FORMATTER CAGE

Abstract

A formatter cage is disclosed. The formatter cage includes a three point mounting system for expansion modules.

Description

BACKGROUND

Some printers or multi-function devices can be customized by installing expansion modules into the device. The expansion modules may be able to add a number of different features to the printer, for example a hard disk drive, a different type of input/output (I/O) port, a different internet connection protocol, additional USB ports, a USB hub, a security module and the like. Most of these expansion modules are attached to the formatter board of the printer.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an example multi-functional peripheral (MFP) with a formatter cage installed in the printer.

FIG. 2 is an isometric view of an example formatter cage 202.

FIG. 3 is a close up of the example cage from FIG. 2.

FIG. 4 is a close up of the example cage from FIG. 2 with an example expansion module 440 installed.

FIG. 5 is a sectional view AA of FIG. 4.

FIG. 6 is an isometric view of an example expansion module 660.

FIG. 7 is an isometric view of another example expansion module 760.

DETAILED DESCRIPTION

Printers are sold at different price points. The lowest price point printer has a base set of features. Each increase in the price point has a corresponding increase in the feature set for a printer. Some users want to increase the feature set of their printers beyond the feature set of a given price point, but do not need all the features included in the next higher price point. Other users may want a single feature that is only available in the highest price point printer. Yet other users may want to add features to their primers that are not currently available in any of the printers currently for sale.

In one example, a printer will support expansion modules that can be installed into the printer. In some examples the printer is a standalone printer. In other examples the printer may be a component of a multi-functional device (MFD). MFD are also known as multi-functional peripherals (MFP) or All-in-One (AiO) devices. Some expansion modules may he provided by the company that produced the printer and other expansion modules may be provided by companies other than the printer manufacturer. The expansion modules may be able to add a number of different features to the printer, for example a hard disk drive, a different type of input/output (I/O) port, a different internet connection protocol, additional USB ports, a USB hub, a security module and the like.

Printers typically include a formatter. The formatter is typically implemented as a printed circuit board (PCB). The formatter receives incoming print data and formats the data so that the data can be sent to a print engine. The print engine may be a LaserJet engine, an inkjet engine or the like. The formatter PCB is typically mounted in a card cage and the card cage is mounted in the printer. The card cage is typically used to hold the formatter PCB and used to reduce the electro-magnetic radiation (EMI) and radio frequency radiation (RFI) emitted by the formatter PCB. The card cage is also known as the formatter cage. In some examples the card cage with the formatter attached is designed to be removable from the printer by the user. This allows the user to install expansion modules onto the formatter. In other examples the card cage is accessible through a door in the printer.

FIG. 1 is an isometric back view of an example multi-functional peripheral (MFP) 100 with a formatter cage installed in the printer. MFP 100 comprises a printer 101 and a scanner 105. MFP 100 can use the printer and scanner as standalone devices for printing, scanning and faxing documents, or can use the printer and scanner in combination to copy documents. Formatter cage 102 is shown installed in printer 101. The MFP 100 is coupled to a network or other devices by connecting cables to the formatter card through openings in the formatter cage.

FIG. 2 is an isometric view of an example formatter cage 202. Formatter cage 202 comprises a base 208, two sides (201 and 216), a back plate 212, a faceplate 214, a lid 204 and a formatter PCB 206. The cage is typically formed from a single piece of sheet metal, but could also be a molded metal part. The two sides (210 and 216), the back plate 212, and the faceplate 214 are perpendicular to the base and form an enclosed volume. The base 208 has a top side facing the enclosed volume. The formatter PCB 206 is mounted to the top side of the base inside the enclosed volume with 4 screws 235 (see FIG. 3). The door 204 is removably attachable to the cage with a series of tabs along one end that fit into slots in the back plate 212. The door is shown detached from the cage in FIG. 2.

FIG. 3 is a close up of the example cage from FIG. 2. FIG. 3 shows a connector 330 mounted to the top side of the formatter PCB 206. In one example the connector 330 is a Peripheral Component Interconnect Express (PCIe) 1X connector. Other types of connectors may also be used, for example USB connectors. The formatter PCB 206 also has a mounting hole near the edge of the formatter PCB 206 that is adjacent to the side 210 of cage 202. A slot 332 is formed in the faceplate 214. In one example, the slot 332 is formed inside a knockout area 334 in faceplate 214. The connector 330, the mounting hole 336 and the slot 332 form a three point mounting system for expansion modules. In some examples all three mounting points are used to secure the expansion module into the formatter cage. In some example, when the expansion module is below a weight threshold, only two mounting points may be used (the slot and the connector).

FIG. 4 is a close up of the example cage from FIG. 2 with an example expansion module 440 installed. Expansion module 440 has a tab 442 that fits in 334. Expansion module 440 also comprises a PC board 448. The PC board is perpendicular to the formatter PCB. A male connector tab on the PC board (see FIG. 6) fits into connector 330 and a locking clip on the expansion module, which clips to connector 330, holds expansion module 440 in place.

The volume available for expansion module 440 has been maximized. The length L of the available volume runs from the edge of connector 330 to the faceplate 214. The width W of the volume runs from one side 210 of cage 202 to the Application specific integrated circuit (ASIC) 444. In one example the length available to an expansion module is 118 mm and the width is 78 mm. The height or depth of the volume has been maximized. The height of all the components mounted under the area covered by the expansion module is below a threshold height. All the taller components have been moved out from under the area covered by the expansion module 440. For example the ASIC 444 and formatter power components 446 have been relocated away from the area coved by the expansion module 440. The area 450 to the left of the formatter PCB 206 is reserved for other components of the printer.

FIG. 5 is a sectional view AA of FIG. 4. FIG. 5 shows cage 202 comprising base 208 and two sides (210 and 216). Formatter PCB 206 is mounted in cage 202 on base 208. Expansion module 440 is shown mounted in cage 202. All the components (562) mounted under the expansion module 440 are below a height threshold 560. In one example the height threshold is 11.3 mm. The ASIC 444 and power components 446 are shown mounted on formatter PCB 206. The ASIC b 444 and power supply components 446 are taller than the height threshold 560 and are mounted on areas of the formatter PCB that are not underneath the expansion module 440. For example the bulk capacitors in the power supply components are 14 mm high and the micro USB connector & plug is 28.5 mm high. Keeping the components mounted underneath the expansion module 440 below a height threshold maximizes the depth D that the expansion module can occupy. In one example the depth available to an expansion module is 19 mm.

The lid 204 is easily opened and closed which allows user access into cage 202 to install expansion modules. The lid 204 is also removable from the cage 202. In some examples expansion modules will include a built in lid replacement. This gives the expansion module some additional depth that can be used.

FIG. 6 is an isometric view of an example expansion module 660. Expansion module 660 allows a disk drive to be added to the printer. Expansion module 660 comprises a disk drive 668, a PC board 648, and a mounting frame 669. PC board 648 is mounted to disk drive 668 in a vertical orientation. PC board 648 has male connector tabs 664 formed along the bottom edge of the PC board 648. The male connector tabs 664 fit into, and couple with, the connector 330 mounted on the top side of formatter PCB 206.

Mounting frame 669 is attached to disk drive 668 and surrounds disk drive 668. Mounting frame 669 comprises a tab 642, a clip 666 and a mounting post 662. Tab 642 fits in slot 332 in faceplate 214. Clip 666 snaps over connector 330 and holds expansion module 660 in place. Mounting post 662 comprises two cantilevered tabs that snap into mounting hole 336 (see FIG. 3) in formatter PCB 206. Mounting post may use other attaching devices, for example a screw.

FIG. 7 is an isometric view of another example expansion module 760. Expansion module 760 allows an additional network port to be added to the printer. Expansion module 760 comprises a network interface card 772 and a PC board 748. PC board 748 is mounted to network interface card 772 in a vertical orientation. PC board 748 has male connector tabs 764 formed along the bottom edge of the PC board 748. The male connector tabs 764 fit into, and couple with, the connector 330 mounted on the top side of formatter PCB 206.

Network interface card 772 includes a network connector 770. Network connector is wider than slot 332 formed in faceplate 214. To install this expansion module the knockout portion 334 formed in faceplate 214 needs to be removed. Once the knockout portion 334 is removed, network connector 770 fits through the larger opening. Threaded holes are provided in the expansion module on either side of network connector. Holes on either side of the knockout portion allow screws to hold the end of expansion module 760 in place. Expansion module 760 is below a weight threshold and only uses two of the three mounting points in the three point mounting system in cage 202 (i.e. the connector 330 and the slot/knockout hole in faceplate 214).

In some examples, more than one expansion module may be installed in a printer. The first expansion module will be installed inside case 202 with a connector sticking through the knockout hole in faceplate 214. A second expansion module may attach to the connector of the first expansion module that is sticking through the knockout hole in faceplate 214.

In one example the connector 330 mounted on formatter PCB is a PCIe 1X connector. When the connector 330 is a PCIe 1x connector, the PC board (648 and 748) on the expansion module is a PCI Express card. The following table identifies the conductors on each side of the edge connector on a PCI Express card. The solder side of the printed circuit board (PCB) is the A side, and the component side is the B side. PRSNT1# and PRSNT2# pins must be slightly shorter than the rest, to ensure that a hot-plugged card is fully inserted.

PCI express × 16 connector pinout
Pin	Side B	Side A	Comments
1	+12 V	PRSNT1#	Must connect to furthest-apart PRSNT2#
2	+12 V	+12 V
3	+12 V	+12 V
4	Ground	Ground
5	SMCLK	TCK	SMBus and JTAG port pins
6	SMDAT	TDI
7	Ground	TDO
8	+3.3 V	TMS
9	TRST#	+3.3 V
10	+3.3 V aux	+3.3 V	Standby power
11	WAKE#	PERST#	Link reactivation; power and REFCLK
			stabilized
Key notch
12	Reserved	Ground
13	Ground	REFCLK+	Reference clock differential pair
14	HSOp(0)	REFCLK−	Lane 0 transmit data, + and −
15	HSOn(0)	Ground
16	Ground	HSIp(0)	Lane 0 receive data, + and −
17	PRSNT2#	HSIn(0)
18	Ground	Ground
PCI ×1 board ends at pin 18

The definitions for all the signal lines in the PCIe 1X connector will conform to the PCIe standard. The PCIe standard for a 1X connector requires two power rails or outputs. One power rail supplies 3.3 volts and another power rail supplies 12 volts. In some examples the formatter PCB may not have a 12 volt source. In this case the definition for the power lines in the PCIe 1X connector will he modified. Instead of supplying 12 volts on one rail and 3.3 volts on the other rail, the PCIe 1X connector will supply a non-standard voltage, for example 5 volts, on one rail and 3.3 volts on the other rail.

The 3.3 volt power rail in the PCIe 1X connector will be enabled whenever the formatter PCB is powered up. In some examples the non-standard voltage power rail in the PCIe 1X connector will not be enabled unless the expansion module has an identification code (IC) that indicates that the expansion module is compatible/compliant with the non-standard voltage. One way to retrieve the IC from the expansion module is to use the standard PCie signal lines in the PCie connector to communicate with the installed expansion module. Another way is to use side band communication on the 3.3 volt power rail. Side band communications is also known as Inter-Integrated Circuit or I²C. Using either method of communication, the IC of the installed expansion module can be retrieved and compared to a stored list if ICs that indicate that the installed expansion module is compatible/compliant with the non-standard voltage.

Once installed, expansion modules can communicate with the formatter PCB through connector 330. The installed expansion modules will use the standard protocol for the type of connector installed. For example when the connector is a PCie 1X connector, the expansion module will use the PCIe protocol to communicate with the formatter. When the connector is a USB connector, the expansion module will use the USB protocol to communicate with the formatter. cm 1. A formatter cage, comprising:

• • a base attached to two side plates, a back plate, and a faceplate, where the two side plates, the back plate, and the faceplate extend from the base to form an enclosed volume and where a top side of the base is in the enclosed volume;
  • a formatter printed circuit board (PCB) mounted to the top side of base;
  • a connector mounted on a top side of the formatter PCB; and
  • a slot in the faceplate, where the slot and the connector form a two-point mount for an expansion module, the connector to interface with the expansion module when the expansion module is received in the slot.

Claims

2. The formatter cage of claim 1, further comprising a hole adjacent to the slot.

3. The formatter cage of claim 1, further comprising a knockout section in the faceplate, wherein the knockout section is removably disposed in the slot.

4. The formatter cage of claim 3, further comprising a pair of holes on opposite sides of the knockout section.

5. The formatter cage of claim 3, further comprising a hole on each of two opposite sides of the slot to receive screws to hold an end of the expansion module.

6. The formatter of claim 1, wherein the formatter PCB is to supply a voltage on a power rail of the connector and the voltage varies based on an identification code supplied by the expansion module to the PCB.

7. The formatter of claim 1, wherein, based on an identification code supplied by the expansion module, the formatter PCB supplies a first non-zero voltage and a second, different non-zero voltage.

8. A printer comprising:

a housing;

a formatting cage mounted inside the housing, the formatter cage comprising a base connected to two side plates, a back plate, and a faceplate, where the two side plates, the back plate, and the faceplate extend from the base to form an enclosed volume and where a top side of the base is in the enclosed volume;

a formatter printed circuit board (PCB) mounted to the top side of the base; and

a knockout in the faceplate, the knockout removable to allow mounting of a larger formatter PCB.

9. The printer of claim 8, wherein the knockout comprises a plurality of knockouts including a first knockout to accommodate a first expansion module and a second knockout to accommodate a second expansion module.

10. The printer of claim 9, wherein the second expansion module connects directly to the first expansion module.

11. The printer of claim 9, wherein the first and second expansion modules are independently selected from the following group of expansion module types: a hard disk drive expansion module, as input/output (I/O) port expansion module, an internet card expansion module, a universal serial bus (USB) port expansion module, a USB hub expansion module, and a security expansion module.

12. The printer of claim 9, further comprising an expansion module mounted to the formatter PCB, wherein the expansion module provides an identification code which modifies a first voltage supplied to a power rail by the formatter PCB.

13. The printer of claim 12, wherein the formatter PCB supplies a second, different, non-zero voltage to the expansion module.

14. A printer comprising:

a formatter cage having a faceplate;

a knockout in the faceplate of the formatter cage to provide or enlarge a slot in the faceplate and

a module mourned through the slot in the faceplate and connected to a plug connector of the printer, wherein the mounted module has at most three points of physical contact with other components of the printer including at the slot, at the plug connector, and at a third contact that supports the module.

15. The printer of claim 14, wherein the third contact comprises a screw.

16. The printer of claim 14, wherein the mounted module only makes physical contact at the slot and at the plug connector.

17. The printer of claim 14, further comprising:

a second knockout in the faceplate to expand the slot in the faceplate; and

a second module mounted in the expanded slot of the faceplate.

18. The printer of claim 14, wherein the printer is part of a multifunctional device.

19. The printer of claim 14, wherein the module comprises a hard drive.

20. The printer of claim 14, wherein the module comprises a USB hub.