The present invention relates to a torque tool and more particularly to the tubular body of an electronic torque wrench.
A torque wrench has a tubular body, a plurality of components mounted on the tubular body, and a working head mounted at a front end of the tubular body. An electronic torque wrench uses electronic components to set the torque value to be applied and sense the torque applied, so the number of components required by an electronic torque wrench and the total volume of the components are both smaller than those of a mechanical torque wrench. An electronic torque wrench has a relatively small number of components, its tubular body need not have a large interior space. This explains why the tubular body of an electronic torque wrench seldom has a uniform outer diameter throughout but has a relatively small outer diameter at the junction between the working head and the tubular body (hereinafter referred to as the small diameter portion) to reduce the weight, volume, and material of the wrench. The relatively large deflection and deformation of the small diameter portion also allow the torque applied to be sensed more precisely.
After actual use, however, it was found that the tubular body 10 has many drawbacks. First, Since the tubular body 10 is sleeved by the large and small tubes 14, 12, a gap 18 is formed at the junction of the two tubes 12 and 14, dust tends to enter the tubular body 10 through the gap 18, that is to say, the conventional tubular body 10 is not dustproof. The electronic components in the tubular body 10, therefore, may end up covered with dust such that their service lives and accuracy are compromised.
Second, the conventional tubular body 10, which includes tubes of different diameters fitted together and secured by the coupling elements 16, has a relatively high production cost and assembly cost. Moreover, since at the junction the large and small tubes 14 and 12 have a gap and the tubes are not tightly attached, the structural strength of the tubular body is weak, and the gapped junction is also unsightly. The foregoing drawbacks of the conventional tubular body of an electronic torque wrench have yet to be overcome.
The primary objective of the present invention is to overcome the aforesaid drawbacks by providing a tubular body for an electronic torque wrench wherein the tubular body includes a large diameter portion and a small diameter portion and is dustproof at the junction between the two portions.
Another objective of the present invention is to provide a tubular body for an electronic torque wrench wherein the tubular body can be manufactured at a lower cost than its prior art counterparts.
Still another objective of the present invention is to provide a tubular body for an electronic torque wrench wherein the structural strength of the tubular body is enhanced.
Yet another objective of the present invention is to provide a tubular body for an electronic torque wrench wherein the tubular body has a more beautiful appearance.
The present invention provides a tubular body for an electronic torque wrench, wherein the tubular body has an integrally formed structure and includes a small diameter portion, a bridge portion, and a large diameter portion;
the small diameter portion, the bridge portion, and the large diameter portion are sequentially connected along the longitudinal direction of the tubular body; the outer diameter of the large diameter is larger than that of the small diameter portion;
the bridge portion has two ends connected respectively to a rear end of the small diameter portion and a front end of the large diameter portion; and
the length of the tubular body is 1.18˜2.6 times the length of the large diameter portion, and the length of the small diameter portion is 0.18˜1.6 times the length of the large diameter portion.
Accordingly, the junction between the large diameter portion and the small diameter portion is free of gaps and therefore dustproof. The tubular body is integrally formed rather than assembled from two tubes of different outer diameters and hence has a lower production cost and higher structural strength and makes a better looking wrench than the conventional tubular bodies.
Preferably, the length of the bridge portion is 0.085˜0.32 times the length of the large diameter portion.
The tubular body further has an opening in the peripheral wall of the large diameter portion.
Preferably, the length of the opening does not exceed one half of the length of the large diameter portion, and the depth of the opening is approximately one half of the outer diameter of the large diameter portion.
The distance from the front end of the tubular body to the rear end of the opening is defined as a layout length, and the layout length is preferably 0.67˜0.86 times the length of the tubular body.
The objectives, features, and intended effects of the present invention can be better understood by referring to the following detailed description of two preferred embodiments of the invention with the accompanying drawings, in which:
Please refer to
Referring to
In the preferred embodiment shown in
The small diameter portion 22 has an outer diameter D1, and the large diameter portion 24 has an outer diameter D2, wherein the outer diameter D1 is 0.7˜0.8 times, preferably 0.75˜0.78 times, the outer diameter D2. The foregoing length and outer diameter ratios produce the preferred structural proportion of the tubular body 20 and can satisfy the requirement in structural strength as well as in the comfortableness of operation.
An opening 26 is formed in a front section of the peripheral wall of the large diameter portion 24 by cutting the tubular body 20. Preferably, the opening 26 has a length P not greater than one half of the length N of the large diameter portion 24. For example, the length P of the opening 26 is 0.35˜0.48 times, preferably 0.44˜0.47 times, the length N of the large diameter portion 24. The rear section of the large diameter portion 24, i.e., the section rearward of the opening 26, forms a gripping area 28 of the tubular body 20 and is intended to be gripped by the user. The distance from the front end of the tubular body 20 to the rear end of the opening 26 is defined a layout length R, which limits the position of the rear end of the opening 26. The layout length R is 0.69˜0.74 times, preferably 0.71˜0.73 times, the length L of the tubular body 20. The gripping area 28 has a gripping area length S defined between the rear end of the opening 26 and the rear end of the tubular body 20. The gripping area length S is 0.26˜0.31 times, preferably 0.27˜0.29 times, the length L of the tubular body 20 and the gripping area length S is 0.45˜0.51 times, preferably 0.46˜0.5 times, the length N of the large diameter portion 24. Referring to
Referring to
When the electronic torque wrench 50 is used to rotate a threaded element (e.g., a bolt, nut, or the like), the torque applied to the wrench 50 can be known by sensing the deflection of the small diameter portion 22. The length and diameter ratios between the large diameter portion 24 and the small diameter portion 22 in this preferred embodiment provide the wrench 50 with the optimal strength and allow the small diameter portion 22 to be deflected in the optimal manner so that an accurate torque value can be obtained and a long service life, expected. The ratio of the layout length R to the length L of the tubular body 20 sets a limit on the position of the rear end of the opening 26 so that the most appropriate gripping area 28 can be formed, allowing the user to operate the wrench 50 with ease by gripping the tubular body 20.
Apart from the advantages mentioned above, the tubular body 20 of the present invention is integrally formed and therefore has no gap at the junction between the large diameter portion 24 and the small diameter portion 22, meaning the tubular body 20 is dustproof, i.e., can prevent the entry of dust and dirt.
Moreover, the one-piece configuration of the tubular body 20 makes possible a simpler manufacturing process, a shorter assembly time, and hence lower production cost than in the prior art, which entails fitting two separate tubes (i.e., a large diameter tube and a small diameter tube) together and then securing the tubes with a plurality of coupling elements.
In addition, the integrally formed tubular body 20 has higher structural strength and can cope with larger operating forces than in the prior art, and the tapered bridge portion 25, which joins the large diameter portion 24 and the small diameter portion 22 together, eliminates assembly gaps and thereby renders the tubular body 20 a better appearance and more visually pleasant.
Please refer to
Each portion of the tubular body 20′ also has a length as defined in the first preferred embodiment, and the various lengths are also defined by ratios based on the length N of the large diameter portion 24. More specifically, the length L of the tubular body 20′ is 1.18˜2.6 times, preferably 1.2˜2.5 times, the length N of the large diameter portion 24; the length O of the bridge portion 25 is 0.085˜0.32 times, preferably 0.2˜0.3 times, the length N of the large diameter portion 24; and the length M of the small diameter portion 22 is 0.18˜1.6 times, preferably 0.2˜1.5 times, the length N of the large diameter portion 24. It is worth mentioning that the length M of the small diameter portion 22 in this embodiment may vary greatly within the aforesaid ranges, i.e., may be far less than the length N of the large diameter portion 24 or more than 1.5 times the length N of the large diameter portion 24. The layout length R is 0.67˜0.86 times, preferably 0.69˜0.85 times, the length L of the tubular body 20′.
The second preferred embodiment has the same effects as the first preferred embodiment shown in
The above embodiments are only used to illustrate the present invention, not intended to limit the scope thereof. Many modifications of the above embodiments can be made without departing from the spirit of the present invention.
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107143999 | Dec 2018 | TW | national |
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Number | Date | Country | |
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20200180129 A1 | Jun 2020 | US |