FR2658258A1 - In line gearbox with floating gearwheels - Google Patents

Abstract

Mechanical gearbox characterised by: A primary shaft (1) in its rotation driving a number of gearwheels equal to the number of speeds, (ratios) in the box. A hollow secondary shaft (2) inside which there moves a speed-selector slider (3). The end of the slider, through the use of a recess (4) controls the forward and backward movement (or vice versa) of a sliding gearwheel with dog clutch (5). This sliding gearwheel with dog clutch, during its movement, engages in the circular cavity formed inside each floating gearwheel (6) and therefore becomes secured to it. The hollow floating gearwheels perform their rotation about the secondary shaft through the use of ball bearings; they become secured to the secondary shaft only when they are engaged by the dog clutch.

Description

ONLINE GEARBOX WITH FLOATING SPROCKETS
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I: Technical field of the invention
It is essentially a mechanical box adaptable to all
motors (motors for motor vehicles in particular).

II: Indication of the state of the prior art
It is impossible to draw up an exact inventory of all models here
of existing boxes, given their number and their extreme
diversity. However, most, if not all, of them
operate by using multiple selector slides
speeds. Each slide actuates a synchronizing sliding pinion
likely to select a maximum of two speeds; otherwise,
most boxes have 3 trees
- a primary shaft connected to the engine by the clutch,
- an intermediate shaft,
- a secondary shaft which transmits the rotational movement to
wheels.

Finally, most mechanical boxes have as many pinions
walkman as sliding speed selector.

The novelty lies in the intervention of a selector slide
single speed which itself drives a single sliding pinion,
regardless of the number of gears in the gearbox.

In addition, this box only uses two trees (primary
and secondary), hence its extreme conceptual simplicity.

III: DESCRIPTION
1) The primary shaft of this gearbox does not have any particular characteristics compared to a conventional mechanical gearbox, except that it drives in its rotation a number of toothed pinions strictly identical to the number of gears that comprises the box ; this is due to the fact that this box has no intermediate shaft. All these pinions are integral with it, and rotate at the same speed as it. Only their diameter differs: they are arranged in a rigorous order of increasing (or decreasing) diameter along this tree. The primary shaft rotates on ball bearings embedded in the walls of the gearbox housing.

 2) The secondary shaft is constituted by a hollow cylindrical axis comprising a deep longitudinal groove (7) over its entire length, in the interior part of the housing of the box. This groove starts from the periphery to join the central recess (8). The central cylindrical recess extends at one or the other (or both) of the ends, to give passage to a slide, and allow its free movement forwards or backwards, inside the secondary shaft (Fig 2 and 3). The periphery of the secondary shaft is provided with longitudinal grooves (9) over its entire portion located inside the housing of the box (Fig 3). The secondary shaft rotates freely on ball bearings embedded in the walls of the gearbox housing. A sliding pinion "dog clutch" and "synchronizer" moves itself freely along the horizontal grooves of the periphery of the secondary shaft .

3) The sliding clutch and synchronizing pinion
- control mechanism
The control consists of a cylindrical central axis (or slide) whose diameter corresponds exactly to that of the central recess of the secondary shaft. The end of the slide comprises a peripheral recess in which the end of a tongue (10) secured to the sliding pinion bears. This tongue slides freely in the longitudinal groove of the secondary shaft which serves as a guide (Fig 4).

- structure and function of the sliding pinion:
- "interior" structure:
It is very simply a hollow metal ring comprising longitudinal grooves which are received in the corresponding grooves (9) of the periphery of the secondary shaft.

 This ring is movable along the secondary shaft and has a tongue (10) which fits exactly into the longitudinal groove (7) of this tree. The end of the tongue (10) comes to rest without friction on the hollow part (4) of the slide (Fig 4 and 5).

- "external" or peripheral structure of the sliding pinion
It can be broken down into three parts starting from the center of the ring in the horizontal direction (Fig 6).

* a central part at the level of which the periphery of the ring is provided with regular straight teeth of rounded shape (ll);
* two intermediate lateral parts, located on either side, and comprising only two diametrically opposite teeth (12), which are in fact only the extension of two central teeth (Fig 6).

 NOTE: The ends of all the teeth are rounded to facilitate the engagement of the sliding pinion inside the floating pinions crossed by the secondary shaft, but without contact with them.

 * finally two lateral parts, totally devoid of teeth, which allows the sliding pinion to engage without resistance when it approaches any of the floating pinions.

4) floating gables
We have previously seen that all the pinions of the primary shaft are integral with it, and rotate at the same speed as it. Each of these pinions drives in its rotation a "floating" pinion (6), hollowed out in its central part, to allow the passage of the sliding pinion.

The term "floating" derives from the mode of rotation of these pinions which are not integral with any axis, as long as the sliding pinion does not come to engage in their central cavity. These pinions are held in place and perform their rotation by means of ball bearings which are inserted in a circular groove of rounded shape (13), formed symmetrically on each face of the floating pinions. The ball bearings are themselves held in their locations by rigid anchoring "lugs" fixed to the box housing, with no possibility of play. Each floating pinion is separated from the next by a fixed distance interval ( dimension substantially equivalent to the horizontal length of the sliding pinion).

The floating pinions are arranged in an order of diameter opposite to that of the pinions of the primary shaft and are in permanent contact with the corresponding pinions of the primary shaft which drive them in their rotation. The floating gears therefore rotate freely around the secondary shaft, without contact with it. It is therefore a silent box with constant setting. It is the sliding pinion which, by moving along the secondary shaft, selects the speed.

- external structure of floating gables
These are conventional toothed wheels, the only features of which are: - to be hollow, - to present on each side face a rounded groove of circular shape (13), serving as housing and guide for the ball bearings
- internal structure of floating gables
Their characteristics are identical to those of the periphery of the sliding pinion
* a central portion provided with regular straight teeth of rounded shape, the intervals of which serve to accommodate the corresponding teeth of the sliding pinion
* an intermediate part comprising only two teeth (16), diametrically opposite which are the extension of two central teeth
* a lateral part, devoid of teeth, in which is hollowed out the housing of a flexible metal ring 05> slightly ovalized (Fig 9).

5) Principle of interconnection and synchronization
When the gearbox is disengaged, each floating pinion rotates at its own speed, and, when the sliding pinion moves along the secondary shaft, it meets a floating pinion which rotates at a speed different from its own . The smooth end of the sliding pinion engages without difficulty in the smooth part of the floating pinion, but, when the end of its "long" teeth reaches the level of the flexible oval ring, it can only continue to progress by exerting a pressure on it to make it undergo a slight deformation. The friction exerted by the teeth of the sliding pinion on the internal walls of the flexible metal ring, lead to a start of synchronization, and this synchronization is completed when the the end of the long teeth of the sliding pinion comes to bear on the end of the corresponding teeth of the floating pinion, causing it to rotate. Nothing is more opposed to the progression of the sliding pinion which can engage all of its teeth between those of the selected floating pinion.

 The "relative" locking of the selected speed is carried out automatically by means of two flexible oval metal rings, which are no longer subjected to a forced spacing, return to their initial shape, trapping the teeth of the sliding pinion in rotation. Likewise, each "neutral" position between two successive floating gears will be protected by the same principle of automatic locking (Fig 9).

6) Main technical characteristics
This box is extremely simple to design, and the understanding of its operating mode is particularly easy. Its main characteristics are as follows
- robustness and reliability: this box is practically foolproof; indeed, none of its parts is structurally fragile when the floating gears rotate without being clutched, they are in permanent contact with the corresponding gears of the primary shaft which neutralize their gravity; they then exert only negligible lateral pressures on the ball bearings which serve essentially as a guide. When they become motors by being clutched, they are completely integral with the secondary shaft, and the bearings always act only as a guide.

 - bolte of low cost of realization (great homogeneity of the components, moreover easy to machine).

- ease and precision of ordering
each speed being separated from the next by a constant distance interval, all speeds are available "linearly".

In the case of a manual control with lever on the floor, the selection of speeds will be done by linear progression of the lever from front to back (or vice versa), and in a logical order of speed selection (increasing or decreasing according to qu '' push the lever back and forth or vice versa).

Finally, the number of speeds can be increased without this posing any additional technical difficulty, since it suffices, for each additional speed, to provide an additional additional pinion on each of the two shafts. The only impact is then a proportional lengthening of the length of the box and the slide.

 - small footprint and reduced weight box: its width can be limited to the diameter of the widest floating gear, increased by twice the thickness of the box casing, or in any case less than fifteen centimeters - its length will be directly proportional to the number of gears in the box (as an indication, the length of a six-speed gearbox and a reverse gear could be close to thirty centimeters) - its height will be equal to double the distance separating the two shafts , increased by twice the width of the box casing, or in any case less than twenty centimeters.

- ease of automation
* electric motor actuating the slide by means of a conventional rack and pinion device.

 * possibility of control by hydraulic piston.

NOTE: Manual control does not seem to pose a priori any particular technical problem for an automotive engineer since it essentially involves controlling the rectilinear movement of a solid cylindrical axis inside a hollow cylindrical axis. Of course, as with a conventional gearbox, it will be essential to provide a stop to prevent any possibility of direct access to reverse gear.

7) Legend of the explanatory drawings
Fig 1: Schematic diagram of a five-speed gearbox plus a reverse gear.

1 - primary tree
3 - slide
5 - sliding pinion neutral position
a6 floating gears of 1st, 2nd, 3rd, 4th, 5th and reverse.

 18 - intermediate reverse gear off-center and free on its axis.

Fig 2: schematic diagram of the secondary shaft
8 - central recess
9 - longitudinal grooves
Fig 3: Cross section of a portion of the secondary shaft
7 - continuous longitudinal groove
8 - central recess
9 - longitudinal grooves
Fig 4: Schematic diagram of the sliding pinion control system (axial longitudinal section)
2 - hollow secondary shaft
3 - gear selector slide
10 - sliding pinion control tab.

Fig 5: Cross section of the sliding pinion and the secondary shaft
2 - hollow secondary shaft
3 - central slide.

 5 - sliding gear.

10 - control tab
12 - long toothing of the sliding pinion.

Fig 6: Schematic diagram of the sliding pinion
11 - short central teeth
12 - long teeth
Fig 7: Side sectional view of a floating sprocket gear
2 - hollow secondary shaft
3 - central recess serving as slide housing
5 - sliding pinion and its control tongue
Fig 8: Cross section of the edge of a floating gear
13 - groove serving to house the ball bearings.

Fig 9: Schematic diagram of the dog clutch with synchronization (neutral position)
2 - secondary shaft
5 - dog clutch sprocket
6 - sectional view of the central part of a floating gable
15 - ovalized ring (cross section)
17 - empty space due to the slightly oval shape of the rings.

Claims (5)

 1) Mechanical gearbox adaptable to all engines (automobile engines in particular), characterized in that the rotation of the engine is transmitted directly from the primary shaft (1) to the secondary shaft (2) by intermediate of conventional serrated pinions which are in permanent contact with the teeth of floating pinions (6) and drive them in their rotation by the intervention of a single speed selector slide (3).  2) Gearbox according to claim 1 characterized by a hollow secondary shaft whose inner cylindrical recess (8) is extended by a longitudinal groove (7) joining its periphery.  3) Gearbox according to claims 1 and 2 characterized in that the single speed selector slide (3) moves longitudinally inside the secondary shaft.  4) Gearbox according to claims 1 - 2 and 3 characterized in that the sliding pinion (5) consists of a metal ring which can move over the entire length of the secondary shaft, along the grooves thereof (9), the longitudinal groove formed on a radius of the secondary shaft serving as a housing for the tongue (10) of the sliding pinion, and in that the periphery of the ring is provided with short straight teeth (11) of shape rounded and two long teeth of the same shape, diametrically opposite (12) exercising a synchronization function.  5) Gearbox according to all of the preceding claims, characterized in that the hollow gear pinions (6) called "floating pinions" are arranged in an order of increasing diameter (opposite to that of the pinions of the primary shaft) and perform their rotation by bearing on ball bearings integral with the case of the box, thanks to a circular groove (13), hollowed out on either side of each floating pinion, and in that the internal cavity of each floating pinion is provided with teeth identical to those of the sliding pinion (5) a flexible oval metal ring which is housed in a lateral circular recess situated on either side of the central cavity of the floating pinion.