DE185781C - - Google Patents

Description

MahetC'tcfycn cßal'ci ι ('etui Ii.

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

CLASS 49 «. GROUP

There are already thread cutting benches with Norton gearboxes known, with those without Replacement of wheels can be cut with both metric and Whitworth threads can. In relation to these known banks, the invention is only in the special one overall structural arrangement of the speed change of the intermediate shaft of a Norton gearbox to enable

ίο to cut a larger number of intermediate threads in addition to the usual threads without changing wheels. In the drawing, FIG. 1 shows a side view of the headstock, FIG. 2 shows a section through the same, FIG. 3 shows a longitudinal section on an enlarged scale according to line AA of FIG. 4, FIG. 4 shows a cross section along line BB of FIG. 3 and Figure 5 is an end view.

ao With the Whitworth threads, a certain number of threads comes to the English inch, which depends on the diameter of the screw. If you pick out those screws with 2 to 30 thread turns to the inch, the following series results for the number of thread turns per inch: 30, 28, 24, 22, 20, 18, 16, 14, 12, 11, 10, 9, 8, 7.50, 7, 6.50, 6, 5.50, 5, 4.75, 4.50, 4.25, 4, 3.75, 3.50, 3.25. 3. ² '75, 2.50, 2.25, 2.

Now determine the number of threads that come to four inches, and If this length is set as the numerator and the number of threads as the denominator, the following is obtained Line:

4th 4th 4th 4th 4th 4th 4th 4th 4th 4th 120 112 96 IO 88 9 80 8th 72 64 4th 4th 4th 4th 4th 4th 4th 56 48 44 40 36 32 30th 4th 4th 4th 4th 4th 4th 4th 28 26th 24 22nd 20th 19th 18th 4th 4th 4th 4th 4th 4th 4th 17th 16 15th 14th 13th 12th II

40

45

This series corresponds to the basic types.

The lead screw lathes have a constant which is related to them Ratios stands; it is the number of threads per lead screw Customs. For cutting a screw, which

e.g. the ratio

corresponds, must

advance the carriage 4 inches while the work spindle rotates 120 revolutions. Assuming 4 threads per inch of the lead screw, the Make the spindle 4 revolutions as the slide advances one inch and 4x4 revolutions during operation

complete path of the sledge. So if you multiply the counters by 4, you get a new row whose counters the number of revolutions of the lead screw and their Denominator indicate the number of revolutions of the work spindle.

In addition, it is necessary to determine the number of teeth for the one corresponding to the unit To determine the wheel, and proportionally to this number one then obtains the teeth of the remaining ones the given conditions.

Depending on the size, if you take the

■ Resistance and the speed of the lathe for example 32 teeth for this wheel on, it is sufficient to determine the ratios of the teeth that Multiply the numerator and denominator by 2, which gives you a series of fractions receives whose counters indicate the number of teeth that have the guide or head wheel must, the denominator of the number of teeth of the gear of the lead screw BEZW. of the taken Specify the gear.

If one wanted to construct these ratios mechanically, a gear would have to be used of 32 teeth are meshed with as many other gears as there are denominators, and each of them so have many teeth than the denominators indicate.

Such a gear transmission would be useless because of its size.

If one examines these ratios more closely, one sees that ten of them can be viewed as basic numbers for all the rest, because by means of these ten you can find the others by simply multiplying them with the ratios 2: 1, 1: 2, ι: 4 determine.

These basic IO numbers are as follows:

32 32 32 32 32

■ 60 56 52 48

_3_2_ 40

32 3 ²
38 36

34

44

32

32

Multiply them by 2: 1, 1: 2, 1: 4, so you not only get all the ratios in the basic series, but one more Number of intermediate values.

So if you equip the lathe with a set of 10 wheels, the individual wheels of which have numbers of teeth corresponding to the denominators of the above fractions, and the individual wheels alternate with a gear, the number of teeth corresponds to the numerator of the fractions, and further between the axis of the last-mentioned wheel and the workpiece spindle switches on an intermediate gear, the one ratio of 2: 1, 1: 1, 1: 2, ι: 4 enable, one obtains through suitable Switching of these wheels all basic threads of the series. And besides' still 9 secondary threads.

In order to perfect the lathe, in addition to the ten basic gears, an eleventh auxiliary wheel has been added which, through suitable switching of the intermediate gears, supplies four new threads which often occur in practice. It is therefore possible to cut the 31 basic threads and 13 secondary threads, so on the whole a uniform series of λόώ 44 threads without having to change any wheel.

The number of basic gears can of course be greater or less than eleven and one By combining them, a greater or lesser number of thread turns can be achieved cutting, depending on the requirements placed on the lathe.

The thread cutting machine, which is based on the above calculation, consists of a Norton stepped gear transmission 1, the wheels of which have as many teeth as the denominators of the basic ratios indicate. All the wheels are placed on the end 2 ^{1 of} the lead screw 2 and are partially covered in a box 5 which serves as a bearing for the shaft 3. On this shaft 3 sits a gear 3 ¹ , the number of teeth corresponds to the numerator of the basic row. This gear wheel 3 ¹ can be brought into connection with each of the step wheels by means of an intermediate ^{wheel 4 1} mounted in a swingable and displaceable lever 4, 4 ^2. In order to hold the intermediate wheel in the various positions, the plate 5 ^{1 of} the box 5 is provided with holes (FIG. 1) into which a pin 4 ³ penetrates. On the end of the shaft 3 are the gears 6, 6 ¹ , 6 ² , with which a gear 7 ² can be connected, the "diameter of which corresponds to the diameters of the wheels 6, 6 \ 6 ² like 1: 1, 1 : 2, 1: 4. The connection is established by an intermediate gear ^{7 1 mounted in a swing-out and displaceable lever 7.}

At the head end of the drive spindle 11 ¹ no there are gears 11 ² and 11 ³ . These can be brought into engagement with gears 10 and ³ , which are seated on the lever 9 which is rotatable about the shaft 12. The gear wheel io ¹ constantly meshes with 10, and io ² constantly meshes with io ³ . The lever 9 can assume three positions, those corresponding to FIG. 5, and the two corresponding to the holes 9 ¹ , 9 ² . In the first-mentioned position, the movement is reduced by the gear wheel io ³

averages. In the position 9 ¹ the gears 1.1 ⁸ and 11 ^{2 are} out of engagement with the gears of the lever 9; in the position 9 ² the gears -ro ¹ , 10, 11 ² are connected to one another. In the first position the transmission ratio is 2: 1, in the last 1: 1.

Claims (1)

Patent claim: Lead screw lathe for cutting threads, be'i on which a stepped gear is arranged on the lead screw, the individual wheels of which can be brought into connection with a gear wheel arranged displaceably on a secondary shaft by means of an intermediate wheel mounted in a swing-out lever, characterized in that on this secondary shaft 3 gears (6, 6 ¹ , 6 ² ) are arranged, the diameters of which are chosen so that the diameter of a gear (7 ² ) provided on an intermediate shaft, which can be brought into connection with one of the three gears at will, to them as 1: 1, 1: 2.1: 4, and that this intermediate shaft from the workpiece spindle (11 ¹ ) through a further intermediate ^{gear (io 1} , ι o ² , 11 ² , 11 ³ ) either with a transmission ratio ι : ι or 2: 1 is driven, for the purpose of being able to cut a number of intermediate threads in addition to the usual threads without changing wheels. 1 sheet of drawings,