DE1921311A1 - Compensation mechanism for a measuring device - Google Patents

Description

Compensation mechanism for a measuring device So far, measuring devices, those used to measure the volume of a gas flowing through a passage Corrections for changes in temperature and pressure of the aes are thereby made made that integrating corrective devices are provided in series became. For example, the temperature correction device would be one of a measuring device driven input shaft and an output shaft, and a similar pressure correcting means would have an input shaft coming from the output shaft of the temperature correcting device is driven. Such arrangements are satisfactory from the point of view of operation, however, they necessarily involve complicated designs.

According to the invention, the pressure and temperature correction devices combined in a single compact unit, the single input shaft and having a single output shaft, these shafts along if desired a common. Axis arranged could be. The input shaft drives a disk via a floating or freely movable ring, which over a first floating lever is adjusted to set the drive ratio between a drum and the disc to change. The disc drifts over a second floating one Ring on the output shaft and a second drum. The second floating nin u.ird independently adjusted to the drive ratio between the pulley and the output shaft to change.

It can be seen that a compact design; will be held there only one washer is required. by using floating rings in ae A high arad ad sensitivity is achieved as a floating mechanism Ring can be turned very easily by turning its associated lever and takes a sideways position and on the other hand by moving its lever as a result of the force given to it by its assigned drive element very little friction occurs in such operations, 90 that to perform only a very small amount of force is required for an adjustment.

It is evident, ate with a volumetric measuring device, temperature and pressure corrections are different Difficulties arise, according to Qer differences in the relationships between the corrected volume and the pressure and between the corrected volume and the temperature, the former being linear and the latter nonlinear (hyperbolic) is. The pressure and temperature response of the compensation device must match the changes in pressure and temperature inputs that are common are linear or at least approximately linear. Therefore, if need separate equalizers for the pressure and the temperature are arranged in series, these are each different address this Experience leads to complications in the mechanical Execution.

The main purpose of the invention is therefore to provide a compensation mechanism to create that responds to two variables, is of simple execution and one has a high degree of sensitivity.

Further purposes and advantages of the invention will be apparent from the following Description in which the invention is explained, for example, with reference to the drawing st.

Fig. 1 is a partially schematic view of a measuring device, which is provided with a balancing mechanism according to the invention.

Figure 2 is a rear view of the balance mechanism.

Figure 3 is a side view of the balancing mechanism, from the right Side of Fig. 1 seen from.

Figure 4 is a bottom plan view of the balance mechanism.

Figure 5 is a top plan view of the balance mechanism.

Fig. 6 is a front view of the balance; Fig. 7 is a partial view. in which a floating ring in its position in relation to a drum and a Disc is reproduced.

Fig. C is a schematic representation of the equalization mechanism to explain how it works.

Tn Fig. 1 is generally at 2 a volumetric measuring device for denotes a gas or another elastic medium (e.g. steam), which is of any known type and provides an output to a rotary shaft L. Such measuring devices are, if they are used to measure gas quantities, devices usually bellowed, and for the sake of simplicity it is assumed that the measuring device is of this type, though -is obvious that also other types of measuring devices including dynamic measuring devices (those of the non-inevitable or turbine type) can be used The measuring device 2 supplies its output to a cell 4 and operates a counter 6 via bevel gears 8 and 10. The counter 6 is used to visually check the operation of the measuring device 2 provided.

An input shaft 12 of the compensation or compensation device, which is indicated generally at 14, is driven by the shaft 4 via a speed reduction gear driven, which gears 16 and 18, pinions 20 and 22 and a shaft 24 has.

An output shaft 26 of the balancer drives a counter 28 via two bevel gears 30 and 32, and it can also use a printout counter Press 34.

Such printout counters are known and they periodically print one Count indicator on a moving strip to provide a record, from which times and corresponding counting displays can be determined. The counters 28 and 34 indicate the volume returned to standard conditions.

A temperature sensing element 36 is arranged to measure the temperature of the gas at the measuring point and a Bourdon tube 38 is actuated. The Bourdon tube 38 rotates an arm 40 around the axis of an "Elle 42" via a linkage, the one arm 44 and a handlebar 46. The arm 40 is provided with a slot 48 in FIG which an adjusting screw 50 is arranged through a threaded hole in a Cement 52 passes through, which is attached to the de of the handlebar 46 so that it can pivot, the effective lever arm and thus the extent of the movement of the arm 40 in response on temperature changes to determine which is the position of the end of the Bourdon tube 38 determine.

The shaft 42 is rotatable and runs in not shown fixed arranged bearings. The movement of arm 4 (causes cell 42 to rotate, and an arm 54, the end of which is clamped on the point 42, rotates as a result with 'temperature changes. A pointer 56 attached to arm 54 provides a direct display of the temperature on a scale on a plate 58. On the An arm 60, which is provided with a threaded flange 62, is also fastened to 42 through which an adjusting screw 64 passes. The lower end of the adjustment screw 64 is mounted in a member 66 at the end of an arm 68 so that the position of arm 68 with respect to arm 60 can be adjusted. The arm 68 is open the shaft 42 is loosely arranged so that its position is not directly influenced by the pivoting position the shaft 42, but rather by the arm 60 is influenced.

Between the arm 68 and a floating lever 70 is a handlebar provided, which has a cement 72, which with the arm 68 by a spring clip 74 is connected, which is riveted to the cement 72 at 76 and with a pin 78 which engages a small hole in the arm 68. The element 72 is attached to an element 80 by means of screws 82 passed through an aligned Go through a slot in the element 80 and screw it into threaded holes in the element 72 are.

The screws 82 allow linearity adjustment, and the Screw 64 allows zero adjustment.

An additional slot 84 is provided in element 80, and in the element 86 a corresponding slot is provided that corresponds to the slot 84 is aligned. Two spindle-like members 88 and 90 are in the slot 84 of element 80 and arranged in the corresponding slot of element 86, and collars on these spindle-like elements 88, 90 prevent separation of the Elements 80 and 86. The ends of neither 92 go through in elements 88 and 90 holes provided through it, and the spring 92 strives the spindle-like elements 88 and 90 separated from each other and attached to the inden Keep slots. This arrangement creates an idle connection between the Elements 80 and 86 and allows a degree of overflow of element 0 in both Directions beyond the limits of movement of the lever 70. The 1!; Element is Q6 connect to aem lever 70 by a spring clip 94 similar to the clip 74 is.

One in communication with the gas entering the measuring device 2 Standing opening 96 is connected to a Bourdon tube 98 via a nohr 100. One rotatable shaft 102 is operated via a linkage, which an element 104, which connected to the Bourdon tube 98, elements 106 and 108 which are used for relative adjustment are held together by screws, and has an arm 110 on the rotatable cell 102 is attached. The arm 110 is provided with a slot 112, and that Element 108 is in any desired position along arm 110 through a screw 114 is fixed.

An arm 116 is frictionally connected to the rotatable shaft 102 and provided with a pointer 118 which is an indication of the gas pressure on a scale on a plate 120 mounted on the balancer.

An arm 122 fixed on the shaft 102, which by rotating the Shaft 102 is rotated is provided with a flange 124 and an adjusting screw 126 which are similar to corresponding parts on arm 60. One arm 128 is pivotally connected by a pin 130 to the arm 122, and its angular position with respect to the arm 122 is adjusted by a zero adjustment screw 126, the end of which is mounted in an element 132. With the arm 128 is a lever 134 connected via a linkage, which has a slotted element 136 and an element 138, which by means of spring clips 140 and 142 with the arms 128 and 134 tied together are. Two set screws 144 pass through the slot in element 136 and through Threaded holes in element 135 therethrough, and they are provided for linear adjustment to enable.

According to the illustration in FIGS. 2 to 6, .e has a compensating device 14 a frame 146 which is provided with two members 148 and 150 through which a pin 152 extends therethrough. hat is a first movable frame 154 provided, which has arms 156 and 158, both of which are provided with holes, through which the run 152 passes. The frame 154 accordingly thought about the Rotate pin 152, but its movement is limited by a keder 160 (Fig. 4) which surrounds a screw 1b2 and which between the head of the screw 162 and a flange 164 of the frame 154 is held compressed. the screw 162 is screwed into frame 146 and held in place by a nut 166.

The shaft 12 get through a bearing in the arm 158 of the movable frame 154 and drives a drum 165, the opposite end of which in the Arm 156 of the frame 154 is mounted. Additional frame parts 170 and 172 are on the ores 158 and 156 are attached and provided with slots through which the floating Lever 7G passes through; the frame part 172 is provided with a slot 174, and A similar slot (not shown) is provided in the frame part 170. Of the floating lever 70 is provided with an elongated slot 176, the length of which corresponds approximately to the diameter of a ring 178. The slot 176 includes the Ring t76 with just enough play to allow rotation, but tight enough to have an inevitable control of the angular position of the ring and the lateral To enable position adjustment of the lever 7 through the ring.

A second movable frame 180 is for rotation about the Pin 152 is arranged regardless of the position of the first movable frame 154 and similarly provided with bearings for a drum 182 which is the output shaft 26 drives. Portions 184 and 186 of frame 180 are slotted around the tax lever 134 to hold, and a ring 188 is held in a slot 190 of the lever 134 and adjustable in position by lever 134. The movement of the frame 180 is limited by a spring 192 (Fig. 5) between the head of a screw 194 and a flange 196 of the frame 180 is kept pressed together. The levers 70 and 134 extend approximately diametrically across their respective ring 178 and 188

A shaft 198 is attached to the frame 146 and extends into the interior a hollow cylindrical part 200 extends (Fig. 3) in which a bearing is provided which allows the cylinder 200 to rotate about the shaft 198.

A disk 202 is arranged on the cylindrical part 200 and provided with a smooth surface 204.

It should be noted at this point that the drums 168 and 182 are so arranged are that their axes are parallel to a diameter of the surface 204.

The rings 178 and 188 are of the drums 168 and 182 respectively on the surface 204 of the disk 202 held.

The cross-section of each of the rings 178, 188 is advantageously such that, as can be seen from FIG. 7, a single point of contact between the outer edge of each ring and face 204 of disc 202 is present while two points of contact between each of the drums 168, 182 and the inner surface of the respective ring 178 and 188 are present. The outer surface of each ring is beveled to a creating circular edge 208, while the inner surface with two circular Edges 210 is provided. It is desirable that the two inner edges 210 lie close together.

According to a modification, the inner surface of each of the rings 178, 188 have the shape of a cylindrical surface so that when the axis of the ring and the axis of the corresponding drum 168 or 182 are in alignment with one another, there is a line of contact between the drum and the cylindrical surface of the ring is. If the axes are not parallel, there are of course only two There are points of contact between the ring and the surface of the drum.

The rings 178, 188 are through against the surface 204 of the disk 202 the effect of the leathers 160 and 192, respectively, which are pressed onto the corresponding frame 164 and 180 act, in which the drums 168 and 182 are arranged. There three points of contact between each ring, the disc and the corresponding drum are present, the rings cannot tilt and are in a stable position held perpendicular to the disk surface 204.

According to FIG. 6, the end surface 206 of the cylindrical part 200 is with provided with a scale which, as can be seen from the description below, can be used to calibrate the instrument.

Every X 14 compensation device benefits from the Properties of the floating ring drawn to a delicate setting the drive ratio between the shafts 12 and 26 to make.

In operation, the shaft 12 rotates, as can be seen in particular from FIG. 2 counterclockwise (when looking at its end), and it granted the disk 202 through the drum 168 and the floating ring 178 a rotation in Counterclockwise. When the point of contact between the ring 178 and the sheath 202 is closer to the peripheral edge of the disk 202, the disk becomes relatively slow driven while when the Touch point closer to the center of disk 202, the speed of rotation of the disk in relation to the speed of rotation of the Wave 12 increases0 Initially, the floating lever 70 is in one Position that the axis of the drum 168 and the axis of the ring 178 are parallel, 90 that the plane of the peripheral edge 208 of the ring 178 is perpendicular to the radius of the disk 202 passes through the point of contact between the edge 208 of the Ring 178 and face 204 of disc 202 passes therethrough. This is a stable one Position, and the ring 178 tends to remain in the same position, as long as the floating lever 70 is not moved.

Movement of the Et7v of the floating lever 70 to the left (according to Fig. 2) in response to a decrease in temperature leads to the fact that the axis of the Ring 178 is moved out of its parallel position to the axis of the drum 168. The ring 178 is in fact "steered" by the lever 70 and in one such direction driven so that its axis is again parallel to the axis of the drum 168, however, the point of contact then lies between the ring 178 and the surface 204 of FIG Disk 202 closer to its center and in alignment with the pivot point at the end of the lever 70. Accordingly, the ring 178 returns to a position in which its Axis parallel to the axis of the drum 168 and the plane of its peripheral edge 208 is perpendicular to the badius of the disk 202 which passes through the point of contact passes between the disc and the ring. However, the point of contact lies now closer to the center of disk 202 so that the disk is moving at greater speed is driven.

It should be noted that very little force is required to move the lever 70D and most of the force is used to move the Drum 168 very slightly in Rîchtting; from face 204 of disk 202 path to lift and to compress neither. The ring 178 in its end position moving force is from the measuring device 2 via the cell 12 and the drum 168 delivered.

Similarly, a rise in temperature leads to movement of ring 178 towards the peripheral edge of disk 202.

A decrease in pressure causes the pivot point to move of the lever 134 in the direction to the right (according to FIG. 2), and the resulting "Steering" of the ring 188 causes the point of contact of this ring with the Surface 204 of disk 202 moves toward the center of disk 202, so that the speed of rotation of the drum 182 is decreased. The shaft 26 rotates in the counterclockwise direction when ih Fig. 2 is looked at its end. The the Following the ring 188 causing force is over the disk 202 instead of the drum 182 is supplied.

The device works according to the above explanations to the effect that takes into account the fact that both lower temperatures and higher pressures increase the density of a gas, eo that a given volumetric Flow to which the measuring device responds, an increased mass flow or equivalently represents an enlarged standard flow volume.

Since the volume of a given amount of a gas is a function of its temperature and its pressure according to the relationship (1) V = mR-P where: T is the absolute temperature, P is the absolute pressure, m is the mass and R is the gas constant, a standard volume stands V or the volume of the gas at an arbitrarily chosen standard temperature T0 and a pressure P0 to the actual volume V in following relationship: V (2) V0 T P0 In Fig. 8, the ring 178 is shown schematically in its end position with respect to the surface 204 of the disc 202 and the barrel 168, the point of contact originally being at a distance D2 from the center of the disc 202 and now at a distance D1 from the cement the disc lies.

If it is assumed that D2 represents the position of the point of contact at the arbitrarily selected standard temperature T0 and D1 represents the position of the point of contact at temperature T, then the new drive ratio between drum 16 and disk 202 at temperature T is the drive ratio at temperature T0 according to the "ert in relationship.

When the pressure is initially on the arbitrarily chosen otandard pressure PO is located, the point of contact is between the second ring 188 and the surface 204 of the disk 202 at a distance D3 from the center of the disk 202. When the Pressure on the Sert P increases, the point of contact moves to a distance D4 from the center of the pulley 202, and the new drive ratio between the pulley 202 and the drum 188 at the pressure P is related to the drive ratio at the Standard pressure PO corresponding to the ert 1) 4 D in relation. 3 The drive ratio stands between the 'lelle 12 and the shaft 26 at the temperature T and the pressure p to the drive ratio at the temperature T0 and the pressure P0 corresponding to the "ert D2. D4 D1 D3 in relation.

If aaher D1 changes linearly with the absolute temperature T and D4 changes linearly with the absolute pressure P, is the output of the compensation device at the shaft 26 pronortionally the standard volume flow according to equation (2).

The overall operation of the apparatus is now referred to on Fig. 1 described.

Will a constant gas flow through the inevitably working Measuring device 2 through no typical temperature and pressure assumed, in which the counter 6 delivers correct displays, for example at 15.60 C (600 B) and 1.40 kg / cm2 (20 psi), 80 are the points of contact between the rings 178, 188 and the washer 202 in intermediate positions to create a special Establish a drive ratio between shafts 12 and 26 so that both of them Counters 6 and 28 show correct readings.

If the temperature of the gas falls, the counter 6 delivers a wrong one Specification because a larger amount of Uas through the measuring device 2 for a given Speed of its output shaft 4 passes through it. The working of the Bourdon tube 38 causes however, upward movement of the floating lever 70 so that the ring 178 in the direction opposite the center of the disk 202 is driven. Dad! <Uph becomes the speed of rotation of the disc 202 and, accordingly, the rotational speed of the shaft 26 is increased, and it a correct display appears on the counter 28. A rise in temperature leads to the reverse to reduce the rotational speed of the shaft 26 to the correct speed.

When the pressure of the gas entering the measuring device 2 increases, the quantity of gas flowing through the measuring device is greater than that of the Counter 6 displayed amount. The operation of the Bourdon tube 98 when the pressure rises however, causes the floating lever 134 to move upward about the ring 188 in the direction against the peripheral edge of the disc 202 to move. This will make the The rotational speed of the shaft 26 increases, and again a correct one appears Display on the counter 28.

Conversely, when the pressure decreases, the rotational speed becomes the Shaft 26 reduced accordingly.

It can be seen that at the same time changes in temperature and in print do not represent any difficulty for the equalizer and that Simultaneous changes in temperature and pressure recorded over large areas can be. During the calibration, the various link connections or Linkage can be adjusted so that the positions of the floating rings 178 and 188 the absolute temperature or the absolute pressure linearly over the operating range correspond.

By driving the disc 202 over the temperature responsive floating ring 178 through the drum 168 driven by the measuring device 2 becomes the reciprocal relationship between the otandari volume Vo and the temperature T in equation (2) is successfully satisfied in the invention, and this particular one Arrangement allows a high degree of inaccuracy of the compensation over a large Temperature range.

To calibrate the device, it is desirable to use the gear 16 or on another driven by the necessarily working measuring device 2 Zlement markings are provided so that the rotation of the shaft of the measuring device 2 can be determined with a high degree of accuracy. A number is advantageous Revolutions of the shaft 4 are counted at a given temperature, and / the displays on the surface 206 of the cylindrical part 200 are read, it being known that for a given number of revolutions of the shaft 4 at a particular temperature the cylindrical portion 200 is intended to rotate a certain number of degrees. Settings can be made at different temperatures using the screw 50, of screw 64 and screw 82, and it can be seen that these settings are completely independent of the gas pressure.

A special pressure can be used to calibrate the device for pressure changes applied to the opening 96 and the shaft 4 let turn are counted until a given number of revolutions of the cylindrical part 200 where it is known that each revolution of the part 200 at a particular one Pressure corresponds to a special enlargement of the displays on the counter 28. settings can be made by changing the relationship between the linkage elements 106 and 108 is changed, the screw 126 is adjusted and the relationship between the linkage members 136 and 138 is changed. These settings are used for executed several different pressures, so that the speed of rotation of the gel 26 accurately with respect to the rotation of the part 200 over the operating pressure range is. 8 it can be seen that this calibration process is independent of the temperature.

When the device is used to gas quantities during long periods of time To measure, the expression counter 34 can be used to indicate gas volume periodically print out a moving strip. If the device is used for a long time If guide periods are used, then a high degree of accuracy can be achieved despite considerable Pressure and temperature changes can be obtained. The compensation facility speaks reacts very quickly to changes in temperature and pressure and provides accurate readings over long periods, the balancing device for simultaneous balancing ideally suited for temperature changes and pressure changes over a wide range is because it has two floating rings, one of which is accounted for onaie absolute temperature is set linearly in its position and the other in response to the absolute pressure in its position is adjusted linearly.

If desired, the disc 202 can be replaced with a cone will. In such a modification, the drums measure parallel to the conical Surface are arranged, and the input shaft and the output shaft are not more parallel to each other. The facility modified in this way still works in im essentially the same as the device described above. That common element, to which the floating rings are attached, must have an element a surface of revolution eein, which consists of rectilinear elements, which by its Go through the axis of rotation.

Claims (9)

Patent claims 1. Compensation mechanism for a measuring device, marked by a first drum (168), a means for rotating the drum upon response on the output of the measuring device (2), a rotatable part (202) which has a surface (204) has an enormous surface of revolution made of rectilinear elements passing through Its axis of rotation will pass through a first ring (178) between the surface (204) of the rotatable part (202) and the first drum (168) is arranged, which drives the rotatable part (202) via ring # 178), a second drum (182), which drives an output shaft (26), a second ring (188) between the second drum (182) and the surface (204) of the rotatable part (202). arranged is, wherein the rotatable part (202) the second 'i' drum (182) over the second ring (188) drives a device that is responsive to a first variable quantity the axis of the first ring (178) out of parallel with the axis of the first drum (168) move, and a device responsive to a second variable quantity, about the axis of the second ring (188) out of parallel with the axis of the second To move the drum (182). 2. Compensation mechanism according to claim 1, characterized in that that the means for moving the axis of the first ring (178) is a lever (70) which is provided with a slot (176), the length of which is approximately the Diameter of the first ring t178) and which includes the ring. 3. Compensation mechanism according to claim 1 or 2, characterized in that that the means for moving the axis of the first ring (178) on a pressure sensing device responds, and the means for moving the axis of the second ring (188) responds to a temperature reduction device. 4. Compensation mechanism according to one of claims 1 to 3, characterized by means for adjusting the amount of displacement of the axes of the Rings (178, 188). 5. Compensation mechanism according to one of claims 1 to 4, characterized by means for adjusting the position of each of the rings (178, 188) with with respect to the output of the sensing device concerned. 6. Compensation mechanism according to one of the claims 1 to 5, thereby characterized in that the rotatable part is a disc (202), the surface (204) of which lies in one plane. 7. Compensation mechanism according to one of claims 1 bi o, characterized characterized in that the rotatable part (262) is provided with markings for defining the route, over which it rotates is provided. 8. Compensation mechanism according to one of claims 1 to 7, characterized characterized in that the outer surface of each outer ring (178, 188) is beveled, by a single one between each ring and the surface (204) of the rotatable member (202) To create a point of contact. 9. Compensation mechanism for a measuring device, the output shaft of which is rotatable in response to the volume of medium flowing through the measuring device, characterized by one driven by the output shaft of the measuring device (2) Drum (168), a rotatable part (262) with a surface in the form of a surface of revolution of rectilinear elements that pass through an axis of rotation, one between the drum (168) and the rotatable part (202) arranged ring (178), one on The temperature of the medium responding device, which the distance of the contact point between the ring (178) and the rotatable part (202) from the axis of rotation of the rotatable Partly adjusts and which causes the point of contact to be at a decrease the temperature of the medium is moved closer to the axis of rotation, and one of the rotatable Part (202) powered display device. L e r s e i t e