DE1290847B - Receiver for a telemetry system - Google Patents

Description

first and second drive parts of a motor 15 remote measuring receiver. As in Fig. 5 in it opposite directions is set with a constant, the encoder has a motor 2, the

rotates at a substantially constant speed to drive a cam 4. The engine 2 is connected by lines 6, 8 to an energy source (not shown). A contactor 10, with which the cam 4 can engage during each cycle of rotation of the cam is determined by a Supported rod 12, which is mounted between pairs of rollers 14 for vertical movement. The Stangel2

Water vapor is present in the atmosphere 25 is not shown between the rollers 14 by a or if the recipient inadvertently placed too strong a mechanism in accordance with the

The instantaneous size of the variable to be measured, for example a pressure, a temperature or a medium flow, adjusted vertically. Therefore, the relative position of the contactor 10 to the Cam 4 regulated by the variable to be measured. The cam 4 is supplied with power through a conductor 16 supplied. During part of each rotation cycle, the cam 4 completes a circuit across the

for locking drive engagement between the 35 contactor 10 for a period of time which the first arm and the first drive part and the instantaneous size of the small changes to be measured the second arm and the drive part is proportional to the borrowed. On the rest of the part Drive parts and the arms intermeshing rotation of the contactor 10 is except single-gear type Parts are arranged. intervened with the cam 4 and with it the circuit

An inevitable closed 40 is opened by the invention.

locked drive connection between the drive According to FIGS. 1, 3 and 5, the receiver

spaced apart frame parts 18, 20 and 22, which in a fixed spaced position by Screws 24, 26, 28 and spacers 30, 32, 34 and 36, 38, 40 are held. A shaft 42 is arranged in the frame parts 20, 22 so as to be axially movable and is in axial alignment with a shaft 44 which rotates in the frame members 18, 20 is arranged in a fixed axial position. Between so the opposite ends of the shafts 42, 44 there is a clearance to allow axial movement of the shaft 42 against and from the shaft 44 way to enable. Drive plates 46 and 48 are on bearings 66 between the frame parts 20 and 22 or 70 arranged for the purpose of concentric rotary movement with the axis of the shaft 42.

The plates 46, 48 are provided with rings 50 and 52, respectively, on their periphery. The rings 50, 52 are on their respective plates for rotation with

Tied with the teeth set on the rings go through 60 them. From the following is, each an even number of teeth plus a reason, the rings 50, 52 are preferably made pre-selected fraction of a tooth on a self-lubricating material, e.g. B. a point. Polyamide, and they're all around yours

The invention is provided below with gear teeth 54 and 56 by means of the scope. Drawing on an embodiment in the individual 65 radially inward of the teeth 54 and 56 are the nen described. facing sides of the rings 50, 52 with

F i g. 1 is a plan view of a device provided with stepped teeth 58 and 60 respectively,
measure of the invention; A U-shaped spring 62 is between the plates

Speed are rotated, and a device is provided which the two arms alternately engages with the drive part concerned.

In known receivers of this type, the drive transmission takes place between the drive part and the associated arm by means of a friction clutch. If now excessive amounts of oil and / or

is lubricated, the clutch can slip uncontrollably, which may result in a faulty Work and inaccuracies in the display result.

The invention aims to avoid the disadvantages of the known receivers.

According to the invention, a receiver of the type mentioned in the introduction is characterized in that

share and their assigned arms created, so that inaccuracies as they arise by slipping a friction clutch can be avoided with certainty.

According to a preferred embodiment of the invention, the gear-like parts consist of a tooth-bearing collar on each of the arms and a tooth-bearing ring on each of the drive members.

Preferably, each of the teeth of the collars and each of the teeth of the rings can have an engagement surface be provided, which runs substantially at right angles to the drive path of the associated drive part.

According to another embodiment of the invention, the teeth-bearing rings in the Arch created by each ring during a full cycle of engagement of the teeth on the

46, 48 and presses the plates in opposite directions against the frame parts 20 and 22. The plate 46 is provided with a thrust bearing 64 for engagement with a thrust bearing insert 66, which is arranged in a recess of the frame part 20. Similarly, plate 48 is provided with the thrust bearing 68 for engagement with a thrust bearing insert 70 which is in a recess of the frame part 22 is arranged. One on the shaft 42 for axial movement with its fixed plate 72 is disposed between the plates 46,48. The plate 72 is close to its periphery freely engaged with a spacer 36 which allows rotation but not axial Movement of the plate and shaft prevented (Fig. 7).

On the shaft 42, an arm 74 is rotatably arranged between the plates 46 and 72, the outer end of which is bent over in a U-shape. The arm 74 is provided near its outer U-shaped end with a collar 76 zo which has stepped teeth 78, and the stepped teeth 78 are arranged on the arm 74 so that they engage with stepped teeth 58 on the ring 50 can. The collar 76 is preferably made of a self-lubricating material, e.g. B. a polyamide. The arm 74 is provided at its opposite end with a standoff collar 80 which holds the arm 74 substantially parallel to the plate 46 when the arm 74 is pressed against the plate 46 to engage the teeth 78 with the teeth 58 allow. A coil spring 82 is connected at one end to the plate 72 and at its other end to the arm 74, and the spring 82 presses the arm 74 against the spacer 36 which acts as a stop for the arm 74.

A second arm 84 is rotatably mounted on shaft 42 between plates 48 and 72, and that outer end of the arm 84 is bent over into a U-shape, and this U-shaped end can be connected to a stop 85 come into contact, which is adjustably arranged in a spacer 38 (FIG. 7). The arm 84 is provided near its outer U-shaped end with a collar 86 which has stepped teeth 88. The collar 86 is arranged on the arm 84 such that its stepped teeth 88 with the stepped Teeth on the ring 52 can engage. Like the federal government 76, the federal government 86 is graduated with its Teeth 88 preferably made of a self-lubricating material, e.g. B. a polyamide. The arm 84 is at its opposite end with a spacer collar 90 to the same Purpose provided, which has already been described in connection with the spacer collar 80 of the first arm 74 became.

The collars 76 and 86 are each provided with a pin 91 and 93, respectively, and the pin 91 has a head 95 and the pin 93 has a head 97. As best shown in FIGS. 5 and 7, each pin extends outwardly from its collar and through a cutout 99 along the outer edge of the plate 72, and the heads 95 and 97, respectively, lie on opposite sides of the plate 72, each on that side of the Plate facing the associated collar. A coil spring 92 is connected at one end to the plate 72 and at the other end to the arm 84, and the spring 92 urges the arm 84 against the spacer 38 and into engagement with the adjustable stop 85.

An L-shaped arm 89 is wedged at one end on the shaft 44 and extends with its other end over the frame part 20 and between the outwardly extending ends of the arms 74 and 84. The arm 89 is with stops 89 a and 89 b , which are arranged between the rings 50, 52, and the stops are usually out of contact with the rings, but are arranged so that they come into contact with the rings and keep them spaced apart if the spring 62 should not be able to maintain the desired spacing at the moment of teeth disengagement. A toothed wheel 94 is keyed on the shaft 44 on one side of the arm 89, and the shaft 44 is provided with a spring 96, the outer ends of which bear against a plate 98 carried in the frame part 20. The spring 96 presses the arm 89 and the gear 94 against the frame part 18 and, together with the frame part, acts as a brake to hold the gear and the arm in place for the reasons explained below.

An electromagnet 98 is arranged on the rear side of the frame part 22. The Electromagnet 98 is provided with an armature 100 which at one end to the fixed housing of the electromagnet is hinged. The armature 100 is engaged at its other end with a nut 104, which is arranged on the shaft 42 adjustable. Between the nut 104 and the frame part 22 is the shaft 42 is provided with a shoulder 106. A ring 108 carried by the shaft 42 is on the Shaft between the shoulder 106 and the inside of the armature 100 is displaceable. A first helical compression spring 110 rests with one end on the frame part 22 and with its other end on the one side of the ring 108. A second helical compression spring 112 is at one end on the opposite side of the ring 108 and with its other end to the armature 100. From the For reasons explained below, it is preferable that the urging force of the spring 112 be twice that of Force of the spring 110 is.

A motor 114, which is arranged on the rear side of the frame part 22, drives a gear 116 with it constant speed. The motor 114 is connected to the lines 6 leading to the energy source and 8 connected. The gear 116 is in driving engagement with the teeth 56 of the plate 48 carried collar 52 and also meshes with a gear 118, which is on a counter shaft 120 is wedged, which is rotatably mounted at its ends in the frame parts 20, 21. With the wave 120 is also keyed to a gear 122 which is in driving engagement with the teeth 54 of the plate 46 fortified federal 50 stands. When the motor 114 drives the gear 116 at substantially constant Speed rotates, due to the meshing gears, the plates 46 and 48 with equal and constant angular velocities, but rotated in opposite directions.

In Fig. 8, the stepped teeth 58 and 78 on the ring 50 and the collar 76, respectively, are enlarged Detail shown. In the following description, it is assumed that the stepped teeth 60

and 88 on the ring 52 and the collar 86 are identical in shape.

According to FIG. 8 the ring 50 is rotated in the direction of the arrow. Each of its teeth 58 has a surface which extends substantially perpendicular to the direction of movement of the ring and an inclined surface B which extends at an angle with respect to surface A and the direction of movement of the ring. The teeth 78 on the collar 76 have one

the fixed on the shaft 42 plate 72 of the Plate 48 moved away against plate 46. When the shaft 42 moves away from the plate 48, the Plate 72 engages head 95 of post 91 and engages stepped teeth 60 and 88 of the ring 52 or the collar 86 out of engagement. At the same time, when moving against the plate 46 the head 97 of the pin 93 released by the plate 72 so that the central hub of the plate 72 with the

Surface C which engages substantially perpendicular to the center hub of arm 74 and extends the direction of movement of the collar, and a stepped teeth 78 on collar 76 with the stepped surface D. th teeth 58 on ring 50 engage .

As best seen in Figs. 1, 2 and 4 can be seen The plate 46 and the ring 50 are through the

A gear segment 130 is mounted on a shaft 132- motor 114 clockwise with respect to FIG wedged in the frame parts 18 and 20 rotatable 15 shaft 42 rotated when on the front of the is stored, the teeth of the tooth segment 130 receiver being looked at. When teeth 78 and are in engagement with the teeth of the gear 94. 58 are engaged, the arm 74 becomes concentric The shaft 132 extends through the frame part 18 to the axis of the shaft 42 rotated clockwise, through and is mitigated on the outside of the frame part and the outer U-shaped end of the arm 74 a pointer 134 fastened on the shaft moves this arm 89 when it touches the arm 89

see. The free end of the pointer 134 strokes a scale 136.

To work, the motor 114 is connected to the energy source by lines 6 and 8,

and the gear 94 clockwise and moves the pointer 134 via the tooth segment 130 With reference to the scale 136. When the electromagnet 98 becomes de-energized again, the armature 100 becomes again

so that it releases the plates 46 and 48 and their ent- 25, and the springs 110, 112 move the speaking rings 50 and 52, respectively, with essentially shaft 42 out of the housing and the plate 72 at constant speed, but in opposite directions the plate 46 away against the plate 48. Drives the remote directions. The plate 72 is on
prevented from rotating by a fork-shaped extension 72 a , which is connected to the spacer 36 30
is engaged (Figs. 6 and 7). The one with the plate
72 keyed shaft 42 is also against a
Rotation held. When power is supplied to the
Electromagnet 98 is interrupted, press the

Springs 110 and 112 rotate the armature 100 of the elec- tric 35 74 and 84, become the outer U-form magnets away, and the shaft 42 is moved over an arc in gene ends of the arms, wherein the length of this arc depends on the time interval during which the electromagnet 98

stepped teeth 78 and 58 disengage and teeth 88 and 60 re-engage.

As can be seen from the above description, the rotation of the plates 46 and 48 arms 74 and 84 depending on the position of plate 72 under the control of the electromagnet 98 optionally rotated. When the arms

energized or de-energized. As long as the time interval

their extreme position, d. H. in the position shown in FIG.

When the shaft 42 is in its extreme position

If the plate 72 fixed on the shaft 42 remains constant, each of the arms 74, 84 is positioned up to against the plate 48 and the arm 84, and the arm 89 is moved, released and through its stepped teeth 88 of the the arm 84 and the helical spring 82 or 92 are returned to its initial discharge collar 86 with the stepped starting position. When one arm is released teeth 60 of the ring carried by plate 48 and returned to its original position-52 engaged. When the plate 72 is guided against the arm 45, the other arm engages and 84 and the plate 48 is in place, the head begins to drive. As long as the time interval kon-97 of the pin 93 with the plate 72 in engagement and
holds arm 74 from plate 46 to collar 50

remains constant, the arm 89, the gear 94, the tooth segment 130 and the pointer 134 are held by the spring 96 in a fixed position.

When the time interval during which the solenoid 98 is energized or de-energized is changed becomes, the arcs through which the arms 74, 84 are driven change in a similar manner. Therefore if the solenoid 98 during a

When looking at the front of the receiver, the motor 114 drives the plate 48 and the ring 52 in a counterclockwise direction and the plate 46 and ring 50 in a clockwise direction. if therefore the electromagnet 98 is de-energized and the

stepped teeth 88 with the stepped teeth 60 55 energized longer time intervals and during a

are in engagement, the arm 84 is de-energized in a counterclockwise shorter time interval, the arm 74

Pointer direction concentric to the axis of the shaft 42 over a longer arc and the arm 84 over

turned. When the arm 84 is driven counterclockwise a shorter arc. During the

direction rotates around the shaft 42, moves the U-för- first cycle after changing the time interval

mige end of the arm, when it touches the arm 89, 60 stand the arms 74, 84, which are depending on the case

move this arm 89 and the gear 94 counterclockwise over the longer arc with the arm 89

pointer direction, and the gear 94 moves over and the pointer 134 in contact and set their

Tooth segment 130 the pointer 134 with respect to the position. The arm 89 and the pointer 134 remain

Scale 136. again in a fixed position until the next change

When the solenoid 98 is energized, it becomes 65 of the time interval.

Armature 100 tightened and shaft 42 against the if the stepped teeth 78 and 88 of the collars

Force of the springs 110, 112 moved into the housing. 76 and 86 with the stepped teeth 58 and 60, respectively

When the electromagnet 98 attracts the armature 100, it is of course possible to

that the teeth on the driven arms are not slightly less than Va tooth length. When re-aligning with the teeth at the contact points of the teeth on the fourth cycle, drive plates are located. For example, in FIG. 8 showing the teeth only slightly less than ¹ U tooth length except teeth slightly out of alignment, and alignment. On the fifth cycle, when the arm 74 carrying the collar 76 moves against the 5 teeth on the driven arm and the ring 50 carried on the drive plate 46 are in the same orientation as on the drive plate, little relative movement occurs before first cycle. By doing this, the ring 50 reduces the collar 76 driving. Because of the shape, thus four working cycles, the loss of arc on little exercise of the gear teeth will be if a misalignment is greater than ¹ Ai of a tooth length. As soon as the size direction occurs, the movement of the collar 78 and io of the variables measured on the encoder changes, its arm 74 is temporarily delayed. As a result, the changed size of the variable as visual is the arc over which the powered arm display on the receiver is rotated with an accuracy somewhat smaller than the intended arc complete by Vi one tooth length at the time. This loss in the arc, given that the receiver has four cycles of movement, is of course a maximum if that has been completed. If it is assumed that on the stepped teeth of the driven collar and the drive plate, a gear with 1001 teeth is brought into engagement before the drive ring, if that is seen and a drive arc of 90 ° perpendicular surface of the teeth on the driven is then a loss of motion from the fret immediately behind the perpendicular surface ¹ U tooth is sufficiently within the intended one of the teeth on the driving ring, and 20 accuracy of such a receiver. Of course it is a minimum, if the stepped teeth can be brought into engagement by changing the additional fraction of the driven collar and the driving of a tooth and the number of cycles the precision ring can be engaged when changing the counterbore. If, for example, an additional fraction of the correct surfaces of the teeth is in precise alignment on the drive arc V10 one. 35 tooth would be within 10 cycles

Loss in arch movement affects visual indication to less than ½ of a tooth length of course the accuracy of the recipient. If that be exactly.

Loss is a maximum, although the length of the arch will be borne by the drive plates

teeth to a little less than a full tooth length and changes the teeth on the driven arms. Although some loss is permissible, 30 will be made of a self-lubricating material, the loss in the receiver according to the invention allows the relative movement of the teeth to be considerably reduced by a special deselection of the number during engagement and disengagement the graduated teeth can cause wear and tear. Thus, in the rings 50 and 52 of the drive plates 46 and receivers, respectively, according to the invention, it is desirable to have a 48, such that a fraction of a tooth is included in the number 35 of precisely recurring re-engagement of the teeth which are more angular Avoid teeth. By using movement of the rings 50 and 52 corresponding to a full cycle of an odd number of teeth on one of the gears of the encoder cam 4 contained in the gear train of the motor 114, the unity becomes. Assume, for example, that the grip between the teeth on the rings of the drive plates 46 and 48 shifted during time 40 the drive plates and the teeth on the driven one full cycle of rotation of the encoder collar by four cycles at a time. Rotating this cam 4 over an arc of exactly 90 ° allows a more even distribution of any and that the stepped teeth 58 and 60 of the wear that may occur
Rings 50 and 52 carried by plates 46 and 48, respectively, as shown in FIG. 5 is shown, the recipient

are at such a distance from each other that 45 catcher motor 14 and the encoder motor 2 are present by the within 90 ° 250 ¹ A teeth. When lines 6 and 8 are connected in parallel to a single (not further assumed in this embodiment that shown) power source. The stepped teeth of the motors 114 and 2 on the first cycle must be those with constant driven collar and the drive ring so brought into speed and preferably synchronous motors that the vertical surfaces 50 are the starting speeds of the teeth on the driven collar directly selected are that the length of time one complete revolution between the vertical surfaces of the teeth on the hung of the encoder cam 4 is equal to the length of time, drive ring lie, then the loss in which is required to either the arm 74 or arc movement is a maximum and just a little Arm 84 over a full arc between the less than a full tooth length. During the first 55 spacers 36 and 38 driving cycle, the drive plate moves 250 whole of course from that full arc the width of the teeth and ¹ U tooth forward. Furthermore, during arm 89 and the setting made for the end of the cycle, the driven arm will pull off the stop 85. In other words, the expulsion plate is released and pressed in by its spring, the duration of a complete reversal of its initial position. If the depth of the encoder cam 4 is equal to the total stepped teeth at the beginning of the next cycle, again the amount of time required for the arm 74 to be brought into engagement, the driven spacer 36 lies over its arc in clock arm by ¹ U tooth out of alignment. As a result, pointing in contact with the arm 89 applies on the second cycle the loss in the drive, where at the moment of contact it is released slightly less than ³ Å of a tooth 65 movement of the arm 89, and by length. At the start of the third cycle, the teeth on arm 84 are only slightly less than Va tooth out of alignment away from adjustable stop 85,. across his arch in a counterclockwise direction and the loss in arching motion is to drive contact with arm 89 where he is in

909 511/1582

Moment of contact without moving the arm 89 is released.

The electromagnet 98 is connected to the contactor 10. As stated above, the movement of the contactor 10 is controlled by the position of the rod 12, the position of the rod 12 being determined by the instantaneous size of the variable to be measured. For each rotation of the encoder cam 4, the time interval during which the contactor 10 is closed and the time interval during which the contactor 10 is opened depend on the instantaneous size of the variable. Since the contactor 10 controls the energization and de-energization of the electromagnet 98, which in turn controls the relative arcs through which the arms 74 and 84 are rotated, respectively, during each operating cycle, the instantaneous magnitude of the variable being measured, as it controls the rod 12 and the Contactor 10 changes, expressed directly by the position of the pointer 134 on the scale 136 .

As described above, the motors 2 and 114 and the solenoid 98 are connected to a single energy source, but separate energy sources can also be provided. Since it is desired that the motors 2 and 114 rotate synchronously at a constant speed, it is preferable to connect the two motors to a common power source in parallel. However, the electromagnet 98 can be connected to another energy source, and in this case one of the lines leading to the electromagnet would have to be connected directly and the other line via the contactor 10 and the cam 4 to the energy source.

In the receiver of the invention, a positive or gear-like drive is provided between the stepped teeth 58 and 60 of the rings 50 and 52 carried by the drive plates 46 and 48, respectively, and the stepped teeth 78 and 88 of those carried by the driven arms 74 and 84, respectively Bundles 76 and 86 produced and maintained. When the stepped teeth of the driven arm are moved into engagement with the stepped teeth of the rings carried by the drive plates, the surfaces of the stepped teeth that extend at right angles and perpendicular to the drive direction are brought into contact with each other. To prevent misalignment during operation, the U-shaped ends of arms 74 and 84 are arranged so that only one leg of the U engages arm 89, the interface between the U-leg and arm 89 is substantially in the plane of the teeth on the corresponding ring. This design prevents the collars 76 and 86 from tilting, which could occur if the forces were not in one plane. Therefore, the perpendicular surfaces of the stepped teeth are held perpendicular to the drive direction and a positive interlock drive is established between the two parts until the teeth on the driven collar are retracted from the teeth on the driving ring by energizing or de-energizing the electromagnet 98. This positive drive is essential as it eliminates any possibility of slipping or slipping.

Claims (5)

Patent claims: 1. Receiver for a telemetry system for displaying measured values, its pointer with a control part that determines its position and can be moved in one direction or the other is operatively connected, which is moved in one direction by a first arm, when the first arm, which can be moved in this one direction by a first drive part, has a predetermined point is moved beyond, and which by a second arm in the opposite one Direction is moved when the opposite of a second drive part in this Direction movable second arm is moved beyond a predetermined point, wherein the first and the second drive part rotated by a motor in opposite directions at a constant speed are, and a device is provided, which the two arms alternately with brings the drive part in question into engagement, characterized in that for locking Drive engagement between the first arm (74) and the first drive part (46) and between the second arm (84) and the drive part (48) on the drive parts and the Poor intermeshing gear-like parts (50, 58 and 76, 78 or 52, 60 and 86, 88) arranged are. 2. Receiver according to claim 1, characterized in that the gear-like parts from a tooth bearing collar (76 and 86, respectively) on each of the arms (74, 84) and a tooth supporting ring (50 or 52) on each of the drive parts (46, 48) exist. 3. Receiver according to claim 2, characterized in that each of the teeth (78 or 88) of the collars (76 or 86) and the teeth (58 or 60) of the rings (50 or 52) with an engagement surface (A or C) is provided, which runs essentially at right angles to the drive path of the associated drive part (46 or 48). 4. Receiver according to claim 2 or 3, characterized in that the teeth (78, 88) the collar (76 or 86) and the teeth (58 or 60) of the rings (50 or 52) from a self-lubricating Material, e.g. B. a polyamide exist. 5. Receiver according to claim 2, 3 or 4, wherein the two opposite directions run in an arc, characterized in that the rings (50, 52) carrying the teeth in the Arch created by each ring during a full cycle of engagement of the teeth on the Bonds (76 or 78) with the teeth on the rings is traversed, each one straight Number of teeth plus a preselected fraction of a tooth. 1 sheet of drawings