CN101378867A - Tool chuck with sliding sleeve and chuck mechanism - Google Patents

Abstract

A tool chuck may include a chuck body defining a longitudinal axis. A sleeve may be mounted on the chuck body for movement between a first axial position in which the chuck body is rotatable together with the sleeve, and a second axial position in which the chuck body is rotatable relative to the sleeve to actuate to the tool chuck. The chuck body may be rotatable in a first direction to actuate the tool chuck up to a first torque threshold, and rotatable in a second direction to actuate the tool chuck up to a second, different torque threshold.

Description

Tool chuck with sliding sleeve and chuck mechanism

Enjoy by Richard C.NICKELS according to 35 U.S.C. § 119 (e) the application requests, JR. wait that the people submitted on April 18th, 2005, name to be called the U.S. Provisional Patent Application No.60/672 of " TOOL CHUCK WITH SLIDINGSLEEVE AND CHUCK MECHANISM ", 076 priority, the content of this application will all comprise in this application as a reference.

The application is involved on September 24th, 2004 by Nickels, Jr. the name that waits the people to submit to is called the U.S. Provisional Application No.60/612 of " TOOL CHUCK WITH SLIDING SLEEVE AND CHUCK MECHANI SM TOREMOVE OPERATOR VARIABILITY ", while pending trial, 789.The full content of the provisional application of application number is ' 789 is in this application involved as a reference.

Technical field

Generally speaking, the present invention relates to be used for annex is connected to tool chuck (tool chuck) on the power transmission machine (power driver).

Background technology

Open and the multiple tool chuck that draws the tool chuck pawl in is developed by relatively rotating between the tool chuck parts.In some applications, tool chuck can comprise that available hand rotates (having or do not have the chuck key) and opens and draw in the sleeve pipe of chuck jaws.In other were used, the power that can be used to the ultromotivity driver opened and draws chuck jaws in.For example, tool chuck can be provided with sleeve pipe, and this sleeve pipe can move axially to the position that sleeve pipe is touched the housing of { ground (that is, being fixed rotationally) } power transmission machine.Therefore, when the driver power consumption increased (power up), the axle of driver (therefore chuck body is also arranged) can be rotated with respect to sleeve pipe.Relatively rotating expansible and drawing chuck jaws between axle and the sleeve pipe.

Traditional no key-shaped tool chuck is not impeccable.For example, the torque that tightens or unclamp that is applied in the chuck actuation process may change with the factors such as stability of handling sleeve pipe as operating personnel.On the one hand, if the operator handles sleeve pipe with bigger power, in the chuck actuation process, be applied with bigger torque so.On the other hand, if the operator handles sleeve pipe with less power, in the chuck actuation process, then be applied with less torque so.

The inconsistent tool chuck that may occur of the torque that applies tightens inadequately and tightens problems such as tension.If tool chuck tightens inadequately, annex can be with respect to tool chuck slippage (slip) (even inadvertently dropping from tool chuck).If tool chuck is excessively tightened, the back off tool chuck may be very difficult to take out annex.In addition, when chuck jaws touches (bottom out) annex (when tightening) or when chuck jaws reaches mobile greatest limit (when unclamping), the danger of high-speed impact may take place between the actuated element of power transmission machine.In traditional electric tool or other electric devices, because the torque that applies in the chuck actuation process can not be restricted, such high-speed impact may damage actuated element.

Summary of the invention

In an instantiation, tool chuck can comprise the chuck body that supports chuck jaws.Sleeve pipe can be installed on the chuck body so that can rotate so that move between second axial location of actuation tool chuck with respect to sleeve pipe in first axial location and (2) chuck body that (1) chuck body can be rotated with sleeve pipe.When sleeve pipe was in second axial location, (1) chuck body can be rotated in a first direction with the actuation tool chuck up to reaching first torque threshold, and (2) chuck body can be rotated in a second direction, with actuation tool chuck to the second, different torque threshold.

In another instantiation, tool chuck can comprise chuck body.Sleeve pipe can be installed on the chuck body so that between first axial location and second axial location, move.The first clutch device part that sleeve pipe can comprise when sleeve pipe is in second axial location and the second clutch device partly meshes.When applying first torque threshold first clutch part along first direction with respect to the slippage of second clutch part, when applying second torque threshold first clutch part along second direction with respect to the slippage of second clutch part.The size of first torque threshold and second torque threshold can be different.

In another instantiation, tool chuck can comprise the chuck body that limits longitudinal axis.Sleeve pipe can be installed on the chuck body so that between first axial location and second axial location, move.Sleeve pipe can comprise when sleeve pipe during along second axial location can with the clutch part of synergistic clutch part engagement.Clutch part can have towards the working face perpendicular to the longitudinal axis direction.

In an instantiation again, the tool chuck of power transmission machine can comprise chuck body and clutch ring.Clutch ring can be activated so that the engagement of control tool motor or disengagement and annex is kept and/or break away from by tool-user.

In another instantiation, tool chuck can comprise chuck body and the chuck jaws that limits longitudinal axis.Sleeve pipe can be fixedly mounted on the chuck body.Tool chuck can comprise clutch mechanism, and this mechanism is applicable to the cover that advance the puck vertically is fixed with engagement and prevents inadvertently unclamping or tightening of chuck jaws.

In another instantiation, tool chuck can comprise chuck body and the chuck jaws that limits longitudinal axis.Sleeve pipe can be fixedly mounted on the chuck body.Tool chuck can comprise the clutch mechanism with one or more clutch part.In case tool chuck is tightened, the first clutch of first sleeve pipe part partly breaks away from the second clutch of second sleeve pipe, forces the rear portion propelling of first sleeve pipe to the chuck body previous dynasty.The rear portion of chuck body can comprise the sunk part of the lock pin part forward that is used to receive the first clutch part, with and the lock pin part chimeric and prevent relative motion between first sleeve pipe and the chuck body.

In an instantiation again, the tool chuck with instrument of instrument motor can comprise chuck body, chuck jaws and be installed in the sleeve pipe that the brake function of the actuator that loads according to axle spring on the chuck body moves between first axial location and second axial location.Actuator can activate under user's manipulation, thereby the operation tool motor unclamps or the chuck jaws of tightening tool chuck.

Description of drawings

By more fully understanding the present invention to the detailed description that instantiations more of the present invention carry out below in conjunction with accompanying drawing, similar elements is represented by similar Reference numeral in the accompanying drawing, to provide these examples only in order illustrating, to the invention is not restricted to these instantiations.

Fig. 1 is the schematic diagram that is not subjected to a tool chuck of concrete form restriction of the present invention;

Fig. 2-4 is for being provided to the schematic diagram of the clutch mechanism example in the tool chuck shown in Figure 1;

Fig. 5 is the schematic diagram that is not subjected to another tool chuck example of concrete form restriction of the present invention;

Fig. 6 is for being installed on the decomposition diagram of the building block example on the device housing shown in Figure 5;

Fig. 7-9 is for being provided to the schematic diagram of the clutch mechanism example in the tool chuck shown in Figure 5;

Figure 10 is the partial schematic diagram that is not subjected to the another tool chuck example of concrete form restriction of the present invention;

Figure 11 and 12 is for being provided to the schematic diagram of the clutch mechanism example in the tool chuck shown in Figure 10;

Figure 13 is the decomposition diagram of the building block example of tool chuck shown in Figure 10;

Figure 14 and 15 is for being provided to the schematic diagram of the clutch mechanism example in the tool chuck shown in Figure 10;

Figure 16 is the schematic diagram that is applicable to as the clutch ring mechanism of user's interface of the power drill main drive motor that is used to control annex maintenance/disengaging;

Figure 17 A and 17B are the schematic diagram that is used for a clutch mechanism example of a tool chuck example;

Figure 18 A and 18B show the locking mechanism of the tool chuck of the present invention's one instantiation;

Figure 19 shows a tool chuck example that is used for to the present invention's one instantiation the constant spring loaded actuator that tightens is provided.

The specific embodiment

I. the instantiation shown in Fig. 1-4

Fig. 1 shows and does not change operating personnel and by a unrestriced instantiation of the tool chuck 50 of uniform torque actuated.Tool chuck 50 can be arranged on (for example, drilling machine) on the power transmission machine, is used for clamping annex (for example, drill bit).Certainly, what can expect is, tool chuck 50 can be provided in to be used for the various annexes of clamping (except that drill bit) on the various power transmission machines (except that drilling machine).

A. the structure of example

With reference to figure 1, tool chuck 50 can comprise chuck body 20.The rear end of chuck body 20 can be fixedly mounted on the axle 85 of power transmission machine.The front end of chuck body 20 can have the passage that supports a plurality of chuck jaws 2 slidably.Chuck jaws 2 tiltables, the front end that causes each chuck jaws 2 converges towards the axis 10 of chuck body 2.Chuck jaws 2 can have the end-face helical (facing threads) 3 of radial outward respectively.For the sake of clarity, only show a chuck jaws 2 among Fig. 1.

In this instantiation, the feature of chuck jaws 2 is " threaded " chuck jaws.That is to say that the end-face helical 3 of chuck jaws 2 by radial outward activated (that is, advancing and/or retraction) with the interaction of the end-face helical 18 of the radial inward of nut 16.But these instantiations of the present invention are not limited to this structure.For example, can be equipped with " pusher (pusher) " pawl and support these pawls by chuck body.Pusher pawl is well-known to this area, therefore, and for for simplicity, in the detailed description of this omission to the pusher pawl.Can in instantiation of the present invention, be equipped with various types of by the chuck jaws of opening and drawing in that relatively rotates between the tool chuck parts (for example, nut and chuck body).

Chuck body 20 can support anterior cannula 30 and rear sleeve 40.Anterior cannula 30 and rear sleeve 40 can relatively rotate each other.As described in greater detail, clutch mechanism (comprising two synergistic clutch part 32,42) can be arranged between anterior cannula 30 and the rear sleeve 40.Clutch mechanism can lock together anterior cannula 30 and rear sleeve 40 up to reaching given torque threshold rotationally.In case reach given torque threshold, clutch mechanism can get out of the way the torque that (giveway) or slippage (slip) are applied with restriction in the chuck actuation process.In addition, clutch mechanism can be designed so that to be used for the given threshold value of tightening tool chuck less than the given threshold value that is used for the back off tool chuck.

Anterior cannula 30 can be supported to and it is axially fixed on the chuck body 20 and can rotates relative to chuck body 20.Anterior cannula 30 can have nut 16 regularly.In this instantiation, anterior cannula 30 and nut 16 can be independently with visibly different element so that the assembling of tool chuck 50.Certainly, what can expect is that anterior cannula 30 and nut 16 can be whole single type structures.The rear end of anterior cannula 30 can comprise clutch part 32.

Rear sleeve 40 can be supported to make its with respect to chuck body 20 (so also with respect to anterior cannula 30) shown in Figure 1 axially forward the position and axially carry out axially-movable between backwards the position.Rear sleeve 40 also can rotate with respect to chuck body 20.The front end of rear sleeve 40 can comprise clutch part 42.Clutch part 42 can interact with the clutch part 32 of anterior cannula 30.The rear end of rear sleeve 40 can comprise flange 44.Flange 44 interacts with the synergistic flange 92 of power transmission machine housing 90.

Compression spring 25 can be trapped between anterior cannula 30 and the rear sleeve 40.Compression spring 25 can apply effect to rear sleeve 40 makes it arrive axial position forward shown in Figure 1.

B. the clutch mechanism of example

Make the structure of clutch mechanism and effect more apparent by means of 2-4 with reference to the accompanying drawings, these accompanying drawings are the fragmentary cross-sectional views (dissecing perpendicular to axis 10) that are provided to the unrestriced instantiation of the synergistic clutch part in the tool chuck shown in Figure 1 50.Illustrated among Fig. 2-4 and be in axially the rear sleeve of position backwards, caused clutch part to mesh with being operated.In this case, clutch part can be positioned at the position of the radial inward of another clutch part.

Synergistic clutch part can comprise the corresponding work face.In this manual, term " working face " is meant the surface with the clutch part of the working face friction engagement of synergistic clutch part.In Fig. 2-4, the working face of described clutch part can be towards the direction perpendicular to the axis 10 of tool chuck.That is, shown in Fig. 2-4, the working face of a plurality of clutch part can towards with the parallel plane direction of drawing, and axis 10 is perpendicular to the plane of drawing.

B (1). the clutch mechanism of example shown in Figure 2

As shown in Figure 2, the clutch part of anterior cannula 30 ' can be the form of arm 32 ', and the clutch part of rear sleeve 40 ' can be the form of lock pawl 42 '.Arm 32 ' can be installed on the anterior cannula 30 ' by pin 33, makes arm 32 ' to pivot around pin 33.Anterior cannula 30 ' also can comprise and is positioned at two shoulders 34,35 of arm 32 ' side and restricted arm 32 ' around the pivotal action of pin 33.

In the chuck actuation process, (hereinafter be also referred to as " chuck actuation patterns " once in a while), when tool chuck 50 does not open fully or draws in (for example, chuck jaws still open or when drawing in), arm 32 ' can be posted by on the lock pawl 42 ', lock pawl acts on arm 32 ' successively so that it pivots and one of in the shoulder 34,35 around pin 33.At this moment, anterior cannula 30 ' and rear sleeve 40 ' lock together rotationally.When tool chuck drew (annex that is equipped with or does not have dress to insert) fully in or opens fully, the rotatory force that is applied to lock pawl 42 ' by arm 32 ' increased.At this, rotatory force rises to and can make the radially threshold value of direction transmission outwardly (causing rear sleeve 40 ' strain) of lock pawl 42 ', thereby arm 32 ' can be slided (slide) below and process lock pawl 42 '.In this case, clutch mechanism can get out of the way (or slippage), can limit the torque that is applied in the chuck actuation process whereby.

Radially the direction big I that drives the required rotatory force of lock pawl 42 ' is subjected to for example to make the influence of the working face of the elastic performance of material of rear sleeve 40 ' and arm 32 ' with respect to inclination (or crooked) degree of the radially reference line R that extends from axis 10 outwardly.Suppose that working face tilts, working face the and radially angle between the reference line R is more little makes the required rotatory force of clutch mechanism slippage then big more.In other words, working face is precipitous more with respect to circumference reference line (its with radially reference line R is vertical), then makes the required rotatory force of clutch mechanism slippage big more.

As shown in Figure 2, the shoulder 34 of anterior cannula 30 ' can be higher than (radially) shoulder 35.Therefore, compare with shoulder 34, shoulder 35 can allow arm 32 ' to be pivoted to the radially farther degree (that is, by bigger angular displacement) of reference line R of distance around pin 33.Therefore, when arm 32 ' reclines shoulder 35 (as shown in Figure 2), the inclination of the working face of arm 32 ' (with respect to reference line R radially) degree is bigger than the inclined degree when arm 32 ' reclines shoulder 34.In this mode, cause that clutch mechanism along the first direction slippage (promptly, as shown in Figure 2, when lock pawl 42 ' slips over the arm 32 ' of the shoulder 35 that reclines) rotatory force (or torque threshold) can be less than causing the rotatory force (or torque threshold) of clutch mechanism along second direction slippage (, when lock pawl 42 ' slips over the arm 32 ' of the shoulder 34 that reclines).Can realize that this torque threshold official post gets chuck and tightens the given torque threshold of the given torque threshold of process less than the chuck release process.

To those skilled in the art, it is conspicuous the instantiation of clutch mechanism shown in Figure 2 being carried out multiple remodeling.For example, need not pivotable structure, can make arm 32 ' is the cantilever that stretches out from anterior cannula 30 ' and can strain.At this moment, lock pawl 42 ' can make cantilever 32 ' elastic bending and one of the shoulder 34,35 that reclines causes lock pawl 42 ' can slip over cantilever 32 '.Because shoulder 34 is higher than (radially) shoulder 35, shoulder 35 provides less support for cantilever 32 '.In this mode, cause that clutch mechanism along first direction (promptly, as shown in Figure 2, when lock pawl 42 ' makes cantilever 32 ' towards shoulder 35 elastic bendings) rotatory force (or torque threshold) of slippage can be less than causing the rotatory force (or torque threshold) of clutch mechanism along second direction (, when lock pawl 42 ' makes cantilever 32 ' towards shoulder 34 elastic bendings) slippage.

B (2). the clutch mechanism of example shown in Figure 3

As shown in Figure 3, anterior cannula 30 " clutch part can be part (raised feature) 32 with raised features ", and rear sleeve 40 " clutch part can be lock pawl 42 " form.Part 32 with raised features " comprise two slopes 36,37.

In the chuck actuation process, tool chuck 50 does not open fully or when drawing in, has the part 32 of raised features " lock pawl 42 can recline ", make anterior cannula 30 " and rear sleeve 40 " lock together rotationally.Tool chuck draws in or when opening fully fully; by part 32 with raised features " be applied to lock pawl 42 " on rotatory force rise to lock pawl 42 " the driven threshold value of direction (cause rear sleeve 40 " strain) outwardly radially, cause part 32 with raised features " at lock pawl 42 " slid underneath and through lock pawl 42 ".

As shown in Figure 3, the inclined degree of the working face on slope 36 (with respect to reference line R radially) can be greater than the inclined degree of the working face on slope 37.In this case, cause that clutch mechanism along first direction (promptly, when lock pawl 42 " working face by slope 36 is when radially direction is driven outwardly) rotatory force (or threshold value torque) of slippage can be less than causing the rotatory force (or threshold value torque) of clutch mechanism along second direction (, when lock pawl 42 " working face by slope 37 when radially direction is driven) slippage outwardly.Can realize that this threshold value torque differences makes chuck tighten the given threshold value of the given torque threshold of process less than the chuck release process.

B (3). the clutch mechanism of example shown in Figure 4

The example of clutch mechanism shown in Figure 4 and clutch mechanism shown in Figure 3 are similar a bit, and similarity is anterior cannula 30 " form of ' clutch part also can be the part with raised features 32 that comprises two slopes " '.Their difference will be described below.

As shown in Figure 4, rear sleeve 40 " form of ' clutch part can be lock pawl 42 " ', it is compressed radially inwardly direction biasing of spring 43.Compression spring 43 and lock pawl 42 " in the pothole 41 of ' can be received in rear sleeve 40 " '.

In the chuck actuation process, when tool chuck 50 does not open fully or draws in, have the part 32 of raised features " ' projection 42 reclines " ', make anterior cannula 30 " ' and rear sleeve 40 " ' lock together rotationally.When tool chuck draws in fully or open fully; by part 32 with raised features " rotatory force on ' be applied to projection 42 " ' rises to and makes projection 42 " ' radially outwardly direction (and entering in the pothole 41) offset the influence of compression spring 43 and driven threshold value; therefore, have the part 32 of raised features " slippage and process lock pawl 42 below ' can at lock pawl 42 " ' " '.Then, 43 pairs of lock pawls 42 of compression spring " ' work, make its position that turns back to radial inward (as shown in Figure 4).In this instantiation, clutch mechanism can be at rear sleeve 40 " ' be not subjected to slippage under the situation of any strain.

As described in top instantiation, can realize that threshold value torque official post chuck tightens given torque threshold in the process less than the given threshold value in the chuck release process.

C. example working order

Axial location tool chuck 50 according to rear sleeve 40 can differently turn round.When rear sleeve 40 was in axially forward position, as shown in Figure 1, power transmission machine can the work of normal operation pattern.At this moment, since clutch part 32,42nd, (that is, clutch mechanism is inoperative) that throws off, and rear sleeve 40 can rotate with respect to anterior cannula 30.Because flange 44,92 can be thrown off, rear sleeve 40 also can rotate with respect to the housing 90 of driver.When the driver power consumption increased (power up), axle 85 drove chuck body 20 rotationally, and chuck body drives chuck jaws 2 successively rotationally.Because the friction between these building blocks, chuck jaws 2 can be rotated with nut 16, anterior cannula 30 and rear sleeve 40.Therefore, entire tool chuck 50 can be used as single unit and rotates together.

Operating personnel shift rear sleeve 40 onto axial position backwards also with enough force compresses springs 25, and power transmission machine is turned round with the chuck actuation patterns.Like this, anterior cannula 30 and rear sleeve 40 locked together rotationally by engagement between the clutch part 32,42 and interaction (that is, clutch mechanism works) and reached given torque threshold.Simultaneously, rear sleeve 40 and housing 90 can be locked together rotationally by the chimeric of flange 44,92.

When the driver power consumption increased, axle 85 drove chuck body 20 rotationally, and chuck body can be rotated with chuck jaws 2.Chuck body 20 (therefore also comprising chuck jaws 2) can be rotated with respect to nut 16 and anterior cannula 30.This is because anterior cannula 30 keeps locking (passing through clutch mechanism) with rear sleeve 40 rotationally, and rear sleeve 40 keeps locking (by flange 44,92) with housing 90 rotationally.End-face helical 18 and the interaction between the end-face helical 3 of radial outward that can be by radial inward relatively rotating between nut 16 and the chuck body 20 (therefore also comprising chuck jaws 2) drive chuck jaws 2 and open or draw (rotation direction that depends on axle 85) in.

When arriving, tool chuck 50 opens fully or during the curling position, nut 16 is tightened on the pawl screw thread 3, at this moment, by nut 16 rotatory force that increases is delivered to clutch part 32 from chuck body 20 (and chuck jaws 2).Rotatory force rises to and makes clutch mechanism get out of the way the threshold value of (or slippage).In this mode, clutch mechanism can be limited in the torque that is applied in the chuck actuation process.

Driver can increase so that tighten respectively or back off tool chuck 50 along opposite rotation direction power consumption.Under the circumstances, with reference to figure 2-4, clutch mechanism can cause in anterior cannula to clockwise rotate with respect to rear sleeve along a direction slippage in the time of tool chuck 50 can being designed to tighten.For example, what the designer can expect is that the screw thread 3 of chuck jaws 2 and the screw thread of nut 16 18 are left hand thread or right-handed thread, activate with the chuck jaws that realizes expectation.In this mode, chuck tightens the given torque threshold of the given torque threshold of process less than the chuck release process.In case the clutch mechanism slippage, operating personnel can unclamp rear sleeve 40, allow spring 25 that rear sleeve 40 is turned back to forward axial location.

II. the instantiation shown in Fig. 5-9

Fig. 5-9 shows another unrestriced instantiation of tool chuck 150, and it can be by uniform torque actuated under the situation of not changing operating personnel.In this instantiation, clutch mechanism is arranged between rear sleeve and the power transmission machine housing.

A. the structure of example

With reference to figure 5, tool chuck 150 can comprise chuck body 120.The rear end of chuck body 120 can be fixedly mounted on the axle 185 of power transmission machine.The front end of chuck body 120 has the passage that supports a plurality of chuck jaws (not shown) slidably.How chuck jaws and they interact similar with the instantiation of front with nut (and anterior cannula).Therefore, for simplicity, do not repeat them here.Instantiation is such as described above, and the present invention can be equipped with by the various chuck jaws that can open and draw in that relatively rotate between the tool chuck parts.

Chuck body 120 supports anterior cannula (not shown) and rear sleeve 140.Anterior cannula and rear sleeve 140 can be coupled, and rear sleeve 140 can and be rotatably fixed on the anterior cannula with respect to the anterior cannula axially-movable.Only for example rather than to the restriction of instantiation of the present invention, anterior cannula can comprise the longitudinal rack that is received by the synergistic characteristic (feature) that is arranged on the rear sleeve 140.Also can be equipped with multiple different coupling unit well known in the art.

Rear sleeve 140 can be supported to and make it can be with respect to chuck body 120 (therefore also with respect to anterior cannula) axially towards front position and axially axially-movable between the position backwards.The first half that tool chuck 150 has been shown among Fig. 5 (promptly, axis 110 upper sections) have and be in axially the rear sleeve 140 of position backwards, and the Lower Half (that is axis 110 below parts) that shows tool chuck 150 has the rear sleeve 140 that is in axially towards the front position.Compression spring 125 can be trapped between rear sleeve 140 and the chuck body 120.125 pairs of rear sleeves 140 of compression spring are exerted one's influence, and it is arrived axially towards the front position.

As will be described in more detail as follows, clutch mechanism (comprising two synergistic clutch part 142,192) can be arranged between rear sleeve 140 and the power transmission machine housing 190.Clutch mechanism locks together rear sleeve 140 and housing 190 rotationally, up to reaching given torque threshold.In case reach given torque threshold, clutch mechanism can get out of the way (or slippage), with the torque that is applied in the restriction chuck actuation process.

The rear end of rear sleeve 140 can comprise vertically towards the rear to the shank 145 that protrudes.Each shank 145 comprises that inside is provided with the mid portion of groove 148.Each groove 148 comprises towards the lower surface of radial outward direction.Each shank 145 supports the far-end of clutch part 142 in addition.

Housing 190 can support guard ring 170 regularly.Housing 190 also can support the clutch part 142 interactional clutch part 192 with rear sleeve 140.Clutch part 192 is fixed in rotationally also can be with respect to housing 190 axially-movables on the housing 190.For this reason, housing 190 and clutch part 192 can be coupled by tooth bar.This tooth bar coupling (and other alternative coupled modes) is being known in the art, and therefore, does not repeat them here for simplicity.

Clutch part 192 can be by spring mechanism 175 forward direction biasing vertically.Spring mechanism 175 shown in Fig. 5 can be the wave plate shape.Certainly, these instantiations of the present invention are not limited to this shape, and can be equipped with other spring mechanisms commonly used.

B. the clutch mechanism of example

Can make the structure of clutch mechanism and effect more apparent by 6-9 with reference to the accompanying drawings, these accompanying drawings show the unrestriced example of the clutch part that can be provided in the tool chuck shown in Figure 5 150.

Fig. 6 is guard ring 170, clutch part 192, reaches the decomposition diagram of spring mechanism 175 ' that all these parts are installed in the housing 190.Guard ring 170 can comprise the edge of radial inward, can alternately be arranged with recess 171 and tab 172 along this edge.Guard ring 170 interacts with the shank 145 of rear sleeve 140 in such a way.Recess 171 can hold the axially-movable of shank 145.That is to say that the position is when (with from axially position motion backwards) when rear sleeve 140 moves to axially backwards, shank 145 can slide vertically by the recess 171 of guard ring 170.When rear sleeve 140 (being positioned in axially position backwards) rotated, arbitrary tab 172 can enter in the groove 148 of shank 145.In this case, the tab 172 of guard ring 170 can remain on rear sleeve 140 axial position backwards.

In this instantiation, clutch part 192 can have a side that is provided with a plurality of lock pawls 193.Lock pawl 193 can protrude vertically from clutch part 192.Lock pawl 193 can interact with the clutch part 142 of rear sleeve 140.In Fig. 6, spring mechanism 175 ' can be the main body form with side that supports a plurality of compression springs 176.Compression spring 176 clutch part 192 that reclines.This instantiation of the present invention has more than and is limited to specific spring mechanism.For example, as mentioned above, spring mechanism can be form (as shown in Figure 5) or some other spring mechanisms commonly used of wave plate.

Rear sleeve has been shown among Fig. 7-9 has been in axial position backwards, made clutch part operationally mesh.In addition, tab 172 can be positioned in the groove 148 of shank 145, make guard ring 170 that rear sleeve 140 is remained on axial position (offsetting the influence of spring mechanism 175 and compression spring 125) backwards.

B (1). the clutch mechanism of example shown in Figure 7

As shown in Figure 7, the clutch part of rear sleeve is provided in a side of the form of the part 142 ' with raised features on the shank 145 ' far-end.Part 142 ' with raised features comprises two slopes 136,137.Part 142 ' with raised features can interact with the lock pawl 193 ' that is installed in the clutch part 192 ' in the housing.

In the chuck actuation process, tool chuck 150 do not open fully or when drawing in (for example, chuck jaws still open or when drawing in), the lock pawl 193 ' that can recline of the part 142 ' with raised features locks together rear sleeve and housing rotationally.When tool chuck drew (annex that has or do not have to insert) fully in or opens fully, the rotatory force that is applied to lock pawl 193 ' by the part 142 ' with raised features can increase.Herein, rotatory force rises to lock pawl 193 ' (with clutch part 192 ') vertically towards the rear to the threshold value that is driven the influence of spring mechanism (offset), the part 142 ' with raised features can laterally be slided and slips over lock pawl 193 '.In this case, clutch mechanism can get out of the way (or slippage), limits the torque that is applied in the chuck actuation process whereby.

The working face of part 142 ' that is subjected to the intensity of spring mechanism 175 for example and has a raised features to the big I that drives the required rotatory force of lock pawl 193 ' towards the rear is with respect to the influence of inclination (or crooked) degree of axis 110 vertically.Angle between working face and the axis 110 is more little, makes the required rotatory force of clutch mechanism slippage big more.

As shown in Figure 7, the inclined degree of the working face on slope 136 (with respect to axis 110) can be greater than the inclined degree of the working face on slope 137.In this case, cause that clutch mechanism along first direction (promptly, the working face of lock pawl 193 ' by slope 136 is when backwards direction is driven vertically) rotatory force (or threshold value torque) of slippage can be less than causing the rotatory force (or threshold value torque) of clutch mechanism along second direction (, the working face of lock pawl 193 ' by slope 137 is vertically towards the rear when being driven) slippage.Can realize this threshold value torque differences so that chuck tightens the given torque threshold of the given torque threshold of process less than the chuck release process.

B (2). the clutch mechanism of example shown in Figure 8

As shown in Figure 8, the clutch part of rear sleeve can be provided in a side of shank 145 " part with raised features 142 of far-end " shape.Part 142 with raised features " can comprise two shoulders.Be installed in the clutch part 192 in the housing " lock pawl 193 " comprise two slopes 196,197.

In the chuck actuation process, when tool chuck 150 does not open fully or draws in, have the part 142 of raised features " lock pawl 193 can recline ", rear sleeve and housing are locked together rotationally.When tool chuck draws in fully or open fully, by part 142 with raised features " be applied to lock pawl 193 " rotatory force increase.Here, rotatory force rises to lock pawl 193 " vertically towards the rear to the threshold value that is driven the influence of spring mechanism (offset), make part 142 with raised features " can laterally slide and slip over lock pawl 193 ".In this case, clutch mechanism can get out of the way (or slippage), limits the torque that is applied in the chuck actuation process whereby.

As shown in Figure 8, the inclined degree of the working face on slope 196 (with respect to axis 110) can be less than the inclined degree of the working face on slope 197.In this case, cause that clutch mechanism along first direction (promptly, when lock pawl 193 " working face by slope 196 is when backwards direction is driven vertically) rotatory force (or threshold value torque) of slippage can be less than causing the rotatory force (or threshold value torque) of clutch mechanism along second direction (, when lock pawl 193 " working face by slope 197 when backwards direction is driven vertically) slippage.Can realize that this threshold value torque differences makes chuck tighten the given torque threshold of the given torque threshold of process less than the chuck release process.

B (3). the clutch mechanism of example shown in Figure 9

Clutch mechanism shown in the example of clutch mechanism shown in Figure 9 and Fig. 7 and 8 is similar a bit.Hereinafter will go through its difference.For example, as shown in Figure 9, synergistic clutch part 142 " ', the 192 " ' working face that can have complementary contours.Simultaneously, the working face of clutch part can be bending.Clutch part 142 " interaction and top description to the example shown in Fig. 7 and 8 between ', 192 " ' be similar.

C. the operational situation of example

Axial location tool chuck 150 according to rear sleeve 140 can differently turn round.When rear sleeve 140 was in axially towards the front position, shown in the Lower Half (that is, below axis 110) of Fig. 5, power transmission machine can the work of normal operation pattern.At this moment, because clutch part 142,192 can be thrown off (that is, clutch mechanism is inoperative), rear sleeve 140 can rotate with respect to housing 190.When the driver power consumption increased, axle 185 drove chuck body 120 rotationally, and chuck body drives chuck jaws successively rotationally.Chuck jaws can be rotated with nut, anterior cannula and rear sleeve 140.Therefore, entire tool chuck 150 can be used as single unit and rotates together.

In order to realize the chuck actuation patterns, operating personnel can shift rear sleeve 140 onto axially position backwards and compress spring 125 with enough power.When rear sleeve 140 vertically towards the rear to (with respect to anterior cannula, chuck body 120, and housing 190) during motion, shank 145 can be through the recess 171 of guard ring 170.Shank 145 can be enough distance axis to passing recess 171, the clutch part 142 of shank in axial direction pressure shell body 190 clutch part 192 and offset the influence of spring mechanism 175.

Then, operating personnel rotate rear sleeve 140, and the tab 172 of guard ring 170 is entered in the groove 148 of shank 145, shown in the first half (that is axis 110 tops) of Fig. 5.At this moment, operating personnel can unclamp rear sleeve 140, and rear sleeve is maintained at axial position backwards by means of the tab 172 that inserts in the groove 148.Under this condition, rear sleeve 140 and housing 190 are locked together up to reaching given torque threshold rotationally by engagement and interaction (that is, clutch mechanism works) between the clutch part 142,192.

When the driver power consumption increased, axle 185 drove chuck body 120 rotationally, and chuck body can be rotated with chuck jaws.Chuck body 120 (therefore also comprising chuck jaws) can be rotated with respect to nut and anterior cannula.This is because anterior cannula can keep locking with rear sleeve 140 rotationally (by the tooth bar coupling), sequentially makes rear sleeve keep locking (passing through clutch mechanism) with housing 190 rotationally.Relatively rotating between nut and chuck body 120 (therefore also comprising chuck jaws) can drive chuck jaws and open or draw (rotation direction that depends on axle 185) in.

When arriving, tool chuck 150 opens fully or during the curling position, nut can be tightened on the chuck jaws.At this moment, the rotatory force of increase can be delivered to clutch part 142 by nut and anterior cannula from chuck body 120 (and chuck jaws).Rotatory force rises to and makes clutch mechanism get out of the way the threshold value of (or slippage).In this case, clutch mechanism can limit the torque that is applied in the chuck actuation process.

Driver power consumption in opposite direction increases, so that tighten respectively or back off tool chuck 150.In this case, with reference to figure 7-9, tool chuck 150 can be designed to when it is tightened, clutch mechanism can make shank 145 ', 145 along a direction slippage ", 145 " ' with respect to guard ring 170 move to the left side.In this case, be used for chuck and tighten the given torque threshold of process less than the given torque threshold that is used for the chuck release process.

During the clutch mechanism slippage, rear sleeve 140 can rotate with respect to housing 190 (therefore also with respect to guard ring 170), relatively rotate in the process this, shank 145 can enter in the recess 171 of guard ring 170, and the tab 172 of guard ring 170 slips over and withdraws from from the groove 148 of shank 145 simultaneously.In case tab 172 withdraws from groove 148, spring 125 can make rear sleeve 140 turn back to axial position forward.Can sound and/or the vision indication to operating personnel like this, expression chuck actuation process is finished.

III. the instantiation shown in Figure 10-15

Figure 10 shows another unrestriced instantiation of tool chuck 250, and this tool chuck can be activated by flat torque under the situation of not changing operating personnel.In this instantiation, clutch mechanism is arranged between outer sleeve and the power transmission machine housing.

A. the structure of example

With reference to Figure 10, tool chuck 250 can comprise chuck body 220.The rear end of chuck body 220 is fixedly mounted on the axle 285 of power transmission machine.The front end of chuck body 220 has the passage that slidably supports a plurality of chuck jaws 202.It is skewed that chuck jaws 202 can be, and chuck jaws 202 front end is separately converged towards the axis 210 of chuck body 220.Each chuck jaws 202 has the end-face helical 203 of radial outward.Chuck jaws 202 can be by radial outward the end-face helical 218 of end-face helical 203 and the radial inward of nut 216 interact and activated (that is, be pushed into and/or bounce back).As described in the instantiation of front, the present invention can be equipped with the multiple chuck jaws type (except that shown " threaded " chuck jaws) that can be opened and draw in by relatively rotating between the tool chuck parts.

Chuck body 220 can support inner sleeve 230 and outer tube 240.Inner sleeve 230 and outer tube 240 can be coupled, and make outer tube 240 and to be rotatably fixed on the inner sleeve 230 with respect to inner sleeve 230 axially-movables.Only for example, rather than to the restriction of this instantiation of the present invention, inner sleeve 230 can comprise the longitudinal rack 231 that the synergistic characteristic 249 that is set on the outer tube 240 receives.Between inner sleeve and outer tube, also can be equipped with multiple different coupling unit well known in the art.

Inner sleeve 230 can be supported to and make it be axially fixed to chuck body 220 and can rotate with respect to chuck body 220.Inner sleeve 230 can have nut 216 regularly.Between nut 216 and chuck body 220, bearing 207 can be set, so that relatively rotating between nut 216 and the chuck body 220.

Outer tube 240 can be supported to and make it can be with respect to chuck body 220 (therefore also with respect to inner sleeve 230) axially towards the front position with axially carry out axially-movable backwards between the position.Figure 10 illustrates and have the tool chuck 250 that is in axially towards the outer tube 240 of front position.Compression spring 225 is trapped between inner sleeve 230 and the outer tube 240.Compression spring 225 can be exerted one's influence to outer tube 240, makes it to arrive at axial position forward.

Such as will be described below in more detail, clutch mechanism (comprising two synergistic clutch part 242,292) can be arranged between the housing 290 of outer tube 240 and driver.Clutch mechanism locks together outer tube 240 and housing 290 up to reaching given torque threshold rotationally.In case reach given torque threshold, can make clutch mechanism get out of the way (or slippage), with the torque that is applied in the restriction chuck actuation process.

Baffle ring (latch ring) 260 can be supported in the rear end of outer tube 240.Baffle ring 260 can have have towards axially towards the rear to cam face 262 and towards the axial far-end of the stop surfaces 263 of direction forward.Cam face 262 can tilt with respect to axis 210, and stop surfaces 263 can be perpendicular to axle 210.Baffle ring 260 also can comprise clutch part 242.

Housing 290 support can with the clutch part 242 interactional clutch part 292 of outer tube 240.Clutch part 292 is rotatably fixed on the housing 290 and can radially rotates with respect to housing 290.For this reason, housing 290 can comprise the inner pothole 291 that is provided with clutch part 292 slidably.Clutch part 292 can be by radially biasing outwardly of spring mechanism 275.Spring mechanism 275 shown in Figure 10 can be a leaf spring, certainly, the invention is not restricted to this.For example, spring mechanism can be equipped to wave plate, disc spring, elastic component or some other spring mechanism forms commonly used.

In this instantiation, briefly with reference to Figure 13, can with outer tube 240, synergistic characteristic 249, and baffle ring 260 be set to independent and different elements, this can help the assembling of tool chuck 250.Certainly, in view of outer tube 240, described synergistic characteristic 249, and baffle ring 260 also can be whole single type structure, this instantiation of the present invention is not limited thereto.Similarly, also can with nut 216, inner sleeve 230, and tooth bar 231 be set to independent and different elements, this can help the assembling of tool chuck 250.In view of nut 216, inner sleeve 230, and tooth bar 231 also can be whole single type structure, this instantiation of the present invention is not limited to this.

In this instantiation, two clutch part 292 can be installed on housing 290.But, be understandable that this instantiation of the present invention is not limited to the clutch part 292 of any specified quantity.For example, can be equipped with single clutch part 292 (or more than two clutch part 292).In addition, single spring mechanism 275 can be set so that radially outwardly the direction biasing of all clutch part 292.Certainly, what can expect is to be equipped with additional springs mechanism 275.For example, can be each clutch part 292 independent spring mechanism 275 is provided.

B. the clutch mechanism of example

By 11,12,14 and 15 making the structure of clutch mechanism more apparent with effect with reference to the accompanying drawings, these accompanying drawings show the unrestriced example of the clutch part that can be provided in the tool chuck shown in Figure 10 250.At Figure 11, in 12,14 and 15, shown outer tube is in axially position backwards, and clutch part is operationally meshed.Under this condition, a clutch part 292 can be positioned at the position of the radial inward of another clutch part 242.The working face of these clutch part is towards the direction perpendicular to the axis 210 of tool chuck 250.

B (1). the clutch mechanism of Figure 11 and 12 example illustrated

Shown in Figure 11 and 12, the clutch part of outer tube 240 ' can be arranged on the form of the part 242 ' with raised features on the baffle ring 260 '.Part 242 ' with raised features can comprise two slopes 236 ', 237 '.Be installed in the form that housing 290 ' interior clutch part can be lock pawl 292 '.

In the chuck actuation process, tool chuck 250 do not open fully or when drawing in (for example, when chuck jaws is still opened or is drawn in), the lock pawl 292 ' that can recline of the part 242 ' with raised features locks together rear sleeve 240 ' and housing 290 ' rotationally.When tool chuck draws in fully or open fully (annex that has or do not have to insert), the rotatory force that is applied to lock pawl 292 ' by the part 242 ' with raised features increases.Here, rotatory force rise to lock pawl 292 ' radially inwardly direction (and put in pothole 291 ' in) offset compression spring mechanism 275 ' influence and can driven threshold value, the part 242 ' with raised features laterally slided and slip over lock pawl 292 '.In this case, clutch mechanism can get out of the way (or slippage), limits the torque that is applied in the chuck actuation process whereby.

Radially the big I that drives the required rotatory force of lock pawl 292 ' of the direction inwardly working face of part 242 ' that is subjected to the intensity of spring mechanism 275 ' for example and has a raised features is with respect to the radially influence of the inclination of reference line R (or crooked) degree.Working face the and radially angle between the reference line R is more little is used for making the required rotatory force of clutch mechanism slippage big more.

As shown in figure 11, the inclined degree of the working face on slope 236 ' (with respect to reference line R radially) is greater than the inclined degree of the working face on slope 237 '.In this case, along first direction (promptly, when the working face of lock pawl 292 ' by slope 236 ' when radially inwardly direction is driven) rotatory force (or threshold value torque) that causes the clutch mechanism slippage is less than the rotatory force (or threshold value torque) that causes the clutch mechanism slippage inwardly along second direction when radially direction is driven (, when the working face of lock pawl 292 ' by slope 237 ').The difference that realizes this threshold value torque can make chuck tighten the given threshold value of the given torque threshold of process less than the chuck release process.

In this instantiation, and with reference to Figure 12, the stop surfaces 263 ' of baffle ring 260 ' can be vertically forward direction be pressed against the axial rearward end of lock pawl 292 '.Interaction between stop surfaces 263 ' and lock pawl 292 ' can not provide and can cause radially inwardly the cam action of motion of direction of influence that lock pawl 292 ' offsets spring mechanism 275 '.In this case, lock pawl 292 ' can remain in outer tube 240 ' (and offsetting influence of compressing spring 225) on the axial position backwards.Rear sleeve 240 ' can axially be kept this mode laterally to slip over lock pawl 292 ' up to the part 242 ' with raised features, whereby, can be radially inwardly direction drive lock pawl 292 ' and lock pawl entered in the pothole 291 '.

B (2). the clutch mechanism of Figure 14 and 15 example illustrated

Shown in Figure 14 and 15, outer tube 240 " clutch part can be arranged at baffle ring 260 " on the part with raised features 242 " form.Part 242 with raised features " can comprise two slopes 236 ", 237 ".The clutch part that is installed in the housing can be lock pawl 292 " form.Lock pawl 292 " can be spherical form.

In the chuck actuation process, when tool chuck 250 does not open fully or draws in, have the part 242 of raised features " lock pawl 292 can recline ", make rear sleeve 240 " and housing lock together rotationally.When tool chuck draws in fully or open fully, by part 242 with raised features " be applied to lock pawl 292 " on rotatory force increase.Here, rotatory force rises to lock pawl 292 " radially inwardly direction offset spring mechanism 275 " influence and driven threshold value makes the part 242 with raised features " can laterally slide and slip over lock pawl 292 ".In this case, clutch mechanism can get out of the way (or slippage), limits the torque that is applied in the chuck actuation process whereby.

As shown in figure 14, the slope 236 " the inclined degree (with respect to reference line R radially) of working face greater than slope 237 " the inclined degree of working face.In this case, cause that clutch mechanism along first direction (promptly, when lock pawl 292 " by slope 236 " working face when radially inwardly direction is driven) slippage rotatory force (or threshold value torque) less than cause clutch mechanism along second direction (, when lock pawl 292 " by slope 237 " working face when radially direction is driven inwardly) rotatory force (or threshold value torque) of slippage.Realize that this threshold value torque differences can make chuck tighten the given threshold value of the given torque threshold of process less than the chuck release process.

In this instantiation, and with reference to Figure 15, baffle ring 260 " stop surfaces 263 " with the part 242 with raised features " slope 236 ", 237 " contact.For example, baffle ring 260 " can be provided with limit slope 236 ", 237 " and stop surfaces 263 " groove.Here, the wall that the radial inward of groove is faced limits slope 236 ", 237 ", and the wall of axially facing forward of groove limits stop surfaces 263 ".In Figure 15, groove extends into the plane of drawing.

Stop surfaces 263 " can be vertically forward direction press lock pawl 292 " axial rearward end.Stop surfaces 263 " and lock pawl 292 " between interaction can not provide can cause lock pawl 292 " radially direction is offset spring mechanism 275 inwardly " and the cam action of motion of influence.In this case, lock pawl 292 " can be with outer tube 240 " remain on axially on the position backwards (and offset compression spring 225 influence).Rear sleeve 240 " can keep vertically by this way up to part 242 with raised features " laterally slide and slip over lock pawl 292 ", whereby radially inwardly direction drive lock pawl 292 ".

C. the working order of example

Tool chuck 250 can carry out different runnings according to the axial location of outer tube 240.When outer tube 240 was in axially towards the front position, as shown in figure 10, power transmission machine can the normal mode of operation running.At this moment, because clutch part 242,292 can be thrown off (that is, clutch mechanism is inoperative), outer tube 240 can rotate with respect to housing 290.

When the driver power consumption increased, axle 285 drove chuck body 220 rotationally, and chuck body then drives chuck jaws 202 successively rotationally.Chuck jaws 202 can be rotated with nut 216, inner sleeve 230 and outer tube 240.Therefore, entire tool chuck 250 can be used as single unit and rotates together.

In order to realize the chuck actuation patterns, operating personnel can shift outer tube 240 onto axially position backwards and apply enough power and compress spring 225.When outer tube 240 vertically backwards direction (with respect to inner sleeve 230, chuck body 220, and housing 290) during motion, the cam face 262 of baffle ring 260 slips over clutch part 292, and radially the influence of the spring mechanism 275 of direction counteracting inwardly drives clutch part 292 whereby.Finally, backwards the direction motion vertically of the stop surfaces 263 of baffle ring 260 surpasses clutch part 292.At this moment, spring mechanism 275 can be radially outwardly direction drive clutch part 292 and with clutch part 242 engagements (for example, as Figure 12 or shown in Figure 15).

When clutch part 292,242 engagements, operating personnel can unclamp outer tube 240.Outer tube 240 can be maintained at axially on backwards the position by the recline stop surfaces 263 of baffle ring 260 of clutch part 292.In this case, outer tube 240 and housing 290 can be locked together up to reaching given torque threshold rotationally by engagement and the interaction (that is, clutch mechanism works) between the clutch part 242,292.

When the driver power consumption increased, axle 285 drove chuck body 220 rotationally, and chuck body can be rotated with chuck jaws 202.Chuck body 220 (therefore also comprising chuck jaws 202) can be rotated with respect to nut 216 and inner sleeve 230.This is because inner sleeve 230 keeps locking (by tooth bar 231 and synergistic characteristic 249) with outer tube 240 rotationally, and inner sleeve keeps locking (passing through clutch mechanism) with housing 90 rotationally successively.Relatively rotating between nut 216 and chuck body 220 (therefore also comprising chuck jaws 202) can drive chuck jaws 202 and open or draw (rotation direction that depends on axle 285) in.

When arriving, tool chuck 250 opens fully or during the curling position, nut 216 can be tightened on the chuck jaws 202.At this moment, the rotatory force of increase is passed to clutch part 242 from chuck body 220 (and chuck jaws 202) by nut 216 and inner sleeve 230.Rotatory force rises to the threshold value that clutch mechanism can get out of the way (or slippage).In this case, clutch mechanism can limit the torque that is applied in the chuck actuation process.

Driver can tighten respectively or back off tool chuck 250 along opposite rotation direction power consumption increase.Therefore, as described in the instantiation of front, be used for chuck and tighten the given torque threshold of process less than the given torque threshold that is used for the chuck release process.

When the clutch mechanism slippage, outer tube 240 (therefore also having baffle ring 260) can rotate with respect to housing 290.In this process in relative rotation, clutch part 292 can be radially inwardly direction be driven (by clutch part 242).Clutch part 292 can be separated with stop surfaces 263, causes spring 225 that outer tube 240 is turned back to forward axial location.This can provide sound and/or vision to operating personnel and indicate and represent that the chuck actuation process finishes.

Figure 16 shows the clutch ring mechanism that is suitable as the user interface that is used to control the electric drill drive motors, so that annex maintenance/disengaging.Below the clutch ring mechanism that describes in further detail be can be applicable to have shown in Fig. 1 to 15 and arbitrary example of the tool chuck of described clutch mechanism in.With reference to Figure 16, when handling, the user can utilize the clutch ring 410 on the electric drill driver 400, so that engagement or throw off the drilling tool motor and provide drill bit to keep.For purpose of explanation, hereinafter following pattern will be described: tighten pattern, drill mode and annex release mode.Although to this instantiation without limits, annex can be a drill bit in this example.

In tightening pattern, user's finger leaves trigger piece 420, the user can after (for example move clutch ring 410, clutch ring can be spring-loaded), cause engagement mechanical linkage part 430 (axle that conduct as shown in figure 16 vertically moves with instrument is though this is an example of mechanical linkage part 430).When moving behind the clutch ring 410 (by arrow 437 expression), mechanical linkage part 430 spring 435 that reclines that move backward, thus prevent tool chuck 440 rotations.For example, mechanical linkage part 430 mechanically touched on the main body of instrument sleeve pipe (any one for example in shown outer tube 40,140,240 grades) by clutch mechanism before the switch contact.Mechanical linkage part 430 is also applicable to walking around trigger piece 420, thereby lockable trigger piece 420 (for clarity sake not shown).When clutch ring 410 during by intact total retrusion (when pressing down), mechanical linkage part 430 makes contact 445 closures on the switch 450 of instrument, to start the instrument motor, drill bit is tightened in the pawl 442 of chuck 440.

In one example, in order to provide the sound equipment feedback (not shown with the expression clutch mechanism, but can be in the clutch mechanism shown in the 1-15 any) be in the duty of expectation, as known in the art, (generally being several seconds) can send the engagement resonant in the instrument 400 in tightening drill bit institute elapsed time section.In case drill bit is tightened, but user's loosen the clutch ring 410 makes clutch ring 410 turn back to the centre position.When clutch ring mediates (drill mode), can regulate the torque on the chuck 440 as required and depress trigger piece 420 so that the brill driver in drill mode 400 carries out conventional power-assisted operation (power operations).

In the drill bit release mode, the user is to the chuck 440 promotions previous dynasty or clutch ring 410 is slided, and causes trigger piece 420 lockings.Interlock part 430 can stretch along direction 439, makes the motor counter-rotating with second contact 447 on the closure tool switch 450, and open claws 442 discharges drill bit.Do not need in the process to deviate from trigger piece 420 actions at drill bit.

It is intuitively that the pushing away/spur of clutch ring 410 done, thereby easy to use and judge.Because the process at whole locking or release drill bit can prevent that chuck 440 from rotating, in rotation process, do not need promptly chuck 440, therefore provide additional comfortableness for the user.The another manual operating clutch ring 410 because user's a hand is placed on the implement handle 460 can keep drill bit under the situation of the clutch ring 410 that does not need to hold rotation, therefore can improve drill bit fixing in the pawl 442 of chuck 440.

IV. the instantiation shown in Figure 17 A-17B

Figure 17 A and 17B show tool chuck 350 another unrestriced instantiations, and it has the clutch mechanism that can be activated by flat torque under the situation of not changing operating personnel.In this instantiation, the chuck sleeve pipe does not carry out axially-movable, and clutch mechanism moves vertically in case with sleeve pipe 340 engagement of axial restraint.So, Figure 17 A and 17B show the another example that can have the constant clutch mechanism that tightens on chuck body 320, can prevent that whereby grabbing 302 by the chuck that the contact between chuck sleeve pipe 340 and the workpiece causes inadvertently unclamps.

In the aforesaid instantiation shown in Fig. 1-15, the axially-movable of one of inner sleeve and/or outer tube so that engagement makes sleeve pipe touch clutch mechanism on (ground) tool housing, causes chuck jaws to unclamp or tighten.Clutch mechanism is at the following relief sleeve of given torque settings value (given torque setting) then.In some applications, the user can make chuck body contact with workpiece and cause sleeve movement, thereby causes that chuck body inadvertently meshes with clutch mechanism.But as shown in Figure 17 A and the 17B, sleeve pipe is not done axially-movable, and the axial advance the puck of clutch mechanism with fixing sleeve pipe engagement, the result can prevent inadvertently unclamping of chuck jaws or tighten.

Figure 17 A shows the tool chuck 350 of band clutch mechanism (being made of clutch part 342 and synergistic clutch part 392) when throwing off.In Figure 17 A, tool chuck 350 can comprise chuck body 320.The rear end of chuck body 320 is fixedly mounted on the axle 385 of power transmission machine.The front end of chuck body 320 has the passage that supports a plurality of chuck jaws 302 slidably.Chuck jaws 302 tiltables, so the front end of each chuck jaws 302 converges towards the axis 310 of chuck body 320.Chuck jaws 302 has the end-face helical 303 of radial outward respectively.Chuck jaws 302 can be by radial outward the interaction of end-face helical 303 and the end-face helical 318 of the radial inward of nut 316 activated (that is, be pushed into and/or contract and move back).As described in the instantiation of front, the present invention can utilize by relatively rotating between the tool chuck parts and open and the multiple chuck jaws type (except shown " screw-type " chuck jaws) of drawing in is implemented.

Different with aforementioned instantiation is, 320 of chuck body support single outer tubes 340, and outer tube remains fixed on the chuck body 320 but do not slide vertically.Sleeve pipe 340 can have nut 316 regularly.Be provided with bearing 307 between nut 316 and the chuck body 320 to help relatively rotating between nut 316 and the chuck body 320.

Figure 17 B shows the clutch mechanism of the position of engagement.With reference to figure 17A and 17B, clutch mechanism can comprise the clutch part 342 of the be called as catch pawl 392 that is connected with synergistic clutch part 392 interfaces.Different with aforesaid instantiation, shown in Figure 17 B, can utilize tooth bar 341 with the front of clutch mechanism housing 395 wedge embeddings (keyed to) to tool housing 390, make catch pawl 392 axially-movables of clutch mechanism, so that with baffle ring 360 engagements, prevent that simultaneously clutch mechanism housing 395 from rotating with respect to tool housing 390.

In addition, as with reference to shown in figure 17A and the 17B, when catch pawl 392 against bias spring 325 axial advance the pucks during with chuck body 320 engagements, shown in Figure 17 A, catch pawl 392 is advanced in the clutch mechanism housing 395 radially against latch spring 375.When clutch mechanism housing 395 continues axially to chuck body 320 motions, catch pawl 392 by radial outward eject with baffle ring 360 in sunk part or pothole 391 chimeric.Unclamp at needs then/the front/rear running of instrument motor when tightening chuck jaws 302.Under the situation of given torque, catch pawl 392 can skid off baffle ring pothole 391, and bias spring 325 makes clutch mechanism housing 395 turn back to disengaged position.Such as known to those skilled in the art, can have the sleeve pipe of cam face or the means actuating clutch mechanism of other users expectation by making button slip or rotation.

The gap that can have expectation between tooth bar 341 on the tool housing 390 and the tooth bar (not shown) on the clutch mechanism housing 395 is so that clutch mechanism housing 395 carries out limited rotation with respect to tool housing 390.This helps guaranteeing the desirable engagement of catch pawl 392 and baffle ring pothole 391 under the situation that does not need rotating clip disk body 320 or sleeve pipe 340.

So, this clutch mechanism example can provide simply and intuitively operation in tool chuck 350, and provides to tool chuck 350 and to use when holding the chuck sleeve pipe with a firm grip than the user that the torque that conventional method applied of starter motor is improved to be tightened and unclamp torque.Therefore, the instantiation shown in Figure 17 A and the 17B is applicable to using the constant torque that tightens, to prevent that chuck jaws 302 from excessively being tightened.In addition, do not needing to redesign fully under the situation of instrument running part and this instantiation can be applied on the existing instrument.

Figure 18 A and 18B show the locking mechanism of the tool chuck that is used for the present invention's one instantiation.The locking mechanism that can describe is applied to be constituted as comprising described in Fig. 1-15 and Figure 17 A-17B and is used for sliding and/or any one of the above-mentioned instantiation of the chuck sleeve pipe of axially-movable.Figure 18 A shows the tool chuck 550 in the example " chuck actuation patterns ", and Figure 18 B shows the tool chuck 550 that is locked in " creeping into/the tapping pattern ".For clarity sake, omitted Fig. 1-15, the several characteristic of the chuck mechanism that is shown specifically among arbitrary width of cloth figure of Figure 17 A and/or Figure 17 B.

With reference to figure 18A, shown tool chuck 550 has the chuck body 520 of axle of being connected to 585.For example, the clutch part of anterior cannula 530 ' can be the form with part 532 of raised features, and the clutch part of rear sleeve 540 can be the form of lock pawl 542.In the chuck actuation process, when tool chuck 550 did not open fully or draws in, the lock pawl 542 that can recline of the part 532 with raised features locked together anterior cannula 530 and rear sleeve 540 rotationally.When tool chuck draws in fully or open fully; the rotatory force that is applied to lock pawl 542 by the part 532 ' with raised features rises to the radially driven threshold value of direction (causing rear sleeve 540 strains) outwardly of lock pawl 542, makes the part 532 with raised features in lock pawl 542 slid underneath and through lock pawl 542.

So, in case tool chuck 550 be tightened, the clutch part 542 and the sleeve pipe 530 of clutch part 532 disengagement collar 540 of sleeve pipe 530, and because of the compression spring 525 pushed ahead.But, because the rear end of chuck body 520 comprises sunk part 522, these sunk parts 522 receive the lock pawl part 532 ' forward of the part 532 with raised features, and mesh with lock pawl part 532 ', to prevent relative motion between sleeve pipe 530 and the chuck body 520.If necessary, the surface of sunk part 522 inside and the surface on the lock pawl part 532 ' can have the dentation profile so that engagement.In view of the above, this lock mode example can quite simply design and automatically lock chuck 550.

Though the sunk part 522 that illustrates and the corresponding shape of lock pawl part 532 ' are generally rectangle, obviously, for a person skilled in the art, sunk part and lock pawl part can be difformity, so that promote the interconnection system engagement as locking mechanism.

Figure 19 shows and be used for the constant spring-loaded actuator that tightens on the tool chuck of the present invention's one instantiation.With reference to Figure 19, it shows the example part of spring-loaded actuator 600, and this actuator is applicable to any one parts in the tool chuck shown in comprising above (50,150,250, the 350 etc.) example.

For example, but axle spring loaded actuator 600 manipulate tools motors to unclamp or the chuck jaws (that is, pawl 2,102,202,302 etc.) of tightening tool chuck.Actuator 600 can by mechanically be connected to motor be electrically connected to battery or power line forward-stop-retreating slide switch 610.Actuator 600 also can mechanically be connected to " tightening " sleeve pipe, for example part of the outer tube shown in Figure 19 640 by above-mentioned any clutch mechanism example.

In order to unclamp chuck jaws, actuator 600 is promoted (with 615 expressions) by the attachment to the previous dynasty such as drill bit and so on.At first actuator 600 and the engagement of clutch mechanism (not shown) and make sleeve pipe 640 touch tool housing (for example, housing 90 as shown in Figure 1, the housing 390 shown in Figure 17 A, etc.).Then, continuous the travelling forward of actuator 600 moves to going-back position with slide switch 610, motor power consumption increased, so that provide power for pawl opens.

In order to tighten chuck jaws, actuator can be retracted (referring to arrow 625) away from drill bit.Actuator 600 meshes with clutch mechanism again and makes sleeve pipe 640 touch tool housing 90.Actuator continuously backward motion make slide switch 610 move to forward position, connect motor power to tighten pawl.Obviously, those skilled in the art can constitute actuator 600 and promote actuator 600 forward and tighten chuck jaws, unclamp pawl toward pulling back actuator 600.In addition, as described at aforesaid instantiation, clutch mechanism locks together inner sleeve and outer tube till reaching given torque threshold, in view of the above rotationally, clutch mechanism can get out of the way (or slippage), to prevent applying excessive torque on the chuck cocking mechanism.Also clutch mechanism can be constituted and to guarantee to be used for tightening the available torque of pawl less than the available torque that is used for unclamping pawl.

Though actuator 600 shown in Figure 19 can be implemented by sliding button 601, to those skilled in the art, also the mechanism of the axle collar, switch or other same types can be used for actuator 600.

In view of the above, make spring-loading actuator 600 that operation can be provided simply and intuitively, and can provide than the user to tool chuck and use bigger the tightening and unclamp torque of traditional method of starter motor no key chuck sleeve pipe time of holding with a firm grip.This tool chuck is applicable to the constant torque that tightens, and can be constituted as and can prevent that chuck jaws from excessively tightening.In addition, not needing to redesign fully power tool transmission just can be with actuation applications shown in Figure 19 in existing instrument design.

Several clutch mechanism examples have been described above.But instantiation of the present invention is not limited to the detail of disclosed clutch mechanism example.Obviously, to those skilled in the art, can make multiple conversion and remodeling to clutch mechanism.

For example, can make the relevant position of synergistic clutch part opposite.For example, with respect to one among Fig. 2-4 or several clutch mechanisms shown in the drawings, the clutch part that is arranged on the anterior cannula can replace with the clutch part that is arranged on the rear sleeve, and the clutch part that is located on the rear sleeve can replace with the clutch part that is located on the anterior cannula.Similarly be, with respect to Fig. 7-9,11,12, in 14 and 15 one or several clutch mechanisms shown in the drawings, the clutch part that is located on the rear sleeve (or outer tube) can replace with the clutch part that is located on the housing, and the clutch part that is located on the housing can replace with the clutch part that is located on the rear sleeve (or outer tube).

In addition, clutch part is not limited to Fig. 2-4,7-9, one or several geometries shown in the drawings in 11,12,14 and 15.Thus, can adopt many and optional shape.For example, clutch part can have the shape or the asymmetrical shape of symmetry.The working face of clutch part can be plane and/or curved surface.Synergistic clutch part can have complementary contours or differently contoured working face.

Moreover instantiation of the present invention is not limited to the clutch part element of specified quantity.For example, clutch part can comprise one or more lock pawl, arm, have the part of raised features etc.When clutch part comprises more than a clutch part element, it is desirable to around the axis of tool chuck clutch part element at interval equably, certainly, instantiation of the present invention is not limited in this respect.Simultaneously, the quantity of the clutch part element of a clutch part can equal or be not equal to the quantity of the clutch part element of synergistic clutch part.

Claims (20)

1. tool chuck comprises:

One limits the chuck body of longitudinal axis; And

One sleeve pipe, it is installed on the described chuck body, so that between first axial location that described chuck body is rotated with described sleeve pipe and described chuck body are rotated with second axial location that activates described tool chuck with respect to described sleeve pipe, move,

Described chuck body can be rotated in a first direction, activating described tool chuck up to reaching first torque threshold, and be rotated in a second direction,, with activate described tool chuck up to arrive second, different torque threshold.

2. tool chuck as claimed in claim 1 wherein, also comprises:

Be configured clutch mechanism with described tool chuck engagement and disengaging.

3. tool chuck as claimed in claim 2, wherein, described clutch mechanism activates by the sleeve pipe of sliding button or rotating band cam face.

4. tool chuck as claimed in claim 2, wherein, described clutch mechanism comprises the clutch part that is positioned on the described sleeve pipe, is used for meshing synergistic clutch part when described sleeve pipe is in second axial location, and this clutch part has towards the working face perpendicular to described longitudinal axis direction.

5. tool chuck as claimed in claim 2, wherein, described clutch mechanism comprises the clutch housing by the synergy part wedge embedding of the tool housing that uses one or more tooth bar and the described tool chuck of encirclement, make the axially-movable of described synergistic clutch part energy so that chimeric, prevent that simultaneously described clutch housing from rotating with respect to described tool housing with the baffle ring of described tool chuck.

6. tool chuck as claimed in claim 5 wherein, also comprises:

Be arranged on bias spring and latch spring between described synergistic clutch part and the described chuck body;

When the axial advance the puck of wherein said synergistic clutch part reclined the engagement of described bias spring and described chuck body, described synergistic clutch part was entered in the described clutch housing by the radial inward described latch spring that promotes to recline.

7. tool chuck as claimed in claim 6, wherein, described baffle ring comprises a plurality of sunk parts, and

When described clutch housing axially when clutch body moves, described synergistic clutch part radial outward ejects, with chimeric with described sunk part.

8. tool chuck as claimed in claim 1, wherein, described chuck body has the rear end on the axle that is fixedly mounted in power transmission machine and comprises the front end of a plurality of passages that support a plurality of chuck jaws slidably.

9. tool chuck as claimed in claim 8, wherein, described chuck jaws tilts, and causes its front end to converge towards described longitudinal axis.

10. tool chuck as claimed in claim 8, wherein

Described sleeve pipe has nut, and

Described chuck jaws comprises and the end-face helical of the interactional radial outward of end-face helical of the radial inward of described nut, is used for advancing or the described chuck jaws that bounces back.

11. tool chuck as claimed in claim 1, wherein,

Described sleeve pipe has nut, and

Between described nut and described chuck body, be provided with bearing, so that relatively rotate between described nut and the chuck body.

12. a tool chuck comprises:

One chuck body;

One be installed on the described chuck body, be used for the sleeve pipe that between first axial location and second axial location, moves, this sleeve pipe comprises the first clutch part, described first clutch part can partly mesh with second clutch when described sleeve pipe is in second axial location, and described first clutch partly is configured to apply first torque threshold and can be with respect to the slippage of described second clutch part when second direction applies second torque threshold along first direction.

13. tool chuck as claimed in claim 12, wherein, the varying in size of described first torque threshold and described second torque threshold.

14. a tool chuck comprises:

One chuck body;

One first sleeve pipe;

One second sleeve pipe;

Be in the first clutch part on described first sleeve pipe, and

Be in the second clutch part on described second sleeve pipe, described first clutch part is partly thrown off with this second clutch under the effect that tightens of described tool chuck, forces the rear portion propelling of described first sleeve pipe to the described chuck body previous dynasty.

15. tool chuck as claimed in claim 14, wherein, described chuck body comprises that being positioned at being used on its rear end receives described first clutch one or more lock pawl one or more sunk part partly partly, cause with described lock pawl part chimeric, to prevent relative motion between described first sleeve pipe and the described chuck body.

16. the tool chuck with instrument of instrument motor comprises:

One chuck body;

A plurality of chuck jaws, it selectively is fixed in the annex of power transmission machine wherein, and

One is installed in is used for the sleeve pipe that the brake function according to the axle spring loaded actuator moves on the described chuck body between first axial location and second axial location.

17. tool chuck as claimed in claim 16, wherein, described actuator activates under the user handles, and unclamps or tightens described chuck jaws with the operation tool motor.

18. a tool chuck comprises:

One limits the chuck body of longitudinal axis;

A plurality of chuck jaws, it selectively is fixed in the annex of power transmission machine wherein;

One is installed in the sleeve pipe on the described chuck body; And

One clutch mechanism, it is applicable to axial advance the puck and chimeric with fixing sleeve pipe, inadvertently unclamps or tightens to prevent described chuck jaws.

19. a tool chuck comprises:

One limits the chuck body of longitudinal axis;

One be installed on the described chuck body, be used for the sleeve pipe that between first axial location and second axial location, moves, this sleeve pipe comprises clutch part, described clutch part and synergistic clutch part engagement when this sleeve pipe is in described second axial location, described clutch part has towards the working face perpendicular to described longitudinal axis direction.

20. the tool chuck with power transmission machine of motor comprises:

One chuck body, and

The clutch ring that can be activated by the user of described power transmission machine, it is used for described motor engagement or disengagement so that annex keeps and/or breaks away from.

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