This application claims priority of Taiwanese Application No. 093125345, filed on Aug. 23, 2004.
1. Field of the Invention
This invention relates to a torque-indicating wrench, more particularly to an electrical torque-indicating wrench with a replaceable strain gage unit mounted to a wrench body for measuring a torque applied to a workpiece with a high degree of precision.
2. Description of the Related Art
U.S. Pat. Nos. 3,970,155, 4,006,629, 4,522,075, 4,669,319 and 4,976,133 disclose electrical torque-indicating wrenches that generally have strain gages attached to a lever arm proximate to a head for measuring torque. The head is suited to engage and rotate a workpiece by applying a force to the lever arm. The strain gages detect elastic strains and changes in electrical resistances, translate the changes into an electrical signal, and, in cooperation with a processing circuit which includes a Wheatstone bridge, an amplifier, a recorder, a microprocessor, an output unit, etc., determine a value of torque applied to the workpiece. Strain (ε) is related to a bending moment (M) through the relationship:
When an object with a modulus of elasticity (E) and a moment of inertia (I) relative to a neutral axis is subjected to a bending moment (M), the strain (ε) is directly proportional to a distance (y) between the measured point and the neutral axis. In the aforementioned prior art wrenches, the strain gages are attached to a lateral surface of the lever arm away from the neutral axis so as to produce a larger strain value, based upon which the processing circuit can calculate the torque precisely. However, a relatively large area of the lateral surface of the lever arm to which the strain gages are attached has to be machined with high precision so as to facilitate attachment of the strain gages, thereby resulting in higher manufacturing cost. Furthermore, conventional strain gages are not replaceable once they are broken or damaged.
Referring to
The object of the present invention is to provide a torque-indicating wrench which has a replaceable strain gage unit mounted to a wrench body for measuring a torque applied to a workpiece with a high degree of precision.
According to this invention, the torque-indicating wrench includes a wrench body having a head adapted to engage and turn a workpiece about a rotational axis, and a stem extending from the head in a longitudinal direction radial to the rotational axis to terminate at a coupled end. The stem is made from a material with a first modulus of elasticity, and has two outer longitudinal wall segments respectively extending in the longitudinal direction. A handle is coupled with the coupled end and is operable to turn the head.
At least one strainable body is made from a material with a second modulus of elasticity that is smaller than the first modulus of elasticity, and has a gage carrying major wall which is disposed on a respective one of the outer longitudinal wall segments so as to place the strainable body in a position of use where the strainable body is subject to stretching in the longitudinal direction in response to turning movement of the handle about the rotational axis. The gage carrying major wall has inner and outer major surfaces that are opposite to each other and that are respectively disposed proximate to and distal from the respective one of the outer longitudinal wall segments. The inner major surface, in the position of use, is brought into engagement with and is stretchable relative to the respective one of the outer longitudinal wall segments in the longitudinal direction.
A restraining member is disposed to restrain the strainable body from moving away from the respective one of the outer longitudinal wall segments in a transverse direction transverse to the longitudinal direction and the rotational axis while permitting a stretching movement of the strainable body in the longitudinal direction.
A strain gage unit is attached to the outer major surface to detect change in resistance values which is a function of extent of stretching deformation of the strainable body as a result of application of torque by the head when the head turns the workpiece about the rotational axis, and to translate the change in resistance values into an electrical signal.
A processing circuit is connected electrically to the strain gage unit to calculate a value of the torque applied to the workpiece in accordance with the electrical signal from the strain gage unit so as to generate an output signal.
A display unit is connected electrically to the processing circuit for receiving the output signal from the processing circuit and for translating the output signal into a visual presentation.
Other features and advantages of the present invention will become apparent in the following detailed description of the preferred embodiments of the invention, with reference to the accompanying drawings, in which:
Before the present invention is described in greater detail, it should be noted that same reference numerals have been used to denote like elements throughout the specification.
Referring to
The wrench body 10 has a head 11 which is adapted to engage and turn a workpiece (not shown) about a rotational axis, and a stem 12 which extends from the head 11 in a longitudinal direction radial to the rotational axis, and which terminates at a coupled end 121. The stem 12 is made from a material with a first modulus of elasticity (E1), such as steel with E1=190 Gpa, and has two outer longitudinal wall segments 123 which are opposite to each other relative to a neutral axis (x) of the stem 12 and which respectively extend in the longitudinal direction. Each of the outer longitudinal wall segments 123 is recessed in a transverse direction transverse to the longitudinal direction and the rotational axis to form a concavity 1231, and has front and rear edge portions 1233, 1234 opposite to each other in the longitudinal direction, and a bottom portion 1232 interconnecting the front and rear edge portions 1233, 1234 to define the concavity 1231. The coupled end 121 defines a wire receiving hole 125 which extends to be communicated with the concavities 1231 formed in the outer longitudinal wall segments 123.
The handle 50 is tubular, and has a front portion 51 which defines a forwardly opened recess that extends in the longitudinal direction and that is configured for insertion of the stem 12 in the longitudinal direction so as to be operable to turn the head 11 about the rotational axis, and a rear portion 52 which is opposite to the front portion 51 and which has a display opening 53.
Each of the strain detecting units 20 is detachably mounted in a respective one of the concavities 1231, and includes a strainable body 21, a restraining member and a strain gage unit 22.
The strainable body 21 is made from a material with a second modulus of elasticity (E2) that is smaller than the first modulus of elasticity (E1), such as aluminum alloy with E2=70 Gpa, and has a gage carrying major wall which is disposed on the respective outer longitudinal wall segment 123 so as to place the strainable body 21 in a position of use where the strainable body 21 is subject to stretching in the longitudinal direction in response to turning movement of the handle 50 about the rotational axis. Specifically, the gage carrying major wall has inner and outer major surfaces 211, 212 which are opposite to each other and which are respectively proximate to and distal from the respective outer longitudinal wall segment 123. The inner major surface 211, in the position of use, is attached to and is stretchable relative to the bottom portion 1232 of the respective outer longitudinal wall segment 123 in the longitudinal direction, and is spaced apart from the front and rear edge portions 1233, 1234, as shown in
The restraining member includes two screw holes 1235 which are formed in the bottom portion 1232 of the respective outer longitudinal wall segment 123 and which are opposite to each other in the longitudinal direction, two elongated holes 213 which extend from the outer major surface 212 through the inner major surface 211 and which are elongated in the longitudinal direction, and two screw bolts 23. Each of the screw bolts 23 has a screw shank 231 that extends through a respective one of the elongated holes 213 and that threadedly engages a respective one of the screw hole 1235 which is registered therewith, and an enlarged head 232 that abuts against the outer major surface 212 around the respective elongated hole 213 so as to restrain the strainable body 21 from moving away from the bottom portion 1232 in the transverse direction and so as to permit the stretching movement of the strainable body 21 in the longitudinal direction.
The strain gage unit 22 includes two strain gages 221 which are attached to the outer major surface 212 of the respective strainable body 21 between the elongated holes 213, which are spaced apart from the front portion 51 of the handle 50 in the transverse direction, and which are spaced apart from each other in the longitudinal direction, as shown in
With reference to
The display unit 40 is received in the rear portion 52 of the handle 50, and is connected electrically to the processing circuit 30 for receiving the output signal from the processing circuit 30 and for translating the output signal into a visual presentation for viewing through the display opening 53. As the processing circuit 30 and the display unit 40 are known in the art, a detailed description thereof is dispensed with herein for the sake of brevity.
Referring to
According to the aforesaid relationship between the strain (ε) and the bending moment (M), since the strain gages 221 are attached to the strainable body 21 in this embodiment, the distance (y) from the strain gages 221 to a neutral line (X) of the respective strainable body 21 can be made greater as compared with the aforesaid conventional wrench. In addition, since the second modulus of elasticity (E2) of the strainable body 21 is smaller than the first modulus of elasticity (E1) of the stem 12, and since the strainable body 21 has a moment of inertia (I) that is smaller than that of the handle 101 of the aforesaid conventional wrench, the strain (ε) generated in the strain gages 221 of this embodiment is greater as compared with the aforesaid conventional wrench, thereby producing a significant change in resistance values for processing by the processing circuit 30 to obtain a precise torque value.
As shown in
While the present invention has been described in connection with what is considered the most practical and preferred embodiments, it is understood that this invention is not limited to the disclosed embodiments but is intended to cover various arrangements included within the spirit and scope of the broadest interpretations and equivalent arrangements.
Number | Date | Country | Kind |
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93125345 A | Aug 2004 | TW | national |
Number | Name | Date | Kind |
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3943761 | Shoberg et al. | Mar 1976 | A |
4006629 | Barrett et al. | Feb 1977 | A |
4558601 | Stasiek et al. | Dec 1985 | A |