Abstract:
An improved read/write head for use in computer hard drives is provided. In one embodiment, the read/write head includes first and second thermally conducting plates and a first and second stage of microcoolers. The second thermally conducting plate is thermally coupled to a read sensor of the read/write head. The second microcooler includes a hot plate and a cold plate, wherein the cold plate extends proximate the read sensor so as to cool the sensor to ambient or below temperatures. The first thermally conducting plate extends between the write coil and the read sensor in the read/write head and is thermally coupled to the hot plate of the second microcooler. The hot plate of the first microcooler is thermally coupled to one or more heat dissipation elements.

Description:
CROSS REFERENCE TO RELATED PATENTS 
     The present application is related to U.S. Pat. No. 6,105,381 entitled “METHOD AND APPARATUS FOR COOLING GMR HEADS FOR MAGNETIC HARD DISKS” issued Aug. 22, 2000 and to U.S. patent application Ser. No. 09/734,113 “THERMOELECTRIC MICROCOOLERS FOR COOLING WRITE COILS AND GMR SENSORS IN MAGNETIC HEADS FOR DISK DRIVES” filed even date herewith. The contents of the above mentioned commonly assigned U.S. Patent and co-pending U.S. Patent Application are hereby incorporated herein by reference for all purposes. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Technical Field 
     The present invention relates generally to data storage devices within data processing systems and more particularly to a method and apparatus for alleviating elevated temperatures within the read/write head of a hard disk type data storage devices. 
     2. Description of Related Art 
     The requirement for high density magnetic storage of data on hard disk drives has been increasing steadily for the past several years. Hard disk drives include magnetic heads for reading and writing data to the hard disk. The heads include write coils and sensors for reading data from the disks. For purposes of the ensuing description of the assembly including the write coil and yoke will be referred to as the “write coil” and the assembly including the magnetoresistive sensor situated between magnetic shields will be referred to as the “read sensor” 
     Miniaturization of magnetoresistive (MR) sensors for disk drives in the early 1990&#39;s allowed disk drive products to maximize storage capacity with a minimum number of components. Fewer components result in lower costs, higher reliability, and lower power requirements for the hard disk drives. 
     MR sensors are used for the read element of a read/write head. MR sensors read magnetically encoded information from the magnetic medium of the disk by detecting magnetic flux stored in the magnetic medium of the disk. As storage capacity of disk drives has increased, the storage bit has gotten smaller and its magnetic field has correspondingly become weaker. MR heads are more sensitive to weaker magnetic fields than are the inductive read coils used in earlier disk drives. Thus, the move away from inductive read coils and to MR sensors for use in disk drives. 
     As discussed above, MR sensors are known to be useful in reading data with a sensitivity exceeding that of inductive or other thin film sensors. However, the development of Giant Magnetoresistive (GMR) sensors (also referred to as GMR head chips) has greatly increased the sensitivity and the ability to read densely packed data. Thus, although the storage capacity for MR disks is expected to eventually reach 5 gigabits per square inch of surface disk drive (Gbits/sq.in.), the storage capacity of GMR disks is expected to exceed 100 Gbits/sq.in. 
     The GMR effect utilizes a spacer layer of a non-magnetic metal between two magnetic metals. The non-magnetic metal is chosen to ensure that coupling between magnetic layers is weak. GMR disk drive read sensors operate at low magnetic flux intensities. When the magnetic alignment of the magnetic layers is parallel, the GMR sensor resistance is relatively low. When the magnetic alignment of the layers is anti-parallel, the resistance is relatively high. Heat generated in the read/write head together with heat from other components within the disk drive materially affects the operating temperature of the GMR read sensor in the head. 
     As GMR sensors allow extremely high data densities on disk drives, a stable sensor temperature is essential to accurately read operations in high track density hard disk drives. It is well known that the signal to noise ratio of GMR read sensors increases with a decrease in temperature. Various methods of cooling hard disk drive components are known and include forced air, cooling fins, and heat pipes. Generally, the cooling methods have been limited to attaching materials or structures that have high thermal conductivities to transfer heat away from the head. However, due to space limitations and ambient conditions, means for cooling, whether to ambient or subambient temperatures, are generally not available to the GMR read sensor. 
     As the requirements for the GMR read sensors have been increasing over the years, the requirements for the write coils within the disk drives have also been increasing. New disk drives require fast field reversal during the write operation. This requirement for fast field reversal during the write operation implies larger write currents. Also, as the storage densities increase, the media coercivity has to increase to avoid thermal instability and the superparamagnetic limit. This reinforces the need for even larger write currents. However, large write currents increase the Joule heating in the coil such that the coil temperatures are 40 to 80 degrees Celsius above ambient temperatures. However, for optimal operation, the write coils need to be kept near ambient temperatures. Furthermore, since the write coil is immediately adjacent the GMR read sensor in the head, the heating and elevated temperatures are shared by the GMR read sensor. 
     Therefore, it would be desirable to have a method and apparatus for cooling the GMR read sensor and the write coils in the heads of hard disk drives that would be practical and fit within the structure of the head without requiring serious structural changes to the hard disk drive. Cooling GMR read sensors would significantly enhance magnetic sensing capacity of the GMR read sensors during the read operation and increase performance of the write coils during a write operation. It would also be desirable to provide a practical method for cooling the heads to subambient temperatures that would allow the utilization of GMR materials that have significantly higher sensitivities. 
     SUMMARY OF THE INVENTION 
     The present invention provides an improved read/write head for use in computer hard drives. In one embodiment, the read/write head includes first and second thermally conducting plates and a first and second stage of microcoolers. The second thermally conducting plate is thermally coupled to a read sensor of the read/write head. The second microcooler includes a hot plate and a cold plate, wherein the cold plate extends proximate the read sensor so as to cool the sensor to ambient or below temperatures. The first thermally conducting plate extends between the write coil and the read sensor in the read/write head and is thermally coupled to the hot plate of the second microcooler. The hot plate of the first microcooler is thermally coupled to one or more heat dissipation elements. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The novel features believed characteristic of the invention are set forth in the appended claims. The invention itself, however, as well as a preferred mode of use, further objectives and advantages thereof, will best be understood by reference to the following detailed description of an illustrative embodiment when read in conjunction with the accompanying drawings, wherein: 
     FIG. 1 depicts a cut-away, top plan view of a data storage system in accordance with the present invention; 
     FIG. 2 depicts a high-level conceptual diagram of a Thermoelectric Cooling (TEC) device; 
     FIG. 3 depicts a planar view of a read/write head with cold plate using single stage thermoelectric microcoolers in accordance with the present invention; 
     FIG. 4 depicts a planar view of a read/write head with cold plate using selectively acting two stage thermoelectric coolers in accordance with the present invention; and 
     FIG. 5 depicts a conceptual diagram of a two stage thermoelectric cooler in accordance with the present invention. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     With reference now to the figures, and in particular with reference to FIG. 1, a cut-away, top plan view of a hard disk data storage system is depicted in accordance with the present invention. Data storage system  100  includes a housing  101  containing at least one rotatable data storage disk  102  supported on a spindle  105  and rotated by a drive motor (not shown). Typically, a data storage system will comprise a plurality of disks and a slider  106  with a read/write head  104  for each disk. As an example, in a magnetic disk storage device, each data storage disk  102  has the capability of receiving and retaining data, through the use of a magnetic recording medium formed on at least one disk surface  103 , where the magnetic recording medium is arranged in an annular pattern of multiple concentric data tracks  108 . Though only a few data tracks  108  are shown, it is known that the number of tracks varies according to at least the recording medium and the read/write head  104 . At least one slider  106 , including one or more read/write heads  104  is positioned over data storage disk  102 . Slider  106  is suspended from an actuator arm (not shown) by a suspension (also not shown) and the radial position of slider  106  with respect to data tracks  108  of data storage disk  102 , is controlled by a voice coil motor (not shown). 
     During operation of data storage system  100 , the rotation of data storage disk  102  generates an air bearing between head  104  and disk surface  103 . The air bearing counterbalances a slight downward-biased spring force of the suspension and supports head  104  above disk surface  103  by a small, substantially constant spacing. As disk  102  is rotated by the drive motor, slider  106  is moved radially in and out in response to the movement of the actuator arm by the voice coil motor, permitting read/write head  104  to read and write data from and to the concentric tracks  108 . Though only one read/write head  104  and slider  106  assembly is shown, it is well known that a plurality of sliders  106  may be employed to access a plurality of disks  102 , stacked one atop the other on spindle  105 . 
     The temperature of read/write head  104  may rise during operation of data storage drive  100  due to previously discussed magnetic field changes and ambient conditions in data storage system  100 . The primary contributor of heat is the write coil. Magnetic instability may arise in read/write head  104  due to increasing read/write head  104  temperatures. Higher temperature increases the Johnson voltage noise of the read sensor and decreases the net signal to noise capability of the read sensor. 
     According to the present invention, a thermoelectric microcooler, is mounted on the read/write head  104  and thermally coupled to a cold plate situated between the write coil and the read sensor to provide active heat transfer of the energy dissipated by the write coil. Also, the microcooler device may utilize a separate power source or the same power source as the read/write head  104 . Though Peltier effect thermoelectric cooling (TEC) devices are used to cool many heat producing components such as, for example, blood analyzers, lasers, and microprocessors, lack of efficiency and size has limited their applications. 
     With reference to FIG. 2, a high-level block diagram of a generic TEC device  200  is depicted. Thermoelectric cooling, a well known principle, is based on the Peltier effect, by which DC current from power source  202  is applied across two dissimilar materials causing heat to be absorbed at the junction of the two dissimilar materials. A typical thermoelectric cooling device utilizes p-type semiconductor  204  and n-type semiconductor  206  sandwiched between poor electrical conductors  208  that have good heat conducting properties. N-type semiconductor  206  has an excess of electrons, while p-type semiconductor  204  has a deficit of electrons. As electrons move from p-type semiconductor  204  to n-type semiconductor  206  via electrical conductor  210 , heat energy is transferred from cold plate  212  to hot plate  216 . 
     With reference now to FIG. 3, a schematic diagram of a read/write head  300  for a disk drive is depicted in accordance with the present invention. The read/write head  300  includes a read sensor  308 , bond pads  392 - 397 , and a cold plate  302 . The cold plate  302  is situated between the GMR read sensor and the write coil of read/write head  300 . The relative position of the actual coils is depicted at  312 , while the relative position of the magnetic shields is depicted at  310 . Their functions and locations are well known. In one embodiment, cold plate  302  includes a patterned ring of copper (Cu) or tungsten (W). Given that cold plate  302  is electrically conducting, as is depicted in the present example, then cold plate  302  should be patterned with radial grooves  311  to electrically segment the cold plate such that eddy currents are suppressed. Thereby the coupling effects of the magnetic field produced by the are minimized. 
     In one embodiment, the read/write head  300  includes two thermoelectric microcoolers  356  and  357  thermally coupled to cold plate  302  and on the hot side to copper posts  320 . Heat is thereby transferred from the cold plate, lying between the write coil and read sensor, to the disk drive interior ambient. Microcoolers  356 - 357  are fabricated using an electrodeposition method, which is a low temperature post-processing step after the head fabrication. More information regarding the fabrication of microcoolers is available in U.S. patent application Ser. No. 09/498,826 filed on Feb. 4, 2000 which is hereby incorporated by reference for all purposes. 
     In the prior art, a simple cooling plate of copper placed proximate the write coil and read sensor is thermally connected to copper posts without an intervening active cooling device. Thus, in the prior art, the read/write head write coil and adjacent read sensor were always at a temperature well above the disk drive interior ambient. The inclusion of the thermoelectric coolers  356 - 357  allows the write coils and read sensor of read/write head  300  to be actively cooled to a temperature less than in the prior art. Since the permeability of the yoke of the write coil and the signal to noise performance of the read sensor are sensitive to temperature, the use of microcoolers  356 - 357  in read/write head  300  greatly improves multiple aspects of the read/write head  308  performance. Also, since most of the heat is generated by the write coils, the shape and location of cold plate  311  should align with the write coils. 
     The plurality of copper posts  320  may be constructed from other material that is a good conductor of heat. Alternatively, posts  320  may be replaced by fins. 
     With reference now to FIGS. 4, a planar view of a read/write head  400  with two stage microcoolers is depicted in accordance with the present invention. In this embodiment, in addition to stage one microcoolers  356  and  357  as depicted in FIG. 3, stage two microcoolers  362 - 364  have also been included in the read/write head  400 . In all other regards, the read/write head  400  is similar to read/write head  300  in FIG.  3 . By using a two stage microcooler, the GMR read sensor  308  may be cooled to a point beyond that possible with the use of a single stage microcooler in further recognition of the temperature sensitivity exhibited by read sensor  308 . 
     The cold plate  306  is thermally coupled to thermoelectric coolers  356 - 357  which are each in turn thermally coupled to posts  320 . The cold plate of second stage thermoelectric microcoolers  362 - 364  is thermally coupled to arm  366 , which is constructed from a thermally conductive material, such as, for example, copper, extends beneath but in close thermal proximity to GMR read sensor  308 . The hot plate of second stage microcoolers  362 - 364  is thermally coupled to cold plate  306 . Thus, the read sensor  308  is cooled to an even lower temperature than the write coils cold plate, and possibly event to subambient levels. 
     Because the read head generates much less heat than do the write coils, the second stage microcoolers  362 - 364  do not need to be as large as the first stage microcoolers  356 - 357 . For similar reasons, arm  366 , which serves as the cold plate for second stage microcoolers  362 - 364  does not need to be as large as cold plate  306 . 
     Also, because the physical size of the read/write head elements depicted in FIGS. 3 and 4 are determined by the bond pads, which require much more room than is necessary to implement the basic write coils and read sensor, the cold plates and microcoolers may be included in the read/write head without materially increasing the size of the read/write head. 
     With reference now to FIG. 5, a schematic diagram of a two stage thermoelectric cooler is depicted in accordance with the present invention. Two stage thermoelectric cooler  500  may be implemented as, for example, stage one microcooler  356  and stage two microcooler  364  in FIG.  4 . Two stage microcooler  500  includes a first stage microcooler comprising p-type impurity thermoelectric material elements  502  and  504  and n-type impurity thermoelectric material elements  506  and  508 . Two stage microcooler  500  also includes a second stage comprising p-type impurity thermoelectric material element  510  and n-type impurity thermoelectric material element  512 . 
     A current I 0  is connected by conductor to thermoelectric material elements  502  and  504 . The current I 0  is split into I 1  and I 2 . Current I 1  passes through thermoelectric material element  504  and through region thermoelectric element  506 . Current I 2  passes through thermoelectric material elements  502 ,  510 ,  512 , and  508 . The cold plate for the first stage microcooler is between the first stage and the second stage and is the hot plate for the second stage microcooler. 
     The description of the present invention has been presented for purposes of illustration and description, and is not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention, the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.