DE491580C - Gas knife with wobble bell - Google Patents

Description

Gas knife with tumble bell There are already wet gas knives with tumble bell, their tumbling movement brought about by the gas flowing through the gas meter i will. It 'is the control of the gas flow, which makes the drive a continuous - Ensuring tumbling movement as long as gas is flowing through it by subdividing it accordingly , the interior of the bell or caused by specially arranged channels, for what it. manifold constructive designs are. The tumbling motion of the bell is with a11 these previously known gas knife constructions through kinematics a special storage and guidance of the axis of the bell required. Since the geometric The axis of the bell during the tumbling movement is a cone with a downward pointing tip describes, the bell guide was designed kinematically in such a way that the Bell rides a stub axle that penetrates it and is located below in a universal bearing was taken and passed above by a crank arm. It then only needed for that to be taken care that the bell cannot turn around its journal and an inevitable swashplate guide had been implemented.

This type of wobble bell guide is especially useful for gas meters not inconsiderable disadvantages. The support surfaces are id'es universal joint loaded with the entire weight of the tumbler, and the crank must also be large Record pressures. Both the universal joint and the necessary articulated connection between the upper end of the journal and the crank that would grip it therefore require careful and extensive lubrication when rubbed out the surfaces of these articulated joints that slide on one another should be avoided. Since the whole mechanism is enclosed in a housing and a lubrication t of these joint parts is hardly possible, at least with simple means, it is clear that that the sensitivity and accuracy of such a gas meter is proportionate has already been greatly reduced for a short period of time.

In the kinematics of the swash plate, it is also known, the wobble movement to bring about a disc that theoretically with a cone brings in connection, which rolls on .a second fixed cone.

This guiding principle, which is known in theory, is now or present invention applied to the Taramel, bell of gas knives, and around it and its advantages, which it has in this application, to make clear, is immediately on that in Fig. r in one vertical section shown embodiment referred to such a gas meter.

In that, from a lower part z and the upper part: 2 existing housing the wobble bell 3 is arranged, which is used in any to control the gas flow is suitably divided by partitions or provided with channels. That Housing r, 2 is filled with water in its lower part, and by the tumbling movement control edges of the bell dive in, sometimes out and block gas paths or give: they free. The gas flows through the vertical central connection q, of the housing from below into the bell 3, flows through it, causing the bell to tumble drives, enters the part of the housing above the bell and flows from here through the pipe 5 into the consumption line. The movement of the wobble bell will transferred in some way to a counter.

With: the embodiment of the gas meter shown here in accordance with According to the invention, the lower part r of the housing has an annular shape running around it Guide surface 6, which geometrically corresponds to the outer surface of an upright circular cone 7 belongs, which is indicated in the drawing with dash-dotted lines and the tip 8 of which lies in the center of oscillation of the tumble - lures 3. On this Guide track 6 now rolls around a ring that is attached to the tumbling bell 3 and that runs all the way around from, the one here as the end limit, a special jacket attached to the bell ro is formed; but could of course also be the lower edge of the main mantle 1z of the bell 3. Used as a rolling surface, for which then a corresponding adapted guideway with the effectiveness of the guideway 6 shown here would have to be arranged.

The ring surface 9 of the bell 3 is on the outer surface of a. Cone 12, which is also indicated in the drawing by dash-dotted lines and whose downwardly directed tip coincides with the tip 8 of the cone 7. The two cones 17 and 12 touch. each other in a generatrix 13, so that, while the axis 14 of the cone 7 is perpendicular, the axis 1 5 of the cone 12 is inclined, and when the cone z2 is on the cone? rolls, in turn circles on a conical surface, the axis of which is the axis 14 and the tip of which is at 8. The base surface 16 of the cone rz performs a pure tumbling movement during this rolling, and also of course the bell 3, which is connected to this cone 12 so to speak rigidly. As already mentioned, the guidance of a swash plate by two cones rolling on one another is already known in kinematics. To ensure the inevitability of rolling, however, the crank guide at the free end of the axis of the swash plate has hitherto been retained in kinematics, and a guide is actually required that prevents interruptions of the rolling movement by lifting the rolling cone from the stationary one. The crank guide of the circling end of the disc axis still requires articulated connections, which have the disadvantages mentioned earlier. If the crank guide of the circling end of the swash plate axis is retained, the difference between the kinematics described last compared to the first mentioned is that the universal joint for mounting the lower end of the swash plate axis has been replaced by the cone roller guide, while everything else remains unchanged.

Now the universal joint has to be replaced by a cone roller guide for gas meters of the type mentioned are very significant advantages that have not yet been achieved have been recognized and which mainly lie in the fact that now the possibility is given to simplify the structural design of such a gas meter significantly and to save a lubrication of the rolling surfaces, with a sensitivity of the gas meter is guaranteed, as it has not been known from any of the previously known Wobble bell bearings was possible. - You can, as Fig. I shows, the rolling guide surfaces relocate to the circumference of the bell and this also preserves it with larger bell weights only a very slight specific load (of the guide surfaces, so that a Wear of these surfaces is practically out of the question. The bell is rolling like a big wheel (development of the circumference of the bell) on a rail, with only slight rolling friction and high sensitivity the bell drive is guaranteed. But if you also take the lead of the bell axis at the bottom in a universal joint and at the top by means of a crank and that would be flat added the described cone roller guide, advantages would result from that the universal joint would be relieved of the bell weight and therefore not too would act as a support of the bell, but only as a guide at the proportionate low specific surface loads occur.

But you can also get rid of the need for an upper crank guide and the associated disadvantages when using this conical rolling surface guide. In the embodiment shown in FIG. I, an all-round annular channel 17 is attached to the tumble bell 3, in which there is a certain amount of mercury or some other liquid. This mercury collects at a point in the vicinity of the annular channel 17 and, due to its weight, presses the bell 3 down there, whereby a point or a generatrix of the surface 9 comes into contact with the surface 6. If the gas flow on the wobble bell 3 generates a circular torque, the two conical surfaces roll on one another in the manner described, with the generators 13, in which the two cones touch, to a certain extent rotate around the axis 14 (Of course, there is no rotation in the actual sense; only the point of contact runs around the axis 14). The mercury in the annular channel 17 always collects at the lowest point, which coincides with the point of contact, and therefore this mercury forms an ongoing load which ensures the continuity of the rolling process and prevents the bell from tipping due to the gas pressure which would create a discontinuity in the transfer.

When using such a rotating load on the wobble bell is in contrast to the one previously used with such guides, by the crank conditional positive guidance generates a non-positive guidance, but the With the appropriate size of the running weight, complete safety against inconsistencies. Incidentally, this frictional guidance could also be used in other way than caused by a weight of liquid, namely through a ball or roller running in a channel or through an annular channel a weight attached to the upper end of the pin i8, which may be extended or finally also by a rotating around the axis 1,4, the circumferential points the bell on top of each other, taking a depressing arm. In each of these cases you can the articulated chamfering of the pin 18 of the wobble bell 3 is saved by a crank will. - In the embodiment shown, the arm i9 of the sleeve 2o serves from who is driven from the counter in some orphan; only as a driver, against which the pin 18 of the bell 3 rests loosely.

The conical rolling surfaces can be arranged in various ways and form. So you can z. B. narrow the conical rolling surface 9 of the bell 3 so far; d'that it shrinks to a preferably rounded edge, which is on the wider conical surface 6 rolls. But it could also vice versa the surface 6 to a Edge are narrowed when the surface 9 is widened. If one of the surfaces which roll on top of each other, is narrowed to one edge, the other can also be flat - Ring surface or conical surface can be formed with any inclination. This allows Then, as will be discussed later, change the inclination of the bell.

But you can also multiply the rolling surfaces. In the illustrated Embodiment is in addition to the peripheral part of the conical rolling surfaces a part of these conical surfaces located near the central axis is realized, namely through a flange 2i of the central connecting piece d. and through a flange 22 of a central piece 23 connected to the bell. This increases the stability the bell guide increased by supporting the middle part of the bell, thereby other supports, such as universal joints or the like, are saved, and -The specific surface pressure between the parts rolling on each other still scaled down. At the same time, this middle guide can also be used to to create a safeguard against radial displacement of the bell. The stupid. is with a spherical guide surface 2q. provided, at the circular inner boundary of the flange 22 of the middle piece 23 in the tumble elbow, movement of the bell out is. This is a kind of ball joint through which the bell 3 with the nozzle q. connected is; but since this joint does not have to carry the load of the bell, it has to only to prevent radial displacements of the bell on the guide surfaces 6 and 21 then the stress on the sliding surfaces of this joint connection is natural little, and there would be no noticeable wear even without lubrication. The sensitivity of the bell drive is also only negligibly affected by this.

To prevent radial displacement of the bell when it wobbles, other means can also be used. So z. B. the lower, pointed one The end of the Glockenachszapfens rest on a pan-like support or it can the guide surface 6 are formed like a rail with which the edge of the jacket io the bell 3 is engaged by means of a flange. The guide surface 6 can also be either inside or outside. A guide flange for the obtained quite simply trained coat ro the bell 3 and in these cases the ball guide in the middle part can be omitted.

If a cone roller guide is only available on the circumference of the bell, then so it is recommended to run the bell in the middle through a universal joint: and this can now, in order to bring the friction losses to a minimum, according to the Invention be carried out approximately as it is in Figs. 2, 3 and 4 in two on top of each other vertical elevations and a plan is shown.

It is a universal cutting edge joint, the friction losses of which are also: low - siiyd Like - like ordinary cutting bearings. - This joint consists of a double-cranked ring 25, which carries a radial cutting edge support 26 on its upper side on two opposing depressions and a cutting edge support 27 in a diameter perpendicular to it on the underside or elevations of the ring. Below the ring 25 there is a bracket 28 with the two cutting edges 29 which engage in the supports 27, and above the ring there is the bracket 30 with the two cutting edges 31 which engage in the supports 26 of the ring 25. The bracket 128 is firmly connected to the housing of the gas meter and the Bübatel 30 to the bell, and it is clear that in this way a universal joint with cutting edges is created instead of the usual hinge joints.

In order to free the cutting edges of the joint from radial loads, one can, as FIG. 5 shows, accommodate a ball joint in the cavity of the ring 25. - This consists äus a ring 32 delimited on the outside by a spherical surface, which on the pin 33 of the bell is pushed on loosely and is therefore also in the axial direction can move and from the hollow body 34, which with its spherical bearing surface the ring 32. encloses and is somehow attached to the socket 4 of the housing. Of course, the center point of the ball joint must match that of the cutting cardan joint always collapse.

The bell is also carried by the taper roller track through the Cutting card joint, and the ball joint only has the purpose of cutting the cutting edge to protect against those unfavorable stresses caused by radial displacements the bell could be caused. So here, too, the ball joint is only very little stressed and it therefore affects the sensitivity of the drive only to an insignificant extent. Of course, vice versa, the ring can also be used g z5 will be provided with cutting edges 28, and 3o engage. Others too The attachment of the cutting edges and supports are reversed. possible.

Is such a cardan joint only with the taper roller guide 6, 9 combined according to FIG with universal joint the advantage that the upper crank steering can be saved. If the Schnevdenkardangle is fitted with a bell with: the roller cone guides 6, 9 and 21, 22 combined; So the weight of the bell doesn’t burden it at all, but only serves for centering.

In any case, the measures outlined here will achieve - .., @ That of the previously necessary management organs of the wobble bell, the high demands exposed, would require lubrication and the sensitivity of the reduce the drive generated by the gas, at least some or all of them can be replaced by organs that have the specified disadvantages or more are less free.

The guide rail6 can be lifted as a special feature inside the housing. and lowerable organ are designed to match the inclination or the height of the bell to be able to adjust in the housing for the purpose of calibration. The other way around could of course also the jacket zo or a, part of it adjustable on the bell in the axial direction be arranged, which ensures the same adjustability and @the calibration the gas meter becomes possible. The inclination of the bell can also be adjusted by adjusting it the height of the central support of the bell can be changed.

For the purpose of a differential. Calibration can also - the transmission : serve to move the bell on the counter, if the one shown schematically in Fig. 6 Transfer is applied. Can be easily moved vertically in the gas meter housing a rail 35, on which two arms 36 and 37 are adjustably attached, between, which protrudes a stop 38 attached to the bell shell i, so that During the tumbling movement of the bell, the stop 38 once the upper and once en lower arm 36 or 37 abuts and -the * rail 35 upwards or downwards pushes. With every complete tumbling oscillation of the bell, the rail is once upwards and pushed outwards and this movement is activated by means of a switching mechanism Transfer counter 39 of gas meter i. These arms 36 and 37 are now on the rail adjustable attached. Are the two arms 36 and 37 on the rail 35 set so that both the stop 38, one from above and the other from below, touch, so the stroke of the rail 35 - the swing amplitude of the bell be exactly the same. But if you remove the arms 36 and 37 on the rail 35 from each other such that the stop 38 can move freely between them before if it hits one of the arms, the rail 35 becomes like a drag valve moves and its stroke is smaller, the greater the distance between the arms 36 and 37 is set from each other. One can therefore transfer the tumbling motion the bell on the counter, which is driven by the rail 35, change, which gives the possibility of an accurate calibration.

Similar conditions exist when there is only one arm on the rail 35 is attached, which protrudes between two stops of the bell.

Of course, the adjustabilities described here can be used also combine with each other. ' The structural design of the gas meter in its The entirety and also that of its individual parts permit various changes.

Claims (12)

PATENT CLAIMS: i. Gas knife with wobble bell, characterized in that that the tumbling motion of the bell is performed in a manner known per se Rolling: one or more faces of the bell that geometrically have one or more Circular conical surfaces with a downward pointing tip belong to one or more fixed surfaces, preferably arranged on the housing itself, which geometrically one or more circular conical surfaces with an upward pointing tip and 'more perpendicular' Belong to the axis. 2. Gas knife according to claim i, characterized in that the Continuity of the touch of the rolling surfaces without use a crank mechanism is secured by a load on the bell, which is applied to the respective Contact-generating acts and therefore with the same angular velocity as this running around. 3. Gas meter according to claim i or 2, characterized in that one each of the surfaces rolling on one another is narrowed to an edge, wherein the other surface of a conical surface of any inclination or a flat surface Can belong to area. q .: Gas meter according to claim 1, 2 or 3, characterized in that that the central position of the tumbler bell in relation to the fixed. Rolling surfaces (geometric: the coincidence of the tips of the circular conical surfaces rolling on each other) through to the. bodies that are movable relative to one another and engage one another Guide surfaces is secured, which allows a displacement of the tumbler bell in a radial direction Prevent direction. 5. Gas knife according to claim 4, characterized in that at least one of the rolling surfaces with one or more wheel flanges is provided, which keep the wobble bell centric. 6. Gas meter according to claim q., as - characterized in that the wobble - lock on the housing by means of a Ball or universal joint is performed, the center of oscillation with -den geometric cone points coincide. 7. Gäsrnesser according to claim 6, characterized characterized that the Taurnel bell on the housing by a combined universal and ball joint is guided, one of the elements of the ball joint being axially is movable. B. Universal joint for a gas meter with a tumbler, if necessary according to claim 6 or 7, characterized in that the joint is a cutting cardboard joint is formed with two pairs of cutting edge joints that are perpendicular to one another. G. Universal joint according to claim 8, characterized in that between the two Cardan joint parts, cutting edge joint elements in two mutually perpendicular diameters included, a ring is loosely arranged, which the associated other Schneidgelenkelem.ente wearing. ok Gas meter according to claims i and 2, characterized in that d: aß the load , the wobble bell by a liquid in .an annular channel .of the bell, by a rolling weight or by a weight attached to the inclined bell peg is effected. i i. Gas meter according to claim i or 2 to io, characterized in that that at least one of the rolling surfaces is relative to the body with which it is connected or the central support of the bell is adjustable in height is. 12. Gas meter with wobble bell, thereby marked that to transfer the tumbling movement of the bell to the. Counter a vertically movable Slide (rail 35) is used, the. By engaging adjustable stops of the slide and the bell into a to be transferred to the counter, according to Setting of the stops, longer or shorter switching movement is offset.