DE4320253A1 - Spanner ratchet - Google Patents

Abstract

Disclosed is a spanner ratchet (10) having a bush-like end (11) which in its interior bounds an inner wall surface (12). A pair of rotary bodies (21, 22) are rigidly interconnected by an eccentric shaft (24) and received in the bush-like end (11). A pair of retaining plates (40) is provided at the inner wall surface (12) on both sides of the bush-like end (11) in order to retain the rotary bodies therein. A resiliently flexible plate (31) is provided between the rotary bodies (21, 22), adjoining the eccentric shaft (24). An inverted V-shaped rigid locking element (32) is provided around the eccentric shaft (24) and includes a first and a second portion. The first portion includes a curved first side (323) formed adjacent to the inner wall surface (21) of the bush-like end (11), a straight second side (325) forming a first clearance (X) with the eccentric shaft (24), as well as a free end which interconnects the curved first side and the straight second side and is prestressed by the resiliently flexible plate element (31) in such a way that at least one region of the curved first side (323) adjacent to the resiliently flexible plate element (31) lies in a frictional-locking manner against the inner wall surface (12). The second portion includes a third straight side (326) which is connected to the curved first side (323) and a second ... Original abstract incomplete. <IMAGE>

Description

The present invention relates to a wrench ratchet and in particular on a ratchet to be inserted into a wrench nut.

Wrench ratchets for turning nuts, screws and similar fasteners Stabilizers have become widespread in the field of mechanics. Generally mean they facilitate the rotational movement of such fasteners and cause Ver same as other types of wrenches, such as adjustable wrenches, Socket wrenches and open-ended wrenches, less wear on the fasteners links.

Wrench nuts require a compatible drive mechanism that works on the wrench nut attacks and a handle for exerting torque the nut creates. Ratchet wrench type with ratchet wheel and pawls exert torque on the nut in one direction and drive in the opposite Direction of free rotation relative to the nut. Problems with such ratchets with ratchet wheel and pawls are primarily the result of the complex mechani training of the ratchet mechanism. The ratchet mechanisms were often too fine or sensitive to certain applications and failed due to overuse. In addition, the ratchet mechanisms were designed to be a certain counter moment of the fastener and the nut needed before moving in ge could run in the opposite direction. If the fastener was sufficiently loose and could turn so that the counter torque did not develop, the Be users generally apply this power with their free hand. This often turned out to be uncomfortable and uncomfortable and sometimes impossible.

An object of the present invention is therefore to provide a ratchet which the disadvantages mentioned are overcome and which has a simpler construction and is easier to manufacture.

A solution to this problem according to the invention results from the characteristics of the An saying 1.

According to the present invention, a wrench ratchet includes a hand gripped with a socket-like end with an inner wall surface, which one through the central opening extending through the socket-like end. A couple with each other identical rotating body with an eccentric shaft and egg rigidly connected between them A diameter smaller than that of the central opening is in the central opening arranged of the socket-like end. An annular space is around the eccentric shaft formed around and be through the inner wall surface of the socket-like end borders. The annular space has a porridge on one side of the eccentric shaft test area and on the other side of the eccentric shaft a narrowest area. The two rotating bodies have a central rectangular or square opening also extends through the eccentric shaft. A pair of retention plates is on the bush-like end attached on both sides of the rotating body such that the rotating body in the socket-like end are held. Each of the holding plates has a central round one Opening that is aligned with the rectangular opening and has a diameter, which is less than the diagonal length of the rectangular opening. A resilient Element is arranged between the two rotating bodies. A rigid locking element that around the eccentric shaft is arranged around has a first section and a two section. The first and second sections each have a free end that differs from that widest area away towards the narrowest area of the annular space stretch. The first section includes a curved first side facing the inner wall surface che of the socket-like end is formed adjacent, and a straight second side that a first space between the straight second side and the eccentric shaft bil det. The free end of the first section connects the curved first side and the straight one second side with each other. The free end of the first section is due to the resilient flexing bige element biased such that a resilient element adjacent Be  abuts the curved first side frictionally on the inner wall surface. Of the the second section includes a straight third side ver with the first curved side is bound and a second space between the straight third side and the inner Wall surface forms, as well as a curved fourth side, which is spaced from the eccentric shaft stands and the free end of the second section of the locking element with the straight two side of the first section connects. A survey area is between the straight ones second side and the curved fourth side is formed and lies on the eccentric Shaft in such a way that the locking element can be pivoted about the elevation. An on Drive element or a drive shaft is in the rectangular opening of the identi arranged rotating body and has two end portions, each consisting of a circular Protrude the opening of the retaining plates outwards so that you can use a wrench Nut, d. H. an element that has a receiving opening for the drive shaft and at the other end has an opening for engagement with a fastener, in one gripped to kick.

Preferred further bindings of the invention result from the subclaims.

The invention and further developments of the invention are described below with reference to the drawings rule representations of several embodiments explained in more detail. In the drawings demonstrate:

Fig. 1 is an exploded view of a first preferred Ausführungsbei game of a ratchet in accordance with the present invention;

Fig. 2 (A) is a sectional view of the ratchet of Figure 1 showing the ratchet in egg ner torque transmitting configuration.

Fig. 2 (B) is an enlarged view of the circle "P" + of Fig. 2 (A);

Fig. 3 (A) is a sectional view of the ratchet of Figure 1 showing the ratchet in a freely rotating configuration.

Fig. 3 (B) is an enlarged view of the circle "Q" of Fig. 3 (A);

Fig. 4 is an exploded view of a second preferred embodiment of a ratchet according to the present invention;

Fig. 5 (A) is a sectional view of the ratchet of Figure 4 showing the ratchet in egg ner torque transmitting configuration.

Fig. 5 (B) is an enlarged view of the circle "R" of Fig. 5 (A);

Fig. 6 (A) is a sectional view of the ratchet of Fig. 4 showing the ratchet in a free spinning configuration; and

Fig. 6 (B) is an enlarged view of the circle "S" of Fig. 6 (A).

As shown in FIG. 1, a wrench ratchet 10 according to the invention includes a handle 13 with a socket-shaped end 11 . The socket-shaped end 11 has an inner wall surface 12 which delimits a central opening which extends through the socket-shaped end. The inner wall surface 12 has a pair of annular grooves 121 each formed adjacent the upper and lower ends thereof.

A rotary member 20 includes a pair of identical rotating bodies 21 , 22 which are fixedly connected to one another by an eccentric shaft 24 fastened in between. The rotating body 21 , 22 each have a diameter which is smaller than that of the Innenwan extension 12 , and are arranged in the central opening of the socket-shaped end 11 . The two rotating bodies 21 , 22 have a central rectangular or square opening 26 , which extends through the eccentric shaft 24 . An annular space is formed around the eccentric shaft 24 and is delimited by the inner wall surface 12 . The annular space has a breitesten region 25 on one side of the ex-centric shaft 24, and a narrowest portion 25 'on the opposite, other bodies side of the eccentric shaft 24th

A pair of retaining plates 40 , which are either flat or curved plates ge, are each fixed in the annular grooves 121 of the inner wall surface 12 of the socket-shaped end 11 on both sides of the pair of rotating bodies 21 , 22 , to thereby the identical rotating body 21st To hold 22 in the socket-shaped end 11 . The compression method used to fasten the retaining plates 40 in the socket-shaped end 11 is a known method and is therefore not explained in more detail at this point. After assembly, the central openings 41 of the retaining plates 40 are aligned with the central rectangular opening 26 of the two rotating bodies 21 , 22 . The central openings 41 of the retaining plates 40 have a diameter that is smaller than the diagonal length of the rectangular opening 23 .

A drive element 50 is arranged in the rectangular opening 26 of the rotating body 21 , 22 and has two free ends, which each protrude from the central openings 41 of the retaining plates 40 to receive a wrench nut for turning a nut or the like. The drive element 50 also has a rectangular or square shoulder 51 , which is formed in a central region thereof and is fitted into the rotating bodies 21 , 22 , in order thereby to enable a rotational movement of the driving element 50 together with the rotating bodies 21 , 22 . The retaining plates 40 prevent the drive element 50 from falling out of the rectangular openings 26 in the rotating bodies 21 , 22 .

A V-shaped, resilient element 31 includes a first arm 311 and a second arm 312 , wherein the first arm 311 is inserted into a groove 23 formed in an inner surface of the rotating body 22 . An inverted V-shaped rigid locking element 32 is provided around the eccentric shaft 24 between the mutually identical rotating bodies 21 , 22 and has a first and a second section, each with a free end. The locking element 32 is seen at the widest area 25 of the annular space such that the free end of each section extends from the widest area towards the narrowest area 25 '. The first section of the locking element 32 includes an arcuately curved first side 323 , which is formed adjacent to the inner wall 12 of the socket-shaped end 11 , and a straight second side 325 , which forms a first free space X with the eccentric shaft 24 and the free end of which curved first side 323 and the straight second side 325 connects to each other and is biased by the second arm 312 of the V-shaped, resilient element 32 such that an area adjacent to the resilient element 31 of the curved first side 323 is frictionally attached to the Inner wall 12 of the socket-shaped end 11 abuts. The second portion of the rigid locking member 32 includes a third straight side 326 that is connected to the curved first side 323 and forms a second clearance Y between the third straight side 326 and the inner wall 12 , and a curved fourth side 321 that from the eccentric shaft 24 is spaced, the free end 327 of this section connecting the third and fourth sides 326, 321 together. Furthermore, the locking element 32 includes an elevation 322 , which is formed between the second straight side 325 and the four th curved side 321 and bears against the eccentric shaft 24 , so that the locking element 32 can be pivoted about the elevation 322 .

With reference to FIGS. 2 and 3 it can be seen that when the handle 13 of the socket-shaped end 11 is rotated clockwise, as indicated by the arrow in FIG. 2, friction between the inner wall surface 12 of the socket-shaped end 11 and the GE curved first side 323 of the locking element 32 causes a rotational movement of the locking element 32 together with the bush-shaped end 11 . With further rotation of the handle 13 , a higher friction is generated, whereby the first portion of the locking element 32 causes a wedging effect in the narrowest area 25 'of the annular space and at the same time the locking element 32 enables a clockwise pivoting movement around the elevation 22 . The pivoting process causes a frictional engagement of the curved fourth side 321 of the locking element on the eccentric shaft 24 , which causes a rotational movement of the rotating bodies 21 , 22 together with the bushing-shaped end 11 and thereby a corresponding rotational movement of the drive element 50 .

When the handle 13 is rotated counterclockwise, as shown by the arrow in FIG. 3, the rigid locking element 32 initially performs a rotational movement together with the socket-shaped end 11 . The first portion of the locking element 32 triggers the United blocking with the narrowest area 25 'of the annular space and performs a pivoting movement counterclockwise around the elevation 323 , thereby biasing the resilient member 31 , thereby causing the curved fourth side 321 to be released is made possible by the eccentric shaft 24 . The locking element 32 is then pressed in the direction of the widest area and, due to the resilient element 31, pivots clockwise around the elevation 322 until the curved first side 323 bears against the inner wall surface 12 . With further rotation of the handle 13 it follows a rotational movement of the locking element 32 again in a counterclockwise direction and it enables the curved first side 323 and the curved fourth side 321 to be released from the inner wall surface 12 or the eccentric shaft 24 , as shown in FIG. 3 is shown. In this state, the inner wall surface 12 of the socket-shaped end 11 does not engage the locking element 32 , and the locking element 32 does not engage the eccentric shaft 24 when the handle of the ratchet according to the described embodiment performs a counterclockwise rotation. The bush-shaped end 11 then rotates freely with respect to the rotating bodies 21 , 22 . The locking element 32 is constantly held in the widest region of the annular space during the freely rotating movement of the ratchet.

An important feature is that due to the simple shape of the rigid locking element 32 , this rigid locking element 32 can be produced in a simple manner, where the manufacturing costs can be reduced.

. Referring to Figure 4, another preferred embodiment of the present invention shown to; the inner wall surface 12 'of the socket-shaped end 11 ' of the handle 10 'has a first set of vertically extending locking teeth 12 a', while the ge curved first side 323 'of the locking element 32 ' has a second set of outer locking teeth 323 a ', with the vertical locking teeth 12 a 'cooperate.

With rotation of the handle 10 'of the ratchet according to the invention clockwise, as shown by the arrow in Fig. 5, the locking teeth 323 a' mesh the inner wall surface 12 'with the locking teeth 12 a' of the locking element 32 ', so that between the Locking element 32 'and the inner wall surface 12 ' a greater frictional force is created. The rotating body therefore rotate together with the socket-shaped end 11 '. Upon rotation of the handle 10 'of the ratchet in a counterclockwise direction, as indicated by the arrow in Fig. 6, the locking teeth 323 a', 12 a 'detach from each other, whereby an idling movement of the book sen-shaped end 11 ' relative to the rotating bodies is made possible. Otherwise, the features and objectives of the second preferred exemplary embodiment are the same as in the previously described first exemplary embodiment. The pawl or ratchet mechanism used in the second embodiment is known in the art and thus requires no further explanation.

Claims (3)

1. Wrench ratchet, characterized by
a handle ( 13 ) with a socket-like end ( 11 ; 11 ') with an inner wall surface ( 12 ; 12 ') which limits a central bore extending through the socket-like end;
a pair of mutually identical rotating bodies ( 21 , 22 ), which have a smaller diameter than the inner wall surface ( 12 ; 12 ') and are arranged in the central opening of the bush-like end ( 11 ; 11 '), the two mutually identical rotations body ( 21 , 22 ) have an eccentric shaft ( 24 ) fixedly mounted therebetween and a central rectangular opening ( 26 ) extending through the eccentric shaft ( 24 ), an annular space around the eccentric shaft ( 24 ) between the two identical rotating bodies ( 21 , 22 ) is formed and is delimited by the inner wall surface ( 12 ), the annular space having a widest region ( 25 ) formed on one side of the eccentric shaft ( 24 ) and one on the other, the widest area opposite side of the eccentric shaft ( 24 ) formed narrowest area ( 25 ') and being between the two mitein other identical rotating bodies ( 21 , 22 ) a resilient element ( 31 ) is provided;
a pair of retaining plates (40) for holding the two rotating bodies (21,22) in said sleeve-like end (11; 11 ') on both sides of the pair identical to each other rotary body (21, 22) on the sleeve-like end (11; 11') are attached, each hard holding plate ( 40 ) has a through this extending round opening ( 41 ) which is aligned with the respective central rectangular opening ( 26 ) of the two rotary bodies by, the round opening ( 41 ) has a diameter , which is smaller than a diagonal length of the central rectangular opening ( 26 ) of the two mutually identical rotating bodies ( 21, 22 );
one in the central rectangular openings ( 26 ) of the two rotating bodies ( 21, 22 ) on ordered drive shaft ( 50 ) with two end areas, each of which protrude from the round openings of the retaining plates ( 40 ), so that these end areas in a wrench nut can be used to turn a nut, the drive shaft ( 50 ) has a rectangular shoulder ( 51 ) which is formed in a central region thereof and is fitted into the rectangular opening, so that a rotational movement of the drive shaft ( 50 ) together with the Rotating bodies ( 21 , 22 ) it is possible, wherein the drive shaft ( 50 ) from falling out of the rectangular opening of the two identical rotating bodies is prevented by the retaining plates ( 40 );
an inverted V-shaped, rigid locking element ( 32 ; 32 '), which is arranged around the eccentric shaft ( 24 ) and includes a first section and a second section, which away from the widest area towards the narrowest Extend area, the first and the second section each having a free end, the first section one of the inner wall surface ( 12 ; 12 ') of the bush-like end ( 11 ; 11 ') adjacent, curved first side ( 323 ) and has a straight second side ( 325 ) forming a first clearance (X) between the straight second side ( 325 ) and the eccentric shaft ( 24 ), the free end of the first portion being the curved first side ( 323 ) and the straight Be second ( 325 ) connects together and is resiliently biased by the resilient element ( 31 ; 31 ') such that at least one of the resilient element ( 31 ; 31 ') adjacent B Reaching the curved first side ( 323 ) frictionally on the inner wall surface ( 12 ; 12 ') of the socket-like end ( 11 ; 11 ') engages where in the second section with the curved first side ( 323 ) connected, straight de third side ( 326 ) and one the free end of the second section and the straight second side ( 325 ) of the first section connecting, curved fourth side ( 321 ), wherein a second clearance (Y) between the straight third Be te ( 326 ) and the inner wall surface ( 12 ; 12 ') of the socket-like end ( 11 ; 11th ') Is formed and the curved fourth side ( 321 ) is adjacent to the eccentric shaft ( 24 ), an elevation ( 322 ) being formed between the straight second side ( 325 ) and the curved fourth side ( 321 ), on the eccentric shaft ( 24 ) rests in such a way that the locking element ( 32 ; 32 ') can be pivoted about the elevation ( 322 );
wherein when the handle ( 10 , 10 ') rotates in a first direction, the friction between the curved first side of the rigid locking element ( 32 ; 32 ') and the inner wall surface ( 12 ; 12 ') of the socket-like end ( 11 ; 11 ' ) of the handle ( 10 ; 10 ') causes a pivoting movement of the first section of the rigid locking element around the elevation in the first section and the first section of the locking element wedges in the narrowest area ( 25 ') of the annular space and the curved fourth side ( 321 ) enables frictional engagement with the eccentric shaft ( 24 ); and
wherein upon rotation of the handle ( 10 ; 10 ') in a second direction opposite to the first direction, the friction of the first portion of the rigid locking element ( 32 ; 32 ') for performing a rotational movement in the second direction and a movement in the direction of widest area ( 25 ) causes, whereby the ge curved first side ( 323 ) of the first portion of the locking element ( 32 ; 32 ') a Lö sen from the inner wall surface ( 12 ; 12 ') of the socket-like end ( 11 ; 11 ') is and at the same time the curved fourth side ( 321 ) of the second section of the locking element ( 32 ; 32 ') a release from the eccentric shaft ( 24 ) is made possible. 2. Wrench ratchet according to claim 1, characterized in that the inner wall surface of the socket-like end is provided with a first set of vertically extending locking teeth ( 12 a ') and the curved first side of the rigid locking element ( 32 ') a second set of outer locking teeth ( 323 a ′) has, which are designed to cooperate with the first set of ratchet teeth. 3. wrench ratchet according to claim 1 or 2, characterized in that one ( 22 ) of the rotating body ( 21 , 22 ) has a groove formed in an inner surface and that the resilient element ( 31 ; 31 ') V-shaped is formed from and has two arms ( 311 , 312 ), one of which is inserted into the groove.