Patent Application
20100043607
1. Field of the Invention
The present invention relates to a wood working lathe.
2. Description of the Related Art
A conventional wood working lathe is usually made of metal material like cast-iron, die-cast aluminum and so on. No matter which metal material the wood working lathe is made of, the shortcomings of the metal wood working lathe are instability and properties of wear resistance. Therefore, this kind of wood working lathe is easy to be influenced via temperature and humidity. It causes higher cost of maintenance.
Moreover, during long-time use of the wood working lathe, degree of deformation of bed rails disposed on the wood working lathe would be increased to influence processing accuracy and tilt the location of lathe center. Further, wood pellets are easy to enter transmission case of the wood working lathe as to influence operation of the wood working lathe. Therefore, it is troublesome to clean the transmission case of the wood working lathe frequently.
The present invention is therefore intended to obviate or at least alleviate the problems encountered in prior art.
Referring to this state of the art it is an object of the present invention to improve a guiding rail of a lathe bed of a wood working lathe, with the deformation of the guiding rail being minimized during use. The deformation of the granite guiding rail is one quarter of the deformation of a cast-iron guiding rail of a conventional lathe bed approximately. Moreover, the deviation between lathe centers of fixed and foot stocks of the wood working lathe is 0.01 meters approximately.
Another object of the present invention is that active and passive wheels of base and fixed stocks of the wood working lathe are respectively provided inside of the base and fixed stocks. Hence, it can avoid wood pellets produced from cutting wood works to influence the operation of the active and passive wheels for increasing the efficiency of the wood working lathe.
Yet another object of the present invention is that the foot stock and a tool stock are respectively allowed to fix on the lathe bed or slide along the guiding rail of the lathe bed alternatively via positioned members.
Other objects and advantages of the present invention will be set forth in part in the description and in the drawings which follow and, in part, will be obvious from the description or may be learned by practice of the invention.
The present invention will be described via detailed illustration of the preferred embodiment referring to the drawings.
Referring to
The lathe bed 10 includes a guiding rail 11 extending thereon longitudinally and having an upward opening (not numbered) and an opening 12 vertically formed through the first end thereof, with the opening 12 in communication with the guiding rail 11.
Each base stock 20 is preferred an inverted U-shaped and includes a support surface 21 for supporting the lathe bed 10 steady on the base stocks 20 and an opening 22 formed on the related base stock 20 that is installed to the first end of the lathe bed 10, with the opening 22 corresponding to the opening 12 of the lathe bed 10. However, in an alternative embodiment, it is possible that the base stocks 20 are integrally installed to the lathe bed 10. A driving unit 23 is disposed in the related base stock 20 that is installed to the first end of the lathe bed 10 and includes an active wheel 231 provided with respect to the openings 12 and 22 of the lathe bed 10 and the base stock 20 that is installed to the first end of the lathe bed 10.
Referring to
The foot stock 40 is disposed on the top of the second end of the lathe bed 10 and slidably along the guiding rail 11 via a sliding portion 41, with the sliding portion 41 provided on the bottom of the foot stock 40. A positioned member 42 is adapted for fixing the foot stock 40 onto the lathe bed 10 or allowing the foot stock 40 to slide on the lathe bed 10 alternatively. The positioned member 42 includes a positioned shaft 421 perpendicular to the lathe bed 10 and a lever 422 adapted for controlling the positioned shaft 421 to move with respect the lathe bed 10 upward/downward. The lever 422 has first and second ends 4221 and 4222, with the first end 4221 being perpendicular to the second end 4222 approximately. The second end 4222 of the lever 422 is inserted through the foot stock 40 and an end of the positioned shaft 421, with the positioned shaft 421 disposed inside of the foot stock 40, with the second end 4222 of the lever 422 being perpendicular to the guiding rail 11 of the lathe bed 10. Another end of the positioned shaft 421 is inserted into the guiding rail 11 and engaged with a limited disk 423 as to limit the limited disk 423 in the guiding rail 11. A coupled portion 4223 is provided on the second end 4222 of the lever 422, with the section of the coupled portion 4223 being oval-shaped. In use, the first end 4221 of the lever 422 is operated, and then the coupled portion 4223 biases the positioned shaft 421 to slightly move with respect the lathe bed 10 upward/downward. When the positioned shaft 421 moves with respect the lathe bed 10 upward, the foot stock 40 is fixed on the lathe bed 10. When the positioned shaft 421 moves with respect the lathe bed 10 downward, the foot stock 40 is allowed to slide along the guiding rail 11 via the sliding portion 41.
A through-hole 43 is formed through the foot stock 40 transversely and parallel to the direction of the guiding rail 11. A feeding means 44 is disposed through the through-hole 43 and includes a threaded shaft 441, a hand wheel grip 442 and a tool sheath 443. The threaded shaft 441 is inserted through the foot stock 40 axially via the through-hole 43. The wheel grip 442 is fixed to an end of the threaded shaft 441 opposite to the fixed stock 30. The tool sheath 443 is disposed in the foot stock 40 and engaged with another end of the threaded shaft 441. The wheel grip 442 is operated for driving the threaded shaft 441 to adjust the location of the tool sheath 443 with respect the threaded shaft 441. A positioned element 47 is selectively abutted against the tool sheath 443 via a limited slot 444 that is formed on the tool sheath 443 as to selectively prevent the threaded shaft 441 and the wheel grip 442 from turning relative to the tool sheath 443. A clamping element 45 is connected to the threaded shaft 441 toward the fixed stock 30. A lathe center 46 is coupled to the distal end of the clamping element 45. The lathe centers 36 and 46 of the fixed and foot stocks 30 and 40 are provided in a straight direction parallel to the guiding rail 11 of the lathe bed 10 and adapted for clamping the works to turn.
The tool stock 50 is in form of L-shaped and disposed on the lathe bed 10 transversely. A fixed element 51 is adapted for fixing the tool stock 50 onto the lathe bed 10 or allowing the tool stock 50 to slide on the lathe bed 10 alternatively. A tool rest 52 is inserted to the tool stock 50, with an axis of the tool rest 52 spaced from and parallel to an axis of the lathe bed 10. In use, a user's hand can put on the tool rest 52.
In the present invention, the lathe bed 10, the base, fixed and foot stocks 20, 30 and 40 are all made of granite. In addition, the tool stock 50 can also be made of granite. Therefore, it can minimize the deformation of the guiding rail 11 during use. The deformation of the granite guiding rail 11 is one quarter of the deformation of the conventional cast-iron guiding rail of the lathe bed approximately. And the deviation between the lathe centers 36 and 46 of the fixed and foot stocks 30 and 40 is 0.01 meters approximately.
Granite is a common and widely occurring type of intrusive, felsic, igneous rock. Granite has a medium to coarse texture, occasionally with some individual crystals larger than the groundmass forming a rock known as porphyry. Granite is nearly always massive (lacking internal structures), hard and tough, and therefore it has gained widespread use as a construction stone. The average density of granite is 2.75 g/cm3.
Granite is a highly durable siliceous stone. Compared to marble, it is more resistant to the acids found in lemons, vinegars, and cleaning products and usually will not etch. It is an easy stone to live with.
Granite characteristics make this stone virtually scratch proof. It will not scratch even when directly cut on. Things such as keys, coins, utensils, and appliances won't scratch it either.
Granite will actually dull your knives. Little slivers of the knife can become embedded in your stone. This is very noticeable with the darker stones so make a note if you are using your stone as a cutting board.
The characteristics of granite also make this stone heat resistant. It can withstand heat up to 1200 degrees Fahrenheit. You won't have to worry about any burn or char marks. Seams or joints in your stone can weaken it so you probably don't want to put a pot of boiling water near a seam.
Another granite characteristic is the lower water absorption rate when compared to marbles and limestones.
What are the uses of granite? It is most commonly used for countertops and monuments because of its outstanding durability.
Granite is also used for flooring, window sills, shower surrounds, islands, fireplaces, bar tops, and benches. There are fountains, columns, and accessories carved out of granite, too.
Furthermore, the compartment 31 is in communication with the driven unit 33 inside of the fixed stock 30. And the active and passive wheels 231 and 332 are respectively provided inside of the base and fixed stocks 20 and 30. Hence, it can avoid wood pellets produced from cutting wood works to influence the operation of the active and passive wheels 231 and 332 for increasing the efficiency of the driving unit 23 and the driven unit 33. Moreover, granite can prevent the temperature of the wood working lathe from increasing and avoid users burning.
