This disclosure relates generally to forming structures using slip forming techniques.
Slip forming concrete structures, for example along a horizontal axis, can be done in a number of ways. Structures such as curbs, barriers, or other structures are commonly formed using a slip forming process. Generally, long portions of a structure may be formed in a single pass of a slip form machine. A single machine may be used to provide the initial slip forming of the structure. Frequently, additional touch-up and repairs by humans may be recommended or required, as the process has natural inconsistencies associated with it. While some advances in the slip form process have been made, significant challenges still exist that are difficult to overcome. The slip form process is messy and often unpredictable.
Machines have been improved over the years to support additional functionality, such as in laying roads or curved structures. However, many features are still lacking and many problems exist in the art for which this application provides solutions.
In certain embodiments, a method of slip forming a concrete structure can include using a first slip form mold that travels along a path to form a portion of a concrete structure by delivering a first flow of concrete into the first mold through a first hopper. The first hopper can be configured to receive the first flow of concrete. The portion of the concrete structure can be modified using a second slip form mold different from the first mold by advancing the second mold along the concrete structure and, while advancing the second mold, delivering a second flow of concrete into the second mold through a second hopper that is configured to receive the second flow of concrete. In some embodiments, a system for slip molding a concrete structure can include a first slip forming vehicle. The first slip forming vehicle can include a first hopper, a first delivery system that is configured to deliver a first flow of concrete to the first hopper, and a first slip form mold that is configured to receive the flow of concrete from the first hopper. The system can further include a second slip forming vehicle that includes a second hopper. The second hopper can include a vibration device. The second slip forming vehicle can include a second delivery system that is configured to deliver a second flow of concrete to the second hopper as well as a second slip form mold. The second slip form mold can be configured to receive the second flow of concrete from the second hopper. The second slip form mold can be spaced from the first slip form mold by a following distance.
In certain embodiments, a system for modifying an existing concrete structure can include a modifying mold that is configured to extend across a top portion of an existing concrete structure. The modifying mold can be configured to extend at least partially along a side portion of the existing concrete structure and to travel along a substantially horizontal direction of travel. The modifying mold may be configured to be guided along at least one side of the existing concrete structure. The system may further include a concrete delivery system that is in fluid communication with the modifying mold. The concrete delivery system can be configured to receive liquid concrete. The system may further include a vibrator that is configured to promote a fluid consistency of the liquid concrete and/or compaction of the liquid concrete within the mold. The vibrator can be in fluid communication with the concrete delivery system and with the modifying mold.
In some embodiments, a system for modifying an existing structure can include a modifying mold that is configured to extend across a top portion of an existing structure and to extend at least partially along a side portion of the existing structure. The modifying mold can be configured to travel along a substantially horizontal direction of travel and to be guided along at least one side of the existing structure. The system may include a material delivery system that is in fluid communication with the modifying mold. The material delivery system can be configured to receive liquid material. The system may include a vibrator that is configured to promote a fluid consistency of the liquid material and/or compaction of the liquid material within the mold. The vibrator can be configured to be in fluid communication with the material delivery system and with the modifying mold.
The following drawings and the associated descriptions are provided to illustrate embodiments of the present disclosure and do not limit the scope of the claims and/or examples.
These and other features will now be described with reference to the drawings summarized above. The drawings and the associated descriptions are provided to illustrate embodiments and not to limit the scope of any claim or example. Throughout the drawings, reference numbers may be reused to indicate correspondence between referenced elements.
Although certain embodiments and examples are disclosed below, inventive subject matter extends beyond the specifically disclosed embodiments to other alternative embodiments and/or uses and to modifications and equivalents thereof. Thus, the scope of the claims and/or examples appended hereto is not limited by any of the particular embodiments described below. For example, in any method or process disclosed herein, the acts or operations of the method or process may be performed in any suitable sequence and are not necessarily limited to any particular disclosed sequence. Various operations may be described as multiple discrete operations in turn, in a manner that may be helpful in understanding certain embodiments; however, the order of description should not be construed to imply that these operations are order dependent. Additionally, the structures, systems, and/or devices described herein may be embodied as integrated components or as separate components. For purposes of comparing various embodiments, certain aspects and advantages of these embodiments are described. Not necessarily all such aspects or advantages are achieved by any particular embodiment. Thus, for example, various embodiments may be carried out in a manner that achieves or optimizes one advantage or group of advantages as taught herein without necessarily achieving other aspects or advantages as may also be taught or suggested herein.
Described herein are methodologies and related systems for slip forming concrete structures. It will be understood that although the description herein is in the context of vertical structures along a horizontal axis, one or more features of the present disclosure can also be implemented in slip forming horizontal structures along a horizontal axis, horizontal structures along a vertical axis, vertical structures along a vertical axis, or other dispositions of structures. Moreover, while concrete will be discussed primarily herein, the description herein may apply to other materials that a person of ordinary skill in the art would understand to be used in slip-formed structures.
Unless explicitly indicated otherwise, terms as used herein will be understood to imply their customary and ordinary meaning.
Slip form machines may be used to lay down concrete (e.g., liquid concrete) in one or more structures. The structure may include structure generally along any path, such as horizontal paths (e.g., roads, barriers, curbs, etc.) and/or vertical paths (e.g., buildings, towers, etc.). Paths may include straight lines, curves, or other shapes. Slip form machines can be used to form vertical structures (e.g., towers, barriers, buildings, etc.) and/or horizontal structures (e.g., roads, surfaces, curbs, etc.). As defined herein, vertical structures include structures that generally have a greater vertical dimension than horizontal dimension. Similarly, horizontal structures may be defined as structures that generally have a larger horizontal dimension than vertical dimension. The slip form machine may be a vehicle able to form structures by travelling along a defined path.
After a concrete structure has been slip formed, it may undergo slump. Slump may occur in a variety of ways. For example, concrete may collapse from an original height, which may result in a structure that is shorter and wider than originally formed. Concrete may shear such that the original general shape is not maintained. This may involve portions that break apart from the structure and/or collapse. Slump may also result simply in a mild shortening and/or bowing of the concrete around a mid-section of the structure. This may be referred to as true slump. An amount of slump may be in part determined by the weight of the concrete, the moisture content of the concrete, the composition of the concrete, and/or the shape of the concrete structure. If a structure is unable to support its own weight, slump is likely to occur. Systems for slip forming may form the concrete structure over reinforcing bars. The reinforcing bars may form their own skeleton or structure over which the concrete structure may be formed. This may add strength to the resulting structure and may help prevent slump. Further details on this and related features may be found in U.S. Pat. No. 9,869,066 (application Ser. No. 14/555,094), filed Nov. 26, 2014, the entire disclosure of which is hereby incorporated by reference.
Concrete (or other material) used in a slip forming process may require a certain consistency or workability. Concrete that is too wet may not sufficiently retain its slip formed shape. By contrast, concrete that is too dry may not be sufficiently formable into a desired shape. Concrete that is sufficiently formable or workable may be referred to as being in a plastic state or maintaining its plasticity.
Slip formed structures have been traditionally formed using a single slip form machine (e.g., vehicle). Often additional work may be advantageous or even required to bring the quality and/or dimensions up to necessary particular specifications. For example, a work contract may specify a certain height, width, level of smoothness, and/or other standard. However, it can be labor intensive to adjust, reform, or add on to an existing slip-formed structure that satisfies the required specifications. Workers may have to manually add concrete to the top of the structure to bring it up to a specified height and/or may need to repair portions that have collapsed. Such added concrete may not combine with the previously poured concrete in a satisfactory way and may be prone to further damage, discoloration, or disrepair in the future. For example, the composition of the added concrete may not match the particular composition of the concrete previously poured. Further, when added by hand the added concrete is not vibrated into position the way the originally poured concrete is and may not compact in a structurally sound way. If the slump (e.g., collapse) is too drastic, work may need to be slowed or stopped to accommodate for the delay in adjusting the slip-formed structure. This can run the risk of delaying a project, reducing the quality of the project, and/or increasing a cost of a project. While additional work, such as aesthetic work (e.g., brooming to create a particular texture) may be helpful, frequently workers may be busy with supplying quality finishing touches to a concrete structure that attention to aesthetic work may be rushed or overlooked.
Moreover, under certain conditions time may be of the essence in adjusting the slip-formed structure to meet the specified standards. For example, concrete that is already relatively dry and has been formed into a structure may require immediate attention before alterations and/or additions are no longer possible and/or desirable. For example, if the concrete is As an additional example, certain climates (e.g., hot and dry climates) may cause the concrete to quickly lose its plasticity, thus necessitating immediate attention and additional labor. Certain concrete may be mixed with base ingredients that dry more rapidly than others, thus also presenting time constraints. The implementations described herein can be effective at mitigating or removing many of these challenges, such as, for example, reducing the overall amount of human labor required.
In some embodiments, one or more slip form machines may be used to provide multiple (e.g., two) slip form apparatuses operable in series to overcome such challenges. These apparatuses can form a slip form system that may significantly reduce or even eliminate the need for additional human labor once the structure has been slip formed using the system. A first slip form mold may operate simultaneous with or before a second slip form mold. For example, the first and second slip form molds may be spatially and/or temporally displaced from one another. In some embodiments, a single slip form machine can include the first and second slip form molds. Alternatively, the first slip form mold may be carried by a first slip form machine and the second slip form mold may be carried by a second slip form machine. In some embodiments, the size of the first mold may be larger than the second mold. Additionally or alternatively, the first slip form mold may be configured to handle a greater flow of concrete and/or form a larger slip-formed structure than the second machine.
Because of the amount of concrete needed to complete a job may involve many concrete loads, the slip form apparatuses are adapted to receive batches of concrete from various sources or deliveries. As each batch may include a concrete with a different composition (e.g., different moisture content, base aggregate, etc.), it may be advantageous to blend a new batch of concrete with the old batch of concrete. Advantageously, both the first and second molds can receive concrete from the same batch which allows the finish molding by the second mold to cleanly blend with the original pour from the first mold. However, in certain circumstances, the concrete received from various suppliers may be inconsistent and therefore result in receiving slightly different concrete makeup within each machine and/or within a single batch of concrete. Traditionally, this has caused challenges when slip forming. However, the use of multiple slip forming machines may reduce the challenges associated therewith. Variations in a preliminary concrete structure may be smoothed by a later (e.g., second) slip form machine. Moreover, one or both of the first and second molds may be adapted to receive concrete from different batches simultaneously. By blending a current batch of concrete with a new batch of concrete, the seams that may naturally arise from using multiple batches of concrete with a slip forming machine can be smoothed reduced or minimized. Using a second mold to finish the structure while the original pour is still in a workable state provides a cleaner finished product with increased structural integrity. Whereas with a traditional slip forming machine, visual defects (e.g., patched-up look) may not have been properly smoothed by a manual laborer, a multiple-machine system or multiple-mold system may reduce or eliminate such visual defects.
One or more of the first slip form mold 124 and the second slip form mold 144 may be configured to receive one or more sources of concrete during a job. It may be advantageous for the slip forming system 100 to deliver concrete from the same first concrete source 182 for as long as possible. However, under certain circumstances, a second concrete source 184 can supply the slip forming system 100 with the needed concrete. For example, certain concrete structures may be concrete-intensive such that multiple loads of concrete from various sources may be necessary. In other circumstances, a particular load of concrete is undesirable due to its consistency and/or makeup. Other reasons exist as well.
In certain embodiments, the slip forming system 100 can be configured to receive from the first concrete source 182 and deliver the same batch of concrete to each of the first slip form mold 124 and the second slip form mold 144. This can allow for the first slip form mold 124 and the second slip form mold 144 to form the final concrete structure 148 using the same consistency and/or makeup of the concrete through both molds.
The slip forming system 100 may be configured to receive a second batch of concrete from a second concrete source 184. In some embodiments, the slip forming system 100 is configured to mix concrete from both the first concrete source 182 and the second concrete source 184. For example, when the first concrete source 182 is nearly exhausted of concrete, the second concrete source 184 may arrive to take over the supply of the concrete. During this transition, it may be advantageous to mix the two batches to promote uniformity in the resulting final concrete structure 148 along a greater portion of the structure. As described in more detail herein, the slip forming system 100 may include apparatus to smoothly receive two batches of concrete for one or more of the molds 124, 144 and/or to mix the two batches together before delivering the mixed concrete to one or more of the molds 124, 144.
A preliminary concrete structure 128 may be formed using the first molding system 112 of the first slip forming vehicle 104, as shown. The preliminary concrete structure 128 shown is a vertical structure (e.g., wall) slip formed along a horizontal path. The preliminary concrete structure 128 can have a vertical height as measured from the ground of between about 5 inches and 96 inches. In some designs, the vertical height of the preliminary concrete structure 128 is about 56 inches. Other heights may include about 32 inches, 36 inches, 42 inches, 56 inches, any value therebetween or may fall within any range created from these values. The second slip forming vehicle 108 may include a second molding system 132 that may modify and/or refine the preliminary concrete structure 128. The second molding system 132 can include a second delivery system 136, a second hopper 140, and/or a second slip form mold 144. The second slip form mold 144 may include a mold top 144a and one or more mold sides 144b. The second slip form mold 144 can have a length 158 along the direction of travel D, as shown. The second molding system 132 of the second slip forming vehicle 108 can form the final concrete structure 148. The first slip forming vehicle 104 and the second slip forming vehicle 108 can be separated by a vehicle following distance 152, measured along the direction of travel D. Though shown on separate vehicles, in some embodiments, first slip form mold 124 and second slip form mold 144 can be carried on a single vehicle with the second slip form mold being guided along the initial pour of the first slip form mold. For example, the first molding system 112 and the second delivery system 136 can be partially or fully integrated into a single vehicle. In some designs, the first and second delivery systems 116, 136 can be supplied from a common source of concrete. In embodiments where the first slip forming vehicle 104 and the second slip forming vehicle 108 are the same, the first and second molds 124, 144 may be separated by a following distance, as described herein, for example, within the same vehicle.
The first hopper 120 may be attached at a top of the first slip form mold 124. The mold top 124a and one or more mold sides 124b can define an interior of the first slip form mold 124. The interior of the first slip form mold 124 can be in fluid communication with a discharge opening (not shown) of the first delivery system 116. The first hopper 120 may be rigidly attached to the first slip form mold 124. This can allow seamless delivery of concrete or other material from the first delivery system 116 through the first hopper 120 into the first slip form mold 124. As described herein, it may be advantageous for a system to be able to seamlessly manage one or more sources of concrete. Accordingly, one or both of the delivery systems 116, 136 may include a supplemental delivery system (e.g., the supplemental delivery system 118) that can be configured to deliver a second batch of concrete through the respective hopper 120, 140 while (or shortly after) receiving a first batch through the respective delivery system 116, 136. In this way, the slip forming system 100 can be configured to mix first and second batches of concrete into a mixed batch. The mixed batch can be delivered to one or both of the first hopper 120 and/or the second hopper 140. Because different batches of concrete may have different characteristics (e.g., because of different ingredients, proportions, time after initial preparation, variation in temperature and/or humidity, etc.), it may be advantageous to mix the different batches before delivering concrete to the first slip form mold 124 and/or the second slip form mold 144.
The first hopper 120 may be connected nearer a leading end of the first slip form mold 124 than a trailing end of the first slip form mold 124, as defined by the direction of travel D. This can provide a sufficient length of the first slip form mold 124 to form and/or compress the concrete into the desired structure. The first slip form mold 124 may include a first hopper box 122. The first hopper box 122 can include an elongate portion (e.g., vertically elongate) to allow the concrete to flow where it is needed to create the preliminary concrete structure 128. The first hopper box 122 can extend from between halfway down a height of the resulting preliminary concrete structure 128 to substantially down the full height. The first hopper 120 may include within its interior (e.g., in the first hopper box 122) one or more vibration devices (not shown) to keep the concrete flowing and/or to slow the hardening of the concrete during, before, or after a delivery of the concrete or other material to the first slip form mold 124 and to help compact the concrete within the mold 124. The one or more vibration devices may additionally or alternatively be located within the first slip form mold 124 and/or first delivery system 116. The one or more vibration devices may be configured to vibrate the concrete passing through the first hopper 120 and/or into the first slip form mold 124. Vibrating the concrete can promote greater fill of the first slip form mold 124 and, therefore, a smoother resulting preliminary concrete structure 128. Vibrating the concrete may additionally or alternatively promote compression and compacting of the concrete to form a sturdier preliminary concrete structure 128. The one or more vibration devices may be housed in the first hopper box 122. For example, the vibration device may be oriented parallel to the elongation of the first hopper box 122 (e.g., vertically) to better promote flow and/or compression of the concrete.
A main body of the first slip forming vehicle 104 may be laterally (e.g., perpendicular to the direction of travel D) spaced from the first slip form mold 124 and/or the preliminary concrete structure 128. The main body of the first slip forming vehicle 104 may travel along a path parallel to a path defined by the resulting preliminary concrete structure 128. In such embodiments, this configuration can allow for adjustment of a portion of the concrete structure (e.g., preliminary concrete structure 128) without damaging or otherwise affecting the structure.
The first slip form mold 124 may be guided by one or more guides. For example, the first slip forming vehicle 104 may include a sensor that follows a guide line (not shown). The guide line may be disposed on or along the ground near the first slip forming vehicle 104 and/or opposite it from the resulting preliminary concrete structure 128. The one or more guides may include a line guide and/or a grade guide that one or more sensors track. The line and/or grade guide may be referred to as elevation and/or latitude guides. This can allow for a more consistent placement of concrete or other material and a smoother preliminary concrete structure 128. Line guides and/or grade guides may allow for precision path guidance as human quality checkers may be immediately notified of an error in the path of the machine and/or in the placement of the concrete. The line guides may include a line (e.g., string, wire, etc.) and/or a sensor (e.g., pressure sensor, motion sensor). Additionally or alternatively, some systems or elements thereof (e.g., the machines) may be guided through electronics and/or wireless technology. A virtual mapping system, such as one that employs a GPS signal and/or wirelessly defined path may be used.
The length 156 of the first mold 124 may be sufficiently great to allow the delivered concrete or other material to reasonably solidify to allow the resulting preliminary concrete structure 128 to support its own weight. In some embodiments, the length 156 of the first mold 124 is between about three and twenty feet. In some embodiments, the first mold 124 has a length 156 of about 15 feet. A height of the first slip form mold 124 (e.g., a height of the mold side 124b) can be such that a bottom of the mold is near (e.g., within about six inches) of the ground or of the base of the preliminary concrete structure 128. In some designs, a cross-sectional shape of the preliminary concrete structure 128 is trapezoidal. Accordingly, the mold top 124a and the one or more mold sides 124b may form two or more sides of a trapezoid. Other shapes are also possible and contemplated. The first slip form mold 124 may comprise any sufficiently rigid material. For example, the first slip form mold 124 may comprise metal (e.g., aluminum, steel, etc.), plastic, and/or hardened rubber.
The mold top 124a may be configured to form the concrete to a specified height to within between about ⅛ inch and ¾ inch. In some embodiments, the mold top 124a is configured to achieve a height to within ½ inch of a specified height. The mold sides 124b may be configured to form a specified width of the preliminary concrete structure 128 to within between about 1/16 inch and 1 inch. In some embodiments, the mold sides 124b are configured to form achieve a width to within ½ inch of the specified width. One of the mold sides 124b may be configured to be more rigid than another of the mold sides 124b. For example, it may be advantageous to drive excess concrete to one side or another (e.g., to provide a tighter tolerance on one side of the first slip form mold 124 than another). This may allow for better adjustment of the concrete structure later (e.g., by the second slip forming vehicle 108). Additionally or alternatively, it may be advantageous to include a vibration device (e.g., vibrator) within the first delivery system 116 and/or first slip form mold 124 to promote the mixing and/or compacting of the concrete. For example, the vibration device may be configured to promote a target texture (e.g., liquid texture) of liquid concrete. The second delivery system 136 and/or second slip form mold 144 may similarly include a vibration device. The vibration device can be in fluid communication with one or more of the first slip form mold 124, the first delivery system 116, and/or the first hopper 120. Other variations are possible.
The second hopper 140 may be attached at a top of the second slip form mold 144. The second slip form mold 144 may be referred to as a “topper” mold. This may be because the second slip form mold 144 can be configured to add a layer of concrete to the top of the preliminary concrete structure 128. The second slip form mold 144 may be lighter and/or more flexible than the first slip form mold 124. This can allow for more fine-tune adjusting in the formation of the final concrete structure 148. This may increase the quality of aspects (e.g., appearance, specifications) the final concrete structure 148. The mold top 144a and one or more mold sides 144b can define an interior of the second slip form mold 144. The interior of the second slip form mold 144 can be in fluid communication with a discharge opening (not shown) of the second delivery system 136. The second hopper 140 may be rigidly attached to the second slip form mold 144. This can allow seamless delivery of concrete or other material from the second delivery system 136 through the second hopper 140 into the second slip form mold 144. The second hopper 140 may be connected nearer a leading end of the second slip form mold 144 than a trailing end of the second slip form mold 144, as defined by the direction of travel D. This can provide a sufficient length of the second slip form mold 144 to form and/or compress the concrete into the desired structure.
The second slip form mold 144 may include a second hopper box 142. The second hopper box 142 can include an elongate portion (e.g., vertically elongate) to allow the concrete to flow where it is needed to create the final concrete structure 148. The second hopper box 142 can extend from less than halfway down a height of the mold side 144b to substantially down the full height of the mold side 144b, as shown, or any height therebetween. The second hopper 140 may include within its interior one or more vibration devices (not shown) to promote more consistent flow of the concrete during, before, or after a delivery of the concrete or other material to the second slip form mold 144 and to help compact the concrete within the mold 144. Additionally or alternatively, a vibration device may be located within the second slip form mold 144 and/or the second delivery system 136 (e.g., within the second hopper box 142 and/or the first hopper box 122). The vibration device can be in fluid communication with one or more of the second slip form mold 144, the second delivery system 136, and/or the second hopper 140. The one or more vibration devices may be configured to vibrate the concrete passing through the second hopper 140 into the second slip form mold 144. Vibrating the concrete can promote greater fill of the second slip form mold 144 and, therefore, a smoother resulting final concrete structure 148. The one or more vibration devices may be housed in the second hopper box 142. For example, the vibration device may be oriented parallel to the elongation of the second hopper box 142 (e.g., vertically) to better promote flow and/or compression of the concrete.
The second slip form mold 144 can be configured to supply an additional height and/or width to the preliminary concrete structure 128. For example, the second slip form mold 144 may be configured to add between about ⅛ inch and 6 inches to the height of the preliminary concrete structure 128. This additional height may be referred to as a “topper.” In some embodiments, the second slip form mold 144 is configured to add approximately an inch to the height of the preliminary concrete structure 128. Other variations are possible. For example, the second slip form mold 144 may be configured to add approximately two, three, five, six, ten, twelve, eighteen, twenty-four, or thirty-six inches of concrete or any value therebetween or a range of any value therein or even more.
A main body of the second slip forming vehicle 108 may be laterally (e.g., perpendicular to the direction of travel D) spaced from the second slip form mold 144 and/or the final concrete structure 148. The main body of the second slip forming vehicle 108 may travel along a path parallel to a path defined by the resulting final concrete structure 148. In such embodiments, this configuration can allow for adjustment of a portion of the concrete structure (e.g., final concrete structure 148) without damaging or otherwise affecting the structure. In some embodiments, the main body of the second slip forming vehicle 108 may be disposed behind (e.g., relative to the direction of travel D) the first slip forming vehicle 104. The main bodies of the first slip forming vehicle 104 and second slip forming vehicle 108 may be disposed on the same side of the concrete structure as each other (for example, as shown in
The second slip form mold 144 may be guided by one or more guides. For example, the second slip forming vehicle 108 may include a sensor that follows a guide line (not shown). The guide line may be disposed on a ground near the second slip forming vehicle 108 and/or opposite it from the resulting final concrete structure 148. The one or more guides may include an elevation guide and/or a latitude guide that one or more sensors track. This can allow for a more consistent delivery of concrete or other material and a smoother final concrete structure 148. The one or more guides may be identical to the one or more guide lines used in conjunction with the first slip forming vehicle 104 and the first slip form mold 124.
The length 158 of the second mold 144 may be sufficiently great to allow the delivered concrete or other material to reasonably solidify without causing undue pressure on the resulting final concrete structure 148. In some embodiments, the length 158 of the second mold 144 is between about two and fifteen feet. In some embodiments, a height of the second slip form mold 144 (e.g., a height of the mold side 144b) can be such that a bottom of the mold is above half of a height of the resulting final concrete structure 148. However, other designs are possible (see, e.g.,
The second slip form mold 144 may comprise any sufficiently rigid material. For example, the second slip form mold 144 may comprise metal (e.g., aluminum, steel, etc.), plastic, and/or hardened rubber. The mold top 144a may be configured to form the concrete to a specified height to within between about 1/16 inch and ¾ inch. In some embodiments, the mold top 144a is configured to achieve a height to within ½ inch of a specified height. In some embodiments, the mold is configured to achieve a specified height. The tolerances described herein may be in reference to the specified height (e.g., to within the tolerance described). The mold sides 144b may be configured to form a specified width of the final concrete structure 148 to within between about 1/32 inch and 1 inch. In some embodiments, the mold sides 144b are configured to form achieve a width to within ½ inch of the specified width. The mold top 144a and/or mold sides 144b may be configured to achieve tighter tolerances than the mold top 124a and/or mold sides 124b, respectively. One of the mold sides 144b may be configured to be more rigid than another of the mold sides 144b. For example, it may be advantageous to drive excess concrete to one side or another (e.g., to provide a tighter tolerance on one side of the second slip form mold 144 than another).
One or both of the first slip forming vehicle 104 and the second slip forming vehicle 108 may travel along a path (e.g., an axis). Both machines may travel along the same path or they may be different (e.g., may be on opposite sides of a concrete structure). Each machine 104, 108 may travel at a specified velocity. For example, one or both of the machines 104, 108 may travel at between about 3 inches/minute and 15 feet/minute. Under certain conditions, it may be preferable for one or both of the machines to be travelling at between about 1 foot/minute and 5 feet/minute. In some embodiments, each machine may be configured to travel at the same velocity. For example, in some embodiments the first slip forming vehicle 104 and the second slip forming vehicle 108 are the same vehicle. In such embodiments, many elements described, for example, in
The second slip forming vehicle 108 may trail the first slip forming vehicle 104 by a vehicle following distance 152. The vehicle following distance 152 may be defined as a distance between a trailing end of the first slip forming vehicle 104 and a leading end of the second slip forming vehicle 108. The vehicle following distance 152 may be adjusted based on the temperature, humidity, weather, and/or ingredients of the concrete (or other material) applicable at the time of the slip forming. For example, the vehicle following distance 152 may be relatively shorter during hotter temperatures, lower humidity, and/or drier climate. A drier concrete mix may also cause a shorter vehicle following distance 152. The vehicle following distance 152 may be between about 10 ft and 150 ft. While the vehicle following distance 152 may frequently be measured in a spatial dimension, it can also be described using a temporal dimension. For example, the vehicle following distance 152 may be between about 1.5 minutes and 90 minutes.
The vehicle following distance 152 may be different from a mold following distance 154. However, the vehicle following distance 152 may be related. For example, the mold following distance 154 may be based on the vehicle following distance 152 and/or may be affected by a speed of travel of the first slip forming vehicle 104 and/or the second slip forming vehicle 108. The mold following distance 154 (if measured in time) may be between about 1.5 minutes and 90 minutes. Moreover, the mold following distance 154 may be similarly adjusted based on the temperature, humidity, weather, and/or ingredients of the concrete (or other material) applicable at the time of the slip forming. The mold following distance 154 may be between about 8 ft and 140 ft.
The vehicle following distance 152 and/or the mold following distance 154 may be determined by a length of time in which the concrete in the preliminary concrete structure 128 is in a plastic stage (e.g., where the concrete is still plastic). Thus, during a method of slip forming as described herein, the vehicle following distance 152 and/or mold following distance 154 may be adjusted to accommodate for changes in the weather, changes, in temperature or climate, and/or updates in a consistency of concrete received from a supplier.
The slip form mold 160 can define one or more heights. The one or more heights may be defined by the mold side 160b. The mold side 160b can define a vertical mold height 176 and/or a slanted mold height 178. The slanted mold height 178 may be different from the vertical mold height 176. The vertical mold height 176 may be between about 3 inches and 72 inches. The slanted mold height 178 may be between about 4 inches and 96 inches.
It may be advantageous to be able to manipulate a portion of the mold profile 190 in real-time. For example, a dimension (e.g., the upper mold width 168, the lower mold width 172, the vertical mold height 176, etc.) of the concrete structure 164 may need to be adjusted (e.g., due to shifting of the concrete and/or updated specifications for the dimension). Accordingly, a hinge 188 may be included in the mold profile 190. The hinge 188 may allow for adjustment of the dimension of the concrete structure 164. In some embodiments, the hinge 188 is configured to rotate a portion (e.g., half, the mold side 160b) of the slip form mold 160. In this way, the hinge 188 can allow a first portion (e.g., a first side) of the mold to track a path defined by the concrete structure 164 (e.g., a path going into or out of the page) while simultaneously adjusting a second portion (e.g., a second side) of the mold. The hinge 188 may be disposed anywhere within the mold profile 190. The hinge 188 can define a rotation axis. The rotation axis may be approximately parallel to a direction of travel. Alternatively or additionally, the hinge 188 may be configured to translate a portion of the mold.
As shown in
A slip forming system 100 may be used in performing a slip forming method.
The delivery of the second flow of concrete may occur while the second mold is advanced at block 312. The first flow of concrete may be greater than the second flow of concrete. For example, the first slip forming vehicle 104 may be configured to deliver more than 10 times a volume of concrete than the second slip forming vehicle 108 in the same time. The first slip form mold 124 may be configured to form a structure having a height of more than 15 times a height of a structure that the second slip form mold 144 may be configured to form in the same time. For example, the second slip form mold 144 may be configured to add an inch to a concrete structure while the first slip form mold 124 may be configured to add more than twenty inches of height of concrete structure to a surface. In some designs, the first mold may spatially lead the second mold along a direction of travel (e.g., the direction of travel D). It may be advantageous to deliver the first flow of concrete along a first portion of the path while simultaneously delivering the second flow of concrete along a second portion of the path (e.g., along a portion of the concrete structure).
At block 424, the method can include pouring a third portion of the structure through the first mold using the mixed supply of concrete. The third portion may be laterally displaced from the first and/or section portions of the structure. For example, the third portion may be further downstream of the first and/or second portions (e.g., along the direction of travel described herein). At block 428, the method may include pouring a fourth portion (e.g., a portion above the third portion) of the structure through the second mold using the mixed supply of concrete. The fourth portion may be analogous to the second portion and/or the third portion may be analogous to the first portion. For example, pouring the fourth and/or second portions may include modifying the respective third and/or first portions. Modifying may include adding concrete, removing concrete, and/or any other meaning as described herein.
The following represents some examples of the systems and methods described herein.
In a 1st example, a method of slip forming a concrete structure can include: using a first slip form mold traveling along a path, forming a portion of a concrete structure by delivering a first flow of concrete into the first mold through a first hopper, the first hopper configured to receive the first flow of concrete; and using a second slip form mold different from the first mold, modifying the portion of the concrete structure by: advancing the second mold along the concrete structure; and while advancing the second mold, delivering a second flow of concrete into the second mold through a second hopper configured to receive the second flow of concrete.
In a 2nd example, the method of example 1, wherein using a first slip form mold traveling along a path comprises advancing the first slip form mold along a guide, and wherein advancing a second mold along the concrete structure comprises advancing the second slip form machine along the guide.
In a 3rd example, the method of any of examples 1-2, wherein advancing a second mold along the concrete structure comprises advancing a top of the second mold at a greater height than a height at which a top of the second mold is advanced.
In a 4th example, the method of any of examples 1-3, wherein the path advanced by the first slip form machine is substantially limited to movement within a horizontal plane.
In a 5th example, the method of any of examples 1-4, wherein forming the portion of the concrete structure comprises advancing the first mold over a structure comprising reinforcing bars.
In a 6th example, the method of any of examples 1-5, wherein the first mold has one or more dimensions different from the second mold.
In a 7th example, the method of example 6, wherein a height of the first mold is greater than a height of the second mold.
In a 8th example, the method of any of examples 6-7, wherein the second mold has a lower tolerance than the first mold.
In a 9th example, the method of any of examples 1-8, wherein using the first slip form mold traveling along the path comprises disposing the first slip form machine laterally from the portion of a concrete structure relative to a direction of travel of the first slip form machine.
In a 10th example, the method of any of examples 1-9, wherein advancing the second mold along the concrete structure comprises advancing the second mold at a rate of between approximately 3 inches/minute and 15 feet/minute.
In a 11th example, the method of any of examples 1-10, wherein delivering the second flow of concrete into the second mold through the second hopper comprises delivering the second flow of concrete nearer a leading end of the second mold than a trailing end of the second mold relative to a direction of travel.
In a 12th example, the method of any of examples 1-11, wherein delivering the first flow of concrete into the first mold through a first hopper comprises delivering a volume of concrete at a rate at least ten times a rate of the second flow of concrete into the second mold through the second hopper.
In a 13th example, a system for slip molding a concrete structure can include: a first slip forming vehicle comprising: a first hopper; a first delivery system configured to deliver a first flow of concrete to the first hopper; and a first slip form mold configured to receive the flow of concrete from the first hopper; a second slip forming vehicle comprising: a second hopper comprising a vibration device; a second delivery system configured to deliver a second flow of concrete to the second hopper; and a second slip form mold configured to receive the second flow of concrete from the second hopper, the second slip form mold spaced from the first slip form mold by a following distance.
In a 14th example, the system of example 13, wherein the second hopper comprises a vibration device configured to vibrate the concrete.
In a 15th example, the system of any of examples 13-14, wherein the following distance is between approximately 10 ft and 150 ft.
In a 16th example, the system of any of examples 13-15, wherein the following distance is between approximately 1.5 minutes and 90 minutes.
In a 17th example, the system of any of examples 13-16, wherein the first slip form mold has a height greater than a height of the second slip form mold.
In a 18th example, the system of any of examples 13-17, wherein the first slip form mold has a length along a direction of travel greater than a length of the second slip form mold.
In a 19th example, the system of any of examples 13-18, wherein the second hopper disposed nearer a leading end of the second slip form mold than a trailing end of the second slip form mold in relation to a direction of travel.
In a 20th example, the system of any of examples 13-19, wherein the second slip forming vehicle further comprises a clearance indicator disposed between the first slip form mold and the second slip form mold.
In a 21th example, a system for modifying an existing concrete structure includes: a modifying mold configured to extend across a top portion of an existing concrete structure and to extend at least partially along a side portion of the existing concrete structure, the modifying mold configured to travel along a substantially horizontal direction of travel and to be guided along at least one side of the existing concrete structure; a concrete delivery system in fluid communication with the modifying mold, the concrete delivery system configured to receive liquid concrete; a vibrator configured to promote a fluid consistency of the liquid concrete, the vibrator in fluid communication with the concrete delivery system and with the modifying mold.
In a 22nd example, the system of example 21, wherein the modifying mold comprises a hinge and wherein a portion of the modifying mold is configured to be rotatable relative to the hinge, the hinge defining a rotational axis substantially parallel to the substantially horizontal direction of travel.
In a 23rd example, the system of any of examples 21-22, wherein the system further comprises a forming mold configured to shape the existing concrete structure into a structure having a top and at least one side.
In a 24th example, the system of example 23, wherein a distance between a trailing portion of the forming mold and a leading portion of the modifying mold is between approximately 8 ft and 150 ft, wherein the trailing portion and the leading portion are determined based on the direction of travel.
In a 25th example, the system of any of examples 21-24, wherein the existing concrete structure is in a plastic phase when the modifying mold travels along the existing concrete structure.
In a 26th example, a system for modifying an existing structure includes: a modifying mold configured to extend across a top portion of an existing structure and to extend at least partially along a side portion of the existing structure, the modifying mold configured to travel along a substantially horizontal direction of travel and to be guided along at least one side of the existing structure; a material delivery system in fluid communication with the modifying mold, the material delivery system configured to receive liquid material; a vibrator configured to promote a fluid consistency of the liquid material, the vibrator in fluid communication with the material delivery system and with the modifying mold.
In a 27th example, the system of example 26, wherein the modifying mold comprises a hinge and wherein a portion of the modifying mold is configured to be rotatable relative to the hinge, the hinge defining a rotational axis substantially parallel to the substantially horizontal direction of travel.
In a 28th example, the system of any of examples 26-27, wherein the system further comprises a forming mold configured to shape the existing structure into a structure having a top and at least one side.
In a 29th example, the system of example 28, wherein a distance between a trailing portion of the forming mold and a leading portion of the modifying mold is between approximately 8 ft and 150 ft, wherein the trailing portion and the leading portion are determined based on the direction of travel.
Reference throughout this specification to “some embodiments” or “an embodiment” means that a particular feature, structure or characteristic described in connection with the embodiment is included in at least some embodiments. Thus, appearances of the phrases “in some embodiments” or “in an embodiment” in various places throughout this specification are not necessarily all referring to the same embodiment and may refer to one or more of the same or different embodiments. Furthermore, the particular features, structures or characteristics may be combined in any suitable manner, as would be apparent to one of ordinary skill in the art from this disclosure, in one or more embodiments.
As used in this application, the terms “comprising,” “including,” “having,” and the like are synonymous and are used inclusively, in an open-ended fashion, and do not exclude additional elements, features, acts, operations, and so forth. Also, the term “or” is used in its inclusive sense (and not in its exclusive sense) so that when used, for example, to connect a list of elements, the term “or” means one, some, or all of the elements in the list.
Similarly, it should be appreciated that in the above description of embodiments, various features are sometimes grouped together in a single embodiment, figure, or description thereof for the purpose of streamlining the disclosure and aiding in the understanding of one or more of the various inventive aspects. This method of disclosure, however, is not to be interpreted as reflecting an intention that any claim or example require more features than are expressly recited in that claim or example. Rather, inventive aspects lie in a combination of fewer than all features of any single foregoing disclosed embodiment. Accordingly, no feature or group of features is necessary or indispensable to each embodiment.
A number of applications, publications, and external documents may be incorporated by reference herein. Any conflict or contradiction between a statement in the body text of this specification and a statement in any of the incorporated documents is to be resolved in favor of the statement in the body text.
Although described in the illustrative context of certain preferred embodiments and examples, it will be understood by those skilled in the art that the disclosure extends beyond the specifically described embodiments to other alternative embodiments and/or uses and obvious modifications and equivalents. Thus, it is intended that the scope of the example embodiments which follow should not be limited by the particular embodiments described above.
This application claims the benefit of priority under 35 U.S.C. § 119(e) to U.S. Provisional Application No. 62/655,076, filed on Apr. 9, 2018, entitled “SLIP FORMING STRUCTURES USING MULTIPLE MOLDS,” which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | |
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62655076 | Apr 2018 | US |