Patent Grant
12064892
The present invention relates to binding machines, office document binding machines in particular.
Office binding machines utilizing plastic binding combs, metal binding combs, and spiral binding, and the corresponding punch apparatus are well known and utilized to create multipage bound documents for a variety of uses such as presentation materials, instructional manuals, and corporate or project reports are only a few of a multitude of bound document examples created by these types of machines. Typically, these types of machines are specialized and are only utilized for the purpose of binding and for a particular type of comb or binding spine such as the Swingline C340 CombBind Binding Machine.
There are non-typical machines which endeavor to combine the comb binding mechanisms into one machine by way of a complex array of punching dies, comb spreaders and crimpers utilizing a complex array of punching dies and actuation levers, making an already complex task even more complex, such as the Akiles DuoMac-421 Heavy Duty 2-in-1 Punching and Binding Machine. Still other machines are designed to utilized one main binding method and the needed support mechanisms while adding the additional capability of round hole punching for ring binding of which Tamerica 213B combination Punch & Bind Machine is an example. While these types of machines attempt to bring value, they utilize features which are more and more seldom utilized while aggravating the situation further by adding additional complexity above and beyond a more basic machine. Therefore, office workers which are not familiar or comfortable engaging with even a basic binding machine will engage these more complex machines even less, making them even more underutilized.
In this application, the disclosed invention, “Multi-Functional Document Binding Device”, addresses the addition of useful features within a document binding device, while clarifying and therefor simplifying the processes when engaging the machine's functions as to make it inherently more operator friendly. In its simplest embodiment of the device, it is inclusive of the mechanisms and functionality needed to bind a document, including a paper stack punching device along with the corresponding binding mechanism which aligns to the punching pattern of the main device (plastic comb, wire comb, spiral comb) with the additional capability to modularly add additional functionality its original base functionality. In an alternative embodiment, we are disclosing a device with built-in multifunctionality uniquely executed in a way as to encourage an operator to engage with it on a more daily basis as to familiarize themselves over time with the devices additional capabilities including the seemingly more intimidating functionalities. Furthermore, we are disclosing features which simplify the operator's perceived device operational processes even with the additionally added elements by the use of transforming elements which aid in the operator's determination of which functions and processes are accessed in what order and what time for a particular desired outcome when utilizing the device and its systems.
The most common binding machines or devices in an office environment utilize plastic or wire expanded combs, and plastic or wire spiral combs. Other forms of binding which include adhesive, thermal and non-thermal, and sewn are known, but are not as commonly used in the office environment and therefor they will not be described in detail within this application, but are not excluded as possible binding methods which can be incorporated within the disclosed embodiments of the disclosed device and system. Less typically, some binding machines simply conjoin or lump some of the differing comb binding capability into one main machine as ways to add additional value to the purchaser and or operator of the device. These types of devices, of which an exemplary machine is shown in
Furthermore, our research has confirmed that office workers needing to create presentation material find binding machines to be difficult to use and not intuitive, and therefor instruction is typically needed to understand the inherently complex array of procedure, processes and consumables which work with a particular machine. Our research further confirmed that many office workers resorted to other more familiar and therefore easier methods of creating bound documents including stapling and ring binding. Due to these research findings, we endeavored to solve these unmet needs by creating a unique binding device which incorporates these less complex binding methods within an office binding machine therefore inducing more engagement and familiarity with the machine as to make it approachable when the operator needs to engages the seemingly more complex functions of the machine when wanting to create more sophisticated bound documents.
We are disclosing a device which modular engagements and an actuation or controlling means through the use of a primary actuator, which can be either manual, motorized and or motor assisted. This feature allows for punching in a multitude of punching stations utilizing a primary actuator of which when engaged, can actuate secondarily actuated sub-assemblies, or modularly added stations as well. For example, the main actuator can be utilized to punch square holes for plastic combs in one station, and round holes in another, while actuating the comb crimping, and or comb spreading actions at yet another station along with other additional actions. The primary lever simplifies the process for the operator since they only need to engage the primary lever for multiple tasks vs. the typical one lever for each task needed. When motorized, there can be a sensor or an array of sensors to detect when a given task is engaged by the recognition or lack thereof of an element to engage and the corresponding communication to the user by visual or audio means. Even if it's found to be advantageous to consolidate the lever actuators into several vs. one primary actuator with, or without sub-actuations, whether automatic or semi-automatic, we are disclosing within this application how to actuate greater than one, a multitude of actions either at once or sequentially when reconfiguring the device for a given purpose.
For binding devices utilizing plastic, wire, and spiral combs, typically include a stack punch operation which allow for a stack of paper to be punched along its edge. The punch feature punches the corresponding holes along that edge to accommodate the shape of the particular comb style the machine has been designed for. In a proposed embodiment of the invention, the device has, but not limited to two primary document ingress slots, with one or both allowing access to the optionally integrated and interchangeable, movable and or selectively engageable punch dies. One of these document ingress slots would allow that particular slot to be set up for a specific purpose, such as for round hole punching of the inserted documents for use in more simple three ring binders, while leaving the other available ingress slot or slots, to be set up for another purpose such as square hole punching for use with plastic comb binders. The disclosed device meets our objectives through the use of a manual and or auto-transforming elements which allow access to certain features while restricting access to others in an effort to guide the operator through the more sequentially relevant and compatible procedures vs. allowing access to features which are not compatible nor sequentially relevant and therefor creating more waste of materials and time due to vague device operations and general procedural confusion during the binding and assembly processes.
In solving the previously stated issues, when accessing the round three-hole punch feature on an exemplary embodiment of the disclosed invention, the comb binding elements are covered by a lid which is in the lowered or down position. The lowered position allows operational access to the three-hole punch ingress slot while covering the comb binding station/feature including the comb punching ingress slot as to prevent inadvertent square punching along the document edge when round punching is desired. In the exemplary alternative, when wanting to comb bind, the lid on the device would be up allowing access to the square punch ingress slot and the plastic comb spreading station, which are compatible and sequentially relevant to those processes, while preventing access to the round three-hole punch ingress slot which is not. Other means can be utilized to ensure only compatible and sequentially relevant features are accessible during particular steps are, but not limited to regulating accessibility to certain pertinent consumables by latching the access to them on and off (lock and unlock) depending on which step you are in the process of binding, or which binding method the device is set up to execute. Still other actions could be slide engagements to allow the main lever arm to actuate one mechanical step while not engaging others, visual indicators could also be sequentially activated mechanically or electro mechanically by each prior step as to help instruct the device operator of the next step and or which consumable to utilize when. User selectable engagements as well as auto and semi-automatic transformations when reconfiguring the device which allow for selective activation of actions such as but not limited to punching, stapling, spine comb crimping, spin comb spreading and closing and coil spinning as well as sub actions, such as but not limited to certain punch dies, paper stack insertion access, accessory doors and cover sheet offsets are all disclosed within this application.
It was noted during further research along with usage studies, alignment of punches and or the holes they create when attempting to utilize cover and back sheets within the multi-page bound documents is difficult at best. In this application, we disclose unique alignment mechanisms for cover sheets (both front and back) vs. the pages in-between those covers. This is accomplished by the use of a bias spring alignment mechanism which can be moved out of the way to accommodate a cover and the corresponding back spacing variance when punching (allowing a uniform border) and then returns to the default spacing after punching is complete which reduces operator setting error saving time and material waste. Along with this solution, we further disclose a punch alignment arrangement which allows for visual confirmation of the setup to ensure proper alignment whether it is to duplicate a previously punched set of papers allowing the capability to easily add additional sheets to an existing document or to ensure the new setup aligns to accommodate the family look of an entire array of documents. This alignment arrangement allows for visual confirmation, adjustment control, while ensuring precise repeatability.
We are further disclosing improvements within the machines and processes which add additional performance and ease of use elements to improve the modular and or integrated features within the device along with pertaining supportive accessories which enhance the appearance, functionality and output quality of the documents being processed by way of the disclosed device.
As disclosed herein, described and illustrated, the invention can be applied to a wide array of devices and machines which punch, staple, emboss, decorate and bind documents for presentations and should not be limiting by the disclosed embodiments within this document in any way. To the contrary, the present disclosure is intended to encompass all modifications, alterations, substitutions within the spirit and scope of the disclosed inventive features.
In one form, the invention is directed to a device for performing operations on sheets of material. The device includes a housing having a first receiver for sheets of material for a first operation and a second receiver for sheets of material for a second operation, and a lid having a first position and a second position. The first receiver is open to receiving sheets when the lid is in a first position. The second receiver is open to receiving sheets when the lid is in a second position.
In one form, the lid blocks the second receiver from receiving sheets when the lid is in the first position.
In one form, the first operation is performed by a stapler.
In one form, the second operation is performed by a hole punch.
In one form, the second operation is performed by a binding hole punch.
In one form, the device further includes a drawer within the housing. The drawer is prevented from opening when the lid is in the first position.
In one form, the hole punch includes a punch die assembly. The punch die assembly has a plurality of dies slidably coupled to an assembly rail. The dies are coupled to move in unison when the die positions are changed along the assembly rail.
In one form, the first receiver is a slot bounded by the lid and a surface of the housing.
In one form, the first operation is actuated by an actuator at a first time. The second operation is actuated by the actuator at a second time.
In one form, the second receiver includes a cover spacing guide. The cover spacing guide has a first position to guide a stack of paper and a second position to guide a cover for the stack of paper. The cover spacing guide moves from the second position to the first position after the binding hole punch is activated.
In one form, the invention is directed to a device for performing binding operations on sheets of material. The device includes a housing, a lid, a first slot for receiving stacks of material to be bound, and a second slot for receiving material to be punched. The lid covers the second slot when the lid is in a closed position and exposes the second slot when the lid is in an open position.
In one form, the lid includes a recess. A stapler is positioned in the recess.
In one form, the device further includes a stapler in communication with the first slot and a hole punch assembly in communication with the second slot. An actuator is coupled to the stapler to actuate stapling and also coupled to the hole punch assembly to actuate punching.
In one form, the actuator actuates the hole punch when the lid is in the open position.
In one form, the device further includes a drawer in the housing. The drawer is openable when the lid is in the open position and not openable when the lid is in the closed position.
In one form, the second slot has a guide for positioning the sheets of material in the slot. The guide has a first position and a second position. The guide is movable from the first position to the second position by the user. The guide moves back to the first position upon punching of the sheets of material in the slot and the removal of the sheets of material from the slot.
In one form, the hole punch includes a punch die assembly. The punch die assembly has a plurality of dies slidably coupled to an assembly rail. The dies are coupled to move in unison when the die positions are changed along the assembly rail.
In one form, the invention is directed to a device for binding sheets of material. The device has a housing and a lid having an open position and a closed position. A first slot is in communication with an assembly for a first operation on the sheets of material. A second slot is in communication with an assembly for a second operation on the sheets of material. A third slot is in communication with an assembly for a third operation on the sheets of material. The lid and portion of the housing form the first slot. The lid closes the second slot when in the closed position. The third slot is blocked by the lid when the lid is in an open position.
In one form, the assembly for the first operation, the assembly for the second operation, and the assembly for the third operation are all actuated by the same actuator.
In one form, the actuator acts to actuate the first assembly when the lid is in the closed position. The actuator acts to actuate the second assembly when the lid is in the open position.
For stapling, when a stack of paper is place within optionally adjustable guide rail 704 and slid into place, stapler lever 706 is actuated to insert the appropriate binding staple into the paper stack. In some embodiments, the staple assembly 700 may be activated to staple the stack of paper by the actuation handle 904. Actuation handle 904 may also be used for other operations, such as hole punching, by being operatively coupled to a hole punching mechanism. If the operator would like to create a staple bind along the entire spine of the document edge, stapler lever 706 can be configured to slidably move along a repositionable guide rail within cavity 702 to the next position and then actuated as to again insert the appropriate binding staple into the paper stack. This can be sequentially done several times until the desired number of binding staples have been inserted along the spine of the document. Once the document is removed, a slide on, snap on, or adhesively attached cover can be assembled over the staples as to create a higher level of finish even when the document is stapled.
In some embodiments, the staple anvil of stapling assembly 700 which shapes the underside of the staple can be configured in a manner as to enable and secure the slide on or snap on cover. A heavy-duty higher capacity stapling assembly can be inserted additionally or, as an alternative and optionally, be actuated by actuation handle 904 since this handle is more robust and would give the operator more leverage. All manual stapling operations can be achieved by motorized means and be powered by battery DC or plugin AC sources and these types of stapling mechanisms are well known in the marketplace today. Disclosed as unique is a staple means which is assistive where a mechanical stapler is assisted by powered means or stored power means or mechanically actuated stored power means so as to make the enacting and/or initiating of the staple cycle feel familiar but with the added benefit the power assist allows for thicker stacks to be stapled and edge bound.
In embodiments that include a round hole punch function, round hole punch slot 504 is accessible since this is a less complex operation than comb binding and is the next most commonly used binding operation after stapling. After raising punch actuation handle 904 upwards, which in turn rotates actuation mechanism assembly 900 ensuring the punch dies are then in their retracted state (not shown), the operator then places a stack of paper into round hole punch slot 504, and while holding the inserted stack in place and/or allowing the stack to rest against an optional pull-out or wireframe paper stack support assembly, the operator then proceeds to lower punch actuation handle 904 in a downward stroke, which in turn rotates the actuation mechanism 900 to engage the punch dies with the inserted stack of paper to create the desired round punch holes along the spine of the inserted stack of paper. After the punch sequence has been completed, actuation handle 904 then can be raised again sequentially to release the punch die from the paper to allow the paper to be retracted from punch slot 504. As an alternative to the directly engaged punch die to handle actuation, an interim cam-driven mechanism can be utilized to allow paper to be inserted even when actuation handle 904 is in the lowered position, as the handle is raised rotating actuation mechanism 900 which then engages the punch die actuator and on the operator's downstroke action of the actuation handle 904, the punch die is actuated, the paper stack is punched within punch slot 504, and the die is retracted on the same sequential downstroke. This punch actuation sequence uniquely allows the paper stack to be inserted and retracted when the actuation handle 904 is in the lowered position. All manual punching operations can be achieved by motorized means and be powered by battery DC or plug-in AC sources and these types of punching mechanisms are well known in the marketplace today.
In some embodiments, round hole punch slot 504 is accessible since this is a less complex operation than comb binding and is the next most commonly used binding operation after stapling. However, in other embodiments, only one operation is operable at any one time. The operator places a stack of paper into round hole punch slot 504, and while holding the inserted stack in place and/or allowing the paper stack to rest against an optional pull-out or wireframe paper stack support assembly (currently shown in the retracted or lowered state), the operator then proceeds to lower punch actuation handle 904 in a downward stroke to engage the punching mechanism of the machine.
For example, when the machine is in plastic comb binding mode, device lid 104 is in a raised position and is configured to momentarily block easy access to round hole punch slot 504. This is done to make it easier for the operator to understand binding hole punch slot 602 is the primary punch slot to use when binding. Similarly, in some embodiments, access to the stapler assembly 700 is also blocked. In some embodiments the placement of device lid 104 in the raised position prevents the stapler assembly from being activated. In other embodiments, various features are made less easy to access in order to signal or guide the operator to the correct apparatus to use. Thus, one skilled in the art will recognize that describing a function as “blocked” may have a range of meaning, including making a function or apparatus less easy to access or use.
Furthermore, binding comb storage drawer 310 is allowed to be opened to access the stored binding combs when the device is in the binding configuration. When binding, the operator raises punch lever handle 904 upwards, which in turn rotates actuation mechanism assembly 900 ensuring the punch dies of binding punch assembly 600 are then in their retracted state (not shown), the operator then places a stack of paper into binding hole punch slot 602, and while holding the inserted stack in place and/or allowing the stack to rest against an optional pull-out or wireframe paper stack support assembly, the operator then proceeds to lower punch actuation handle 904 in a downward stroke, which in turn rotates the actuation mechanism 900 to engage the punch dies with the inserted stack of paper to create the desired punch holes along the spine of the inserted stack of paper. After the punch sequence has been complete, actuation handle 904 then can be raised again sequentially to release the punch die from the paper to allow the paper to be retracted from binding hole punch slot 602.
As an alternative to the directly engaged punch die to handle actuation, an interim cam-driven mechanism can be utilized to allow paper to be inserted even when actuation handle 904 is in the lowered position, as the handle is raised rotating actuation mechanism 900 which then engages the binding punch assembly 600's actuator and downstroke of the actuation handle 904, the punch die is actuated, the paper stack is punched within binding hole punch slot 602, and the die is retracted on the same sequential downstroke. This punch actuation sequence uniquely allows the paper stack to be inserted and retracted when the actuation handle 904 is in the lowered position.
All manual punching operations can be achieved by motorized means and be powered by battery DC or plug-in AC sources, and these types of punching mechanisms are well known in the marketplace today.
To punch covers and backs with the proper spacing, cover spacing guide 606 can be utilized to ensure the cover and back pages are punched properly. Typically covers and backs are dimensionally larger than the pages which are to be bound in-between. Spacing guide 606 is designed to move outwards by a preset range (optionally adjustable by the operator) which in turn shifts the alignment of binding hole punch slot 602 in a manner as to accommodate the larger cover and back sheets. As an alternative embodiment, the spacing guide can be configured to return to its default position (non-cover spacing position) after the punching cycle, to ensure the operator engages the spacing guide 606 only as needed and doesn't inadvertently leave it in the incorrect position and create waste due to incorrectly punched pages.
After a cover or back has been punched, or when the operator is ready to bind the pages with a comb, plastic comb 320 can be inserted into binding assembly 300, in this case a comb spreader assembly, (other binding systems would include a metal comb versus plastic comb 320 and the corresponding metal comb holder and crimper, a document clamp and spiral binder spinner, etc.), placing the plastic comb 320 behind and aligned with comb retainer 302 ensuring the comb is engaged with comb prongs 304. Prong lever 308 is pulled towards the front of the machine which in turn slides the comb prongs 304 toward the front of the machine, which then opens or expands plastic comb 320. The operator then places either the previously punched cover or back onto the expanded plastic comb 320, and then the sequentially corresponding pages with the cover or back then being the last one inserted, depending on how the operator has initiated their document stacking order. Once the entire document has been assembled, prong lever 308 is actuated in the reversed direction to release plastic comb 320, allowing it to retract to its natural state securing all the document's pages within.
The foregoing disclosure of specific embodiments is intended to be illustrative of the broad concepts comprehended by the invention.
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