US3666189A - Means and techniques useful in prestressing concrete structures - Google Patents

Means and techniques useful in prestressing concrete structures Download PDF

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US3666189A
US3666189A US49277A US3666189DA US3666189A US 3666189 A US3666189 A US 3666189A US 49277 A US49277 A US 49277A US 3666189D A US3666189D A US 3666189DA US 3666189 A US3666189 A US 3666189A
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Prior art keywords
carriage
wire
circular structure
movement
platform
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US49277A
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Maximiliaan J Dykmans
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DYK PRESTRESSED TANKS Inc
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Individual
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Assigned to DYK PRESTRESSED TANKS, INC. reassignment DYK PRESTRESSED TANKS, INC. ASSIGNMENT OF ASSIGNORS INTEREST. Assignors: DYKMANS, MAXIMILLIAN J.
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    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04GSCAFFOLDING; FORMS; SHUTTERING; BUILDING IMPLEMENTS OR AIDS, OR THEIR USE; HANDLING BUILDING MATERIALS ON THE SITE; REPAIRING, BREAKING-UP OR OTHER WORK ON EXISTING BUILDINGS
    • E04G21/00Preparing, conveying, or working-up building materials or building elements in situ; Other devices or measures for constructional work
    • E04G21/12Mounting of reinforcing inserts; Prestressing
    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04GSCAFFOLDING; FORMS; SHUTTERING; BUILDING IMPLEMENTS OR AIDS, OR THEIR USE; HANDLING BUILDING MATERIALS ON THE SITE; REPAIRING, BREAKING-UP OR OTHER WORK ON EXISTING BUILDINGS
    • E04G21/00Preparing, conveying, or working-up building materials or building elements in situ; Other devices or measures for constructional work
    • E04G21/12Mounting of reinforcing inserts; Prestressing
    • E04G2021/127Circular prestressing of, e.g. columns, tanks, domes

Definitions

  • ABSTRACT In wrapping wire around a concrete tank to prestress the same, a carriage is caused to travel around the tank by a motor-driven sprocket wheel thereon engaging a chain which extends tightly around and on the tank.
  • the wire is fed from a supply spool onto a wire-gripping drum and is then laid on the outer tank wall with a wire tension established by monitoring deviations in stress with respect to a nominal value of stress, and using such deviations to produce changes in the differences in peripheral linear speed between on the one hand the sprocket wheel speed (carriage speed) and on the other hand the linear speed of the wire-gripping drumv
  • Such stress is maintained substantially constant at the same nominal value whereby the wire is uniformly and accurately stressed when and as it is being wrapped around the tank wall.
  • a platform carrying wire tensioning apparatus may be raised or lowered on the carriage during carriage movement, either in the forward direction or in reverse direction or when the carriage is at standstill.
  • Means are incorporated to assure a constant spacing between wire convolutions.
  • control means are incorporated to maintain constant tension regardless of carriage speed either in a forward or reverse direction or at carriage standstill.
  • the wire may be laid in a continuous helix or in steps accurately controlled as to height.
  • means are incorporated to achieve or maintain an automatic wire tension regardless of carriage movement in either direction of carriage movement or at standstill.
  • the wire may be tensioned from a slack or zero tension condition to any desired tension and maintained automatically at such tension without requiring carriage movement.
  • the desired tension may be preadjusted to any desired value while the carriage is in motion either in the forward or reverse direction.
  • a hydraulic-electrical system is used for these urposes.
  • the present invention relates to improved means and techniques which are particularly useful in the prestressing of concrete structures such as, for example, reservoirs, nuclear reactors, pressure vessels in general, and pressure pipes. It will be appreciated that the invention in its broader aspects is useful for other purposes such as, for example, laying cable under controlled tension.
  • a specific object of the present invention is to provide im proved means and techniques whereby a more uniform and accurate stressing of wire is obtained in the process of wrapping the same around cylindrical structures.
  • Another specific object of the present invention is to provide a system of this character in which the wire tension is automatically adjusted so as to make such wire tension substantially constant in intensity.
  • Another specific object of the present invention is to provide a system of this character in which stresses are monitored to derive information as to the condition in the wire and using such information in a manner as to change relative speeds between carriage travel and the rate at which the wire is wrapped to thereby obtain constant tension in the wire during the wrapping process.
  • Another specific object of the present invention is to provide a system of this character in which a differential mechanism is controlled in accordance with changes in stress so as to minimize variations in such stress.
  • Another specific object of the present invention is to provide a system of this character incorporating means for assuring accurate spacing of wire convolutions on the tank.
  • Another specific object of the present invention is to provide an improved control system for achieving controlled movement of a platform on the carriage to achieve a constant predetermined spacing between wound wire convolutions on the tank.
  • Another specific object of the present invention is to provide a versatile system of this character which provides independent adjustments expediously and without substantial duplication, i.e., various components are used in multi functions such as in producing carriage movements, controlled vertical movements of a platform carrying the wire tensioning apparatus, and controlled wire tensioning regardless of carriage or platform movements or during standstill.
  • Another specific object of the present invention is to provide an improved system which provides automatic control of wire tension under all conditions.
  • FIG. I illustrates relationship of apparatus with respect to a concrete wall of a tank around which a carriage effectively pulls itself while laying wire on the tank in a stressed conditron.
  • FIG. 2 is generally a view in side elevation and partly in diagrammatic form illustrating the wheeled carriage with the vertically adjustable platform carried thereon.
  • FIG. 3 is an electrical diagram illustrating connections to various components which are mounted on the vertically moveable platform shown in FIGS. 1 and 2.
  • FIG. 4 illustrates means in which one of the switches shown in FIG. 3 is actuated.
  • FIG. 5 illustrates the manner in which the individual wire strands S are spaced using the apparatus described herein.
  • FIG. 6 illustrates a hydraulic control system mounted on the vertically moveable platform in FIGS. 1 and 2.
  • FIG. 7 illustrates the mechanism, a portion of which is illustrated also in FIG. 2.
  • a sprocket chain C encircles the outer wall W of the concrete structure T.
  • the chain C may be considered stationary, particularly since the major length of the same is in nonsliding contact with wall W.
  • the chain C is used to propel the wheeled carriage 7 having wall-engaging wheels 8 and ground-engaging wheels 9.
  • This carriage 7 mounts a platform 5 which is vertically adjustable on carriage 7 and which carries the mechanism for propulsion of the carriage 7 around the wall and for simultaneously laying or wrapping wire or strand S around the wall under tension. As illustrated in FIG.
  • the wire, strand, cable, or the like, S, which is wrapped around the wall W with tension uniformly and accurately being applied to such cable during such wrapping extends from a supply reel R, which may be mounted on carriage 7, to and around a wire-gripping drum 2] (which is coaxially mounted with the previously mentioned sprocket wheel 20 but which may rotate independently of the same on different shafts 20A, 21A as illustrated in FIG. 2) and then to the structure wall W for prestressing of the same.
  • the wire S At the point where the wire S first engages the drum 21, the wire is spring-urged against such drum by device 6 for purposes of assuring a non slip condition between the wire and its gripping drum 21.
  • the wire-gripping drum has a sprocket wheel 213 secured thereto as illustrated in FIG. 2 with a chain 41 extending over such wheel 21B and a sprocket wheel 42 on shaft 40.
  • the wire S is tensioned and thus stretched as a result of the lineal speed of the carriage 7 being somewhat greater than the rate at which the wire S is laid on the wall, i.e., assuming that the effective diameters of sprocket wheel 20 and wire drum 21 are the same, as they may be in practice, the sprocket wheel 20 rotates somewhat faster than the wire-gripping drum 21 to cause the wire to be stretched and hence tensioned. For that purpose, rotation of wire drum 21 is impeded in controlled manner.
  • the shaft 10 driven by motor 30 also drives an axle gear of a differential system 82.
  • the other axle gear 84 and a sprocket wheel 15 are on the same shaft 11.
  • a chain 16 passes over sprocket 15, and a sprocket 16A on shaft 40 so that the wire drum sprocket 21B and connected wire drum 2] rotate together at a speed determined by the rotational speed of shaft 40 which is controlled as presently described.
  • a ring gear 89 on housing 87 is in mesh with a gear 98 on the output shaft 96 of a control motor 92.
  • Means 91A may be provided on shaft 96 to limit rotation of ring gear 89 in one direction when power is removed, i.e. to prevent rotation in the opposite direction as described in more detail later.
  • the control motor 92 is controlled by the output of a servo system 97 having two inputs which are compared in system 97 and functioning to control motor 92 in accordance with such comparison.
  • One of such inputs is a current or voltage derived from a torque transducer 100 associated with shaft 40 in such a manner as to produce such current or voltage that changes in intensity with the torque being applied to shaft 40.
  • the other input is a manually adjustable input derived from the tap 102 on potentiometer resistor 103 having its outside terminals connected to opposite terminals of voltage source 104.
  • the mechanism previously described for propulsion and controlled wire laying is all mounted on the platform 5.
  • the platform is slidably mounted in the carriage 7 and is vertically adjustable therein so that successive convolutions of wire laid on the tank wall may be of different elevation.
  • the wire wrapping is started at the bottom off the tank with the platform 5 being raised each time the carriage makes one revolution around the tank.
  • the platform 5 is held in the position to which it is adjusted by a cable 200 having one of its ends secured to the platform 5 at region 5A and its other end wound around a winch drum after passage over a supporting pulley 203 rotatably mounted on the upper portion of carriage 7 at 7A.
  • This drum 202 is drivable by the output shaft 205 of a hydraulic winch motor 206 which is supplied with hydraulic fluid from pump 207 via hydraulic line 208, solenoid valve 209 and hydraulic lines 210.
  • the pump 207 is driven by the motor 30 via shaft 10, sprocket wheel 212 on shaft 10, chain 214, and the input sprocket wheel 215 of pumps 207.
  • fluid may be returned to the sump 220, in which case the winch drum remains stationary, i.e., the platform 5 remains in a stationary adjusted position when and as the carriage 7 is being propelled by power being applied to motor 30.
  • the winch drum 202 has coaxially mounted therewith for movement therewith, a so-called cam wheel 222 which is preferably of the same diameter as the drum 202 for operation of a control switch LS 2 for purposes described later.
  • the switch LS 1 is in the form of a microswitch on carriage 7 and has its actuating element movable into engagement with a stationary post 242 on the ground whereby such switch LS l is actuated at least once per revolution of the carriage 7 around the tank T.
  • the switch LS 2 as shown in FIGS. 2 and 4 has its actuating element cooperating with the cam wheel 222 which has cams spaced thereon one eighth of an inch apart so that for each one eighth of an inch peripheral movements of the cam 222, the switch LS 2 is operated through an On-Off-On cycle.
  • the diameter ofthe cam wheel 222 is equal to the diameter of the winch drum 202 (FIG. 2) this Aa-inch movement corresponds to one-half of that movement or onesixteenth of an inch movement of platform 5 because of the manner in which it is supported by cable 200.
  • switches L8 1 and LS 2 are nonnally closed switches, and each as seen in FIG. 3 are associated with a so-called Eagle type counter device 246 which incorporates a clutch winding 247 and a so-called advance winding or coil 248.
  • the energization of winding 247 results in operation of the normally closed switch 247 A as indicated by dotted line 247 B
  • energization of coil 248 results in operation of normally closed switches 248 A and 248 B as indicated by the dotted lines 248 C and 248 D.
  • the control circuit is energized by 120 V AC. applied between leads L1 and L2.
  • Switch L8 1 and winding 247 are in series between lines L1 and L2.
  • Switches LS 2, 2488 and coil 248 are in series between lines L1 and L2.
  • Switches 247A and 248A are in a series circuit with relay coil 250 between lines L1 and L2; and when coil 250 is energized, it operates its associated relay switches 250A and 2508 as indicated respectively by dotted lines 250C and 250D.
  • the series circuit comprising switches 247 A, 248A is bridged or shunted by a manually operable normally open push button type switch 254, termed a jog switch for obtaining small movement of the platform 5 when the carriage 7 is in movement.
  • Switch 250A when closed energizes the pilot light 256.
  • the other relay switch 250 B is connected in a control circuit for the solenoid valve 209 for control of the platform raising and winch motor 206 (FIG. 2); and for that purpose, the solenoid valve 209 has correspondingly two windings 209 A, 209 B. Either one or neither one of these solenoid valve windings 209 A, 209 B may be selected for energization depending upon the position of a three-position, manually operable selector switch 260 having an "OfF'position, a Raise position, and a "Lower" position.
  • the switch 260 is illustrated in its Raise" position wherein the lead 261 is connected to one terminal of coil 209 A having its other terminal connected to the minus lead 264 of DC power supply 265.
  • lead 261 In the Lower position, lead 261 is con' nected to one terminal of winding 209 8 having its other terminal connected to lead 264. In the Oi-F position of switch 260, neither one of the windings 209 A, 209 B is energized.
  • This lead 261 is connectable to the other positive lead 267 of source 265 via a two-position manually operable switch 270 having either an Automatic or a "Manual" position.
  • leads 261 and 267 In the Manual position, leads 261 and 267 are interconnected directly; in the Automatic position these two leads 261, 267 are connectable via the previously mentioned relay switch 250 B which is connected in series with the switch 270 in its Automatic" position.
  • this pitch control circuit is now described under the condition that switch 270 is adjusted to its Automatic" position and switch 260 is in its Raise position.
  • the counter 246 is of the type which is manually adjustable to respond to and produce a control operation in accordance with each of a predetermined number of pulses applied thereto.
  • the counter known commercially as an Eagle Cycle-Flex counter, may be adjusted such that the number of counts may be from one to 40 in number, depending upon the desired wire pitch.
  • the desired wire pitch is eleven-sixteenths inch and the counter is manually adjusted to respond in succession to only each of the first I 1 counts or digits developed by the cam disc 222 of the cable winch drum 202 (FIGS. 2 and 4).
  • the counter 246 is automatically reset to its assumed preadjusted count of l 1 upon operation of switch L8 1 by stationary post 242 (FIG. 2). This assures initiation of the pitch control of wire S always on a point on the vertical line 280 (FIG. 5).
  • the wire S is then no longer laid horizontally as in dicated by the wire distance S1, S2, but the succeeding wire section S2, S3 is inclined due to raising of the platform 5 and when the vertical line 282 is reached (corresponding to point S3) the wire is again laid horizontally without any upward or downward movement being imparted to the platform 5 when and as the carriage 7 is being propelled around the tank T so that consequently the points 53, S4, S5, and S6 are in the same horizontal plane.
  • the post 242 again causes the switch LS 1 to be actuated to again allow a lifting of platform 5.
  • switch LS 1 results in energization of clutch 247 and resetting of the counter switch 246 to its assumed preset l I count. This 11 count is counted down one digit at a time each time switch LS 2 is operated (FIG. 4).
  • switch 247A is closed to condition a circuit for relay coil 250.
  • the relay coil 250 is energized to close switch 2508 to thereby connect solenoid valve raise coil 209A between DC lines 267, 264 in which case hydraulic power is supplied to the winch motor 206 (FIG. 2) which then rotates winch drum 202, and this rotation continues to cause the switch LS 2 to be operated.
  • the first time switch LS 2 is operated, the platform 5 is raised one count, i.e., one-sixteenth inch and the count of the counter switch 246 is reduced from an initial count of l l to the count of i0.
  • the eleventh count i.e., the counter reads zero and the switches 248A and 2488 remain open thereby deenergizing relay coil 250 and preventing energization of the solenoid valve. This condition prevails until the carriage 7 is moved around the tank to again operate switch LS1 and thereby reset the counter switch 247 to the preset l l count.
  • Manual override or jogging of the platform may be accomplished to change wire spacing if desired by operating pushbutton switch 254 which causes relay coil 250 to be energized.
  • Such jogging may result in either upward or downward movement of the platform 5 depending upon whether switch 250 is initially adjusted to its Raise" or its Lower position.
  • Selector switch 270 in "Manual position enables a direct manual control through the Raise or Lower" contacts of selector switch 260, even if part or the entire automatic-pitch-control circuit is or becomes inoperable. This means that the amount of pitch can be controlled manually without the use of the automatic pitch control circuit. By simply working the selector switch 260 from its Off position to its Raise position, it is possible to develop manually the required amount of pitch simulatin g the purpose of the automatic pitch control circuit.
  • the distance between lines 280 and 282 may be decreased or increased as desired and indeed this distance may at one extreme correspond substantially to the circular distance around the tank, in which case the pitch is considered as being of constant inclination without horizontal stretches of the wire.
  • This latter mode of constant inclination may be achieved simply by adjusting switch 270 to its Manual" position.
  • This pump 207 continues to pump hydraulic fluid when the three position switch 260 is in its Off position in which case the fluid is not delivered under pressure to the winch motor 206 but is allowed to return to the sump 220.
  • FIG. 6 Further details of the hydraulic system are illustrated in FIG. 6 where the hydraulic system includes three pumps 300, 301, and 207.
  • Pump 301 is required to have the largest capacity and it serves to supply fluid under pressure to the motor 30 for driving the carriage 7 around the tank.
  • the fluid flow is from the reservoir 220 through the valve 306 and filter 307 to the inlet of pump 301 and delivered under pressure to the selector valve 309 and forward and reverse valve 310 from whence the fluid is delivered to hydraulic motor 30.
  • the pump 301 is a so-called stem control pump in that it incorporates a large lever which may be moved manually to produce a continuous change in speed of motor 30 starting from zero speed to maximum speed.
  • the valve 309 is a selector valve which transfers fluid flow either to motor 30 as described above or to the platform winch motor 206 via the solenoid valve 209 in which latter case the platform may be raised or lowered, depending upon the energization of solenoid valve coil 209A or 2098 (FIG. 3) without requiring movement of the tower for that purpose.
  • the fluid in this latter instance flows through valve 309, check valve 315, and through valve 209 to winch motor 206.
  • the pump 207 is not operating because it requires for its operation movement of the carriage 7, i.e., rotation of shaft 10 which chain drives the sprocket drive 215.
  • Check valve 316 prevents flow from valve 309 to the outlet of pump 207. Jogging of the platform 5 may be accomplished using pushbutton switch 254 or may be moved continuously by adjusting the switch 270 to its Manual position, (FIG. 3).
  • This large pump 301 is driven by a gasoline engine 320 which serves also to drive the pump 300 for supplying fluid under pressure to the servo motor 92 for the automatic control of wire tensioning and detensioning in the process of winding the wire S under the desired constant tension.
  • Pump 300 is a pressure compensated pump delivering fluid under substantially constant pressure.
  • the flow of fluid is from reservoir or sump 220 through valve 306 and filter 307, through pump 300, servo valve 332 to the servo motor 92 whose shaft 96 drives the differential system 82 having a rotatable element 11 (FIG. 2) thereof coupled to the wire drum 21B via a shaft 40 in which the torque is sensed by load cell 100.
  • the servo valve 332 receives an output from amplifier 340 to which a command signal is supplied from potentiometer 103 on control panel 341. Another input to amplifier 340 is the output of preamplifier 343 which receives an input from the torque load cell and provides a signal which is applied to the tension indicator 344 on panel 341.
  • This tension indicator 344 may be of the visual type such as to produce a digital indication, but is preferably a recorder for purposes of achieving an ink permanent record of tension.
  • a permanent-type paper recorder is illustrated also at 344 in FIG. 3. It may be of the type supplied by Hewlett-Packard with conventional recording paper advancing mechanism which is operated in accordance with a signal applied thereto via leads 350 from the output of amplifier 352 having an input signal developed in accordance with the actuation of switch 360, such switch 360 being a proximity type switch which as shown in FIG. 2 is mounted adjacent to a magnet 36] extending from shaft 40 and is actuated thereby upon rotation of shaft 40.
  • the pulses developed upon actuation of switch 360 are used to move the paper of recorder 344 a distance propor tional to the number of such pulses processed in proximity amplifier 352 so that the distance traveled by the paper upon which a recording is made is a measure of the amount of wire S that has been wound on the tank.
  • the signal recorded is applied to the recording signal input terminal 362, 363.
  • Terminal 362 is connected to the output of amplifier 343 as is also digital meter 344A, the other terminal 363 and the other terminal of meter 344A are connected to an adjustable reference point on resistance 365 which is connected across the load cell power supply 370.
  • the output of amplifier 340 is applied to the servo valve 332 in the normal Run position of the two-position, manually adjustable switch 380 in which case the amplifier output is applied via connected switch contacts, E, F, and U to the terminals 384, 385 of valve 332, in which case either positive or negative voltages as the case may be are continuously applied to valve 332 in the process of maintaining constant wire tension.
  • switch 380 is actuated to its other "Stop position to thereby disconnect the servo valve 332 from the amplifier and to connect lead 390 to terminal 384 via contacts G and H and to connect terminal 385 via switch contacts K and L to the common ground lead 392 and at the same time to apply the command voltage on the tap of command potentiometer 103 via resistances 394, 395 and switch contacts C, D, and E to an output terminal of amplifier 340 by a feedback path which includes a connection between the junction point of resistances 394, 395 to one terminal of amplifier 340.
  • the housing 82 In normal operation when the carriage 7 is moving and a constant tension is being maintained by the servo system the housing 82 continuously rotates and variations eiflier below or above a nominal speed serves to increase or decrease the tension to restore the tension to its nominal adjusted value.
  • the housing gear 84 oscillates slightly about a normal stationary position. If there were no leakage in the hydraulic system, there would be no such slight oscillation or hunting.”
  • FIG. 7 illustrates details of a one way stop mechanism 91A in which the shaft 96 (FIGS. 7 and 2) mounts a disc 918 on which is secured a stop block 91C.
  • the disc 91B rotates in a clockwise direction as indicated by arrow 91D; but when the carriage speed is reduced to zero, such rotation stops and there is then a tendency for the tension in the previously stressed wire to rotate the shaft 96 in the opposite or counterclockwise direction.
  • a stop member 91B is pivoted at 91F and is urged outwardly by a compression spring 91G having one of its ends bearing against stop lever 91E and the other one of its ends bearing against a stationary abutment 91H.
  • This spring is sufliciently strong and long to prevent engagement of lever 915 with block 91C during clockwise rotation of shaft 96, but when and as the carriage movement is being reduced to zero, as for example in the process of shutting down the system overnight, the lever handle 91.] is manually moved in a clockwise direction about pivot 91F to be positioned behind the block. In so shutting down the system, the tension in the wire is reduced slightly by adjusting the resistance 103. Once the system is so locked off with lever 91E positioned as shown in FIG. 7, changes in resistance 103 which normally cause a lowering of wire tension are no longer effective because the disc 91A is prevented from rotating anticlockwise by lever 915. To unlock the system, the resistance 103 is adjusted for a higher tension than the lock-off tension, in which case the disc 91A rotates clockwise to allow the lever 915 to move away from abutment 9IC under the influence of spring 910.
  • wire tension may be adjusted without the need for moving the carriage.
  • carriage stationary adjustment of resistance 103 causes the servo motor 92 to drive the ring gear 89 to cause the wire-gripper drum 21 to move in a corresponding direction.
  • This may be accomplished not only by adjustment of resistance 103 but also by operating the jog switches 396 or 397. In the latter instance, the tension change may be accomplished more rapidly.
  • the differential housing gear 89 is rotated to cause shaft 11 to rotate with, however, shaft 10 remaining stationary.
  • wire tension is maintained constant not only during forward wire laying movement of the carriage 7 but also in those instances where the carriage 7 is being moved in the reverse direction as, for example, when it is desired to return to a so-called wire clamp ing off point on the tank wall or to correct wire spacing.
  • the structure of the wire gripper is of importance, and for that reason, the wire gripper described in my US. Pat. No. 3,510,041, issued May 5, I970 is preferred because lack of wire tension on one side does not destroy the gripping action as is the case, for example, when a conventional capstan or drum is used. Using a wire gripper of the character described in that patent, wire slack may be tolerated.
  • the platform 5 may be raised or lowered at car riage standstill with full power using the carriage pump 301 and selector valve 309 in its condition wherein it supplies fluid under pressure to motor 206. It is noted again that at standstill, pump 207 does not function because it requires carriage movement for its operation.
  • the vertical movement of platform 5 during horizontal carriage movement may be controlled by setting of the counter 246 (FIG. 3) and/or by adjustment of flow of pump 207 using handwheel control 207A which serves to control or adjust the volume of fluid being supplied to motor 206.
  • the switch 270 (FIG. 3) is in its "Manual" position the slope of the wire is such that a continuous helix is formed because in such case the counter circuit 246 has no control function, assuming, of course, that the selector switch is in "Raise or "Lower position.
  • the pump 300 is as indicated previously a pressure regulated or compensated pump for purposes of delivering sufiicient constant pressure under all conditions.
  • the pump 301 is a so-called manually operable stem control pump which through manual adjustment is capable of delivering an oil flow in continuous infinite steps from zero to maximum flow capacity with the flow rate being substantially directly proportioned to the amount of manual stem movement.
  • the pump 207 is a variable volume type pump, the output volume of which may be controlled by a handwheel control 207A and when such handwheel is adjusted, the flow of fluid is directly proportioned to the speed of input sprocket 215 (FIG. 2), i.e. directly proportional to speed of carriage 7.
  • the handwheel control 207 is adjusted for zero fluid flow in which instance carriage movement produces no vertical movement of platform 5.
  • the handwheel control 107A may be adjusted for maximum flow in those instances where it is desired to accomplish a steep raising or lowering of the platform 5.
  • a carriage for movement around said stationary circular structure; means for supporting said carriage adjacent to the outer wall of said circular structure for circumferential movement around said circular structure; a wire upply; means on said carriage for gripping wire supplied thereto from said wire supply; said gripping means including at least one movable element; means for moving said carriage around said circular structure; means for producing movement of said movable element such that a tension is developed in said wire; means operating concurrently with said movement producing means for sensing a condition representative of the tension in said wire and developing a first signal; means developing a second signal independently of said first signal but representative of a desired tension in said wire; a servo system responsive to and controlled in accordance with said first and second signals and functioning to produce a control signal representative of the difference in said first signal and said second signal; and means responsive to said control signal and controlling said movement producing means to restore said first signal to a value commensurate with said second signal,
  • a carriage for movement around said stationary circular structure; means for supporting said carriage adjacent to the outer wall of said circular structure for circumferential movement around said circular structure; a wire supply; means for gripping wire supplied thereto from said wire supply; said gripping means including at least one mova ble element; means for moving said carriage around said circular structure; means for producing movement of said movable element such that a tension is developed in said wire; means operating concurrently with said movement producing means for sensing a condition representative of the tension in said wire and developing a first signal; means developing a second signal independently of said first signal but representative of a desired tension in said wire; a servo system responsive to and controlled in accordance with said first and second signals and functioning to produce a control signal representative of the difference in said first signal and said second signal; and means responsive to said control signal and controlling said movement producing means to restore said first signal to a value commensurate with said second signal, a platform,
  • a system as set forth in claim 2 including means for initiating operation of said coupling means at a predetermined location of the carriage and for disabling the same prior to completion of travel of the carriage around the tank.
  • a system as set forth in claim 2 including adjustable means for coupling said carriage moving means directly to said platform changing means to the exclusion of said carriage such that said platform may be moved without requiring movement of the carriage.
  • a system as set forth in claim 3 including means responsive to actual extent of platform movement for disabling said coupling means.
  • a system as set forth in claim 5 including means for presetting said actual extent and means for adjusting the last mentioned means.
  • a carriage for movement around said stationary circular structure; means for supporting said carriage adjacent to the outer wall of said circular structure for circumferential movement around said circular structure; a wire supply; means on said carriage for gripping wire supplied thereto from said wire supply; said gripping means including at least one movable element; means for moving said carriage around said circular structure; means for producing movement of said movable element such that a tension is developed in said wire; means operating concurrently with said movement producing means for sensing a condition representative of the tension in said wire and developing a first signal; means developing a second signal independently of said first signal but representative of a desired tension in said wire; a servo system responsive to and controlled in accordance with said first and second signals and functioning to produce a control signal representative of the difference in said first signal and said second signal; and means responsive to said control signal and controlling said movement producing means to restore said first signal to a value commensurate with said second signal, and means on
  • said indicating means includes recording means having a movable recording medium and means for producing a recording thereon, means coupling said medium to said element for movement therewith, and means actuating said recording producing means in accordance with a signal derived from said tension sensing means.
  • a carriage for movement around said stationary circular structure; means for supporting said carriage adjacent to the outer wall of said circular structure for circumferential movement around said circular structure; a wire supply; a platform movable vertically on said carriage; means on said platform for gripping wire supplied thereto from said wire supply; said gripping means including at least one movable element; means for moving said carriage around said circular structure; means for moving said platform vertically on said carriage; means for producing movement of said movable element such that a tension is developed in said wire; means monitoring a condition of stress developed in said system and producing a first signal in accordance with such stress; means developing a reference signal means operating in accordance with the joint action of said first and reference signals and developing a bidirectional control signal, a control motor controlled in accordance with said control signal and having an output shaft; means coupling said output shaft to said one movable element; and adjustable means cooperating with said output shaft and having two positions, one of
  • a carriage for movement around said stationary circular structure means for supporting said carriage adjacent to the outer wall of said circular structure for circumferential movement around said circular structure; a wire supply; a platform movable vertically on said carriage; means on said platform for gripping wire supplied thereto from said wire supply; said gripping means including at least one movable element; means for moving said carriage around said circular structure either in the forward or reverse direction; means for moving said platform vertically on said carriage; means controlling movement of said movable element such that a tension is developed in said wire; said means for moving said platform including a coupling between said carriage moving means and such platform such that the carriage and platform move at proportionate rates.
  • said carriage moving means includes a carriage motor and a first pump for supplying energy to said motor; said platform moving means including a platform motor; and a second pump driven by said carriage to supply energy to said platform motor.
  • a system as set forth in claim 11 including selector valve means to either communicate said first pump to said carriage motor or to said platform motor.
  • a carriage for movement around said stationary circular structure; means for supporting said carriage adjacent to the outer wall of said circular structure for circumferential movement around said circular structure; a wire supply; a platform movable vertically on said carriage; means on said platform for gripping wire supplied thereto from said wire supply; said gripping means including at least one movable element; means for moving said carriage around said circular structure; means for moving said platform vertically on said carriage; means controlling movement of said movable element such that a tension is developed in said wire; and means responsive to the amount of vertical movement of said platform and controlling said platform moving means.
  • a system as set forth in claim 13 including means for disabling the last recited means and for rendering said carriage moving means effective to operate said platform moving means.
  • a carriage for movement around said stationary circular structure; means for supporting said carriage adjacent to the outer wall of said circular structure for circumferential movement around said circular structure; a wire supply; a platform movable vertically on said carriage; means on said platform for gripping wire supplied thereto from said wire supply; said gripping means including at least one movable element; means for moving said carriage around said circular structure; means for moving said platform vertically on said carriage; means controlling movement of said movable element such that a tension is developed in said wire.
  • a system as set forth in claim 16 including means for rendering the last mentioned means ineffective and for producing incremental movement of said platform.
  • a carriage for movement around said stationary circular structure; means for supporting said carriage adjacent to the outer wall of said circular structure for circumferential movement around said circular structure; a wire supply; means for gripping wire supplied thereto from said wire supply; said gripping means including at least one movable element; means for moving said carriage around said circular structure; means controlling movement of said movable element such that a tension is developed in said wire; the last mentioned means including a differential system including a first axle gear; a second axle gear, and a ring gear coupled to said first and second axle gears; a motor having an output shaft coupled to said ring gear; a one-way stop associated with said shaft to limit movement of said shaft in one direction only; said first axle gear being connected to said carriage moving means; said second axle gear being coupled to said movable element.
  • a system as set forth in claim 18 including means responsive to tension developed in said wire for controlling said motor.
  • a system as set forth in claim 18 including means for moving said carriage either in the forward or in the reverse direction.
  • a carriage for movement around said stationary circular structure; means for supporting said carriage adjacent to the outer wall of said circular structure for circumferential movement around said circular structure; a wire supply; means for gripping wire supplied thereto from said wire supply; said gripping means including at least one movable element; means for moving said carriage around said circular structure; means controlling movement of said movable element such that a tension is developed in said wire; and means on said carriage for indicating the tension developed in said wire.
  • said indicating means includes a recording medium, means for moving said recording medium in accordance with movement of said movable element and means for simultaneously making a record on said medium in accordance with tension in said wire.
  • a carriage for movement around said stationary circular structure; means for supporting said carriage adjacent to the outer wall of said circular structure for circumferential movement around said circular structure; a wire supply; a platform movable vertically on said carriage; means on said platform for gripping wire supplied thereto from said wire supply; said gripping means including at least one movable element; means for moving said carriage around said circular structure; means for moving said platform vertically on said carriage; means controlling movement of said movable element such that a tension is developed in said wire; means for producing forward and reverse movement of said carriage moving means, and means for producing either up or down movement of said platform; means for disabling said carriage moving means; means for disabling said platform moving means.
  • a system as set forth in claim 23 including means for automatically maintaining constant tension in said wire regardless of up or down movement of said platform or forward or reverse movement of said carriage.

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  • Engineering & Computer Science (AREA)
  • Architecture (AREA)
  • Mechanical Engineering (AREA)
  • Civil Engineering (AREA)
  • Structural Engineering (AREA)
  • Tension Adjustment In Filamentary Materials (AREA)
  • Electric Cable Installation (AREA)
US49277A 1970-06-24 1970-06-24 Means and techniques useful in prestressing concrete structures Expired - Lifetime US3666189A (en)

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CA (1) CA941351A (enExample)
DE (1) DE2052003A1 (enExample)
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Cited By (12)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3770219A (en) * 1971-09-01 1973-11-06 Rocla Concrete Pipes Ltd Winding machine
US3912181A (en) * 1972-10-03 1975-10-14 Price Brothers Co Method and apparatus for wrapping a bevel pipe core
US4002304A (en) * 1975-06-06 1977-01-11 General Atomic Company Method and apparatus for stressing a tendon and banding a structure
US4058278A (en) * 1975-11-05 1977-11-15 B.V.S. Apparatus for winding plural strips under tension
US4059238A (en) * 1972-03-13 1977-11-22 Kurt Vogt Machine for winding containers
US4776145A (en) * 1983-12-09 1988-10-11 Dykmans Max J Multi purpose dome structure and the construction thereof
US4879859A (en) * 1983-12-09 1989-11-14 Dykmans Max J Method and apparatus for constructing circumferentially wrapped prestressed structures utilizing a membrane
US5094044A (en) * 1983-12-09 1992-03-10 Dykmans Maximilliaan J Multi-purpose dome structure and the construction thereof
US5134830A (en) * 1983-12-09 1992-08-04 Dykmans Max J Method and apparatus for constructing circumferentially wrapped prestressed structures utilizing a membrane
US5408793A (en) * 1983-12-09 1995-04-25 Dykmans; Max J. Multi-purpose dome structure and the method of construction thereof
US5675941A (en) * 1983-12-09 1997-10-14 Dykmans; Maximiliaan J. Method and apparatus for constructing prestressed structures utilizing a membrane and floating dome assembly
CN117005310A (zh) * 2023-07-27 2023-11-07 中国五冶集团有限公司 一种竖向预应力钢棒张拉辅助紧固装置及其使用方法

Families Citing this family (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
FR2357457A2 (fr) * 1976-07-09 1978-02-03 Bvs Procede et machine d'enroulement de bandes sur un corps cylindrique
US6112497A (en) 1997-06-30 2000-09-05 The Coca-Cola Company Variety pack vendor and method of using
CN107366431A (zh) * 2017-05-23 2017-11-21 成都智诚利合科技有限公司 一种混凝土中预埋钢筋捆扎设备的捆扎器

Citations (11)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2142252A (en) * 1937-03-04 1939-01-03 Clark Thread Co Recording device
US2159969A (en) * 1937-01-12 1939-05-30 Schlafhorst & Co W Appliance for testing the tension of textile threads or yarn
US2321465A (en) * 1942-04-14 1943-06-08 John M Crom Method of and apparatus for banding tanks
US2520402A (en) * 1944-08-18 1950-08-29 Lock Joint Pipe Co Wire-wrapping machine
US2573793A (en) * 1945-07-04 1951-11-06 Lock Joint Pipe Co Wire-winding apparatus
US2589366A (en) * 1941-05-16 1952-03-18 Continentale Et Coloniale De C Machine for hooping tubes
US3281085A (en) * 1964-03-12 1966-10-25 John M Crom Tank banding mechanism
US3338527A (en) * 1964-07-30 1967-08-29 Humes Ltd Apparatus for forming pre-stressing windings on concrete or like pipes
US3379385A (en) * 1965-09-03 1968-04-23 Price Brothers Co Machine for tensioning and winding wire onto pipe
US3477652A (en) * 1968-04-17 1969-11-11 Francis X Crowley Tank banding apparatus
US3572596A (en) * 1968-04-02 1971-03-30 Maximiliaan J Dykmans Cable stressing and winding apparatus

Patent Citations (11)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2159969A (en) * 1937-01-12 1939-05-30 Schlafhorst & Co W Appliance for testing the tension of textile threads or yarn
US2142252A (en) * 1937-03-04 1939-01-03 Clark Thread Co Recording device
US2589366A (en) * 1941-05-16 1952-03-18 Continentale Et Coloniale De C Machine for hooping tubes
US2321465A (en) * 1942-04-14 1943-06-08 John M Crom Method of and apparatus for banding tanks
US2520402A (en) * 1944-08-18 1950-08-29 Lock Joint Pipe Co Wire-wrapping machine
US2573793A (en) * 1945-07-04 1951-11-06 Lock Joint Pipe Co Wire-winding apparatus
US3281085A (en) * 1964-03-12 1966-10-25 John M Crom Tank banding mechanism
US3338527A (en) * 1964-07-30 1967-08-29 Humes Ltd Apparatus for forming pre-stressing windings on concrete or like pipes
US3379385A (en) * 1965-09-03 1968-04-23 Price Brothers Co Machine for tensioning and winding wire onto pipe
US3572596A (en) * 1968-04-02 1971-03-30 Maximiliaan J Dykmans Cable stressing and winding apparatus
US3477652A (en) * 1968-04-17 1969-11-11 Francis X Crowley Tank banding apparatus

Cited By (13)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3770219A (en) * 1971-09-01 1973-11-06 Rocla Concrete Pipes Ltd Winding machine
US4059238A (en) * 1972-03-13 1977-11-22 Kurt Vogt Machine for winding containers
US3912181A (en) * 1972-10-03 1975-10-14 Price Brothers Co Method and apparatus for wrapping a bevel pipe core
US4002304A (en) * 1975-06-06 1977-01-11 General Atomic Company Method and apparatus for stressing a tendon and banding a structure
US4058278A (en) * 1975-11-05 1977-11-15 B.V.S. Apparatus for winding plural strips under tension
US4879859A (en) * 1983-12-09 1989-11-14 Dykmans Max J Method and apparatus for constructing circumferentially wrapped prestressed structures utilizing a membrane
US4776145A (en) * 1983-12-09 1988-10-11 Dykmans Max J Multi purpose dome structure and the construction thereof
US5094044A (en) * 1983-12-09 1992-03-10 Dykmans Maximilliaan J Multi-purpose dome structure and the construction thereof
US5134830A (en) * 1983-12-09 1992-08-04 Dykmans Max J Method and apparatus for constructing circumferentially wrapped prestressed structures utilizing a membrane
US5408793A (en) * 1983-12-09 1995-04-25 Dykmans; Max J. Multi-purpose dome structure and the method of construction thereof
US5675941A (en) * 1983-12-09 1997-10-14 Dykmans; Maximiliaan J. Method and apparatus for constructing prestressed structures utilizing a membrane and floating dome assembly
US5881530A (en) * 1983-12-09 1999-03-16 Dykmans; Maximiliaan J. Method and apparatus for constructing prestressed structures utilizing a membrane and floating dome assembly
CN117005310A (zh) * 2023-07-27 2023-11-07 中国五冶集团有限公司 一种竖向预应力钢棒张拉辅助紧固装置及其使用方法

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CA941351A (en) 1974-02-05
DE2052003A1 (de) 1971-12-30
GB1337572A (en) 1973-11-14
FR2095442A5 (enExample) 1972-02-11

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Legal Events

Date Code Title Description
AS Assignment

Owner name: DYK PRESTRESSED TANKS, INC.,CALIFORNIA

Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNOR:DYKMANS, MAXIMILLIAN J.;REEL/FRAME:004688/0162

Effective date: 19870213

Owner name: DYK PRESTRESSED TANKS, INC., A CORP. OF CA.

Free format text: ASSIGNMENT OF ASSIGNORS INTEREST.;ASSIGNOR:DYKMANS, MAXIMILLIAN J.;REEL/FRAME:004688/0162

Effective date: 19870213