The invention relates to systems for lifting a concrete forming structure or apparatus.
Hydraulically lifted concrete form systems for elevator cores are presently known and used on building construction sites. In leveling these hydraulically lifted concrete forms from floor to floor, several systems are presently used, and they each have significant drawbacks.
The first known raising system utilizes water levels. The problems with water levels are that they must be maintained and serviced prior to every lift to be sure they are operational. The accuracy of the lift is determined by the operator of the system. The accuracy of how even the form is lifted is dependent on how quickly the water levels respond in the tubes and how quickly the operator responds to variances. Often times the operator will ignore or not be aware of variances that can be critical to the loading of major form components creating an unsafe condition.
The water lines used in a water leveling system can often become kinked and/or clogged causing the readings to be incorrect. During winter conditions, precautions have to be taken to be sure that the water or other liquid in the lines does not freeze. In summer conditions, the water or other liquid in the lines can evaporate, requiring the operator to top off the liquid prior to starting. Because of the length of the water lines and the routing that often times must be taken, the lines are prone to damage. All these factors contribute to inaccuracy in the lifting process. Frequently the water levels are ignored, and the concrete form is lifted with no leveling assistance.
A second type of system used to coordinate lifting the system involves having men located at each of the critical lifting points to physically measure the progress of the lift from the previous pour as it progresses. The progress is often shouted out to the operator or communicated via radio. The operator analyzes what each of the measurements mean and turns the power units on or off accordingly. The system is very labor intensive and inaccurate requiring many men to measure at once and is only as accurate as the men doing the physical measurement and the ability of the operator to analyze the information and respond quickly to it.
A third method depends on the operator's ability to sense that the concrete form is rising. In this method, the operator uses reference structures that are close by to coordinate the rise of the system. This method is the most inaccurate since no actual measuring devices are used.
A fourth method depends on the repeatability of mechanical pump valves or sensors. This method operates on the theory that if all cylinders are pumped an equal volume, they will all ascend equally. This is often not true because the equipment used cannot guarantee repeatability. For instance, there may be leakage in the system or there may be variances in the construction of the items employed in the lift. The number of hydraulic cylinders coordinated at once is limited.
Monitoring the system in order to achieve the desired lift height on all four systems depends on a physical measurement by the operator or a helper of the operator.
The present inventors recognize a need for a form control and monitoring system that coordinates all hydraulic cylinders quickly, safely and precisely.
The invention provides a form control and monitoring system that coordinates the raising of form elements by lift apparatus so that the form elements are lifted in a closely controlled, automatic manner. The lift apparatus includes plural lifting devices wherein the extent of lifting at each device is closely controlled with respect to the other lifting devices. This close control can be used to ensure a precise, even lifting of the entire lift apparatus. The control and monitoring system of the invention particularly enhances hydraulically lifted concrete form systems such as used for elevator cores.
The invention includes one or more form elements for defining an area to receive a formable material, such as concrete. According to one embodiment, each element is attached to the form structure. A lift apparatus is provided for lifting the form elements. The lift apparatus comprises a measurement device for measuring the position of the lift apparatus relative to a fixed point. The lift apparatus is connected to the form structure. A control unit is provided for controlling the lift apparatus. The control unit is signal connected to the measurement device and is signal connected to the lift apparatus.
In one embodiment, the lift apparatus comprises a plurality of jack assemblies connected to the form structure. The jack assemblies are connectable to a formed object, such as a previously formed concrete structure, or a base. Each jack assembly comprises an actuator, such as for example a hydraulic cylinder for raising the form elements along with the form structure.
In another embodiment, the measurement device comprises a plurality of sensors. Each sensor is connected to each jack assembly for measuring a distance that the actuator moves the form structure.
In another embodiment, the control unit comprises deviation calculating instructions for calculating a deviation defined by a difference between a position of each jack as reported by the corresponding sensor. The control until continuously computes the deviation while the control unit is in a lifting mode. The control unit comprises deviation comparison instructions for comparing the deviation to a predefined deviation tolerance range. The control unit comprises pausing instructions for stopping a respective one or more of the jacks when the sensor corresponding to the jacks provides a position value that is outside of the deviation tolerance range.
In another embodiment, the control unit comprises pausing instructions for pausing one jack while the sensor corresponding to the jack reports a position value that is outside of a deviation tolerance range and above the position values of the non-paused jacks. Also the control unit may comprise pausing instructions for pausing all other jacks while the sensor corresponding the non-paused jack reports a position value that is outside of a deviation tolerance range and below the position values of the paused jacks.
The control unit may comprise completion detecting instructions for signaling one or more of the jacks to stop when the jack has reached the pre-defined or a user defined lift distance or final lift height.
After the lift is complete the form elements or panels can be anchored to the previously formed object, for example concrete. The jacks then may be disconnected from the formed object and retracted back to their starting position.
Numerous other advantages and features of the present invention will become readily apparent from the following detailed description of the invention and the embodiments thereof, and from the accompanying drawings.
Referring to
As shown in
In one embodiment, the control unit may be a computer and the control unit may comprise one or more electronic processor chips, programmable logic controllers, logic processors, memory circuits, RAMs, ROMs, electronic chips, and or microprocessors. In one embodiment, the functions and or operations carried out by the control unit can be in the form of machine readable instructions. In one embodiment, the machine readable instructions may, for example, comprise one or more gates of a circuit, instructions hardcoded into a circuit, or programmable instructions, as for example software code, executed by a processor or circuit capable of reading those instructions.
Also, referring to
In this embodiment, referring specifically to
With the system 30 in the initial set up position, the system 30 is ready for operation. The process as described below and shown in
Referring now to
As indicated at step 48, as the central control panel 13 receives these continuous updates on the travel distance or position value of each actuator 5, the central control panel 13 continuously computes the height difference between the actuators 5. The process, as indicated at step 50, is also retrieving a pre-defined stored height tolerance parameter or deviation tolerance range. The process executed by the central control panel 13 then, at step 52, compares the computed height differential between the actuators 5 to the retrieved tolerance parameter or deviation tolerance range. If all of the actuators 5 are within the height tolerance parameter, the process proceeds to step 54 where it determines if the actuators 5 have reached the absolute height entered by the operator at the start of the lifting operation. If the actuators 5 have reached the absolute height, then the lifting process has been completed, and the process ends as indicated at step 56. If however at step 54 the absolute lift height has not vet been reached, then the process continues to step 58 where the system continues to lift the actuators 5, and the process returns back to step 46.
Referring again to step 52, if the process had determined that the height differential between the actuators 5 was not within the height tolerance parameter, then the process proceeds to determine if the height of the evaluated actuator 5 is less than the acceptable tolerance at step 60. If the height of the evaluated actuator 5 is less than the acceptable tolerance, then the height of the evaluated actuator 5 is too low with respect to the other actuators 5 being lifted and needs to be raised. The process then at step 62 stops the actuators 5 that are not out of tolerance, while it lifts the actuator 5 that is out of tolerance. While the process does this, it is also capturing the height of the lower actuator 5 that is being lifted at step 64, and at step 66, it is evaluating whether the actuator 5 being lifted is back within tolerance. If it is, then, as indicated at step 58, the process proceeds to lift all of the actuators 5 again. If, however, the process determines at step 66, that the actuator 5 being lifted is still not within the tolerance, the process returns to step 62 and continues to lift the lower actuator 5. This process continues until the lower actuator 5 is brought within height differential tolerance with respect to the other actuators 5 so that it can continue to lift with the other actuators 5.
Referring again to step 60, if the process determines that the height of the evaluated actuator 5 is not less than the acceptable tolerance, then it must be greater than the acceptable tolerance because at step 52 it was determined that the height differential was outside of the acceptable tolerance either on the high or low side. As such, the height of the evaluated actuator 5 is too high with respect to the other actuators 5 being lifted, and the other actuators 5 need to be raised. The process proceeds to step 68 where the process stops the evaluated actuator 5 that is too high and out of tolerance, while it lifts the other actuators 5 to bring the height differential back within tolerance. While the process does this, it is also capturing the height of the higher actuator 5 with respect to the actuators 5 that are being lifted at step 70, and at step 72, it is evaluating whether the stopped actuator 5 is back within tolerance. If it is, then, as indicated at step 58, the process proceeds to lift all of the actuators 5 again. If, however, the process determines at step 72, that the stopped actuator 5 is still not within the tolerance, the process returns to step 68 and continues to lift the other actuators 5, while holding the actuator 5 that is too high. This process continues until the actuator 5 that is too high is brought within the height differential tolerance with respect to the other actuators 5 so that it can continue to lift with the other actuators 5.
In one embodiment, during the lift, a display monitor 34 (
Referring now to
Referring now to
A user visually inspects the target plate from above to ensure that the laser point 101b generated by the alignment laser emitter 101 is centered on the center 106 of the target 105 to ensure the self-raising form control system 30 and the form panels 3 are in proper vertical alignment. The user may set the preferred proper vertical alignment to provide that the concrete walls 21 are formed perpendicular to the ground or perpendicular to some set horizontal reference. If a user determines that the laser is not centered on the target 106, the user will make manual adjustments to the self-raising form control system 30 to bring the system into proper vertical alignment. In another embodiment, the vertical alignment verification system may comprise a controller and a smart target that automatically checks for proper vertical alignment and makes corresponding adjustments or alerts a user that vertical alignment is not within range.
The vertical alignment verification system 100 may comprise an alignment laser emitter and an alignment target plate pair 101/103 at each actuator 5. However, having a laser emitter and an alignment target plate pair 101/103 on every jack may not be necessary to ensure proper vertical alignment. For a square arrangement of form panels, a minimum of three laser emitter and target plate pairs 101/103 is preferred to ensure proper vertical alignment for every square shaft created by the concrete walls 21.
The alignment laser emitter 101 may be located one level below the target level. For example, in
Once the actuators 5 are retracted to the next lift position, the jack assemblies 32, through the jack support brackets 6, are bolted to the previously poured concrete 21 for each jack assembly 32. After all the concrete forms are poured and stripped, the system is ready to make the next lift. The concrete forms are lifted in this fashion until the total height of the structure has been reached.
While the invention has been discussed in terms of certain embodiments, it should be appreciated that the invention is not so limited. The embodiments are explained herein by way of example, and there are numerous modifications, variations and other embodiments that may be employed that would still be within the scope of the present invention.
This application claims the benefit of U.S. provisional patent application Ser. No. 60/959,093 filed on Jul. 11, 2007.
Number | Name | Date | Kind |
---|---|---|---|
2636274 | Marsh | Apr 1953 | A |
3165835 | Duncan | Jan 1965 | A |
3775929 | Roodvoets et al. | Dec 1973 | A |
3779678 | Scheller | Dec 1973 | A |
3824666 | Roodvoets et al. | Jul 1974 | A |
3973885 | Schmidt | Aug 1976 | A |
4040774 | Scheller | Aug 1977 | A |
4053238 | George et al. | Oct 1977 | A |
4674870 | Cain et al. | Jun 1987 | A |
4732471 | Cain et al. | Mar 1988 | A |
4889425 | Edwards et al. | Dec 1989 | A |
4889997 | Tomiolo | Dec 1989 | A |
4917346 | Mathis | Apr 1990 | A |
5198235 | Reichstein et al. | Mar 1993 | A |
5492437 | Ortiz | Feb 1996 | A |
6014220 | Kimura | Jan 2000 | A |
6253160 | Hanseder | Jun 2001 | B1 |
6370837 | McMahon et al. | Apr 2002 | B1 |
6483026 | Snider, Jr. et al. | Nov 2002 | B1 |
6557817 | Waldschmitt et al. | May 2003 | B2 |
6601309 | Hedstrom | Aug 2003 | B1 |
6874739 | Gregory | Apr 2004 | B1 |
7137207 | Armstrong et al. | Nov 2006 | B2 |
20050086901 | Chisholm | Apr 2005 | A1 |
Number | Date | Country |
---|---|---|
666513 | Jul 1988 | CH |
3180669 | Aug 1991 | JP |
Number | Date | Country | |
---|---|---|---|
20090041879 A1 | Feb 2009 | US |
Number | Date | Country | |
---|---|---|---|
60959093 | Jul 2007 | US |