DE32784C - Three-wheeled velocipede - Google Patents

Description

IMPERIAL

PATENT OFFICE.

Three-wheeled velocipede.

Fig. 1 of the accompanying drawings shows [ a side view of the Velocipede, Fig. 2 a; Top view of the same, Fig. 3 is a side view and Fig. 4 is a front view of the apparatus by which one can vary the speed of travel without having to change the speed of rotation of the crankshaft. Fig. 5 is a vertical section through this apparatus.

The frame A consists of square steel of mostly square cross-section, which, to increase the strength, is attached in such a way that a diagonal of the cross-section is perpendicular to the direction in which the force acts. At suitable points on the frame, preferably at points B and C, Fig. 1, the rod of the frame is cold-bent, so that a ring or a loop is formed, whereby the elasticity of the frame is greatly increased.

¹ Up to now it has been considered necessary to make the whole frame as rigid as possible in order to avoid the vibrations which arise when driving on uneven ground and which are transmitted from the wheels to the saddle. Here, on the other hand, one seeks to remove the unpleasant effect of the bump through greater elasticity.

That part of the rod of the frame which lies between -B and C is wound to prevent the rod from bending at this point. At D, Fig. 1, the two ends of the frame rod are united in a tube, which with which the steering wheel. bearing fork is connected. This tube has a square opening to accommodate the two ends of the rod, is provided with a slightly conical thread on the outside and is also cut several times along its length as far as the thread extends.

After the rods are inserted into the tube, a nut is screwed onto the thread and thereby pressing the tube firmly against the rod ends.

In order not to take away the hardness of the steel rod of the frame, dgr Bearings and so on on the frame avoided soldering and heating and the bearings and so on. Connected to the frame by folded brackets or sleeves. For the same reason the rod is also twisted and bent when it is cold. The sleeves exist from two halves, which after they have been placed around the frame, screwed through Nuts with a slightly conical thread are held together.

With the crankshaft F, Fig. 3, 4 and 5, two disks EE ^{1 are} connected. The two inner sides of the same each have a helical, exactly symmetrical groove, Fig. 5. Between the two discs there is a link chain b, the connecting pins of which protrude on both sides over the chain links so much that they engage in the grooves α . In these two grooves the chain b is displaceable from the axis F to the circumference of the disks EE ^x , Fig. 5. To the friction of the pins in the grooves

To make it as small as possible, there are small rollers at the ends of the pins. Sitting loosely on the crankshaft next to the disk E or E ^{x is} an arm c, at the outermost end ii of which the two are firmly connected to each other. one-piece arms dd ¹ . are rotatably attached. One arm d ^l sits inside the disk and is connected to the outer end of the chain b . The other arm d is outside the disc; it is made quite thin so that it can be feathered. On the side of the outer end of this arm facing the disk there is a pin e, Fig. 4, which fits into a number of holes made in the disk. On the outside of the arm d there is attached a bracket g which is bent twice at an obtuse angle, FIG. 4, in which an arm h rotatable on the crankshaft is seated. A pin i is attached to a two-armed lever j , the pivot point of which is firmly connected to the frame. A rod k is connected to the lever j and with this again a vertically displaceable rod / which ends at the top in a handle m . This can be comfortably grasped by the driver by hand. If you pull the handle m upwards, the pin i presses against the arm / ?; this slides along the inclined surface of the bracket g and praises the resilient arm d to the side, whereby the pin e sitting on d is pulled out of one of the holes f. If e sits in one of the holes f, the arms cd and d ¹ must rotate with the disks E and E ^1. At the same time, the position of the chain b is thereby also determined; the same cannot move in the groove α . If e is pushed out of f , the connection between the disks and the arms cd and d ^[ is thereby broken and they do not run around with the disks. At the same time, the chain b moves in the grooves α and either comes closer to the circumference of the discs or the axis. A chain G, which is formed from individual flat U-shaped links that fit between the chain links of chain b , is used to transmit the force from the crankshaft to shaft M. G must be long enough to wrap around sprocket EE ¹ reaches around when the chain b has most approximated the circumference of E3 ^l '. The necessary tension in the chain G is always maintained and regulated, for example, by a counter-pressing weight, a spring, etc.

By shifting the chain b in the Nuthen changing the relative speed of the shaft M with respect to the crankshaft at the same speed of F. F is the W ⁷ elle M to rotate the faster, the more the chain b the extent of EE ^{1 is} approaching. The provision of increasing or decreasing the diameter of the wheel in question by means of the chain b can be arranged both on the drive wheel and on the driven wheel. However, it is most expedient if it is only attached to the drive wheel.

Claims (2)

Patent claim:
A three-wheeled velocipede, characterized by the following institutions: ι. an apparatus for changing the speed of the drive shaft without simultaneously changing the speed of the crankshaft, consisting of two disks EE ¹ fixed on the latter, provided with spiral grooves and a short link chain b, which can be moved between the disks in the grooves of the same, over which the pull chain G runs; 2. the use of rods I and k, lever j with pin i, arms cdd ¹ and h to hold and move chain b (Fig · 3) 4 ^and 5) - For this purpose 2 sheets of drawings.