposite second end 20 circular.

The section AA represents the cross section of the first end 15 and section HH represents the cross section of the second end 20 dar. The diameter of the housing 12 at the second end 20 is larger than the diameter of the housing 12 at its first end 15 , In a preferred embodiment, the diameter of the housing is at its first end 15 20 mm to 25 mm and at its second end 20 25 mm to 35 mm with a length of the housing 12 from 80 mm to 120 mm.

From his first end 15 starting and on the second end 20 tapering, the housing tapers 12 first. This is from the transition from section AA to section BB in the side view of the housing 12 in the 2 seen. The cross section BB shows that the shape of the cross section thereby goes from a circular shape to a first, strongly rounded triangular shape. The points marked with h at the periphery of the cross section BB correspond to the comparatively farther away from the midpoint M corners, while the ge with t ge marked points on the circumference correspond to the comparatively closer to the midpoint M lying points between the corners. The points t in each case halve the edge of the rounded triangle lying between two corner points h.

From his second end 20 starting and on the first end 15 tapering towards the cross section of the housing tapers 12 and goes into a rounded circular shape, as shown in section GG and, somewhat more pronounced, in section FF. Again, the comparatively far from the center on the longitudinal axis 86 of the hand tool 10 points at the circumference of the cross section FF are marked with h, while the points of the circumference of the cross section FF that lie closest to the center M are denoted by t. The points h represent the corners of the rounded triangle profile. The points t in each case halve the edge of the rounded triangle lying between two corner points h.

On further, from the cross section FF on the first end 15 In addition, the cross-sectional area of the rounded second triangular shape initially again slightly larger or remains at least the same size. In the 2 this is the result of a comparison of the cross sections FF and EE, which are virtually identical within the framework of the accuracy of the drawing.

On further running towards the first end 15 down to the cross-sectional area of the rounded second triangular shape is then continuously smaller, as in the 2 is illustrated by the transition from the cross section EE on the cross section DD.

The continuous reduction of the cross section of the second triangular shape also stops beyond the cross section DD, so that the second triangular shape still continues to run towards the first end 15 towards the first triangular shape (see section BB) penetrates. The penetration results in a penetration line 17 where the two rounded triangular shapes merge. The cross section CC lies in the region of this penetration and has the cross section of a rounded hexagon. This shape results from the fact that the first triangular shape is rotated by 60 ° with respect to the second triangular shape. The indication of this angle of rotation refers to the longitudinal axis 86 as a rotation axis, or on the center M as a fulcrum. The line 19 marks an elevated area, in which the corner points of the rounded triangular shapes lie in particular.

This shape of the housing is the hand tool 10 suitable to be held in one hand, wherein the front end can be held in particular like a pen. This will make a very fine work with the hand tool 10 allows.

The following is with reference to the 3 an embodiment of an internal structure of the train of crafts 10 explained, which allows the presented here slim case shape.

3 shows a longitudinal section through the hand tool 10 , In the illustrated embodiment, the housing 12 an inner sleeve 28 and an outer sleeve 30 on, which fit together perfectly and are firmly connected. The inner sleeve 28 is preferably made of metal, in particular a light metal such as aluminum and gives the housing 12 the required strength. The outer sleeve 30 preferably consists of one compared to the metal of the inner sleeve 28 poor heat conductive plastic.

This has the advantage that when relaxing the compressed air in the hand tool 10 occurring cooling during manual handling does not cause a disturbing cooling of the gripping surface of the outer sleeve 30 leads. This is perceived as an advantage during handling.

The execution of the inner sleeve of light metal holds the weight of the hand tool 10 low, which also contributes to a good handling and fatigue-free work, especially in fine work and therefore is also perceived as an advantage in handling.

In the inner sleeve 28 is a rotor 32 rotatable in bearings 34 . 36 stored. The rotor 32 is at its end, from the front end 15 of the housing 12 protrudes, rotatably with a tool holder 14 connected. The tool holder is in one embodiment, a collet 38 using a pliers spindle 40 with the rotor 32 connected is. The other end of the rotor 32 is as a hollow spindle 42 designed, whose central cavity 44 with the compressed air valve open 45 and to the connection part 16 connected compressed air supply is pneumatically connected to the compressed air supply.

On an outer surface of the spindle 42 are preferably n mutually equal radial turbine modules 46 . 48 . 50 . 52 arranged, where n may be greater than or equal to two or in principle any number greater than 1. In a preferred embodiment, n is less than or equal to eight. Particularly preferred is an embodiment with n = 4 radial turbines. By the successive arrangement of n radial turbines, which have a comparatively small diameter, the same torque can be generated, as by a single radial turbine, which has a comparatively large diameter. A hand tool with a single radial turbine with a comparatively large diameter is from the aforementioned DE 201 03 600 U1 known.

The preferred series arrangement allows the housing 12 To perform much slimmer than this in the subject of DE 201 03 600 U1 the case is.

The series connection thus improves in particular the handling and unfolds in particular together with the housing 12 relevant features of claim 1 a combinatorial effect in relation to the desired improvement in handling.

Further improvements in the handling result from a special embodiment of the control sleeve 18 , Before an explanation of the control sleeve 18 At first, further elements of the drive of the hand tool are described.

The radial turbines 46 . 48 . 50 . 52 be over in the axial direction along the spindle 42 staggered openings 54 . 56 . 58 . 60 from the cavity 44 the spindle 42 flowed in from inside with compressed air. In this case, three openings are preferably provided for each module of the radial turbine, which are uniform over the circumference of the portion of the spindle 42 distributed within the respective radial turbine module are distributed. After flowing through the radial turbines, the expanded air escapes radially outward, from where it passes through a silencer 62 having exhaust air duct 64 from the hand tool 10 flows. The radial turbines 46 . 48 . 50 . 52 are non-rotatable with the spindle 42 of the rotor 32 coupled and therefore drive the rotor 32 at. In the illustrated embodiment, the rotationally fixed coupling takes place by axial clamping of the radial turbines 46 . 48 . 50 . 52 with the spindle 42 through a clamping nut 66 ,

In operation, the turbine speeds can reach min ^-1 in an order of 100 000th When switching off the compressed air supply, it then continues to run for, for example, about 30 seconds. This results in a safety and injury risk during handling. To reduce these risks, points the hand tool 10 a brake on that in the 3 as a pairing of a friction plate 68 and a printing plate 70 is partially visible and will be explained in more detail below.

The compressed air valve 45 is in the illustrated embodiment, a ball valve with a ball 72 made of an elastic element 74 , For example, a spring, on a circular feed opening of a compressed air channel 76 is pressed to close this opening. The compressed air channel 76 is preferably a central channel in a valve body 77 , To open the valve 45 is a valve pin 78 intended. The valve pin 78 points one of the ball 72 facing first end 80 and a second end 82 on, in one as a valve guide track 84 shaped recess in the inner surface of the control sleeve 18 to be led.

The valve pin 78 itself becomes substantially radial in a guide within the valve body 77 guided. In relation to a longitudinal axis 86 of the hand tool 10 is the distance of that control surface of the valve guide path 84 that the second end 82 of the valve pin 78 facing, from the longitudinal axis 86 of the hand tool from the angle of rotation of the control sleeve 18 dependent. This means that the inward and outward movement of the valve pin 78 by turning the control sleeve 18 is controllable.

3 shows a closed position of the valve 45 , To open the valve 45 becomes the control sleeve 18 around the axis 86 twisted around. Due to the design of the guideway 84 will be the valve pin 78 initially radially inward against the ball 72 pressed. When turning the control sleeve further 18 pushes the valve pin 78 the ball 72 then laterally (ie in the 3 upward) out of the closed position, so that compressed air via the central air inlet 26 at the ball 72 over in the compressed air channel 78 can flow.

4 shows a perspective view of a control sleeve 18 , The control sleeve 18 has recesses distributed over its outer circumference 88 on, which facilitate the adhesion in a manual operation and thus also contribute to improved handling.

Inside the control sleeve 18 is the already mentioned, realized as a recess valve guide track 84 for the valve pin 78 , The axially extending recess 90 opens the valve guide track 84 to the front end 22 the control sleeve 18 and thus allows an axial relative movement between the valve pin 78 and the control sleeve 18 during assembly and / or disassembly of the hand tool 10 , In addition, the control sleeve 18 two to their front end 22 towards open brake pin guide tracks 92 . 94 on, also as depressions in the inner surface of the control sleeve 18 are realized.

5 shows a plan view of the front end 22 the control sleeve 18 and serves primarily to clarify the position of the longitudinal section, which in the 6 is shown. 6 clarifies in particular the position of the cross section, which in the 7 is shown. The 5 and 7 are mirror images to each other. In the drawing plane of the 5 in particular, the brake pin guide tracks are 92 . 94 , In the drawing plane of the 7 in particular, the valve guideway lies 84 , A comparison of these 5 and 7 shows in particular that the operation of the brake and the operation of the compressed air valve 45 takes place in parallel, wherein the control and Absteuerung the compressed air supply over a further rotation angle range away takes place as a releasing and / or braking operation of the brake.

8th shows in schematic form an embodiment of a brake, as in connection with the hand tool according to the invention 10 through the control sleeve 18 is pressed. The brake points for each brake pin guide track 92 . 94 the control sleeve 18 a brake pin 96 on that in the valve body 77 substantially perpendicular to the longitudinal axis 86 of the hand tool 10 is movably guided. For this purpose, the valve body 77 guides 98 on, in which the brake pins are guided translationally displaceable.

The brake pin 96 has one of the control sleeve 18 facing end and one of the control sleeve 18 opposite end 102 on. At this end 102 points the brake pin 96 a sloping plane 104 on. A substantially coaxial with the longitudinal axis 86 of the hand tool 10 lying brake axle 105 has a recess with an inclined plane 106 on. The inclined planes 104 of the brake pin 96 and the brake axle 105 have the same inclination and are arranged and arranged to slide on each other. When opening twisting the control sleeve 18 becomes the brake pin 96 in the 8th pressed down and pushes through the inclined planes 104 and 106 the brake axle 105 to the right. This will create a pressure plate 108 through the action of brake springs 110 from a friction plate 112 lifted off, with the rotor 32 rotatably coupled. This releases the brake.

Conversely, the brake is activated when the control sleeve 18 is rotated in a direction abscuding the compressed air supply and thus closing direction. In this case, the brake pin slides 96 in the 8th upwards and allows the brake springs 110 , the pressure plate 108 against the friction lining 112 to squeeze. The brake is thus realized as a spring brake in which the braking force is applied by springs and is released against the force of the springs. This has the advantage that when closing the control sleeve 18 is automatically braked, even if the control sleeve is closed 18 no manual force is applied anymore.

A manual hold the brake is therefore not required. This also improves the handling and the reliability. On the other hand, the brake springs also cause no automatic adjustment of the control sleeve 18 because the reaction forces of the springs 110 not sufficient to the self-locking frictional forces in the operation of the control sleeve 18 to overcome.

9 shows the subject of the 8th in one around the longitudinal axis 86 rotated by 90 °. Due to the two offset by 180 ° brake axes tilting when operating the brake is effectively prevented. In addition, the offset of the brake axes by 180 ° has the advantage that the brake axes can be distributed around the circumference, so that the central compressed air supply to the rotor can be maintained. Bolts 92 and 94 are preferably mounted so that they move in an anti-parallel operation: The bolt 96 is perpendicular to the drawing plane, while the bolt 100 hanging vertically below the drawing plane.

The 10 shows for a preferred embodiment of a control sleeve 18 the way 114 a brake axle 105 in millimeters, plotted over the angle of rotation of the control sleeve 18 in degrees. The curve 116 shows the way of the valve pin 78 of the compressed air valve 45 also depending on the angle of rotation of the control sleeve 18 in degrees. The 10 shows in particular that the rotatable control sleeve 18 is configured to control the brake and the pressure fluid supply coordinated so that the compressed air valve 45 is triggered in parallel with a release of the brake, and wherein a brake displacement-rotational angle characteristic curve 114 the control sleeve 18 in a first rotation angle range, located in the 10 extends approximately to the angle 32 °, is steeper than in a second, further from the closed position remote rotation angle range. The closed position corresponds to the subject of 10 the angle of rotation 0 of the control sleeve 18 , The second rotation angle range is the range between about 32 and about 110 °, in which the characteristic 114 not only less steep, but in the case shown even without incline runs. The course of the characteristic 116 shows how the entire twist angle range from 0 ° to 110 ° of the control sleeve 18 is used to regulate the compressed air supply. This results in the already mentioned improved meterability. The realization of the actuating element as a rotary sleeve has the advantage that a rotational movement for the adjustment of the hand tool mentioned above is subjectively perceived as ergonomic. The interaction of adjusting torque and the torque of the hand tool causes in the rotatable control sleeve with respect to the sliding sleeve better and more sensitive haptic feedback, as superimposed on the manually applied adjusting torque with a resulting torque change of the hand tool. The better haptic feedback improves in particular the Controllability of small changes in drive power, which improves handling by improving the dosing.

The parallel to the release of the brake taking place controlling the Compressed air supply allows expansion of the adjustment of the actuator at the dosage of the compressed air supply, which is also an improvement the meterability and thus the handling leads.

Thereby, that is a brake displacement-rotational angle characteristic of the control sleeve in a first rotation angle range near the closed position the control sleeve is steeper than in a second, further from the closed position remote rotation angle range, is a quick disconnection of the brake during opening and closing a late closing of the brake Absteuern the compressed air supply ensured. Due to the steeper course the brake is opened when the compressed air supply is activated early and fast, that is over one only small rotation angle range of the sleeve away. Analogous Closing the brake is late and fast. Overall, this is despite the parallel operation of the valve and brake under the influence of a pneumatic drive Successful rubbing of the friction surfaces of the brake largely avoid, so that an improved metering of the compressed air supply not at the expense of the service life of the brake.

A preferred embodiment is characterized in that the control sleeve is set up, a control and Absteuerung the compressed air supply via to make a larger angle of rotation range as a release and actuation of the brake. The control in particular takes place via a further rotation the control sleeve beyond a rotation angle, where the brake is already completely released is. This on the one hand avoids that large torques in case of not yet completely released brake effective be, leading to premature wear of the brake could lead. On the other hand, there is the advantage that a large rotation angle for up and down control the compressed air supply is available, which is the one aspect improves the handling formability dosing.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 20103600 U1 [0002, 0039, 0040]

Claims (10)

Hand tool ( 10 ) with a housing designed as a handle for handling ( 12 ) and one in the housing ( 12 ) rotatably mounted rotor ( 32 ), which rotatably with a tool holder ( 14 ) and is adapted to be driven by a supply of compressed air, characterized in that the hand tool ( 10 ) at least two mutually identical radial turbines ( 46 . 48 ) axially one behind the other and on a part of the rotor ( 32 ) are arranged, which within the housing designed as a handle ( 12 ) in the axial direction approximately in the middle of the housing ( 12 ), and that the housing ( 12 ) at a first, the tool holder ( 14 ) facing end ( 15 ) is circular and there has a first, relatively smaller diameter, that it at a second, the tool holder ( 14 ) opposite end ( 20 ) is circular and there has a second, relatively larger diameter, that it is from its first end ( 15 ) and to the second end ( 20 ) tapered first, wherein its cross section of the circular shape merges into a first rounded triangular shape that it is from its second end ( 20 ) and to the first end ( 15 tapered at first tapering, wherein its cross section of the circular shape merges into a second rounded triangular shape, the cross-sectional area on further running towards the first end ( 15 ) is initially slightly larger and then continuously smaller, in order to continue at the first end ( 15 ) penetrate the surface formed by the first triangular shape, and that the first triangular shape is rotated by 60 ° with respect to the second triangular shape. Hand tool ( 10 ) according to claim 1, characterized in that the diameter of the housing ( 12 ) at its first end ( 15 ) 20 mm to 25 mm and at its second end ( 20 ) 25 mm to 35 mm at a length of the housing ( 12 ) from 80 mm to 120 mm. Hand tool ( 10 ) according to one of the preceding claims, characterized in that the housing ( 12 ) an inner sleeve ( 28 ), which consists of metal. Hand tool ( 10 ) according to claim 3, characterized in that the housing ( 12 ) an outer sleeve ( 30 ), which consists of one compared to the metal of the inner sleeve ( 28 ) is poor heat conductive plastic. Hand tool ( 10 ) according to one of the preceding claims, characterized in that the hand tool ( 10 ) n successively arranged radial turbines ( 46 . 48 . 50 . 52 ), where n is greater than or equal to two and less than or equal to eight, in particular equal to four. Hand tool ( 10 ) according to one of the preceding claims, characterized by a device arranged to control the supply of compressed air and a brake and about a longitudinal axis ( 86 ) of the hand tool ( 10 ) rotatable control sleeve ( 18 ). Hand tool ( 10 ) according to claim 6, characterized in that the control sleeve ( 18 ) recesses distributed over its outer circumference ( 88 ), which are adapted to facilitate the adhesion in a manual operation. Hand tool ( 10 ) according to one of claims 6 or 7, characterized in that the control sleeve ( 18 ) is adapted to the brake and a compressed air valve ( 45 ) in parallel, whereby a control and Absteuerung the compressed air supply via an actuation of the compressed air valve ( 45 ) and over a further range of rotation angle takes place as a releasing and / or braking operation of the brake. Hand tool ( 10 ) according to claim 8, characterized in that the control sleeve ( 18 ) is set up to control a compressed air supply beyond a rotation angle, in which the brake is already completely dissolved. Hand tool ( 10 ) according to one of the preceding claims, characterized in that the hand tool has a spring-loaded brake.